Danfoss Drives

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MAKING MODERN LIVING POSSIBLE Engineering Guide HVAC & Refrigeration applications Facility services design and project engineering of electrical drives 4 steps .to a safe installation Danfoss supports your planning with our longstanding experience www.danfoss.com/drives

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The removable design checklist at the back of this guide leads you to optimal design results in four steps. 2

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Contents Design aids . Part 1: Basics. Reducing costs and increasing convenience . Speed control saves energy . Boosting cost effectiveness . Achieving potential savings in practice . Part 2: Four steps to an optimal system . Step 1: Practical aspects of AC mains systems . Recognising the actual mains configuration Practical aspects of electromagnetic compatibility (EMC) . Electromagnetic effects work in both directions The responsibility rests with the operator Two possible means of reduction Distinguishing between conducted and radiated interference. Coupling mechanisms between electrical circuits Conductive coupling Capacative coupling Radioation coupling 6 8 8 9 10 11 12 12 13 14 Practical aspects of mains power quality . 15 Low-frequency mains interference Supply networks at risk Quality assured by statutory provisions How mains interference occurs Practical aspects of low- frequency mains interference . 16 Effects of mains interference Undervoltage warnings Higher losses Are interference- free frequency converters available ? Analysing mains interference Practical aspects of mains interference reduction . 17 Options for reducing mains interference Chokes at the input or in the DC link Rectifier with 12, 18 or 24 pulses per cycle Passive filters Advantages of passive filters Drawbacks of passive filters Active filters . 18 Advantages of active filters Drawbacks of active filters Current and Distortion Spectrum at Full load Slim DC link . 19 Active front end Advantages of AFE . 20 Drawbacks of AFE Practical aspects of high-frequency interference (RFI) . 21 Radio frequency interference Standards and directives define limits Practical aspects of 1st and 2nd environment .22 The operating site is the decisive factor Environment 1 (Class B): residential environment Environment 2 (Class A): industrial environment Special environments No compromises Practical aspects of mains protection measures . 23 Power factor correction Mains transients Practical aspects of operation with a transformer or standby generator . 24 Maximum transformer utilisation Transformer load Power quality Operation with a standby generator 3

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Contents Step 2: Practical aspects of ambient and environmental conditions . 25 The right installation location Cabinet mount versus wall mount Practical aspects of enclosure ratings . 26 IP rating scheme according to IEC 60529 NEMA enclosure types according to NEMA 250-2003 Practical aspects of cooling design . 27 Compliance with ambient temperature specifications Cooling Relative humidity Practical aspects of special requirements . 28 Aggressive atmosphere or gases Dust exposure . 29 Reduced cooling Cooling fans Filter mats Practical aspects of potentially explosive atmospheres . 30 Potentially explosive atmospheres Step 3: Practical aspects of motors and cabling . 31 Minimum efficiency classes for motors Mandatory minimum efficiencies IE and Eff classes: major differences in details Affected three-phase motors Practical aspects of IE classification of motors. 32 Schedule for MEPS implementation Compliance with EN 50347 mounting dimension specifications Cost-effectiveness Practical aspects of EC and PM motors . 33 What are EC Motors ? Efficiency of EC Motors PM-motors – an alternative to EC ? The Danfoss EC+ concept . 34 Does the best motor efficiency yield the best system efficiency ? Practical aspects of motor suitability for frequency converter operation . 35 Selection criteria Insulation stress Bearing stress Thermal stress Practical aspects of output filters . 36 Sine-wave and du/dt filters Functions and tasks of sine-wave filters When are sine-wave filters used? Retrofitting Practical aspects of motor cables . 37 Rated voltage Cable dimensioning Motor cable length Energy savings Cables with suitable shielding Practical aspects of earthing. 38 The importance of earthing Electrically conductive materials Star-configured earthing system Contact points Conductor surface area 4

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Practical aspects of shielding . 39 The importance of shielding Shielded cables and wiring Shield connection Shield gaps Ground connection .40 Motor supply cable Signal cable Types of shields Step 4: Practical aspects of frequency converter selection . 41 Basic design Constant or variable torque Practical aspects of load curves for HVAC/R applications . 42 Characteristic curves and applications Practical aspects of multi-motor operation (special case) . 43 Design Cable routing Practical aspects of EMC measures . 44 Putting theory into practice Radio frequency interference Practical recommendations Two approaches to RFI filters Mains interference .45 The DC link affects mains interference Reduction measures Mains chokes Rectifiers with 12, 18 or 24 pulses per cycle. 46 Passive filters Active filters, active front ends and low harmonic drives Practical aspects of residual current devices . 47 AC/DC residual current protective devices Leakage current level Practical aspects of earthing and motor protection. 48 Earthing measures in practice Motor protection and motor PTC thermistor Practical aspects of operator control and data display . 49 Simple operating concept Operation under local control.50 Clear display Uniform concept Integrated in the cabinet door Practical aspects of control and parameter configuration with a PC . 51 Extended options Practical aspects of data exchange . 52 Bus systems Better alarm management Better facility management Lower installation costs Simplified commissioning Practical aspects of additional selection factors . 53 Process controller Maintenance Storage VLT® HVAC Drive . 54 Directives related to frequency converters . 55 Index. 56 Abbreviations . 59 Notes. . 60 Design checklist . 62 5

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Design aids for high-level and detailed design Engineering Guide for HVAC/R applications The Danfoss Engineering Guide for HVAC and Refrigeration applications is aimed at engineering firms, public authorities, associations, plant engineers and electrical engineers actively involved in HVAC/R technology. It is conceived as a comprehensive aid for facility services designers (ICA and electrical) and project engineers whose scope of responsibility includes the project engineering of variable-speed systems using frequency converters. For this purpose, our specialists have coordinated the contents of this design manual with facility services designers in the industry in order to provide answers to important questions and achieve the greatest possible benefits for property owners/developers and/or contracting authorities. The descriptions in the individual sections are intentionally concise. They are not intended to serve as extensive explanations of technical matters, but instead to point out the relevant issues and specific requirements for project engineering. In this way, the Engineering Guide for HVAC/R applications provides assistance in the project engineering of frequency-controlled drives and in the assessment of the products of various manufacturers of frequency converters. Project engineering of variable-speed drives often gives rise to questions that are not directly related to the actual tasks of a frequency converter. Instead, they relate to the integration of these devices into the drive system and the overall facility. For this reason, it is essential to consider not only the frequency converter, but also the entire drive system. This system consists of a motor, a frequency converter, cabling, and the general conditions of the ambient situation, which includes the AC mains supply and the environmental conditions. Project engineering and layout of variable-speed drive systems are of decisive importance. The decisions made by the facility services designer or project engineer at this stage are crucial with regard to the quality of the drive system, operating and maintenance costs, and reliable, trouble-free operation. Well-conceived project engineering before- Anyone involved in the project engineering of frequency converters should give careful consideration to the general technical conditions of these devices. 6

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hand helps avoiding undesirable side effects during subsequent operation of the drive system. This engineering guide and included design checklist are ideal tools for achieving the best possible design reliability and thereby contributing to the operational reliability of the overall system. The Engineering Guide for HVAC/R applications is divided into two parts. The first part provides background information on the use of frequency converters in general. This includes the topics of energy efficiency, reduced life cycle costs and longer service life. The second part guides you through the four essential steps in the design and project engineering of a system and provides tips on retrofitting speed control capability in existing systems. It addresses the factors you must pay attention to in order to achieve reliable system operation – the selection and dimensioning of the mains power supply, the ambient and environmental conditions, the motor and its cabling and the selection and dimensioning of the frequency converter – and gives you all the information you need regarding these aspects. There is also a checklist at the back of the manual, which you can use to tick off the individual steps. If you take all of these factors into account, you can achieve an optimal system design that provides reliable operation at all times. 7

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Part 1: Basics Reducing costs and increasing convenience Compared with mechanical speed control systems, electronic speed control can save a lot of energy and substantially reduce wear. Both of these factors significantly reduce operating costs. The more often drive systems are operated (or must operate) under partial load, the higher the potential savings in terms of energy and maintenance costs. Due to the high potential for energy savings, the extra cost of an electronic speed control system can be recovered within a few months. In addition, modern systems have an extremely positive effect on many aspects of system processes and overall system availability. Reduced system wear Frequency converters start and stop motors gently and smoothly. Unlike motors operated directly from the AC mains, motors driven by frequency converters do not cause torque or load shocks. This reduces the stress on the entire drive train (motor, gearbox, clutch, pump/fan/compressor) and piping system, including the seals. In this way, speed control significantly reduces wear and prolongs the lifetime of the system. Maintenance and repair costs are lower thanks to longer operating periods and lower material wear. 50 Hz). This allows the output power to be boosted briefly. The extent to which oversynchronous operation is possible depends on the maximum output current and overload capacity of the frequency converter. In practice, pumps, compressors and fans are often operated at a frequency range of 55-87 Hz. The motor manufacturer must always be consulted regarding motor suitability for oversynchronous operation. Lower noise generation Systems running under partial load are quieter. Speed-controlled operation significantly reduces acoustic noise generation. High energy saving potential With an electronic speed control system, the flow, pressure or differential pressure can be matched to the actual demand. In practice, systems operate predominantly under partial load rather than full load. In case of fans, pumps or compressors with variable torque characteristics, the extent of the energy savings depends on the difference between partial-load and full-load operation. The larger this is, the less time is required to recover the investment. It is typically around 12 months. Optimal operating point adjustment The efficiency of HVAC/R systems depends on the optimal operating point. This point varies depending on system capacity utilisation. The system works more efficiently when it runs closer to the optimal operating point. Thanks to their continuously variable speed, frequency converters can drive the system at exactly the optimal operating point. Increased lifetime Drive systems operating under partial load suffer less wear, which translates into longer service life. The reduced, optimised pressure also has a beneficial effect on the piping. Retrofitting Frequency converters can usually be retrofitted in existing drive systems with little effort. Extended control range Frequency converters allow motors to be operated in the „oversynchronous“ range (output frequency above Start-up current limiting Switching on equipment connected directly to the AC mains generates peak currents that can be up to six to eight times greater than the rated current. Frequency converters limit the startup current to the rated motor current. In this way they eliminate switch-on current peaks and avoid voltage sags due to transient heavy loading of the supply network. Eliminating these current peaks reduces the connected load of the pump system as seen by the electricity supplier, which reduces provision costs and eliminates the need for supplementary Emax controllers. 8 Basics

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Speed control saves energy 100 80 Q, p, P [%] 60 40 20 0 0 20 40 60 Speed n [%] 80 100 Q p P Proportionality rules of fluid flow machines. Due to the physical relationships, the throughput Q, pressure p and power P are directly dependent on the machine speed with fluid flow machines. The energy saving potential when a frequency converter is used depends on the type of load being driven and the optimisation of the efficiency of the pump, compressor, fan or the motor by the frequency converter, as well as how much time the system operates under partial load. Many systems are designed for rarely-occurring peak loads, so they are usually operated under partial load. Centrifugal pumps and fans offer the largest potential for energy savings. They fall in the class of fluid flow machines with variable torque curves, which are subject to the following proportionality rules. The flow increases linearly with increasing speed (rpm), while the pressure increases quadratically and the power consumption increases cubically. The decisive factor for energy savings is the cubic relationship between rpm and power consumption. A pump running at half its rated speed, for example, needs only one-eighth of the power necessary for operation at its rated speed. Even small reductions in speed thus lead to significant energy savings. For example, a 20% speed reduction yields 50% energy savings. The main benefit of using a frequency converter is that speed control does not waste power (unlike regulation with a throttle valve or damper, for example), but instead adjusts the motor power to match exactly the actual demand. Additional energy savings can be achieved by optimising the efficiency of the fan, pump or motor with frequency converter operation. The voltage control characteristic (V/f curve) supplies the right voltage to the motor for every frequency (and thus motor speed). In this way, the controller avoids motor losses resulting from excessive reactive current. Remark: Danfoss VLT® HVAC Drive frequency converters optimise energy demand even further. The Automatic Energy Optimisation (AEO) function constantly adjusts the current motor voltage so the motor runs with the highest possible efficiency. In this way, the VLT® HVAC Drive always adapts the voltage to the actual load conditions it measures. The additional energy saving potential amounts to an extra 3 to 5%. For calculation of expected energy savings when using frequency converters, tools like the Danfoss VLT® Energy Box Software are available. 9

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Boosting cost effectiveness Life cycle cost (LCC) analysis Until a few years ago, plant engineers and operators only considered procurement and installation costs when selecting a pump system. Today a full analysis of all costs is becoming increasingly common. Under the name “life cycle cost” (LCC), this form of analysis includes all costs incurred by pump systems during their operational life. A life cycle cost analysis includes not only the procurement and installation costs, but also the costs of energy, operation, maintenance, downtime, the environment, and disposal. Two factors – energy cost and maintenance cost – have a decisive effect on the life cycle cost. Operators look for innovative controlled pump drives in order to reduce these costs. Example of reduced LCC: The VLT® HVAC Drive has a squareroot function for converting differential pressure readings into to a volumetric flow signal. This allows users to install less expensive sensors in order to reduce procurement costs (Cic). LCC = Cic + Cin + Ce + Co + Cm + Cs + Cenv + Cd Cic = initial capital cost (procurement cost) Cin = installation and commissioning costs Ce = energy cost Co = operating cost Cm = maintenance cost Cs = downtime and lost production costs Cenv = environmental cost Cd = decommissioning and disposal costs Life cycle cost calculation Reducing energy costs One of the largest cost factors in the life cycle cost formula is the energy cost. This is especially true when fans, pump systems or compressors run more than 2000 hours per year. Most existing applications have substantial dormant energy saving potential. This arises from the fact that most systems are overdimensioned because they are designed for worstcase conditions. The volumetric flow is often regulated by a throttle valve. With this form of regulation, the pump always runs at full capacity and thus consumes energy unnecessarily. This is comparable to driving a car with the engine always running at full throttle and using the brakes to adjust the speed. Modern, intelligent frequency converters offer ideal means to reduce energy consumption as well as maintenance costs. Pump curve ] Pressure [bar] 70% 80% 84% 84% 80% Power Valve control a) 50% 60% 70% 80% 84% 84% 84% Set point b) 60% c) Eﬃciency range 70% 80% 84% Speed control System curve 70% 80% 84% Eﬃciency range Speed [n] Flow [Q] 10 a) Valve control: η decreases b) Actual speed control: η curve not aligned to system curve c) Optimal speed control: η curve nearly matches system curve In addition to the pump and system characteristic curves, this plot shows several efficiency levels. Both valve control and speed control cause the operating point to move out of the optimum efficiency range. Basics

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Achieving potential savings in practice The descriptions in the first part of this design considerations focus primarily on the fundamentals and potential savings in HVAC technology. Among other things, they deal with life cycle costs, reducing energy consumption and reducing energy costs and reducing service and maintenance costs. Your task now is to carry out considered, intelligent design in order to achieve these potential benefits in reality. To this end, the second part of this manual guides you through the design process in four steps. The following sections: – Mains systems – Ambient and environmental conditions – Motors and cables – Frequency converters give you all the information about characteristics and data that you need for component selection and dimensioning in order to ensure reliable system operation. In places where more detailed knowledge is advantageous, we provide references to additional documents in addition to the basic information in this manual. The checklist included at the end of this manual, which you can fold out or tear out, is also a handy aid where you can tick off the individual steps. This gives you a quick and easy overview of all relevant design factors. By taking all these factors into account, you put yourself in an ideal position to design a reliable and energy-efficient system. 11

