Amorphous Alloy Dry Type Transformer plays an important role in power transmission and distribution, and heat dissipation design is directly related to its operational reliability.
Material selection is the basis of heat dissipation design. Using insulating materials with high thermal conductivity, such as new nano-composite insulating materials, can effectively speed up the conduction speed of heat inside the transformer. At the same time, for the core and winding, metal materials with good heat dissipation performance are selected, and their structural design is optimized, such as using sheet or columnar structures to increase the heat dissipation area and promote heat dissipation.
The optimization of heat dissipation structure is a key link. Reasonably design the ventilation duct to ensure that air can flow smoothly inside the transformer and take away heat. A combination of natural ventilation and forced ventilation is adopted. During normal operation, natural convection is used to dissipate heat. When the load is large or the ambient temperature is high, forced ventilation equipment such as fans are started to enhance the heat dissipation effect. For example, multiple ventilation holes are set on the transformer casing, and the ventilation path is designed according to the internal heat source distribution, so that cold air enters from the bottom and is discharged from the top after passing through the heat-generating components.
Temperature monitoring and control systems are indispensable. Install high-precision temperature sensors to monitor the temperature of key parts of the transformer in real time. When the temperature exceeds the set threshold, heat dissipation enhancement measures are automatically initiated, such as increasing the fan speed or issuing an alarm to notify the operation and maintenance personnel. Through intelligent temperature control strategies, the heat dissipation intensity can be dynamically adjusted according to the load changes of the transformer to ensure that it operates within a safe temperature range.
In addition, optimize the overall layout of the transformer and reduce the thermal resistance between internal components so that heat can be distributed and dissipated more evenly. For example, reasonably arrange the relative position of the winding and the core, and use spacer heat sinks to reduce the risk of local overheating.
Through the above-mentioned optimization of the heat dissipation design of the Amorphous Alloy Dry Type Transformer, its operating reliability can be significantly improved, the downtime caused by overheating can be reduced, and the stable operation of the power system can be provided with strong guarantees, demonstrating the company's deep technical background and pursuit of excellent quality in the research and development and manufacturing of power equipment.