Distribution Basse Tension
Distribution Basse Tension
Harmonic Mitigating Transformers (HMT’s) are specially designed for non-linear loads which draw significant amounts of harmonic current. While K-factor rated transformers are simply designed to handle the additional losses of supplying non-linear loads, HMT’s actually minimize the voltage distortion and power losses that result from harmonic load currents.
General purpose and K-Factor rated transformers have a high impedance to the flow of harmonic currents, and therefore, when harmonic currents are drawn by the load, significant voltage distortion can be measured on the transformer secondary. This voltage distortion leads to higher losses on nearly all devices supplied by these transformer, and depending on the amount of non-linear loading, can exceed the maximum 5% THD (IEEE 519).
Harmonic Mitigating Transformers provide a low impedance path to these harmonic currents by a combination of phase shifting and zero sequence flux cancelation:
Zero Sequence Flux Cancelation: The secondary windings of HMTs are specially designed such that zero sequence fluxes (3rd, 9th, 15th current harmonics) cancel out without being drawn from the primary and circulating in the primary delta winding. The flux cancelation provides a low impedance path for the zero sequence harmonic currents, which reduces the voltage distortion significantly. Furthermore, with no zero sequence circulating in the primary delta winding, the losses within the transformer are reduced significantly.
Phase Shifting: The non triplean harmonics (5th, 7th, 11th, 13th, 17th & 19th) are mitigated by introducing of phase shifts on the secondary side of the HMT. Depending on the arrangement selected single, dual or triple output), specific harmonic currents can be mitigated without coupling them to the primary windings.
Capacity | 15 to 1,000kVA Three Phase |
Voltage Class | 1.2kV |
Cooling | Air Cooled (ANN) |
Frequency | 60Hz (50/60Hz Optional) |
Conductors | Copper (Cu) or Aluminum (Al) Windings |
Temperature Rise | 150°C (115°C or 80°C Optional) |
Insulation System | 220°C |
Impregnation | Polyester Resin Dipped and Baked |
Efficiency | Meets North American Energy Efficiency Standards:
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K-Factor | Suitable for non-sinusoidal current load with a K-factor not to exceed 4 (K9, K13, K20 Optional) |
Primary Taps | Typically +/-2 x 2.5% taps (refer to dry type distribution transformer catalogue) |
Configuration | Single, Dual or Triple output |
Sound Level | Meets NEMA ST-20 |
Enclosure Type | Type 1 or 3R Indoor (refer to catalog) |
Enclosure Finish | ANSI/ASA 61 Grey |
Warranty | 12 Months (See Warranty and Limitations) |
Quality System | ISO 9001:2015 Quality Management System |
Certifications |
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Reference Standards |
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Optional Features & Accessories |
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Unless designed for special service conditions / environments, below are the standard service conditions for dry type distribution transformers:
To ensure proper operation, avoid installing transformers in environments with excessive moisture, extreme temperatures, or direct sunlight. Maintain recommended clearances and keep all ventilation panels unobstructed.
Any transformer which is not installed and energized immediately should be stored in a dry, clean space having a uniform temperature to prevent condensation on the windings. Dry type transformers with resin dipped or epoxy vacuum impregnated coils can be stored at ambient temperatures as low as -50C. Transformers with encapsulated or epoxy cast coils should not be stored at ambient temperatures below -20C to prevent cracking of the epoxy. Preferably, transformers should be stored in a heated building having adequate air circulation and protected from cement, plaster, paint, dirt, and water or other gases, powders, and dust. The floor on which the transformer is being stored should be resistant to the upward migration of water vapor. Precautions should be taken to prevent storage in an area that water could be present, such as roof leaks, windows, etc. Condensation or absorption of moisture can be greatly reduced by keeping the transformer enclosure 5⁰C-10⁰C above ambient temperature. This can be easily achieved by the installation and energization of space heaters (optional). If the transformer is not furnished with internal space heaters, then external, portable heaters can be used. Note: Lamps or heaters should never come in direct contact with the transformer coil insulation.
It is not advisable to store a dry type transformer outdoors, but in the case that it is unavoidable, protective measures should be taken to prevent moisture and foreign debris from entering the transformer enclosure. The plastic wrapping supplied during shipment should be left in place, and a suitable drying agent such as silica gel packs should be used. The unit should also be checked periodically for indications of condensation on the windings, coil support blocks, core, core clamping system and bus/cables.