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Part 2 : Four steps to an optimal system Step 1: Practical aspects of AC mains systems Recognising the actual mains configuration Various types of AC mains systems are used to supply power to electrical drives. They all affect the EMC characteristics of the system to various degrees. The five-wire TN-S system is the best in this regard, while the isolated IT system is the least desirable. TN-C This is a four-wire system with a common neutral and protective earth conductor throughout the entire system. Due to the combined neutral and protective earth conductor, a TN-C system does not have good EMC characteristics. IT mains system This is an isolated four-wire system with the neutral conductor either not earthed or earthed via an impedance. Note: All EMC features of the frequency converter (filters, etc.) must be disabled when it is used in an IT mains system. TN mains systems There are two versions of this form of mains distribution system: TN-S and TN-C. TT mains systems This is a four-wire system with an earthed neutral conductor and individual earthing of the drive units. This system has good EMC characteristics if the earthing is implemented properly. TN-S This is a five-wire system with separate neutral (N) and protective earth (PE) conductors. It thus provides the best EMC properties and avoids the transmission of interference. TN-S-System TN-S-System Seperate Seperate neutral neutral (N) and (N) and protective protective earth earth (PE) (PE) conductor conductor TN-C-System neutral and and protective earth TN-C-System Combined Combined neutral protective earth conductor to one common conductor conductor to one common conductor throughout the entire system throughout the entire system L1 L1 L2 L2 L3 L3 N N PE PE L1 L1 L2 L2 L3 L3 PEN PEN TT-System TT-System Earthed neutral conductor and and Earthed neutral conductor individual earthing of drive units individual earthing of drive units IT-System IT-System Isolated system withwith the neutral conductor Isolated system the neutral conductor either not earthed or earthed via an either not earthed or earthed via an impendance. impendance. L1 L2 L3 N L1 L2 L3 N L1 L2 L3 N L1 L2 L3 N Forms of electrical mains systems according to EN 50310 / HD 384.3 12 Step 1

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Practical aspects of electromagnetic compatibility (EMC) Every electrical device generates electrical and magnetic fields that affect its direct environment to a certain extent. The magnitude and consequences of these effects depend on the power and the design of the device. In electrical machinery and systems, interactions between electrical or electronic assemblies may impair or prevent reliable, trouble-free operation. It is therefore important for operators, designers and plant engineers to understand the mechanisms of these interactions. Only then will they be able to take appropriate, cost-effective countermeasures at the design stage. This is because the cost of suitable measures increases with each stage of the process. Electromagnetic effects work in both directions System components affect each other: every device generates interference and is affected by interference. In addition to the type and amount of interference an assembly generates, it is characterised by its immunity to interference from nearby assemblies. conforming to the standard. Remedying any interference that may occur (in other words, using these solutions), along with the resulting costs, is the responsibility of the operator. Two possible means of reduction Users and plant engineers have two options for ensuring electromagnetic compatibility. One option is to stop interference at the source by minimising or eliminating the emitted interference. The other option is to increase the interference immunity of the device or system affected by interference by preventing or substantially reducing the reception of interference. The responsibility rests with the operator Previously, the manufacturer of a component or assembly for electrical drives had to take countermeasures to comply with statutory standards. With the introduction of the EN 61800-3 standard for variable-speed drive systems, this responsibility has been transferred to the end user or operator of the system. Now manufacturers only have to offer solutions for operation Eliminating radio interference Radioactivity Harmonic distortion Magnetic elds Lightning protection Corona Microwaves TEMPEST Electromagnetic compatibility (EMC) encompasses a wide variety of factors. The most significant factors in drive engineering are mains interference, RFI suppression and interference immunity. Resistance to interference Protection against contact EMC Electrical corrosion Biological e ects Electrostatic NEMP 13

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Practical aspects of electromagnetic compatibility (EMC) Distinguishing between conducted and radiated interference There are always interactions when several systems are present. Experts distinguish between the interference source and the interference sink, which in practice usually means the device causing the interference and the device affected by it. All types of electrical and magnetic quantities can potentially cause interference. For example, interference may take the form of mains harmonics, electrostatic discharges, rapid voltage fluctuations, high-frequency interference or interference fields. In practice, mains harmonics are often referred to as mains interference, harmonic overoversættelse: e.g.: or simply harmonics. tones Radiation coupling Radiation coupling occurs when an interference sink is located in the farfield region of an electromagnetic field generated by an interference source. For the purpose of electromagnetic analysis, the standard specifies 30 MHz as the boundary between conductive coupling and radiation coupling. This corresponds to a wavelength of 10 metres. Below this frequency, electromagnetic interference is mainly propagated through conductors or coupled by electrical or magnetic fields. Above 30 MHz, wires and cables act as aerials and emit electromagnetic waves. Interference diffusion paths Cable conducted interference (Mains cables, Control cables) 10 kHz 100 kHz 1 MHz Radiation interference (airborn) 10 MHz 30 Mhz 100 MHz300 MHz 1GHz Coupling mechanisms between electrical circuits Now you’re probably wondering how interference is transmitted. As a form of electromagnetic emission, it can essentially be transmitted by conductors, electric fields, or electromagnetic waves. In technical terms, these are called conductive, capacitive and/or inductive coupling, and radiation coupling, which means an interaction between different circuits in which electromagnetic energy flows from one circuit to another one. Electromagnetic interference occurs over the entire frequency range, but the propagation paths and form of diffusion vary. Source of interference Switching circuit parts Power converters Frequency converters Ignition systems Radio telephones Mobile phones Computers Switch mode power supplies Interference sink Interference coupling e.g. conductive, capacitive, inductive or electromagnetic e.g.: Control systems Power converters Frequency converters General radio receiving systems Mobile phones Data/ phone transmission wires Conductive coupling Conductive coupling occurs when two or more electrical circuits are connected to one another by a common conductor, such as a potential equalisation cable. Overview of coupling paths for electromagnetic interference and typical examples Capacitive coupling Capacitive coupling results from voltage differences between the circuits. Inductive coupling occurs between two current-carrying conductors. Frequency converters and EMC Low-frequency effects (conductive) High-frequency effects (radiation) Mains interference/harmonics Radio frequency interference (emission of electromagnetic fields) 14 Step 1

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Practical aspects of mains power quality Low-frequency mains interference Supply networks at risk The mains voltage supplied by electricity companies to homes, businesses and industry should be a uniform sinusoidal voltage with constant amplitude and frequency. This ideal situation is no longer found in public power grids. This is due in part to loads that draw non-sinusoidal currents from the mains or have non-linear characteristics, such as PCs, television sets, switching power supplies, energy-efficient lamps, and frequency converters. Mains power quality will decline even more in the future due to the European energy network, higher grid utilisation and reduced investments. Deviations from the ideal sinusoidal waveform are therefore unavoidable and permissible within certain limits. Facility services designers and operators have an obligation to keep mains interference to a minimum. But what are the limits and who specifies them? Quality assured by statutory provisions Standards, directives and regulations are helpful in any discussion regarding clean, high-quality mains power. In most of Europe the basis for the objective assessment of the quality of mains power is the Electromagnetic Compatibility of Devices Act. European standards EN 61000-2-2, EN 61000-2-4 and EN 50160 define the mains voltage limits that must be observed in public and industrial power grids. The EN 61000-3-2 and 61000-3-12 standards are the regulations concerning mains interference generated by connected devices. Facility operators must also take the EN 50178 standard and the connection conditions of the electricity company into account in the overall analysis. The basic assumption is that compliance with these levels ensures that all devices and systems connected to electrical distribution systems will fulfil their intended purpose without problems. Measurements show distinct distortion of the mains voltage waveform due to interference from nonlinear loads. How mains interference occurs Specialists refer to the distortion of the sinusoidal waveform in mains systems caused by the pulsating input currents of the connected loads as “mains interference” or “harmonics”. They also call this the harmonic content on the mains, which is derived from Fourier analysis, and they assess it up to 2.5 kHz, corresponding to the 50th harmonic of the mains frequency. The input rectifiers of frequency converters generate this typical form of harmonic interference on the mains. Where frequency converters are connected to 50-Hz mains systems, the third harmonic (150 Hz), fifth harmonic (250 Hz) or seventh harmonic (350 Hz) are considered. This is where the effects are the strongest. The total harmonic content is also called the total harmonic distortion (THD). The ideal situation of a sinusoidal mains voltage is rarely found nowadays in our mains grids. 15

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Practical aspects of low-frequency mains interference Analysing mains interference To avoid excessive impairment of mains power quality, a variety of reduction, avoidance and compensation methods can be used with systems or devices that generate harmonic currents. Mains analysis programs, such as VLT® MCT 31 Harmonic Calculation software, can be used for system analysis as early as the design stage. In this way, operators can consider and test specific countermeasures beforehand and ensure subsequent system availability. Remark: Danfoss has a very high level of EMC expertise and many years of experience in this area. We convey this experience to our customers by means of training courses, seminars, workshops and in everyday practice in the form of EMC analyses with detailed evaluation or mains calculations. VLT® MCT 31 estimates the harmonic current and voltage distortion of your application and determines if harmonic filtering is needed. In addition the software can calculate the effect of adding mitigation equipment and if your system complies with various standards. Effects of mains interference Harmonics and voltage fluctuations are two forms of low-frequency conducted mains interference. They have a different appearance at their origin than at any other point in the mains system where a load is connected. Consequently, the mains feed, mains structure and loads must all be taken into account collectively when assessing mains interference. The effects of an elevated harmonic level are described below. Note: Excessive harmonic content puts a load on power factor correction equipment and may even case its destruction. For this reason, they should be fitted with chokes. – Shorter lifetime of devices and components, for example as a result of additional heating effects due to resonances. – Malfunction or damage to electrical or electronic loads (such as a humming sound in other devices). In the worst case, even destruction. – Incorrect measurements because only true-RMS instruments and measuring systems take harmonic content into account. Undervoltage warnings – Incorrect voltage measurements due to distortion of the sinusoidal mains voltage. – Reduced mains power capacity Are interference-free frequency converters available? Every frequency converter generates mains interference. However, the present standard only considers the frequency range up to 2 kHz. For this reason, some manufacturers shift the mains interference into the region above 2 kHz, which is not addressed by the standard, and advertise them as „interference-free“ devices. Limits for this region are currently being studied. Higher losses – Harmonics take an additional share of the active power, apparent power and reactive power 16 Step 1

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Practical aspects of mains interference reduction Options for reducing mains interference Generally speaking, mains interference from electronic power controllers can be reduced by limiting the amplitude of pulsed currents. This improves the power factor λ (lambda). To avoid excessive impairment of mains power quality, a variety of reduction, avoidance or compensation methods can be used with systems and devices that generate harmonics. – Chokes at the input or in the DC link of frequency converters – Slim DC links – Rectifiers with 12, 18 or 24 pulses per cycle – Passive filters – Active filters – Active front end and VLT® Low Harmonic Drives from a B6 rectifier can be reduced from a THD of 80% without chokes to approximately 40%. Chokes with a Uk of 4% have proven to be effective for use in frequency converters. Further reduction can only be achieved with specially adapted filters. 10% or 5%. Filter modules can be used with individual frequency converters or groups of frequency converters. To obtain the best possible results with a harmonic filter, it must be matched to the input current actually drawn by the frequency converter. In terms of circuit design, passive harmonic filters are installed ahead of a frequency converter or a group of frequency converters. Rectifier with 12, 18 or 24 pulses per cycle Rectifier circuits with a high number of pulses per cycle (12, 18 or 24) generate lower harmonic levels. They have often been used in high-power applications in the past. However, they must be fed from special transformers with multiple phase-offset secondary windings that provide all the necessary power to the rectifier stage. In addition to the complexity and size of the special transformer, the disadvantages of this technology include higher investment costs for the transformer and the frequency converter. Advantages of passive filters This type of filter offers a good price/ performance ratio. At relatively low cost, the operator can obtain a reduction in harmonic levels comparable to what is possible with 12- or 18-pulse/cycle rectifiers. The total harmonic distortion (THD) can be reduced to 5%. Passive filters do not generate interference in the frequency range above 2 kHz. As they consist entirely of passive components, there is no wear and they are immune to electrical interference and mechanical stress. Chokes at the input or in the DC link Even simple chokes can effectively reduce the level of harmonics fed back into the mains system by rectifier circuits as mains interference. Frequency converter manufacturers usually offer them as supplementary options or retrofits. The chokes can be connected ahead of the frequency converter (on the feed side) or in the DC link after the rectifier. As the inductance has the same effect in either location, the attenuation of the mains interference is independent of where the choke is installed. Each option has advantages and drawbacks. Input chokes are more expensive, larger, and generate higher losses than DC chokes. Their advantage is that they also protect the rectifier against mains transients. DC chokes are located in the DC link. They are more effective, but they usually cannot be retrofitted. With these chokes, the total harmonic distortion Passive filters Where there are especially stringent harmonic distortion limit requirements, passive mains interference filters are available as options. They consist of passive components, such as coils and capacitors. Series LC circuits specifically tuned to the individual harmonic frequencies and connected in parallel with the load reduce the total harmonic distortion (THD) at the mains input to Drawbacks of passive filters Due to their design, passive filters are relatively large and heavy. Filters of this type are very effective in the load range of 80–100%. However, the capacitive reactive power increases with decreasing load and it is recommended that you disconnect the filter capacitors in no-load operation. Remark: Danfoss VLT

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Practical aspects of mains interference reduction Active filters When requirements with regard to mains interference are even more stringent, active electronic filters are used. Active filters are electronic absorption circuits that the user connects in parallel with the harmonic generators. They analyse the harmonic current generated by the nonlinear load and supply an offsetting compensation current. This current fully neutralises the corresponding harmonic current at the connection point. The degree of compensation is adjustable. In this way harmonics can be almost completely compensated if so desired, or (perhaps for economic reasons) only to the extent necessary to enable the system to comply with statutory limits. Here again it must be borne in mind that these filters operate with clock frequencies and produce mains interference in the 4–18 kHz range. Advantages of active filters Operators can incorporate active filters at any desired location in the mains system as central measures, depending on whether they wish to compensate individual drives, entire groups, or even an entire distribution system. It is not necessary to provide a separate filter for each frequency converter. The total harmonic distortion drops to a THD level ≤ 4%. M Supply Central compensation Drawbacks of active filters One drawback is the relatively high investment cost. In addition, these filters are not effective above the 25th harmonic level. The effects above 2 kHz generated by the filters themselves must also be taken into account with active filter technology. They may require further measures to keep the mains system clean. 3- M 3- M 3- Group compensation M 3- Individual compensation M 3- Active filters can be installed at any desired point in the mains system, depending on whether they should provide compensation for individual drives, entire groups, or even entire mains systems. Current and Distortion Spectrum at Full Load Typical without filter With AHF 010 With AHF 005 Without filter With AHF 010 With AHF 005 Advanced Harmonic Filters (AHF) reduce the total harmonic current distortion to 5% or 10% at 100% load. 18 Step 1

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Slim DC link Recent years have seen the increasing availability of frequency converters with a“slim” DC link. In this approach, manufacturers greatly reduce the capacitance of the DC link capacitors. Even without a choke, this reduces the fifth harmonic of the current to a THD level below 40%. However, it causes mains interference in the high frequency range that would otherwise not occur. Due to the broad frequency spectrum of devices with slim DC links, there is a greater risk of resonances with other components connected to the mains, such as fluorescent lamps or transformers. Devising suitable measures is correspondingly time-consuming and very difficult. In addition, converters with slim DC links have weaknesses on the load side. With converters of this sort, load variations result in significantly larger voltage variations. As a result, they have a greater tendency to oscillate in response to load variations on the motor shaft. Load shedding is also difficult. During load shedding the motor acts as a generator with high peak voltages. In response to this, devices with lean DC links shut down faster than conventional devices in order to protect against destruction due to overload or overvoltage. Due to the small or zero capacitance, converters with slim DC links are not good at riding through mains dropouts. As a rule of thumb, a slim DC link has around 10% of the capacitance of a conventional DC link. In addition to mains interference due to the input current, converters with slim DC links pollute the mains with the switching frequency of the motor-side inverter. This is clearly visible on the mains side due to the low or zero capacitance of the DC link.  Conventional DC link  Slim DC link Converters with slim DC links generate higher harmonic levels, especially in the higher frequency ranges. effective in attenuating low-frequency mains interference. Like frequency converters with slim DC links, they generate mains interference in the high frequency range. An active front end is the most expensive approach to reducing mains interference, since it amounts to a supplementary, full-fledged frequency converter that is able to feed power back into the mains system. The low harmonic drive option does not offer this capability and is accordingly somewhat less costly. – Slim DC link Active Front End `Low Harmonic Drives´ (LHD) is often used when describing Active Front End (AFE) drives. However, this is a bit misleading as Low Harmonic Drives might cover many different technologies and include both passive and active mitigation. Active Front End drives have IGBT switches on the drive input circuits that replaces conventional rectifiers. These circuits use semiconductor devices with fast switching characteristics to force the input current to be approximately sinusoidal and they are very 19

