Transformer coil producing company by Canwin

Electrical equipment manufacturer from China: Poor power quality can severely impact the performance of transformer equipment, leading to a variety of negative outcomes. These consequences not only affect the operational efficiency of the equipment but also pose significant economic concerns. One of the primary damages caused by poor PQ is the deterioration of the transformer’s health. Poor PQ, characterized by factors like voltage sags, swells, harmonics, and transients, can cause excessive heating in transformers. This undue heat can degrade the insulation material used in transformers, subsequently reducing their lifespan and potentially leading to catastrophic failures. Therefore, poor power quality can lead to considerable damage to transformer equipment, resulting in economic losses, reduced energy efficiency, and decreased productivity. Therefore, maintaining high power quality is crucial for the optimal performance of transformer equipment and overall operational efficiency. See additional details on cut to length line manufacturers.

How to deal with the failure of the main transformer cooler? The failure of the main transformer cooler may cause the temperature of the main transformer to rise, thereby affecting the normal operation of the transformer. Therefore, if it is found that the main transformer cooler is faulty, it is necessary to take timely measures to deal with it. Here are some possible approaches: Replacing Faulty Cooler Parts: If some parts in your cooler are damaged or malfunctioning, consider replacing those parts to restore the cooler to working properly. The specific operation needs to be carried out according to the structure of the cooler and the cause of the failure. Clean the cooler: If the pipes or cooling fins in the cooler are clogged or dirt accumulates, it may reduce the cooling effect and affect the normal operation of the transformer. The way of cleaning can be used to remove the dirt and sundries inside the cooler to restore the normal operation of the cooler.

Rising temperature: The capacity of the transformer will decrease as the temperature rises. Therefore, it is necessary to consider the appropriate heat dissipation method and heat dissipation area when designing the transformer to ensure that the temperature rise of the transformer does not exceed the allowable range. Connection method: Different transformer connection methods, such as star, delta, etc., will also affect the capacity of the transformer. For the star connection, the capacity of the transformer can be increased by about 3 times; for the delta connection, the capacity of the transformer is relatively small. Insulation level: The insulation level of the transformer determines the insulation capability and safety performance of the transformer, and also affects the capacity of the transformer. To sum up, the capacity of the transformer is related to factors such as input voltage and output voltage, load nature, temperature rise, connection method and insulation level. When selecting a transformer, it is necessary to comprehensively consider various factors according to the actual situation to ensure the normal operation and stability of the transformer.

Independently developed a series of high -speed cut to length line which up to 128 pcs/mins, which increased the cutting speed 2-3 times Independently developed the bridge automatic cutting and automatic lamination cut to length line, which can realize 20 large transformer core column level for automatic lamination, this project has won the record and nomination of Guangdong major research and development projects; Participated in the application and filing of the major science and technology special project of intelligent robot and equipment manufacturing”in the research and development plan of key fields in Guangdong province in 2018-2019. The company has been constantly extending the innovation chain around the guiding ideology of industrial chain deploy innovation chain.

Canwin, a electrical equipment manufacturer mainly produces 150 model oil-type transformer core shearing equipment below 1 600KVA, 300 model dry type transformer core shearing equipment below 6300KVA, 400 model special transformer core shearing equipment below 12500KVA and 600 model special transformer core shearing equipment below 63000KVA. 800 model extra transformer core shearing equipment, 1000 model extra transformer core shearing equipment, the type 1250 model CRGsilicon steel CNC slitting machine, and the dry type transformer core under 110KV automatic cutting and laminated processing center, oil transformer core automatic cutting robot automatic lamination processing center, reactor cutting center below 35Kv, 220KV high voltage china transformer equipment tc. Transformer core & transformer coil manufacturing and assembly, including coil windings using copper and silver alloyed or continuously transposed copper cable.Canwin hire famous designer in Europe as our senior consultant, and germany Siemens as our strategic partner. The products have formed 5 series and more than 50 specifications.Canwin is your best choice of electrical equipment suppliers.

Oil immersed transformers are the most commonly used equipment mainly because of their simple structure and reliable operation. It has faster heat dissipation, uniform conduction, and better insulation performance than the dry-type transformer.Oil transformers are used in power distribution or electrical substations. Their transformer core and coils are immersed in oil, which cools and insulates. Oil circulates through ducts in the coil and around the coil and core assembly, moved by convection.

The transformer coils are referred to as the primary and secondary windings. When applying AC current to the primary winding of the transformer, the transformer coil creates a pulsing magnetic field. The core of the transformer works to direct the path of the magnetic field between the primary and secondary coils to prevent wasted energy.The machine is a very powerful and versatile machine which can wind a wide range of HV coils for distribution transformers using round and rectangular wires. It is fully automatic with paper strip winding.Winding material lnsulated with an epoxy resin -environmentally friendly.

As a result of mutual inductance, a transformer produces a transformed voltage or current when the magnetic flux produced by one winding (primary winding) links with another winding (secondary winding). There is a magnetic coupling between these two windings, and they are electrically isolated. In addition, magnetic reluctance is also known as opposition to magnetic flux flow. If, for example, the magnetic flux produced by a primary winding passes through air or any nonferrous material in order to reach a secondary winding in a transformer, it would result in a reduction in magnetic flux. Due to the high reluctance of air or nonferrous materials, it will reduce magnetic flux. See even more information on https://www.canwindg.com/

Epoxy resin is non – combustible, flame retardant, self – extinguishing solid insulation material, safe and clean. It is also a solid insulation material with proven insulation and heat dissipation technology for more than 40 years.Epoxy resin products can be used for dry type transformer, for insulation parts, for instrument transformer, for electrical composite parts and for room temperature curing. Epoxy resin dry transformer uses epoxy resin as insulation material. The high and low voltage windings are made of copper tape (foil), industrial epoxy resin is poured in vacuum and cured, forming a high strength FRP body structure. Insulation grade F, H. Epoxy resin dry transformer has the characteristics of good electrical performance, strong resistance to lightning impact, strong resistance to short circuit, small size and light weight. Temperature display controller can be installed to display and control the operating temperature of the transformer winding to ensure the normal service life of the transformer.

The main pillar of the smart grid is the smart substation, which is not only an important hub for power transmission and distribution, but also directly affects the operational and monitoring capabilities of the smart grid through its operational safety and stability. Through the network, information can be exchanged, and the transformer can share information with the process layer and the station control layer. On the premise of ensuring product performance, the integration of monitoring, control, measurement, protection, and metering is designed to achieve the integration of transformer components with actuators, sensors, and transformers.

Dry-type transformers are widely used in local lighting, high-rise buildings, airports, dock CNC machinery and equipment, etc. Simply put, dry-type transformers refer to transformers whose iron cores and windings are not impregnated with insulating oil. The relevant technical parameters of dry-type transformers include: Rated capacity (kVA): The capacity that can be delivered during continuous operation at rated voltage and rated current. Rated voltage (kV): The working voltage that a transformer can withstand during long-term operation.