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Slitting line machine manufacturer with canwindg.com: What are the consequences of parallel operation of transformers that do not meet the parallel operation conditions? Parallel operation of transformers that do not meet the parallel operation conditions may lead to the following consequences: Voltage instability: Different transformers may have different electrical parameters, such as transformation ratio, resistance, inductance, etc. If these transformers with different parameters are forced to run in parallel, the overall electrical parameters after paralleling may be unstable, thereby affecting the quality of power supply. Uneven load distribution: If the transformers with uneven load distribution are forced to run in parallel, different transformers may bear different loads, thus affecting the service life and stability of the transformers. Excessive temperature rise: If different transformers are operated in parallel, their heat dissipation conditions and methods may be different, which may cause excessive temperature rise of some transformers, and may even damage the transformer. Discover additional information on slitting line machine.
Adopt energy-saving measures: During the operation of the transformer, energy-saving measures can be adopted, such as adopting a high-efficiency cooling system, reducing the load rate of the transformer, optimizing the operation scheduling of the transformer, etc., to reduce energy loss and improve efficiency. Regular maintenance and overhaul: Regular maintenance and overhaul of transformers can maintain the normal operation and stability of transformers, thereby reducing energy loss and improving performance. Choose the appropriate transformer connection method: Different connection methods of the transformer will also affect the performance of the transformer. When choosing a transformer connection method, the optimal connection method can be selected according to actual needs and load characteristics to improve efficiency. To sum up, improving transformer efficiency can be achieved by optimizing design, selecting high-quality materials, adopting energy-saving measures, regular maintenance and overhaul, and selecting appropriate connection methods. In practical applications, various factors need to be considered comprehensively to select the most suitable method for improving performance.
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.
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.
CANWIN is not just a length lines company, but also electrical equipment manufacturer. It is the legend of people who have forged their lives with faith and action. CANWIN electrical machinery equipment manufacturing deploys an innovation chain through the industrial chain.Equipment sales can provide integrated solutions; can provide OEM/ODM services to global transformer manufacturers; can provide raw material supply to transformer manufacturers. In the form of cooperation and mutual benefit, set up the transformer manufacturing center and core processing base in the Middle East, India. Dubai. Vietnam. Thailand. etc.
A China slitting line produces longitudinal cuts in a master coil of steel to predetermined narrower widths. These smaller coils are then sent to downstream operations such as metal stampers, tube producers or roll forming houses that will use the material in their final product. Customized slitting line machine equipment mainly includes the following: Loading trolley, double support uncoiler, feeding device, traction leveling machine, trimming shearing machine, deviation correction feeding device, longitudinal shear line, waste edge winder, feed rack, pre separation device, tensioner, feeding roller, winding shearing machine, steering drum, rear axle, discharge trolley, winding auxiliary support, hydraulic system and electrical system, etc.
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. Discover extra details on https://www.canwindg.com/
With the development of the times, people’s demand for power supply and the reliability of power supply are increasingly high, so the smart grid has emerged accordingly.In the power system, the core and hub of the substation is the transformer.The function of the transformer is mainly to distribute and convert electric energy. The normal operation of the transformer directly affects the normal function of the substation.The intelligent operation of the transformer mainly involves the protection and status monitoring of the transformer, so as to achieve real-time monitoring of the transformer and ultimately ensure the safety and reliability of power supply.
Insulation level: There are standards for insulation levels. The insulation level of a transformer with a rated high voltage of 35 kV and a rated low voltage of 10 kV is represented as LI200AC85/LI75AC35, where LI200 indicates that the transformer has a high-voltage lightning impulse withstand voltage of 200 kV, a power frequency withstand voltage of 85 kV, and a low-voltage lightning impulse withstand voltage of 75 kV, and a power frequency withstand voltage of 35 kV. The current insulation level of Aux High-Tech Co., Ltd.’s oil-immersed transformer products is LI75AC35, indicating that the transformer has a high-voltage lightning impulse withstand voltage of 75 kV and a power frequency withstand voltage of 35 kV. Because the low voltage is 400 V, it can be ignored.
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.