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Practical aspects of mains interference reduction Advantages of AFE The total harmonic distortion drops to a THD level of <4% in the range of the 3rd to the 50th harmonics. Four-quadrant operation is possible with AFE devices, which means that the braking power of the motor can be fed back into the mains system. An AFE always needs a higher DC link voltage for proper operation. In many cases this higher voltage is passed on to the motor, resulting in higher stress on the motor insulation. If the DC links of the AFE devices are not separated, filter failure results in failure of the entire device. The power loss may be 40 to 50% higher than that of frequency converters with uncontrolled rectifiers. Another drawback is the clock frequency used by the devices for input current correction. It lies in the range of 3 to 6 kHz. Good (and relatively complex) devices filter out this clock frequency before feeding power into the mains system. The currently applicable standards and statutes do not cover this frequency range. Currently available mains analysers usually do not acquire data in this frequency range and thus do not allow the effects to be measured. However, they can be seen in all devices operating on the affected mains system, such as in the form of increased input current with power supplies. The effects will only become noticeablein later years. Consequently, operators should specifically ask manufacturers about emission levels and countermeasures in the interest of the operational reliability of their own systems. Drawbacks of AFE The technical complexity of the devices is very high, which leads to very high investment costs. In principle, AFE devices consist of two frequency converters, with one supplying power to the motor and the other to the mains system. Due to the increased circuit complexity, the efficiency of the frequency converter is lower in motor operation. Overview of harmonic reduction measures Cost AFE 24-Pulse 18-Pulse Passive Filter 5% Passive Filter 10% Active Filter AC + DC Coils DC Coils No Coils 12-Pulse Harmonic performance Harmonic performance 20 Step 1

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Practical aspects of high-frequency interference (RFI) Radio frequency interference Frequency converters generate variable rotating field frequencies at corresponding motor voltages due to variable-width rectangular current pulses. The steep pulse edges contain high-frequency components. Motor cables and frequency converters radiate these components and conduct them into the mains system via the cable. Manufacturers use radio frequency interference (RFI) filters (also called mains filters or EMC filters) to reduce the level of this type of interference on the mains feed. They serve to protect devices against high-frequency conducted interference (noise immunity) and to reduce the amount of high-frequency interference emitted by a device over the mains cable or by radiation from the mains cable. The filters are intended to limit these interference emissions to a specified statutory level, which means that as much as possible they should be fitted in the equipment as standard. As with mains chokes, with RFI filters the quality of the filter to be used must be clearly defined. Specific limits for interference levels are defined in the EN 61800-3 product standard and the EN 55011 generic standard. Comparision of interference levels Still valid Product standard as obligatory from 2007 Basic environment standard (Residential environment) Group 1+2 EN 55011 Class B (revised standard) EN 61800-3 Standards and directives define limits Two standards must be observed for the comprehensive assessment of radio frequency interference. The first is the EN 55011 environment standard, which defines the limits according to the basic environment: either industrial (classes A1 and A2) or residential (class B). In addition, the EN-61800-3 product standard for electrical drive systems, which came into effect in June 2007, defines new categories (C1 to C4) for device application areas. Although they are comparable to the previous classes in terms of limits, they allow a wider range of application within the scope of the product standard. (Residential environment) Category C1 1st environment (Industrial environment) Group 1 (HF Internal) Class A Category C2 Group 2 (HF External) (Industrial environment) Category C3 Category C4 2nd environment Comparison of the new categories C1 to C4 defined by the EN 61800-3 product standard and classes A and B of the EN 55011 environment standard. EN 61800-3 product standard (2005-07) for electrical drive systems Classification by category Environment C1 1st Environment C2 1st or 2nd Environment (operator decision) < 1000 V No requirement Class B Installation and commissioning by an EMC expert Class A1 (plus warning notice) Class A2 (plus warning notice) C3 2nd Environment C4 2nd Environment > 1000 V In > 400 A Connection to IT network EMC plan required Values exceed Class A2 Voltage/current EMC expertise Limits according to EN 55011 Note: Facility operators must comply with EN 55011 in case of problems. Converter manufacturers must conform to EN 61800-3. Classification of the new categories C1 to C4 of the EN 61800-3 product standard 21

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Practical aspects of 1st and 2nd environment Appartments 1st Environment O F F I C E A P P A R T M E N T S Supermarket T s Busines 1. UMGEBUNG T instead have their own high-voltage or medium-voltage distribution transformers. They are also defined as such in the land register and are characterised by specific electromagnetic conditions: • the presence of scientific, medical or industrial devices; • switching of large inductive and capacitive loads; • occurrence of strong magnetic fields (for example, due to high currents). The environment classifications apply both inside and outside the buildings. T Indu stria l Pro duc tion T Business 2nd Environment Classification of operating environments in 1st and 2nd and special environments in which the operator is allowed a choice. The operating site is the decisive factor The limits for each environment are specified by the corresponding standards, but how are devices assigned to the different environment types? Here again the EN 55011 and EN 61800-3 standards provide information regarding electrical drive systems and components. 1st Environment/ Class B: Residential environment All operating sites directly connected to the public low voltage power grid, including light industrial areas, are classified as residential or business and commercial environments. They do not have their own high-voltage or medium-voltage distribution transformers for a separate mains system. The environment classifications apply both inside and outside buildings. Some examples are business areas, residential buildings and residential areas, restaurant and leisure businesses, car parks, entertainment facilities and sports facilities. Special environments Here the users may decide which type of environment to classify their facility in. This presumes that the area has its own medium-voltage transformer and is clearly demarcated from other areas. Within this area, the user is personally responsible for ensuring the electromagnetic compatibility necessary to enable the trouble-free operation of all devices under certain conditions. Some examples of special environments are shopping centres, supermarkets, filling stations, office buildings and warehouses. 2nd Environment/ Class A: Industrial environment Industrial environments are operating sites that are not connected directly to the public low-voltage power grid, but Grenzwerte für Leitungsgebundene Störspannung Störspannung in dB (durchschnittliche µV) No compromises Class A-2 Class A-1 Class B-1 120 110 100 90 80 70 60 50 40 30 Frequenz in MHz Class AClass BClass A-2 ( <100A ) If a frequency converter that does not conform to Category C1 is used, the device must be provided with a warning notice. This is the responsibility of the user or the operator. In case of interference, experts always base interference elimination on the limits defined for classes A1/A2 and B in the EN 55011 generic standard according to the operating environment. The cost of remedying EMC problems is borne by the operator. The user is ultimately responsible for the appropriate classification of devices with respect to these two standards. 22 Step 1

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Practical aspects of mains protection measures Power factor correction Power factor correction equipment serves to reduce the phase shift (φ) between the voltage and the current and moves power factor closer to unity (cos φ). This is necessary when a large number of inductive loads, such as motors or lamp ballasts, are used in an electrical distribution system. Depending on the design of the DC link, frequency converters do not draw any reactive power from the mains system or generate any phase shift. They have a cos φ of approximately 1. For this reason, users of speed-controlled motors do not have to take them into account when dimensioning any power factor correction equipment that may be necessary. However, the current drawn by the phase correction equipment rises because frequency converters generate harmonics. The load on the capacitors increases as the number of harmonic generators increases, and they heat up more. For these reasons, the operator must fit chokes in power factor correction equipment. These chokes also prevent resonances between load inductances and the capacitance of the power factor correction equipment. Converters with cos j < 1 also require chokes in the power factor correction equipment. The user must take the higher reactive power level into account when dimensioning the cables. Mains transients Transients are brief voltage peaks in the range of a few thousand volts. They can occur in all types of power distribution systems, in both industrial and residential environments. Lightning strikes are a common cause of transients. However, they are also caused by switching large loads on line or off line or switching other equipment, such as power factor correction equipment. Short circuits, tripping of circuit breakers in power distribution systems, and inductive coupling between parallel cables can also cause transients. The EN 61000-4-1 standard describes the forms of these transients and how much energy they contain. Their harmful effects can be limited by various methods. Gas-filled surge arresters and spark gaps are used to provide first-level protection against high-energy transients. For secondlevel protection, most electronic devices use voltage-dependent resistors (varistors) to attenuate transients. Frequency converters also utilise this method. U Transients t Lighting strikes are the most frequent cause of mains transients in systems 23

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Practical aspects of operation with a transformer or standby generator Maximum transformer utilisation In low-voltage systems (400 V, 500 V and 690 V), operators may use speed-controlled drives with ratings up to around1 MW. A transformer converts the voltage of the mediumvoltage grid to the required voltage. In the public power grid (environment 1: residential environment) this is the responsibility of the electricity company. In industrial mains systems (environment 2: industrial environment; usually 500 V or 690 V), the transformer is located on the premises of the end user, who is also responsible for feeding power to the user’s facility. Transformer load In case of transformers that supply power to frequency converters, it must be borne in mind that the use of frequency converters and other rectifier loads causes the generation of harmonics that put an extra reactive power load on the transformer. This causes higher losses and additional heating. In the worst case, this can lead to the destruction of the transformer. Intelligent vector groups (several transformers connected together) may also generate harmonics under certain conditions. Power quality To ensure the quality of the mains power in accordance with the applicable standards, you need to know how much frequency converter load the transformer can handle. Mains analysis programs such as the VLT® MCT 31 Harmonic Calculation software provide an exact indication of how much frequency converter load a transformer can supply in a specific system. Remark: All frequency converters in the VLT® HVAC Drive series are equipped with integrated mains interference chokes as standard. Operation with a standby generator Operators use backup power systems when the continued operation of mains-powered devices is necessary even in the event of mains failure. They are also used when the available mains connection cannot provide sufficient power. Operation in parallel with the public power grid is also possible in order to achieve higher mains power. This is common practice when heat is also needed, such as with combined heat and power units. They take advantage of the high efficiency that can be achieved with this form of energy conversion. When backup power is provided by a generator, the mains impedance is usually higher than when power is taken from public grid. This causes the total harmonic distortion to increase. With proper design, generators can operate in a system containing harmonic generators. In practice, this means that when the system is switched from mains operation to generator feed, the harmonic load can usually be expected to increase. Facility services designers and operators should calculate or measure the increase in the harmonic load in order to ensure that the power quality conforms to regulations and thereby to prevent problems and equipment failure. Asymmetric loading of the generator must be avoided, since it causes increased losses and may cause the total harmonic distortion to increase. A 5/6 stagger of the generator winding attenuates the fifth and seventh harmonics, but it allows the third harmonic to increase. A 2/3 stagger reduces the third harmonic. If possible, the operator should disconnect power factor correction equipment because resonances may occur in the system. Chokes or active absorption filters can attenuate harmonics. Resistive loads operated in parallel also have an attenuating effect, while capacitive loads operated in parallel create an additional load due to unpredictable resonance effects. If these phenomena are taken into account, a mains system fed by a generator can power a certain proportion of frequency converters while still maintaining the specified power quality. A more precise analysis is possible using mains analysis software, such as the VLT® MCT 31 Harmonic Calculation software. In case of operation with harmonic generators, the limits are set as follows: B2 and B6 rectifiers B6 rectifier with choke Controlled B6 rectifier m

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Step 2: Practical aspects of ambient and environmental conditions The right installation location Maximum up-time and long service life of frequency converters in operational use are only possible with proper cooling and clean air. Consequently, selection of the installation location and the installation conditions have a decisive effect on the lifetime of the frequency converter. costs for shielded motor cables are higher because the frequency converter and motor are usually significantly further away from each other than with local installation. Wall mounting is easier to handle in terms of EMC due to the close proximity of the frequency converter and the motor. Shielded motor cables are reduced in length and accordingly represent significantly lower cost. The slightly higher cost of a frequency converter with an IP54 enclosure can easily be offset by the reduced cabling and installation cost. However, in practice around 70% of the devices are mounted in cabinets. Cabinet mount versus wall mount There is no cut-and-dried answer to the question of whether a frequency converter should be mounted in a cabinet or on the wall. Both options have their pros and cons. Cabinet mounting has the advantage that all electrical and electronic components are located close together and protected by an enclosure (the cabinet). The cabinet also comes fully assembled as a complete unit for installation in the facility. A drawback is that the components may affect each other due to the close spacing inside the cabinet, which means that particular attention must be given to EMC-compliant cabinet layout. In addition, the investment Remark: Danfoss frequency converters are available with three different protection ratings: – IP00 or IP20 for cabinet installation – IP54 or IP55 for local mounting; – IP66 for critical ambient conditions, such as extremely high (air) humidity or high concentrations of dust or aggressive gases. Frequency converters can be installed centrally (in a cabinet) or locally (close to the motor). Both options have advantages and drawbacks. 25

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Practical aspects of enclosure ratings IP66/Type 4x enclosed drives are suitable for installation in demanding environments (e.g. cooling towers). Finger-proof converters with protection rating IP20 or IP21 intended for cabinet mounting. IP rating structure according to IEC 60529 IP first character IP0_ IP1_ IP2_ IP3_ IP4_ IP5_ IP6_ Against penetration by solid foreign objects (not protected) ≥ 50 mm diameter 12.5 mm diameter 2.5 mm diameter ≥ 1.0 mm diameter Dust protected Dust-tight Against access to hazardous parts by (not protected) Back of hand Finger Tool Wire Wire Wire IP second character IP_0 IP_1 IP_2 IP_3 IP_4 IP_5 IP_6 IP_7 IP_8 Against water penetration with harmful effect (not protected) Drops falling vertically Drops at 15° angle Spraying water Splashing water Water jets Powerful water jets Temporary immersion Long-term immersion Missing characters are replaced by “x”. NEMA enclosure types according to NEMA 250-2003 Comparision of specific applications of enclosures for Indoor Nonhazardous locations Provides a degree of protection against the following conditions Access to hazardous parts Ingress of solid foreign objects (falling dirt) Ingress of water (dripping and light splashing) Ingress of solid foreign objects (circulating dust, lint, fibers, and flyings **) Ingress of solid foreign objects (settling airborne dust, lint, fibers, and flyings **) Ingress of water (hosedown and splashing water) Oil and coolant seepage Corrosive agents Type of enclosure 1* x x 4 x x x x x x 4X x x x x x x x 12 x x x x x x - Comparision of specific applications of enclosures for Outdoor Nonhazardous locations Provides a degree of protection against the following conditions Access to hazardous parts Ingress of water (rain, snow and sleet*) Sleet ** Ingress of solid foreign objects (windblown dust, lint, fibers and flyings) Ingress of water (hosedown) Corrosive agents Type of enclosure 4 x x x x 4X x x x x x * These enclosures may be ventilated ** These fibers and flyings are nonhazardous materials and are not considered Class III type ignitable fibers or combustible flyings. For Class III type ignitable fibers or combustible flyings see the National Electrical Code, article 500. * External operating mechanisms are not required to be operable when the enclosure is ice covered. ** External operating mechanisms are operable when the enclosure is ice covered. 26 Step 2