In dry-type transformers, the surrounding air plays a critical role in their operation. Generally, low ambient temperatures do not negatively impact an energized transformer, as the no-load losses typically generate enough heat to maintain proper conditions, even in environments as cold as -40°C. However, transformers stored at low temperatures present two primary concerns:
Rex Power Magnetics recommends testing transformers (megger testing), warming them to above 0°C, or following a drying-out procedure if moisture is suspected. Refer to Rex Power Magnetics’ cold start procedures to ensure safe energization in cold conditions. Energizing a transformer with compromised insulation due to moisture can cause damage and potential safety hazards.
The minimum required clearances of a dry type transformer to walls, floors or other equipment must adhere to the local electrical code requirements.
In the absence of such requirements, Rex Power Magnetics recommends that dry type transformers be mounted so that there is an air space of no less than 150mm (6”) between the enclosures, and between the enclosure and any adjacent surface except floors. When the adjacent surface is a combustible material, the minimum permissible separation between the transformer enclosure and the adjacent surface should be 300mm (12”). Where the adjacent surface is the wall on which the transformer is mounted, the minimum permissible separation between the enclosure and the mounting wall should be 6mm (0.25”) so long as the surface is of a non-combustible material.
Temperature rise refers to average increase of temperature of the transformer windings at full load above the ambient temperature. when operating at full load. In addition to the average temperature rise of the windings, transformers also experience a « hot spot » temperature, which refers to the highest temperature point in the windings.
For example, a transformer with a 220°C insulation system may be designed with a 150°C average temperature rise and a 30°C hot spot allowance. This means that Above a 40C ambient, the total absolute temperature will not exceed 220°C. Transformers with lower temperature insulation systems (180°C or 200°C) will be designed with lower temperature rises (115° or C130°C) and hot spots so they can be installed in the same ambient temperature and still not exceed the temperature rating of the insulation system.
The table below shows the maximum average winding temperature rise, maximum hot spot temperature rise and maximum winding temperature for the most common insulation classes. Note that these are based on a max average ambient of 30°C during any 24-hour period and a maximum ambient of 40°C at any time.
Insulation Class | Insulation Class | Average Winding Temperature Rise |
Hot Spot Temperature Rise |
Maximum Winding Temperature |
Class 180 | F | 115°C | 145°C | 180°C |
Class 200 | N | 130°C | 160°C | 200°C |
Class 220 | H | 150°C | 180°C | 220°C |
Customers occasionally specify a transformer of a particular insulation class to be designed with an average temperature rise below the average temperature rise values shown in the table above. The benefits of doing so include:
The life expectancy of a dry-type transformer is primarily determined by the insulation system and the operating temperature. According to IEEE Std. C57.96, the deterioration of insulation is directly related to the time and temperature the transformer experiences during operation. Insulation materials degrade faster at higher temperatures, so the transformer’s life expectancy is closely tied to how well it is kept within its design temperature limits.
In most transformers, the highest temperature occurs at a specific point in the windings, known as the hot spot. This area undergoes the most significant wear over time, making it the primary factor in determining the transformer’s ageing process.
All of Rex Power Magnetics’ dry-type transformers are designed using UL-listed insulation systems with a maximum hot spot temperature that ensures a design life of at least 30 years under standard operating conditions (continuous rated load, typical ambient temperatures, and no sustained overloads). Transformers designed with reduced temperature rise can extend this design life expectancy to over 50 years, as operating at lower temperatures slows the insulation’s ageing process.
Factors That Affect Life Expectancy:
By following proper installation and maintenance practices, such as avoiding overloading and ensuring the transformer operates within its designed ambient temperature, you can significantly extend its lifespan. Rex Power Magnetics’ high-quality transformers are built for durability, ensuring reliable performance for decades under standard conditions.
It`s normal for new transformers to release some harmless odors from the varnish impregnation used in the coils for a week or two after energization. Older Transformers can also release some odor if loaded to a higher level than they have experienced previously in their history.
Rex Power Magnetics’ ventilated distribution transformer terminals are rated 90°C. Conductors with at least a 90°C insulation rating at or below their 90°C ampacity rating should be utilized.