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Practical aspects of cooling design Compliance with ambient temperature specifications External climatic conditions and ambient conditions have a distinct effect on the cooling of all electrical and electronic components in a control room or cabinet. Minimum and maximum ambient temperature limits are specified for all frequency converters. These limits are usually determined by the electronic components that are used. For example, the ambient temperature of the electrolytic capacitors installed in the DC link must remain within certain limits due to the temperature dependence of their capacitance. Although frequency converters can operate at temperatures down to -10 °C, manufacturers only guarantee proper operation at rated load with temperatures of 0 °C or higher. This means that you should avoid using them in areas subject to frost, such as uninsulated rooms. You should also not exceed the maximum temperature limit. Electronic components are sensitive to heat. According to the Arrhenius equation, the lifetime of an electronic component decreases by 50% for every 10 °C that it is operated above its design temperature. This is not limited to devices that are installed in cabinets. Even devices with IP54, IP55 or IP66 protection ratings can only be used within the ambient temperature ranges specified in the manuals. This sometimes requires air conditioning of installation rooms or cabinets. Avoiding extreme ambient temperatures prolongs the life of frequency converters and thereby the reliability of the overall system. Cooling Frequency converters dissipate power in the form of heat. The amount of power dissipation in watts is stated in the technical data of the frequency converter. Operators should take suitable measures to remove the heat dissipated by the frequency converter from the cabinet, for example by means of cabinet fans. The required air flow is stated in the manufacturer documentation. Frequency converters must be mounted such that the cooling air can flow unhindered through the device’s cooling fins. Particularly with IP20 devices in cabinets, there is a risk of inadequate air circulation due to the closely spaced mounting of cabinet components, which causes the formation of heat pockets. See the manuals for the correct mounting distances, which must always be observed. the frequency converter or some of its components are colder than moist ambient air. In this situation, the moisture in the air can condense on the electronic components. When the device is switched on again, the water droplets can cause short circuits in the device. This usually occurs only with frequency converters that are disconnected from the mains. For this reason, it is advisable to install a cabinet heater in situations where there is a real possibility of condensation due to ambient conditions. Alternatively, operating the frequency converter in standby mode (with the device constantly connected to the mains) can help reduce the risk of condensation. However, you should check whether the power dissipation is sufficient to keep the circuitry in the frequency converter dry. Note: Some manufacturers specify minimum side clearances as well as minimum top and bottom clearances. Observe these specifications. Relative humidity Although some frequency converters can operate properly at relatively high humidity (Danfoss units up to 95% relative humidity), condensation must always be avoided. There is a specific risk of condensation when The intelligent cooling design of VLT® frequency converters remove up to 85% of the dissipated heat from the device enclosure via cooling ducts. 27

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Practical aspects of special requirements Unit Ambient parameters Class 3C1 Average value Sea salt Sulphur oxides Hydrogen sulphide Chlorine Hydrogen chloride Hydrogen fluoride Ammonia Ozone Nitrogen mg/m3 mg/ m3 mg/ m3 mg/ m3 mg/ m3 mg/ m3 mg/ m3 mg/ m3 mg/ m3 No 0.1 0.01 0.01 0.01 0.003 0.3 0.01 0.1 Salt mist 0.3 0.1 0.1 0.1 0.01 1.0 0.05 0.5 1.0 0.5 0.03 0.5 0.03 3.0 0.1 1.0 3C2 Max. value Average value Salt mist 5.0 3.0 0.3 1.0 0.1 10 0.1 3.0 10 10 1.0 5.0 3.0 35 0.3 9.0 3C3 Max. value Classification according to IEC 60721-3-3; average values are anticipated long-term values. Maximum values are transient peak values that do not occur longer than 30 minutes per day. Aggressive atmosphere or gases Aggressive gases, such as hydrogen sulphide, chlorine or ammonia, are often present in industrial applications or swimming pools. Contamination of the cooling air can cause the gradual decomposition of electronic components and PCB tracks in frequency converters. Electronic devices in electrical systems or cabinets are especially susceptible. If the ambient air is contaminated in this manner, the operator or plant engineer should either install the frequency converter in a location where the possibility of contamination can reliably be excluded (a different building, a sealed cabinet with a heat exchanger, etc.) or order devices whose circuit boards are coated with a special protective varnish that is resistant to the aggressive gases. A clear sign of an aggressive atmosphere is the corrosion of copper. If it quickly turns dark, forms blisters or even decomposes, circuit boards or devices with a supplementary coating should be used. The specific media and media concentrations that a coating can resist are described in international standard IEC 60721-3-3. Note: You should consider in the design and project engineering phase where the cooling air for the electronic equipment will come from. For example, in a sewage treatment plant you should avoid drawing air from the inflow area, and with a swimming pool you should avoid drawing air from the water treatment area. Remark: VLT® HVAC Drive units come standard with class 3C2 coating. On request, class 3C3 coating is also available. 28 Step 2

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Dust exposure Installation of frequency converters in environments with high dust exposure is often unavoidable in practice. This dust forms deposits everywhere and penetrates into even the smallest cracks. This affects not only locally mounted frequency converters (wall or frame mount) with IP55 or IP66 protection rating, but also cabinetmounted devices with IP21 or IP20 protection rating. The three aspects described below must be taken into account when frequency converters are installed in such environments. cooling capacity. The components become warmer. This causes accelerated aging of the electronic components, and the service life of the affected frequency converter decreases. The same thing happens when dust deposits form on the heat sink on the back of the frequency converter. that prevent the entry of dust into the device. These filter mats quickly become clogged when they are used in very dusty environments, and the fans are no longer able to cool adequately the components inside the frequency converter. Cooling fans The air flow for cooling frequency converters is produced by cooling fans, which are usually located on the back of the device. The fan rotors have small bearings into which dust penetrates and acts as an abrasive. This leads to fan failure due to bearing damage. Note: Under the conditions described above, it is advisable to clean the frequency converter during periodic maintenance. Blow the dust off the heat sink and fans and clean the filter mats. Reduced cooling The dust forms deposits on the surface of the device and inside the device on the circuit boards and the electronic components. These deposits act as insulation layers and hamper heat transfer from the components to the ambient air. This reduces the Filter mats High-power frequency converters in particular are equipped with cooling fans that expel hot air from the interior of the device. Above a certain size, these fans are fitted with filter mats 29

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Practical aspects of potentially explosive atmospheres Potentially explosive atmospheres Ex d: Flameproof protection Drive systems often operate in potentially explosive atmospheres. One example is the inflow area of a sewage treatment plant. If frequency converters are used for speed control of drives in such areas, the facility must fulfil special conditions. The basis for this is provided by EU Directive 94/9/EC, which is called the ATEX directive. It describes the use and operation of equipment and protective devices in potentially explosive atmospheres. This directive harmonises regulations and requirements throughout the EU for the operation of electrical and electronic devices in potentially explosive atmospheres, such as may be caused by dust or gases. If frequency converters are used to control motors in potentially explosive atmospheres, these motors must be equipped with temperature monitoring using a PTC temperature sensor. Motors with ignition protection class “d” or “e” may be used. These ignition protection classes differ in terms of how the ignition of an explosive medium is prevented. In practice, frequency converters are rarely used with “e” class motors. This combination must be approved as an unit, which involves elaborate and expensive type testing. However, the PTB in Braunschweig (Germany) has developed a new approval procedure that will make the use of speed Conformance mark Code no of oﬃcial institute Temperature class Explosion group Protection principle Equipment category Equipment group With ignition protection class “d”, the device is designed to ensure that if a spark occurs in a protected area (such as inside an enclosure), it cannot leave the protected area. Ex e: Increased safety controllers with class “e” motors considerably more attractive in the future. The new concept calls for the acceptance of only the motor itself, while additionally defining specific requirements for thermal monitoring in the EC type test certification process. For instance, speed-dependent current limiting is required in addition to the usual certified PTC thermistor monitoring, in order to deal with the reduced cooling of self-ventilated motors with variable speed control. Although this does not require separate approval of class “d” motors, feeding cables into the “d” area is very complicated. Motors with protection class “de” are the most widely used. In this case the motor itself has a “d” ignition protection class, while the connection space is implemented in compliance with the “e” ignition protection class. The restriction on the “e” connection space consists of the maximum voltage that may be fed into this space. Due to pulse-width modulation of the output voltage, most frequency converter outputs have peak voltages that exceed the allowable limits of class “e” ignition protection. In practice, using a sine-wave filter at the frequency converter output has proven to be an effective way to attenuate the high peak voltages. With ignition protection class “e”, the protection consists of preventing the occurrence of sufficient energy to cause sparking. Note: Never install a frequency converter directly in an area with a potentially explosive atmosphere. It must be installed in a cabinet outside this area. Using a sinewave filter at the output of the frequency converter is also recommended because it attenuates the voltage rate of rise du/dt and the peak voltage Upeak. The connected motor cable should be kept as short as possible due to the voltage drop in the cable. Remark: Danfoss VLT® HVAC Drive frequency converters with the MCB 112 option have PTB-certified motor thermistor sensor monitoring capability for potentially explosive atmospheres. Shielded motor cables are not necessary when VLT® frequency converters are operated with sine-wave output filters. Labelling of devices for operation in potentially explosive atmospheres in accordance with the ATEX product directive (94/9/EC) 30 Step 2

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Step 3: Practical aspects of motors and cabling Minimum efficiency performance classes for motors Mandatory minimum efficiencies Efficiency classification arose in 1998 as a result of a voluntary commitment by the European Committee of Manufacturers of Electrical Machines and Power Electronics (CEMEP) Starting in the summer of 2011, threephase asynchronous motors are subject to mandatory minimum efficiency performance standards (MEPS) in the EU. EU regulations provide for increasingly strict motor efficiency requirements in a staged process extending to 2017. The basis for these minimum efficiency classes, which are also called minimum energy performance standards (MEPS), is formed by the International Efficiency (IE) classes defined in IEC 60034-30, which are internationally recognised. The limits of these classes are in part comparable to those of the eff classes widely used in Europe. with the old method at power levels up to 10 kW and around 1% worse at power levels of 100 kW and above. The standard takes these differences into account for the harmonisation of the IE and eff classes. In addition to the IE1 to IE3 classes defined by the IEC 60034-30 standard, the draft version of IEC 60034-31 defines a new class: IE4. Classes IE1 to IE3 are primarily oriented towards mains-operated motors, while IE4 also takes aspects relevant to variable-speed motors into account. IE4 is presently not mandatory; it is used at present only for comparison with other efficiency classes. IE and eff classes: major differences in details Although the limits of the two standards are comparable, they differ in the underlying methods for determining efficiency. The efficiency of the eff classes is based on the determination of individual losses (IEC 60034-2:1996), a method that dates back 100 years. By contrast, the efficiency of the IE classes is determined using a more precise method. The measured results obtained using the accepted method for the IE classes are usually 2 to 3% worse than IEC 60034-30 IE1 (Standard Efficiency) IE2 (High Efficiency) IE3 (Premium Efficiency) eff classes Comparable to eff2 Comparable to eff1 Approximately 15–20% better than IE2 Efficiency classes IE1–IE3 are defined in international standard IEC 60034-30. The eff classes are based on a voluntary agreement between the EU and the CEMEP in 1998. Affected three-phase motors Compliance with the MEPS is mandatory for the following types of threephase motors: – Duty cycle S1 (continuous duty) or S3 (intermittent periodic duty) with a duty cycle greater than 80% – Pole count 2 to 6 Rated power 0.75 to 375 kW – Rated voltage up to 1000 V. Introduction of the MEPS is intended to help reduce energy consumption. However, in rare cases this approach can result in increased energy consumption. For this reason, EU Ordinance 640/2009 describes technically reasonable exceptions for various application areas. They include: – Motors in potentially explosive atmospheres (as mentioned in Directive 94/9/EC) and brake motors – Special motors for use under any of the following operating conditions: – ambient temperatures above 40 °C; – ambient temperatures below 15 °C (0 °C for air-cooled motors); operating temperatures above 400 °C; cooling water temperatures below 5 °C or above 25 °C; – operation at elevations above 1000 m; – motors fully integrated in a product, such as geared motors, pumps or fans, or which (e.g. submersible pumps) are fully surrounded by a fluid medium in operation. Within Europe, the motor of a geared motor is not regarded as an integral constituent and is measured seperately. A similar method is used with special motors. The base motor is measured, and the efficiency class is transferred to the motor variants. 31

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Practical aspects of IE classification of motors Schedule for MEPS implementation The schedule in the EU ordinance provides for a staged increase in motor efficiency requirements. After the scheduled dates, all three-phase motors subject to the ordinance must fulfil the requirements of the specified efficiency class if they are to be marketed in Europe. IE2 motors powered by converters are also accepted as an MEPS alternative to the planned IE3 class. Compliance Power with class IE3 or the alternative of IE2 with a converter must be ensured at the operating site. MEPS 375 kW 7.5 kW 375 kW 375 kW IE2 IE2 IE3 IE3 MEPS alternative -t IE2 with converter IE2 with converter Starting 16 June 2011 Starting 1 January 2015 0.75 0.75 7.5 – – – – Starting 1 January 2017 0.75 Schedule for MEPS implementation Compliance with EN 50347 mounting dimension specifications Synchronous three-phase motors conforming to classes IE2 and IE3 are often larger than motors with lower efficiency. This can lead to problems in the replacement of older motors. Most IE2 motors conform to the shaft heights and fixing dimensions standardised by EN 50347, but the construction form is often longer. In many cases, small 50-Hz IE3 Premium Class motors will not conform to the EN 50347 mounting dimensions. Facility operators should take heed of this in their motor replacement schemes. Alternative to IE3: IE2 plus converter. Motor IE1 IE2 Yes Yes Longer IE3 Larger Larger Larger Shaft height (EN 50347) Fixing dimensions (EN 50347) Motor length Yes Yes Yes It is currently expected that class IE2 and IE3 synchronous three-phase motors will not be able to conform to the mounting dimensions defined in EN 50347. Cost-effectiveness A justified question with regard to the introduction of IE motors is: how cost-effective are they? The higher efficiency is in part achieved by employing a higher proportion of active materials in the motors. Depending on the motor size, you can assume that a motor with a better efficiency class costs approximately 10 to 20% more. In practice, this additional cost can often be recovered quickly. The chart shows the energy cost advantage of an IE motor compared to an IE motor in the next class. This simplified analysis is based on continuous operation at the rated load, 60,000 operating hours, and an electricity price of 8 Euro cents per kilowatt-hour. 4.500 € 4.000 € 3.500 € 3.000 € 2.500 € 2.000 € 1.500 € 1.000 € 500 € 0€ 0,75 kW IE4 to IE3 1,1 kW 1,5 kW 2,2 kW 3 kW 4 kW 5,5 kW 7,5 kW 11 kW 15 kW 18,5 kW IE3 to IE2 IE2 to IE1 Energy cost advantage of an IE motor relative to the next IE class Note: The full text of EU Regulation 640/2009 can be downloaded free of charge from the www.eur-lex.europa.eu website. 32 Step 3

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Practical aspects of EC and PM motors What are EC motors ? In the HVAC market, the term ´EC motor´ is commonly understood to mean a specific type of motor, which many users associate with compact construction and high efficiency. EC motors are based on the idea of using electronic commutation (EC) instead of conventional carbon brush commutation for DC motors. For this purpose, manufacturers of these motors replace the rotor winding with permanent magnets and incorporate commutation circuitry. The magnets boost the efficiency, whilst electronic commutation eliminates the mechanical wear of carbon brushes. As the operating principle is based on that of a DC motor, EC motors are also called Brush Less DC (BLDC) motors. These motors are generally used in low power ranges of a few hundred watts. Motors of this type used for applications in the HVAC sector are typical motors in outer rotor design and cover a limited power range, presently extending to approximately 6 kW. Efficiency of EC motors Split-pole motors and single-phase asynchronous motors have poor efficiency in the power range of a few hundred watts. The idea that EC motors have an enormous efficiency advantage is also based on comparison with these motors. If the efficiencies of EC motors are compared with the typical efficiencies of three-phase asynchronous motors, this advantage decreases rapidly with increasing power. motors, which for this reason are in general classified as AC motors, are available in various forms, including servo motors and motors with the same IEC dimensions as standard three-phase asynchronous motors. One of the main differences between PM and EC motors is the supply voltage. As suggested by the different classifications (DC versus AC motors), EC motors have square-wave commutation while PM motors use sinusoidal commutation. A common feature of both types of motor is that they need control electronics. The overall efficiencies of both systems (motor and electronics) are comparable for systems with similar configurations (mains supply, EMC filter, etc.). However, EC motors have higher torque ripple as a result of squarewave commutation and higher iron losses. In addition, as a result of square-wave commutation their current consumption (distributed over two phases instead of three) is 1.22 times that of PM motors. PM motors – an alternative to EC? Permanent magnet (PM) motors provide an alternative to EC motors, with efficiencies comparable to those of EC motors. They additionally have the advantage relative to EC motors that they are available in a considerably larger power range. PM motors are driven using essentially the same method as that used for three-phase asynchronous motors. PM PMAC Synchronous motors BLDC Brushless DC motor Also known as EC motor or EC technology PMSM Sinusoidal commutation Note: The characteristics of single-phase motors are often compared with the characteristics of three-phase motors in discussions of EC motors. Example: Single-phase EC motors are usually equipped with power factor correction (PFC) to achieve a power factor close to 1, but a three-phase converter does not need PFC for this. Accordingly, users should determine what the technical specifications are based on. IPMSM Embedded magnets SPMSM Surface mounted magnets Usual motor designation: PM motors PMAC = Permanent Magnet AC; BLDC = Brushless DC; PMSM = Permanent Magnet Synchronous Motor; IPMSM = Interior PMSM (embedded magnets); SPMSM = Surface PMSM (magnets mounted on rotor) 33

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Practical aspects of EC and PM motors The Danfoss EC+ concept allows PM motors to be used with Danfoss VLT® frequency converters. Danfoss has integrated the necessary control algorithm in the existing VLT® converter series. This means that there are no changes for the operator. After entering the relevant motor data, the user benefits from the high motor efficiency of EC technology. Motor electronics EC PM Simple Complex Motor construction Complex Simple Power range Commutation up to approx. Square-wave (DC) 6 kW up to MW range Sinusoidal (AC) Basic comparison of EC and PM motors Does the best motor efficiency yield the best system efficiency? What is the benefit of a high-efficiency motor design if the installed bearings reduce motor efficiency ? This principle also applies to the overall system, since optimal system efficiency is the key to reducing energy consumption and thereby reducing costs. System efficiency is calculated according to VDI DIN 6014 by multiplying the efficiencies of the components: Advantages of the EC+ concept n n n n n n Free choice of motor technology: PM or asynchronous with the same frequency converter Device installation and operation remain unchanged Manufacturer independence in the choice of all components Superior system efficiency thanks to a combination of individual components with optimum efficiency Retrofitting of existing systems possible Wide range of rated powers for standard and PM motors η system = η converter x η motor x η coupling x η fan Example efficiency calculation for a drive system with a 450-mm radial fan ECDrive motor += 89% integrated electronics = 68% Fan + fan η η η System η Drive = 60% = 89% = 68% = 60% η = 83% Induction Drive motor + VSD + direct drive fan ηFan = 75% η = 63% System = 83% η ηFan ηSystem Drive η = 89% PM/EC Drivemotor + VSD + direct drive fan ηFan = 75% η = 66% System = 89% η ηFan ηSystem Drive ηFan ηSystem = 75% = 63% = 75% = 66% The stated drive efficiencies (converter x motor) are based on measurements, while the fan efficiencies are taken from manufacturer catalogues. Due to the directly driven fan, ηcoupling = 1 For example, if a fan with low efficiency is driven by a high-efficiency motor, the end result is an average efficiency level. Radial fans with EC motors are a good practical example. To achieve very compact construction, manufacturers often use the EC motor as the hub of the impeller. However, such a large hub significantly reduces the efficiency of the fan and thus the efficiency of the overall system. 34 Step 3

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Practical aspects of motor suitability for frequency converter operation Selection criteria The following aspects must be taken into consideration in connection with motors controlled by frequency converters: – Insulation stress – Vearing stress – Thermal stress – Higher pulse voltages between the windings and the laminations ÛLE put additional stress on the slot insulation – Higher voltages between the win dings Ûwdg put significantly higher stress on the insulation of the wire in the windings. – – – – Electrical shielding System earthing Motor size The earthing system of the motor housing and the motor shaft. Insulation stress Operating a motor with frequency control imposes higher stress on the motor winding than direct mains operation This is primarily due to the steep pulse edges (du/dt) and the motor cable, depending on cable length, type, routing, etc. The steep pulse edges result from the rapidly switching semiconductor devices in the inverter stage of the frequency converter. They operate at a high switching frequency in the range of 2 to 20 kHz with very short switching times in order to reproduce a sinusoidal waveform. In combination with the motor cable, these steep pulse edges are responsible for the following effects at the motor: – High pulse voltages ULL on the motor terminals put additional stress on the interwinding insulation Bearing stress Under unfavourable conditions, frequency-controlled motors may fail due to bearing damage caused by bearing currents. Current flows in a bearing when the voltage across the bearing lubrication gap is high enough to penetrate the insulation layer formed by the lubricant. If this happens, imminent failure of the bearing is signalled by increasingly louder bearing noise. Bearing currents of this sort include high-frequency eddy currents, earth currents and EMD currents (spark erosion). Which of these currents may lead to bearing damage depends on the following factors: – The mains voltage at input of the frequency converter – The steepness of the pulse edges (du/dt) – The type of motor cable Bearing currents can be reduced by the following measures: – Fitting output filters (output chokes, du/dt filters, or sine-wave filters) – Fitting electrically insulated bearings – Good earthing of all metallic system components with low-impedance connections – Shielded motor cables – Fitting a DC suppression filter. Thermal stress Operation with a frequency converter increases the power dissipation in the motor. The additional harmonic content causes iron losses and current heat losses in the stator and rotor. The magnitude of the losses depends on the amplitude and frequency of the harmonics of the drive frequency. The additional current heat losses in the rotor depend on the slot geometry. Iron losses and current heat losses in motors are not load-dependent. The additional losses in the motor cause higher thermal stress on the winding insulation. However, with modern frequency converters the additional heating of standard motors (up to frame size 315) is comparable to the additional warming due to mains voltage tolerances and is therefore negligible. Manufacturers sometime specify a derating factor for transstandard motors (frame size 355 and above). If the converter is not able to generate the full mains voltage at the rated mains frequency, it is advisable to select a motor with Class F insulation. Operating a motor at a voltage lower than with direct mains operation increases the motor temperature by up to 10 K. 1. 2. Coil UWdg ULE U ULL V W Note: Request confirmation from the motor manufacturer that the motor is designed for operation with a frequency converter and confirmation of the allowable operating speed range (minimum and maximum rpm). Pulse voltages appear in the motor at the motor terminals (ULL) and between the windings and the lamination stack (ULE). There is also a voltage stress between the windings (Uwdg). Note: Bearing currents result from the action of the entire s

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Practical aspects of output filters Sine-wave and du/dt filters The output filter options include sine-wave and du/dt filters. Unlike sine-wave filters, the only task of du/ dt filters is to reduce the steepness of the pulse edges. They are simpler in design than sine-wave filters (smaller inductances and capacitances) and are therefore less expensive. Sine-wave filters, which are also called motor filters or LC filters, may optionally be fitted to the outputs of frequency converters. They smooth the rectangular voltage pulses at the output to convert them into a nearly sinusoidal output voltage. • Reducing motor noise • Allowing longer motor cables to be used. • Improving EMC characteristics • When used with Danfoss frequency converters, sine-wave filters enable operation with unshielded motor cables in compliance with EN 618003 RFI category C2. Retrofitting If a facility operator converts oldermodel motors previously powered directly from the mains to speed control operation and retrofits them with a frequency converter, it is always advisable to use a sine-wave filter unless the motor datasheet indicates that the windings are designed for operation with a frequency converter. When renovations are being carried out, it is often worthwhile to replace old low-efficiency motors with new energy-efficient motors. A supplementary sine-wave filter is not necessary in such cases. The new motors usually pay for themselves very quickly due to reduced energy costs. When are sine-wave filters used? • With wet-running pumps • With very long motor cables (including situations where this is necessary due to parallel operation) • With well pumps • With motors lacking good interwinding insulation • Whenever standard motors are not used (consult motor manufacturer) • With some types of compressors Functions and tasks of sine-wave filters • Reducing the voltage rate of rise (du/dt) at the motor terminals • Reducing peak voltage ÛLL du/dt filter Motor insulation stress Motor bearing stress Electromagnetic compatibility Maximum motor cable length, EMC compliant Max. motor cable length, not EMC compliant Motor noise at switching frequency Relative size (compared to converter) Voltage drop Reduced – longer motor cables can be used Slightly reduced Eliminates harmonics in motor cable. No change in EMC class Depends on manufacturer FC 102: max. 150 m shielded Depends on manufacturer FC 102: max. 150 m unshielded No effect 15–50% (depends on power) 0.5% Sine-wave filter Reduced – longer motor cables can be used Reduced circulating currents but not synchronous currents Eliminates harmonics in motor cable. No change in EMC class Depends on manufacturer FC 102: max. 150 m shielded or max. 300 m unshielded Depends on manufacturer FC 102: max. 500 m unshielded Reduced 100% 4–10% Common mode filter No reduction Reduced synchronous currents Reduced high-frequency emissions (above 1 MHz). No change in EMC class Depends on manufacturer FC 102: max. 150 m shielded Depends on manufacturer FC 102: max. 300 m unshielded No effect 5–15% None 36 Step 3

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Practical aspects of motor cables Rated voltage Peak voltages up to three times the DC link voltage in the frequency converter occur in the motor cable. They severely stress the motor cable and the motor insulation. The stress is higher if the frequency converter output does not have a du/dt filter or sine-wave filter. For this reason, the rated voltage specification of the motor cables should be at least U0/U = 0.6/1 kV. High-voltage insulation testing of cables with this specification is usually performed with a test voltage of at least 3,500 V AC and usually 4,000 V AC, and in practice they have proven to have good resistance to insulation breakdown. Motor cable length In installations with long motor cables the voltage drop over the cable must be taken into account in cable dimensioning. Design the system so the full output voltage reaches the motor, even with a long motor cable. The length of the motor cable that can be connected to a standard frequency converter is typically 50 to 100 metres. Even with these cable lengths, products from some manufacturers cannot provide the full output voltage at the motor. If users need cables longer than 100 m, there are only a few manufacturers that can meet this requirement with standard products. Otherwise it is necessary to provide supplementary motor chokes or output filters. Cables with suitable shielding Shielded cables should have a shield coverage of at least 80%. Some examples of suitable cable types are: – Lapp Ölflex 100-CY – Helu Y-CY-JB – Helu Topflex-EMV-UV-2YSLCYK-J Note: Consult the manufacturer regarding the lengths of cables that may be connected to the frequency converter and the expected voltage drop. With a standard VLT® HVAC Drive frequency converter, you can connect a shielded cable up to 150 m long or an unshielded cable up to 300 m long and still have the full voltage at the motor. Current rating [A] of PVC cable at 40°C ambient temperature mm² 1 1,5 2 4 6 10 16 25 B1 10,3 13,5 18,3 24,0 31 44,0 59,0 77,0 B2 10,1 13,1 17,4 23,0 30,0 40,0 54,0 70,0 C 11,7 15,2 21,0 28,0 36,0 50,0 66,0 84,0 E 12,4 16,1 22,0 30,0 37,0 52,0 70,0 88,0 Cable dimensioning The required cross-section of the motor cable depends on the output current of the frequency converter, the ambient temperature, and the type of cable installation. Overdimensioning the wire cross-section to allow for harmonics is not necessary. Energy savings The voltage drop over a motor cable, as well as the resulting heat dissipation, is nearly proportional to its Installation method B1: Conduclength and on the tors in dependent conduit or closed wiring ducts frequency. For the selection and dimensioning of Accordingly, you should keep cable cables and conductors, EN 60204-1 runs as short as possible and dimension the wire cross-sections no larger and VDE 0113-1 provide current capacity data for wire cross-sections than is electrically necessary. Installation method B2: MultiInstallation method B1: Conduc- conductor cable or multiconup to 120 mm². If larger wire crosstors in conduit or closed wiring ductor sheathed cable in conduducts sections are necessary, useful inforit or closed wiring ducts mation can be found in VDE 0298-4. ethod B1: Conducethod B1: Conducor closed wiring or closed wiring Installation method C: Direct Installation method B2: Multi- installation on or in walls and/or ceilings or in cable trays conductor cable or multiconductor sheathed cable in conduit or closed wiring ducts Installation method B1: Conductors in conduit or closed wiring ducts Installation method C: Direct installation on or in walls and/or ceilings or in cable trays Installation method C: Direct installation on or in walls and/or ceilings or in cable trays Installation method E - Installation frei in Luft, an Tragseilen sowie auf Kabelpritschen und -konsolen ethod B2: Multiethod B2: Multile or multiconle or multiconed cable in condued cable in conduing ducts ing ducts ethod C: Direct ethod C: Direct or in walls and/or or in

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Practical aspects of earthing The importance of earthing Frequency converter Output lter PE Protective earth outdoor conductor Facility earthing To avoid disturbance do not use facility earthing An earthing plan should always be generated for every system or facility. Earthing measures are generally imperative in order to fulfil the statutory requirements of the EMC and Low Voltage directives. They are a prerequisite for the effective use of other measures, such as shielding and filters. Other measures are of no benefit without good earthing. For this reason, the earthing arrangements must be checked and verified for proper EMC implementation before retrofitting shielding or filters and as the first step in troubleshooting. Star-configured earthing system All earthed points and components must be connected to the central earthing point as directly as possible, such as by means of a potential equalisation rail. This results in an earthing system in which all connection points are connected radially to the earthing point. This earthing point must be defined unambiguously. wire, such as high-flexibility instrument wire, or by using special earthing straps or cables. Braided earthing straps are often used nowadays in practice; they replace the rigid conductors used in the past. These straps have a significantly higher surface area with the same cross-section. Note: System earthing has a substantial effect on smooth, trouble-free facility operation. Ground loops must be avoided. Good potential equalisation is essential. Generate a suitable earthing plan as early as the design and projecting engineering stage. Contact points After paint and corrosion have been removed, connections must be made to contact points using a large surface area. Serrated washers are better for this purpose than plain washers. Tin-plated, zinc-plated or cadmiumplated components should be used in preference to painted components. Multiple contacts for the shield connection must be provided in connectors. Electrically conductive materials Operators must ensure that metallic surfaces are earthed with low-impedance connections. In terms of EMC, the decisive factor is not the cross-section of the conductor but instead its surface area, since high-frequency currents flow on the surface due to the skin effect. The portion with the smallest conductor surface area is what limits the ability to drain leakage currents. Earthed surfaces have a shielding effect and reduce the amplitude of ambient electromagnetic fields. Conductor surface area A large conductor surface area for draining high-frequency currents can be obtained by using fine stranded 38 Step 3

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Practical aspects of shielding The importance of shielding DDC etc. Enclosure plate Frequency converter DDC etc. Enclosure plate Output relais DDC Frequency converter Earthing strip Wrong Correct Remove cable isolation Min. 10mm² Compensation cable Control cables Output re Earthing All cables mounted on one plate side DDC Mains supply L1 L2 L3 PE Min. 200mm between control cables, motor cables and signal cables Motor cable Remove cable iso Correct Min. 10mm² Min. 10mm² Motor PE Min. 10mm² Compensation cable Control cables All cables mounted on one plate side The purpose of shielding is to reduce the magnitude of radiated interference (which may affect adjacent systems or components) and to improve the interference immunity of individual devices (immunity to interference from external sources). Implementation of shielding measures in existing systems (e.g. cable replacement or additional enclosures) is possible only at considerable expense. Manufacturers of frequency converters usually provide suitable information regarding compliance with statutory limits, which also includes information on additional measures that may be necessary, such as shielded cables. Frequency converters generate steep-edged pulses on their outputs. These pulses contain high-frequency components (extending into the gigahertz range), which cause undesirable radiation from the motor cable. This is why shielded motor cables must be used. The task of the shield is to “capture” the high-fre- quency components and conduct them back to the interference source, Mains supply in this case the frequency converter. cable shielding. EMC (earthing) cable Motor cable glands or cable clamps can Min.earthing 200mm between cables, be usedcontrol for this purpose. They fully motor cables and signal cables L1 surround the shield and connect it to L2 Shielded cables and wiring ground over a large area. The shield L3 PE Even good shielding that complies Min. 10mm² must be routed directly to the earthing PE Min. 10mm² point and clamped firmly over a large with the limits does not fully eliminate area and the connection should be the radiation. In the near-field region, kept as short as possible at each end of you can expect to find electromagthe cable. netic fields that components and All other connection methods degrade system modules located in this the effectiveness of the shield. Users environment must be able to withoften twist the shield braid into a stand without any degradation of their pigtail and use a clamping terminal operation. Here the standard requires to connect it to ground. This form of conformance to the limits at a speciconnection creates a high transfer fied distance (e.g. 30 dB at a distance impedance for high-frequency of 10 m for Class B). With regard to the signal components, which causes level of the allowable limit, the interference to be radiated from the standard distinguishes between use in shield instead of being fed back to the 1st environment (residential environsource. As a result, the shielding effect ment) and 2nd environment (industrial may be reduced by as much as 90%. environment). For detailed information, see “The operating site is the decisive factor” section of this manual Shield gaps on page 22. Shield gaps such as terminals, switches or contactors must be Shield connection bridged by connections with the The cable shield must be connected lowest possible impedance and the all the way around to achieve effective largest possible surface area. Mo 39

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Practical aspects of shielding Ground connection The ground connection of a shield is crucial for its effectiveness. For this reason, serrated washers or split washers must be fitted under enclosure assembly screws and painted surfaces must be scraped clean in order to obtain a lowimpedance contact. Anodised aluminium enclosures, for example, provide inadequate ground bonding if plain washers are used under the fastening screws. Earth and ground leads should be made from wire with a large cross-section, or better yet from multi-cored grounding wire. If wire cross-sections less than 10 mm² are used with low-power motors, a separate PE line with a cross-section of at least 10 mm² must be run from the converter to the motor. Types of shields Frequency converter manufacturers recommend using shielded cable to shield the wiring between the frequency converter and the motor. Two factors are important for selection: the shield coverage and the type of shielding. The shield coverage, which means the amount of cable surface covered by the shield, should be at least 80%. With regard to the shield type, a single-layer braided copper shield has proven to be extremely effective in practice. Here it is important that the shield is braided. By contrast, a wound copper wire shield (such as type NYCWY) leaves long slit-shaped areas uncovered, and HF components can easily escape through these gaps. The surface area for leakage currents is also significantly smaller. Shielding is available in bulk for retrofitting. It can be pulled over the cable to provide the desired shielding effect. For short connections, metal hoses or pipes can be used as an alternative. Cable ducts can replace shielding only under certain conditions (a radiation-proof duct with good cover contact and a good connection between the duct components and ground). Cables with double shielding further improve the attenuation of emitted and radiated interference. The inner shield is connected at one end, while the outer shield is connected at both ends. Twisted conductors reduce magnetic fields. Shielded cables with twisted conductors can be used for signal lines. The attenuation of the magnetic field increases from around 30 dB with a single shield to 60 dB with a double shield and to approximately 75 dB if the conductors are also twisted. Motor supply cable In order to comply with radio frequency interference limits, cables between frequency converters and motors must be shielded cables with the shield connected to the equipment at both ends. Signal cable The distance between the motor cable and the signal cable should be more than 20 cm, and the mains cable and motor cable should be routed separately as much as possible. Interference effects decrease significantly with increasing distance. Additional measures (such as divider strips) are essential with smaller separations. Otherwise interference may be coupled in or transferred. Control cable shields must be connected at both ends in the same way as motor cable shields. In practice, single-ended grounding may be considered in exceptional cases. However, it is not recommended. Transfer impedance, Zt mΩ/m 105 Aluminum coated with copper wire 104 Spiral copper wire or reinforced steel cable 103 102 Copper wire, single-layer, braided with percental varying screen coverage 10 1 Copper wire double-layer, braided Copper wire double-layer, braided with magnetic screened interlayer 10-1 10-2 Cable inside copper or steel tube 10-3 0,01 0,1 1 10 100 MHz There are many types of shielded cable. Only some of them are suitable for use with frequency converters. 40 Step 3

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Step 4: Practical aspects of frequency converter selection Basic design In practice, designers and operators often select frequency converters solely on the basis of their rated power in kilowatts. However, frequency converters must always be selected on the basis of the actual rated motor current Inom under the highest system load. This selection criterion is more reliable because motor output power depends on the mechanical shaft load instead of the electrical input power. The motor efficiency is also not taken into account. By contrast, the rated capacity of frequency converters (in kilowatts) is based on the rated power Pnom of four-pole motors. In addition, motors in the same power class may have different rated currents, depending on the motor manufacturer and the efficiency class. For example, the rated current of an 11-kW motor can range from 19.8 A to 22.5 A. Remark: An 11 kW VLT® HVAC Drive frequency converter has a rated current of 24 A. This provides enough reserve power to drive a motor rated at 11 kW. However, the rated current alone is not sufficient to determine the corresponding electrical input power. The frequency converter must also supply a sufficiently high motor voltage. With a 400 V mains system, this means a full 400 V at 50 Hz on the motor terminals. There are still frequency converters on the market that are not able to achieve this. The output voltage is reduced due to voltage drops in the filters, chokes and motor cable. If the output voltage is reduced to 390 V, for example, the motor needs more current to produce the required power. Remark: A special modulation method is used in VLT® HVAC Drive units to provide the full motor voltage. Even with 10% undervoltage on the mains, the rated motor voltage and rated motor torque are maintained. As the losses increase quadratically with the current, the motor heats up more, which reduces its service life. Of course, the user must also take the increased current demand into account in the design. time, in addition to the rated motor torque, for example to enable a pump in which sludge has collected and deposited to overcome the resulting static friction. This briefly available maximum torque is called overload torque. In applications that do not need start-up torque significantly higher than the rated motor torque, a relatively low overload capacity is generally adequate (for example, Roots blowers with unloaded start-up require only 110 % of the rated motor torque). Note: Displacement pumps, Roots blowers and compressors are not classified as fluid flow machines. Due to their operating principle, frequency converters for use with such equipment should be designed for constant torque. Constant or variable torque The load driven by the motor is the key factor for selecting the right frequency converter. A distinction must be made between loads whose torque characteristic increases quadratically with increasing speed (such as centrifugal pumps and fans) and loads that can require high torque from the motor over their entire working range, even at low speeds (such as Roots blowers). Most drive systems in HVAC applications have a load curve that increases quadratically with speed until the rated torque is reached. In order to achieve efficiency-optimised operation under these load conditions, the frequency converter provides a motor voltage that increases quadratically with the motor rotating field frequency. For applications with a constant high torque, in most cases it is also necessary to consider the requirement for acceleration or start-up under heavy load. In this case, the frequency converter must be able to supply extra drive power to the motor for a short 41

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Practical aspects of load curves for HVAC/R applications Characteristic curves and applications Constant-torque applications Low starting torque (110% overload) Scroll compressor [0.6 to 0.9 nominal] Screw compressor [0.4 to 0.7 nominal] Piston compressor [0.6 to 0.9 nominal] Normal starting torque [overtorque] Scroll compressor [1.2 to 1.6 nominal] Screw compressor [1.0 to 1.6 nominal] cylinder compressor [up to 1.6 nominal] 4-cylinder compressor [up to 1.2 nominal] 6-cylinder compressor [up to 1.2 nominal] High starting torque [overtorque] 2-cylinder compressor [up to 2.2 nominal] 4-cylinder compressor [up to 1.8 nominal] 6-cylinder compressor [up to 1.6 nominal] Variable-torque applications Fans Centrifugal pumps Well pumps1 Pressure booster pumps Filter feed pumps Groundwater pumps1 Hot water pumps Heating pumps (primary and secondary circuit) Ducted impeller pumps (solids) Cooling water pumps (primary and secondary circuit) Cistern pumps Sludge recirculation pumps Sump pumps1 Turbocompressors Submersed pumps1 Surplus sludge pumps 1 Sine-wave filter recommended Note: Compressors usually have a limited speed range (min./max. speed or frequency) as well as a limited number of start/ stops and/or require a sinusoidal filter for operation. Remember to check the torque characteristics of pumps before using them. Constant torque Drehzahlunabhängige Drehzahlunabhängige Belastungscharakteristik Belastungscharakteristik Speed independent Variable torque Drehzahlabhängige Drehzahlabhängige Belastungscharakteristik Belastungscharakteristik Speed dependent load characteristics Drehmoment Drehmoment load characteristics Drehmoment Torque Torque Drehmoment Drehzahl Drehzahl Speed Konstantes Drehmoment Konstantes Drehmoment 1) 1) Drehzahl Drehzahl Speed Quadratisches Drehmoment Quadratisches Drehmoment Anwendung mit quadratischem Drehmoment Anwendung mit quadratischem Drehmoment 2) 2) 2) Anwendung mit konstantem Drehmoment in % Anwendung mit konstantem Drehmoment in % 42 Drehkolbengebläse 110 Drehkolbengebläse 110 Oberflächenbelüfter 110 Oberflächenbelüfter 110 T auchmotorpumpen T auchmotorpumpen 2) 2) Unterwasserpumpen Unterwasserpumpen Step 4

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Practical aspects of multi-motor operation (special case) Design If the operator’s objective is to run several motors in parallel from the same frequency converter, the following factors must be taken into account in the design: The rated currents and powers of the motors must be added together. Selection of a suitable frequency converter is based on the two sums power and current. For motor protection, the operator must connect the PTC thermistors of the motors in series, and the frequency converter will then monitor this series-connected signal. The connected motors operate the same in terms of their rated speed. This means that the frequency converter drives all of them at the same frequency and with the same voltage. Note: Due to the fact that the resistances of the series-connected PTC thermistors add together, there is no point in using the thermistor monitoring capability of the frequency converter for motor protection if more than two motors are operated in parallel. Cable routing To be avoided with multi-motor operation: Parallel conductors cause additional capacitance. For this reason, users should always avoid this type of connection. The working currents drop because the LC filter blocks the clock frequency. This allows the motors to be connected in parallel. The motor cables may also be routed together over longer distances if necessary. Recommended for multi-motor operation: daisy-chain the motor cable from one motor to the next. To be avoided Recommended Recommended M MM M MM Sinus M MM VSD VSD VSD M MM Sinus VSD Sinus Filter VSD Filter VSD Filter M MM VSD VSD VSD M MM M MM Problematisch: Parallele Leitungen Problematisch: Parallele Leitungen Problematisch: Parallele Leitungen erzeugen zusätzliche Kapazitäten. erzeugen zusätzliche Kapazitäten. erzeugen zusätzliche Kapazitäten. Nur bei kurzen Kabeln zu empfehlen Nur Nur bei kurzen Kabeln zu empfehlen bei kurzen Kabeln zu empfehlen M MM Nach (Sinus) Filter sind parallele Leitungen Nach (Sinus) Filter sindsind parallele Leitungen Nach (Sinus) Filter parallele Leitungen unproblematisch unproblematisch unproblematisch M MM Ideal: Kabel von Motor zu Motor durchIdeal: Kabel von von Motor zu Motor durchIdeal: Kabel Motor zu Motor durchschleifen schleifen schleifen 43

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Practical aspects of EMC measures Putting theory into practice All frequency converters are wideband interference sources, which means they emit interference over a wide frequency range. Facility operators can reduce the amount of interference emitted by frequency converters by taking suitable measures. For example, they can ensure trouble-free facility operation by using RFI filters and mains chokes. With some makes, these components are already installed in the frequency converter. With other makes, the plant engineer must allow additional space (which is always at a premium) for this in the cabinet. For general information regarding EMC, low-frequency mains interference and radio-frequency interference, see pages 13 ff of this manual. Note: Good-quality frequency converters are equipped with good RFI protection and mains interference reduction components as standard. These components account for approximately 15 to 20% of the price of a frequency converter. Radio frequency interference Practical recommendations See pages 21 ff of this manual for extensive information on radio frequency interference. The main objective in practice is to obtain systems that operate stably without interference between their components. Nevertheless, it often happens that after remodelling and/or the introduction of new components, it is no longer possible to make sensitive measurements without interference and/or the instrument signals are corrupted. These pitfalls are exactly what must be avoided. In order to achieve a high level of interference immunity, it is therefore advisable to use frequency converters with high-quality RFI filters. They should fulfil the category C1 requirements specified in the EN 61800-3 product standard and thereby conform to the Class B limits of the EN 55011 generic standard. Additional warning notices must be placed on the frequency converter if RFI filters that do not correspond to category C1, but instead only category C2 or lower, are used. The responsibility ultimately rests with the operator. As mentioned on page 22, in case of problems the inspection authority will always base its recommendations for eliminating interference on the A1/A2 and B limits for interference defined in the EN 55011 generic standard 44 Step 3 according to the operating environment. The operator bears the costs of remedying EMC problems. The operator is ultimately responsible for the appropriate classification of devices with respect to these two standards. Due to the use of cables to transmit signals and power, conductive interference can easily spread to other parts of the system or facility if adequate measures are not taken. By contrast, interference radiated directly from the device or the cable is spatially confined. Its intensity decreases with every centimetre of distance away from the interference source. For this reason, installation of the converter in a suitable cabinet in compliance with EMC rules is usually sufficient to limit radiated interference. However, the system operator should always provide a suitable filter to limit conducted interference. conformance and cabling of integrated filters. Optional external RFI filters installed ahead of the frequency converter also cause an additional voltage drop. In practice, this means that the full mains voltage is not present at the frequency converter input and overdimensioning may be necessary. Costs are incurred for assembly, cabling and the material, and EMC conformance is not tested. Another significant factor is the maximum length of the connected motor cable for which the frequency converter still complies with the EMC limits. In practice, this can range from 1 metre to 50 metres. Better RFI filters are necessary with longer cable lengths. Note: To ensure interference-free operation of the drive system, you should always use a category C1 RFI filter. VLT® HVAC Drive units are supplied as standard with built-in RFI filters conforming to category C1 (EN 61800-3) for use

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Mains interference The DC link affects mains interference See pages 15 ff for a description of the fundamental aspects of low frequency mains interference and measures to reduce it. The increasing use of rectifier loads aggravates the occurrence of mains interference. Rectifiers draw nonsinusoidal currents from the mains. Mains interference due to frequency converters comes primarily from the capacitors in the DC link due to their charging currents. Here the current always flows in brief pulses near the peaks of the mains voltage. Due to the high current, the mains voltage sags somewhat during brief intervals and the mains voltage is no longer sinusoidal. To keep the mains power clean, it is present necessary to limit the fifth harmonic of the current to a level of approximately 40% THD. The requirements are described in the EN 61000-3-12 standard. In application scenarios in which the operator must reduce mains interference to a THD level less than 10% or 5 %, optional filters and active measures may be used in order almost fully to attenuate mains interference from the equipment. (lower mains interference). The degree of distortion of the mains voltage depends on the quality of the mains system (transformer impedance and line impedances). The figures in the following table can be regarded as a guideline for the connected frequency converter load (or other three-phase rectifier load) as a percentage of the rated power of the supply transformer. If the maximum value is exceeded, you should consult the frequency converter manufacturer. In addition to reducing mains interference, mains chokes increase the life of the DC link capacitors because they are charged more gently due to the limitation of the current peaks. Mains chokes also improve the ability of the frequency converter to withstand the stress of mains transients. Wire cross sections and mains fuse or circuit breaker ratings can be smaller due to the lower input currents. However, chokes add to the cost and take up space. Remark: A mains choke in the form of a DC link choke is integrated in all VLT® HVAC Drive frequency converters as standard. This reduces the THD from 80% to 40%, thereby fulfilling the requirement of EN 61000-3-12. The effect is therefore comparable to that of a three-phase mains choke (UK 4%). There is no voltage drop that must be compensated by the frequency converter; the full voltage (400 V) is available to the motor (see page 35). Reduction measures Various options are available to facility operators in order to restrict mains interference. They can be classified into passive and active measures, and they differ in particular in terms of project engineering. Maximum 20% frequency converter load on transformer in case of FCs without mains interference reduction measures, which means unchoked or only lightly choked (e.g. with UK 2%) Maximum 40% frequency converter load on transformer in case of FCs with mains interference reduction measures, which means choked with UK at least 4% The above maximum load figures are recommended guideline values, which based on experience allow trouble-free facility operation. Mains chokes The usual and least expensive way to reduce mains interference is to install chokes either in the DC link or at the input of the frequency converter. Fitting a mains choke in the frequency converter extends the duration of current flow for charging the DC link capacitors, reduces the current amplitude, and significantly reduces the distortion of the mains voltage 45

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Practical aspects of EMC measures A low harmonic drive frequency converter is a frequency converter with a built-in active filter that acts on the mains. Rectifiers with 12, 18, or 24 pulses per cycle In practice, frequency converters with rectifiers having a large number of pulses per cycle are primarily found in the higher power range. They require special transformers for proper operation. Active filters, active front ends and low harmonic drives An innovative approach, based on improved semiconductor devices and modern microprocessor technology, is to use active electronic filter systems. They constantly measure the mains power quality and use an active current source to feed specific waveforms into the mains system. The net result is a sinusoidal current. Compared with the previously described filter options, the architecture of this new generation of filters is complex because they require fast, high-resolution data acquisition and high computing power. It is not possible to make a basic recommendation regarding any of the mains interference reduction measures mentioned here. What is important is to make the right decisions during the design and project engineering stage in order to obtain a drive system with high Passive filters Passive harmonic filters, which consist of LC circuits, can be used in all situations. They have high efficiency, typically around 98.5% or better. The devices are very robust and, with the exception of cooling fans if present, usually maintenance-free. The following must be borne in mind with passive filters. If they are operated with no load, they act as capacitive reactive power sources due to the circulating current flowing in the filter. Depending on the specific application, it may be worthwhile to use a group of filters, possibly with selective connection and disconnection. 46 availability, low mains interference, and low radio frequency interference. In any case, the following factors must be carefully analysed before taking any decisions regarding the reduction measures to be used: - Mains analysis - Exact overview of the mains topology - Space constraints in the available electrical equipment rooms - Options for main distribution or subdistribution systems Note: With the complex active measures there is a risk of totally missing the mark,since these measures have the serious drawback that they cause interference in the frequency range above 2 kHz (see pages 18 ff). Step 3

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Practical aspects of residual current devices AC/DC residual current protective devices In German-speaking countries, different terms were previously used for residual current protective devices sensitive to AC only or devices sensitive to AC and DC. These devices are known internationally as residual current circuit breakers (RCCBs). The higher-level term is “residual current operated device” (RCD) as defined in EN 61008-1. If you use equipment in a protected area that can generate a DC current in case of a fault, you must use RCDs that are sensitive to DC as well as AC current. This applies to all electrical equipment with a B6 rectifier stage (such as frequency converters) connected to a three-phase mains. This type of RCD is called a Type B RCD in accordance with IEC 60755. Due to their operating principle, frequency converters generate earth leakage currents that the plant engineer and/or operator must take into account when selecting the fault current rating. Ask your frequency converter manufacturer what type of RCD is recommended for your application. The RCD must be installed directly between the mains and the rectifier. Integration into a hierarchical structure with other RCDs is not permissible. Leakage current level The leakage current level depends on several factors. Generally speaking, leakage currents are higher in frequency converters and motors having higher power levels. A frequency converter in the 1.5 kW power range with no radio interference suppression measures and a short motor cable (around 2 m) will have a leakage current of around 4 mA. If Class B radio interference suppression is required, the leakage current with the same configuration rises to around 22 mA. A 20 kW frequency converter with Class B radio interference suppresssion and a short, shielded motor cable will have a leakage current of around 70 mA. With regard to the motor cable, users can assume a current of 0.5 to 2 mA per metre of motor cable. Cabling with paired leads yields lower values than single-lead cabling. N 1 M A n 3 5 FI-RCD L1 L2 L3 N PE Type B RCDs have two separate monitoring circuits: one for pure DC and one for fault currents with an AC component. W1 T W2 n E N 2 4 6 Load 47

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Practical aspects of earthing and motor protection Earthing measures in practice Earthing measures are described in detail in the “Motors and cabling” section of Step 3 (pages 31 ff ). If the application requires external filters, they must be fitted as close to the frequency converter as possible. The cable between the filter and the equipment should be a shielded cable, and the filter should be connected to the earth conductor on the mains side and the equipment side. It is also recommended to mount the filter flush with the surface and provide a low-impedance connection between the filter housing and ground. Filters generate leakage currents that can be considerably higher than the rated value in case of a fault (phase drop-out or asymmetric load). To avoid hazardous voltages, filters must therefore be earthed before power is switched on. With leakage currents of 3.5 mA and above, in accordance with EN 50178 or EN 60335 either: -the cross-section of the protective earth conductor must be 10 mm² or more; -or the protective earth conductor must be monitored for an open circuit; -or a second protective earth conductor must be installed in addition. The leakage currents here are highfrequency interference signals. This requires earthing with low-impedance links bonded to a large surface area and connected to earth potential by the shortest possible route. Note: Even the best measures to counter mains interference and radio frequency interference are of no use if their implementation in the installation does not conform to good EMC practice. Interference problems are inevitable in such cases. Motor protection and motor PTC thermistor Frequency converters assume the task of protecting the motor against excessive current. Thermistor sensors or thermal cutouts in the motor winding are used to provide the best possible motor protection. The signal is monitored via suitable input terminals on the frequency converter. Thermistors compliant with DIN 44081 or DIN 44082 are designed to have a resistance within a certain range at the rated response temperature (RRT) (RRT – 5°C < 550 Ω; RRT + 5°C > 1330 Ω). Many converters have functions suitable for monitoring such thermistors. In the case of motors operated in explosion hazard areas, thermistor monitoring is allowed only with certified trip devices (see page 30). The protective function of motor protection switches is limited to direct mains operation. In electrical systems with frequency converters, they can only provide motor protection in an emergency situation when the frequency converter is bypassed by a suitable circuit. The motor protection function of the switch is ineffective with frequency converter operation. Nevertheless, with proper dimensioning it can be put to good use with converter-driven motors as a sort of three-phase circuit breaker that only protects the wiring. Remark: Many frequency converters have a supplementary function called „thermal motor image“. The motor temperature is calculated from the motor data and the amount of power transferred to the motor. This function is usually implemented very conservatively and tends to trigger earlier than absolutely necessary. The actual ambient temperature at the start of the calculation process is usually not taken into account. However, this function can be used to provide a simple form of basic protection if no other form of motor protection is available. Note: With VLT® HVAC Drive, terminals 50 and 54 are normally designated for connecting thermistors. This port is suitable for motor temperature monitoring using three to six PTC bead thermistors (standard configuration: three beads per motor). 48 Step 3

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Practical aspects of operator control and data display Simple operating concept The basic technology of all frequency converters is the same, so ease of use is a decisive factor. Many functions, as well as integration in machines or systems, require a simple operating concept. It must fulfil all requirements for easy and reliable configuration and installation. The options range from simple and inexpensive numerical displays to convenient control panels that display data in text form. Simple control panels are adequate for the basic task of observing operating parameters such as current or voltage. By contrast, control panels with convenience features allow the display to show additional parameters or present them all at the same time. Clear grouping of functions and easy manual operation are also possible, as well as options for access via software, a field bus, or even remote maintenance using a modem or the Internet. A modern frequency converter should be able to combine all of the operating concepts mentioned below in a single device or to make them possible and it should at least allow switching between manual and remote control at all times. This control panel won the international iF Design Award for user friendliness in 2004. The LCP 102 was selected for this distinction from among 1000 entries from 34 countries in the category “man-machine and communication interfaces”. Graphic control panels offer ease of use and can display information in plain text. Easy commissioning Features such as Danfoss Smart Start considerably simplify the commissioning of converters. It guides the user through the basic converter settings. 49

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Practical aspects of operator control and data display Operation under local control The basic requirement is support for local operation using a local control panel. Even in the era of networked communication, there are many tasks that require the ability to control the equipment directly – such as commissioning, testing, process optimisation and on-site maintenance activities in facilities. In each of these cases, the operator or technician may need to be able to alter local values in order to incorporate the changes in the system directly and perform related tasks, such as fault diagnosis. For this purpose, the control panel should provide a simple and intuitive man-machine interface. times, especially for rarely used parameters, in order to eliminate operator errors as much as possible here as well. For the optimal use of integrated diagnostic functions, it is very helpful to be able to display graphic plots (“scope function”) in addition to alphanumeric data. In many cases this form of data display, such as ramp shapes and/or torque curves, makes troubleshooting easier. Integrated in the cabinet door In many facilities in which frequency converters are installed in cabinets, facility engineers should integrate the control panels in the cabinet doors to provide process visualisation. This is only possible with frequency converters that have detachable control panels. With the control panel integrated in the cabinet door using a mounting frame, the frequency converter can be controlled without opening the cabinet door and its operating state and process data can be read out. Uniform concept In HVAC/R systems, a large number of frequency converters are used in a wide variety of applications. The converters, which usually are mostly from the same manufacturer, differ primarily in their power ratings and therefore in their size and appearance. A uniform operator interface for the frequency converters, with the same control panel over the entire power range, offers advantages for plant engineers and facility operators. The basic principle is that simplifying the operator interface makes commissioning and troubleshooting (if necessary) faster and more effective. Consequently, concepts based on plug-and-play control panels have proven their value in practice. Clear display The ideal solution is a graphic display, since it allows the user to select the preferred language for the user interface and the basic display mode can show the essential parameters of the actual application. To maintain clarity, this status information must be limited to the essential parameters and it must be possible to adapt or change the parameters at all times. It is also helpful to be able to block or hide certain functions according to the knowledge level of the operator and to limit parameter display and the ability to modify parameters to what is actually necessary for process adjustment and control. With the large number of functions provided by modern frequency converters, which often have several hundred parameters for optimal adaptation, this reduces operator errors and thereby reduces expensive downtime and facility outages. Likewise, the display should have an integrated help function for the individual functions so that support is available to the commissioning technician or service technician at all Note: Ensure that the frequency converter you plan to engineer into the system has the right operating concept. A design that provides the greatest possible ease of use for parameter configuration and programming is an advantage, since nowadays the functionality of the drive is not the only significant factor. Fast, easy user operation, preferably intuitive, is also important. This is the only way to reduce the effort, and thus the cost of familiarisation and the subsequent interaction times of employees responsible for working with frequency converters. Frequency converter parameters can also be configured and read out with the cabinet door close

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Practical aspects of control and parameter configuration with a PC Extended options In addition to operation using a control panel, modern frequency converters usually support parameter configuration and data readout by a PC program. This software usually runs under Windows and supports several communication interfaces. It enables data exchange over a traditional RS 485 interface, a field bus (Profibus DPV1, Ethernet, etc.) or a USB interface. A clearly structured user interface provides a quick overview of all the drives in a system. A good program also allows users to manage large systems with many drives. Parameter configuration is possible online and offline. Ideally, the program also allows documents to be integrated into the system. Among other things, this makes it possible to access system electrical diagrams or operating manuals from the program. Remark: The MCT 10 program is a Windows-based engineering tool for easy system engineering, parameter configuration and programming of VLT® HVAC Drive units. In addition to parameter configuration, PC software for frequency converters enables users to record process data or manage systems. 51

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Practical aspects of data exchange Bus systems Modern frequency converters are intelligent, which enables them to handle many tasks in drive systems. Nevertheless, even now many devices operate with only four data points in a control system or under control of a DDC and act only as speed controllers. This means that operators do not make full use of the many useful functions and do not have access to stored system data. However, it is easy for users to exploit the full potential of frequency converters by using a field bus link, such as BACnet, to integrate them in the control system. With just one hardware data point, users have full access to all objects of the installed frequency converters. Cabling and commissioning are simpler, which leads to cost savings from the installation phase onward. A large volume of data for effective facility management is available. Decoding of collective fault messages allows faults to be diagnosed, even remotely and the right fault correction actions to be initiated. Better facility management The control room operator is able to monitor and adjust all frequency converter settings remotely. Status data, such as the output frequency or power consumption, can be read out and processed at any time. Additional data for effective energy and peak load management is available without additional components. Simplified commissioning Parameter configuration is performed from the control room. All settings can be copied quickly and easily from one frequency converter to another. A persistent backup copy of the settings can be stored in the display memory. Designers and commissioning staff can document the settings at the press of a button. Note: The RGO 100 Remote Guardian Option sets new standards for monitoring, maintenance and alarm processing for frequency converters in one or more facilities. It supports typical tasks such as remote action, remote maintenance, alarm processing and data logging for system configuration and system monitoring. Lower installation costs It is not necessary to equip every frequency converter with a display. The user or operator can access all relevant frequency converter data via the control system. Simplified wiring with twowire connections Unused frequency converter inputs and outputs can be used as I/O ports to integrate other components in the application or building, such as sensors, filters and limit switches, into the control system. In many cases adding additional I/O points are cheaper than installing and programming an external/ additional DDC controler. There is no need for input and output components, since a single hardware data point is sufficient for controlling the frequency converter. Monitoring functions such as motor thermistor monitoring, dry pump protection, etc., as well as output and operating hours counters, are available without additional components. Better alarm management Detailed alarm messages simplify the pin-pointing of possible fault causes and thereby provide effective support for remote facility monitoring. Remote maintenance using modems or the Internet allows state and/or fault messages to be displayed quickly, even with remote systems or system components. Busses for VLT® HVAC Drive Integrated Modbus RTU FC Protocol N2 Metasys FLN Apogee BACnet (Standard) Optional MCA 101 – Profibus DP V1 MCA 108 – LONworks MCA 109 – BACnet (Extended) MCA 120 – Profinet MCA 121 – EtherNet/IP MCA 122 – Modbus TCP 52 Step 3

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Practical aspects of additional selection factors Process controller Modern frequency converters are intelligent drive controllers. They can perform tasks and functions traditionally handled by PLC/DDCs. The implemented process controllers can also be used to build independent high-precision control loops. This facility is especially useful when retrofitting systems with insufficient DDC capacity or no DDC at all. Active process parameter transducers (actual value transmitters for flow, pressure or level) can be powered from the frequency converter’s 24 V DC control voltage if it has sufficient power capacity. Maintenance Most frequency converters are virtually maintenance-free. Highpower frequency converters have built-in filter mats which must be cleaned from time to time by the operator, depending on the dust exposure. However, it must be noted that frequency converter manufacturers specify maintenance intervals for the cooling fans (approximately 3 years) and capacitors (approximately 5 years) in their equipment. Remark: Danfoss VLT® frequency converter models up to 90 kW are maintenance-free. Models rated at 110 kW or more have filter mats integrated in the cooling fans. They must be checked periodically and cleaned as necessary. Storage Like all electronic equipment, frequency converters must be stored in a dry place. The manufacturer’s specifications in this regard must be observed. Some manufacturers specify that the device must be formed periodically. For this purpose, the user must connect the device to a defined voltage for a certain period. This forming is necessary due to the aging of the capacitors in the device’s DC link. The aging rate depends on the quality of the capacitors used in the device. Forming counters the aging process. Remark: Due to the quality of the capacitors used and the flexible, order-specific manufacturing concept, this procedure is not necessary with VLT® HVAC Drive frequency converters. Controller Reference scaling PID Motor controller Application Process Feed back VLT® HVAC Drive PID process controller block diagram 53

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VLT® HVAC Drive VLT® HVAC Drive units are available with power ratings from 1.1 kW to 1.4 MW and a rated voltage of 200 - 690 V. VLT® Low Harmonic Drive versions are also available for reduced mains interference. Danfoss VLT® HVAC Drives are specifically designed for use in HVAC applications. Dedicated fan features • • • • • • • Velocity-to-flow conversion Intelligent AHU functions Fire Override Mode Extends BMS capacity Resonance Monitoring Stairwell Pressurisation 4 x PID controller • • • • Flow compensation No/low flow Dry pump protection Optional sensorless pump control Dedicated compressor features • Premium torque control • Replace a cascade with a single compressor • Set point in temperature • Fewer starts and stops • Quick start-up improving energy efficiency Unlike many other makes, all important components and functions are integrated as standard: • Built-in RFI filter compliant with EN 61800-3 category C1 (Class B limits as defined by EN 55011) • Built-in mains interference chokes (UK 4%) • AEO function for especially high energy savings • USB interface Dedicated pump features The VLT® HVAC Drive offers a vast number of pump-specific features developed in cooperation with OEMs, contractors and manufacturers around the world. • Embedded Pump Cascade Controller • Vital water supply • Sleep Mode • Dry Pump Protection and • End of Curve • Auto tuning of the PI controllers • Real time clock • VLT® HVAC Drive in low harmonic version • Integrated cascade controller for three fans, pumps or compressors • Optional active and passive mains filters for additional harmonic reduction • Optional sine-wave filter and du/dt filter for all power ratings • RS 485 serial interface • Dimensioned for long service life • Full mains voltage at the output • Long motor cables may be connected (150 m shielded or 300 m unshielded) • PTC thermistor monitoring • Outlet flow monitoring Extensive information is available from your Danfoss contact person or the web. A considerable amount of information is available for downloading on the website. www.danfoss.com/vlt 54

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Directives related to frequency converters CE mark The CE (Communauté européenne) mark is intended to eliminate technical barriers to free trade between the EC and EFTA states (inside the ECU). The CE mark indicates that the product manufacturer conforms to all applicable EC directives which have been transposed into national law. The CE mark says nothing about the quality of the product. Technical specifications cannot be deduced from the CE mark. The directives that must be observed within the scope of use of frequency converters include the Machinery Directive, the EMC Directive, and the Low-Voltage Directive. Machinery Directiveve Application of the Machinery Directive 2006/42/EC became mandatory on 29 December 2009. Machinery Directive 98/37/EC was thereby abrogated. The key message of the directive is that a machine, consisting of an aggregate of interconnected components or devices of which at least one is able to move, must be fashioned such that the safety and health of people and as appropriate, domestic animals or goods are not endangered as long as the machine is correctly installed, suitably maintained and used as intended. Frequency converters are classified as electronic components and are therefore not subject to the Machinery Directive. When plant engineering firms use frequency converters in machines, they generate a manufacturer’s declaration stating that the machine conforms to all relevant statutes and security measures. EMC Directive The EMC Directive 2004/108/EC has been in force since 20 July 2007. Its key message is that devices that are liable to generate electromagnetic interference or whose operation can be adversely affected by such interference must be fashioned such that the generation of electromagnetic interference is limited, insofar as radio and telecommunication devices as well as other devices exhibit a suitable degree of immunity to electromagnetic interference when operated according to their intended use, such that operation according to the intended use is possible. As frequency converters are not devices that can be operated independently and are not generally available, it is not necessary to document conformity to the EMC Directive by means of a CE mark or an EC declaration of conformity. Nevertheless, Danfoss frequency converters have the CE mark as an indication of conformity to the EMC Directive, and a declaration of conformity is available. Low-Voltage Directive The Low-Voltage Directive 73/23/EEC took force on 11 June 1979; the transition period ended on 31 December 1996. The key message is that electrical equipment for use with a nominal voltage of 50 to 1000 V AC or 75 to 1600 V DC must be fashioned such that the safety and health of people and livestock and the preservation of material worth are not endangered as long as the equipment is properly installed and maintained and used as intended. As frequency converters are electrical equipment operating in the specified voltage range, they are subject to the LowVoltage Directive and all devices produced from 1 January 1997 onward must bear a CE mark. Note: Manufacturers of machines or systems should ensure that the frequency converters they use bear the CE mark. An EC declaration of conformity must be provided on request. 55

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Index A Active filters Active front end Aggressive atmosphere/ gases Air conditioning Air flow Ambient temperature Ammonia Amplitude Apparent power Asymmetric load ATEX Automatic energy optimisation (AEO) Availability 17, 18, 20, 46 17, 19, 20, 46 28 27 27, 29 27 28 15 16 24 30 9, 54 8, 16 24 35 35 52 27 25 39 14 17 8 55 18 15 28 17, 23, 24, 37, 45 27 36 28 10 18 27 14 37, 38, 43 51 8 15 41, 42 38 28 53 49, 50 8 27 27, 29 28 23 Cost factor Coupling mechanism Current consumption Current spectrum 10 14 15 D Data display Data exchange DC link DC link voltage DC voltage DDC Decommissioning costs Design checklist Directives Disposal costs Distortion Distortion spectrum Downtime costs Drive system Dust exposure dU/dt filter 49, 50 51 17, 19, 23, 27, 45 34, 37 17, 20 53 10 6, 62 15, 55 10 15 18 10 8 29 20, 35, 36, 37 38, 48 12 33, 34 31, 41 14 8 37 12 55 12, 13, 14, 21, 25, 38, 44 10 7 15 8 21, 22, 23, 24, 39 7, 25 10 30 38 15 7 29 8 9, 41 15 8 B Backup power systems Bearing current Bearing stress Bus system C Cabinet heating Cabinet mounting (central mounting) Cable glands (regular and EMC) Capacitive coupling Capacitor Capacity increase CE mark Central compensation Characteristic curves Chlorine Chokes Climatic conditions Common mode filter Coated PCBs Commissioning costs Compensation current Condensation Conductive coupling Conductor Configuration Connected load Connection conditions Constant characteristic curve Contact points Contamination Control loop Control panel Control range Control room Cooling Corrosion Cos φ E Earthing Earthed neutral conductor EC motors Efficiency classes Electromagnetic waves Emax control EMC cable glands EMC characteristics EMC Directive EMC Energy costs Energy efficiency Energy network Energy savings Environment (1 or 2) Environmental conditions Environmental costs Explosion protection (ATEX) F Facility earthing Facility operator Facility services designer Filter mats Flow Fluid flow machines Fourier analysis Full load 56

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G Generator Generic standard Ground connection Ground loop Group compensation 24 21 38 38 18 16, 24 16, 18 15, 17, 18 16, 17, 42, 43 24 14 27, 35 29 28 28 31 32 30 18 12 14 22, 24 15 10 15 25 10 33 13 14 13, 2 21 14 14 12 26 12 34, 46 47, 48 7, 10 3 41, 42 24 42 8 17, 19, 46 55 24 M Machinery Directive Magnetic field Mains analysis Mains calculation Mains chokes Mains filter Mains fuse/ circuit breaker Mains impedance Mains interference Mains power quality Mains system Mains transients Mains type Maintenance costs Maintenance Material wear Minimum efficiency performance standards (MEPS) Motor bearing Motor cable Motor efficiency Motor insulation Mounting clearance Multi-motor operation 55 14 16, 24 16, 46 44, 45 21 44 24 15, 16-20, 44 15, 16, 17 8, 12, 15, 23 17, 23, 24 12 7, 10 53 8 31, 32 33, 36 35, 36, 37, 39, 40 31 36, 37 27 41 12 28 42 15 8, 10 8 21, 22, 25 36, 37, 38 8 41 8 28 50 41 8, 9 17, 20, 46 8 8 33, 34 23 8 8, 9 9 17, 19, 23 57 H Harmonic calculation Harmonic current Harmonic distortion Harmonic filter Harmonic load Harmonics Heat loss/dissipation Heat sink Hydrogen fluoride Hydrogen sulphide I IE classes IEC enclosures Ignition protection class Individual compensation Individual earthing Inductive coupling Industrial environment Industrial mains Initial capital costs Input rectifier Installation conditions Installation costs Insulation stress Interference emission Interference fields Interference immunity Interference level Interference sink Interference source Interference transmission IP ratings IT mains system N Neutral conductor, seperate/ combined Nitrogen Nonlinear characteristic Non- sinusodial currents O Operating costs Operating point Operating site (EMC) Output Filter Overall system Overload capacity Oversynchronous range Ozone L LC filter, circuits Leakage current Life cycle costs (LCC) Lightning strikes Linear characteristic Load asymmetry Load characteristic Load shock Low Harmonic Drive (LHD) Low-Voltage Directive Low-voltage grid P Panel mounting kit Parallel operation Partial-load operation Passive filters Payback time Peak currents Permanent magnet motors (PM/ PMSM) Phase shift Piping system Potential energy savings Power consumption Power factor

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Index Pressure Process controller Product standard Project engineering Proportionality rules Protection ratings Protective earth conductor Provision costs PTB approval PTC thermistor Public power grid Pump systems 8 53 21 7 9 25, 26 12 8 30 30, 43, 48, 54 15 10 7 14 39 21, 22, 44 8, 41 47 9, 35 24 15, 17, 24, 46 13, 42 27 8 22, 24 47 24 8, 36 21, 42 21, 36, 44 16 10 S Screening measures Second-level protection Service life Shielding Short circuit Sine-wave distortion Sine-wave filter Sinusoidal voltage Special environment Staggered windings Starting current limiting 39 21 8, 27, 29, 42 39 21 15 30, 36 15 22 24 8 15, 17, 18, 20, 45 35 33 9, 10 12 8, 41, 42 24, 45 18, 23, 24, 41 12 16 9 10 23 36, 37, 41 8 10 25 14 35 Q Quality T THD (total harmonic distortion) Thermal stress Three- phase induction motors (TPIM) Throttle valve TN mains systems Torque characteristic Transformer (load, utilisation) Transients TT mains system R Radiation coupling Radiation Radio frequency interference Rated motor current RCD Reactive current Reactive power Rectifier Reduction/Derating Relative humidity Repair costs Residential environment Residual current device Resonances Retrofit RFI filter RFI RMS value Run time, pump U Undervoltage losses V V/f characteristic Valve control Varistor Voltage drop Voltage sags Volumetric flow W Wall mounting (local) Wavelength Winding 58

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Abbreviations AFE AHF ATEX CE CEMEP DC DDC Eff EMD EMC EN FC HVAC IE IEC IP ratings LCC LHD MEPS PCB PFC PTB PTC RCCB RCD RFI THD Active Front End Advanced Harmonic Filters Atmosphère explosible Communauté Européenne European Committee of Manufaturers of Electrical Machines and Power Electronics Duty Cycle Direct Digital Control Efficiency classes (motors) Electromagnetic discharge Electromagnetic compatibility European Norm (standard) Frequency converter Heating Ventilation and Air Conditioning International Efficiency (motors) International Electrotechnical Commission Ingress Protection ratings Life Cycle Cost Low Harmonic Drive Minimum Efficiency Performance Standards Printed Circuit Board Power Factor Correction Physikalisch - Technische Bundesanstalt Positive Temperature Coefficient Residual Current Circuit Breaker Residual Current Device Radio Frequency Interference Total Harmonic Distortion 59

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Notes

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MAKING MODERN LIVING POSSIBLE Frequency Converter Design Checklist The four steps of basic frequency converter design for operationally reliable HVAC/R applications Starting after the determination of the drive task and torque characteristics If you verify all items in this checklist, you can confidently look forward to trouble-free facility operation. Mains systems Mains type: TN-C, TN-S, TT, IT TN-S is favourable with regard to EMC. Special measures are necessary with IT mains systems. Observe the EMC standards and their limits. How much mains interference is already present? What is the maximum allowable harmonic current (THD)? What is the environment class (1 or 2) of the facility? Fit power factor correction equipment with chokes. Are the FCs adequately protected against main transients? Rule of thumb for transformer load: approximately 40% FC load (with choke). Other conditions apply to the FC here than with mains operation. Ambient conditions Installation location FC mounted centrally in a cabinet (IP20) or locally on the wall (IP54 or IP66)? Cooling of cabinet and FC; high temperatures damage all types of electronic components. Coated PCBs for protection against aggressive gases: hydrogen sulphide (H2S), chorine (Cl2 and ammonia (NH3). Dust on or in the FC reduces cooling effectiveness. Here FCs are subject to restrictions. EMC Cooling concept Mains interference (low frequency) Radio frequency interference (high frequency) Power factor correction equipment Aggressive atmosphere/ gases Dust exposure Potentially explosive atmospheres Mains transients Max. transformer utilisation Operation with a standby generator www.danfoss.com/drives

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MAKING MODERN LIVING POSSIBLE Motor and cabling Motor efficiency classes Motor suitability for FC operation Output filter: sine-wave or du/dt Selecting an energy-efficient motor Frequency converter Dimensioning and selection Special case Multi-motor operation Radio frequency interference (high frequency) Mains interference (low frequency) Dimension according to motor current. Take voltage drops into account. Special conditions apply here. Ask the motor supplier to confirm suitability for FC operation. Supplementary filters for special applications. Use a cable with suitable shielding. Observe the maximum connected cable length specification of the FC. Ensure proper potential equalisation. Is an earthing plan available? Use EMC cable glands and terminate the shield correctly. Specify suitable RFI filters for the actual EMC environment. Use mains interference chokes to reduce harmonic currents. Have measures to counter leakage currents been taken? Motor cable Earthing measures Earthing measures Shielding measures RCDs Use only type B RCDs. The FC monitors the motor PTC thermistor. (EX zone PTB approval) Operator control and data display using a text display (installed in the cabinet door). Over bus systems (e.g. Profibus) or over conventional wiring between terminals. FCs can perform DDC tasks or establish autonomous control loops. Is the frequency converter maintenance-free? Motor protection and motor PTC thermistor Operator control and data display Data exchange (bus systems) Process controller Maintenance www.danfoss.com/drives

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What VLT® is all about Danfoss VLT Drives is the world leader among dedicated drives providers – and still gaining market share. Environmentally responsible VLT® products are manufactured with respect for the safety and well-being of people and the environment. All activities are planned and performed taking into account the individual employee, the work environment and the external environment. Production takes place with a minimum of noise, smoke or other pollution and environmentally safe disposal of the products is pre-prepared. UN Global Compact Danfoss has signed the UN Global Compact on social and environmental responsibility and our companies act responsibly towards local societies. EU Directives All factories are certified according to ISO 14001 standard. All products fulfil the EU Directives for General Product Safety and the Machinery directive. Danfoss VLT Drives is, in all product series, implementing the EU Directive concerning Hazardous Substances in Electrical and Electrical Equipment (RoHS) and is designing all new product series according to the EU Directive on Waste Electrical and Electronic Equipment (WEEE). Impact on energy savings One year’s energy savings from our annual production of VLT® drives will save the energy equivalent to the energy production from a major power plant. Better process control at the same time improves product quality and reduces waste and wear on equipment. Dedicated to drives Dedication has been a key word since 1968, when Danfoss introduced the world’s first mass produced variable speed drive for AC motors – and named it VLT®. Twenty five hundred employees develop, manufacture, sell and service drives and soft starters in more than one hundred countries, focused only on drives and soft starters. Intelligent and innovative Developers at Danfoss VLT Drives have fully adopted modular principles in development as well as design, production and configuration. Tomorrow’s features are developed in parallel using dedicated technology platforms. This allows the development of all elements to take place in parallel, at the same time reducing time to market and ensuring that customers always enjoy the benefits of the latest features. Rely on the experts We take responsibility for every element of our products. The fact that we develop and produce our own features, hardware, software, power modules, printed circuit boards, and accessories is your guarantee of reliable products. Local backup – globally VLT® motor controllers are operating in applications all over the world and Danfoss VLT Drives’ experts located in more than 100 countries are ready to support our customers with application advice and service wherever they may be. Danfoss VLT Drives experts don’t stop until the customer’s drive challenges are solved. DKDD.PB.36.U1.02 VLT®isatrademarkofDanfossA/S ProducedbyPE-MMSC2011.08