Experimental Validation and Engineering Optimization of High-Voltage Power Supply in Electrostatic Field Polarization Technology

Abstract:
As a crucial electrical component, the high-voltage power supply plays a significant role in electrostatic field polarization technology. This article explores the practical application of high-voltage power supplies in electrostatic field polarization through experimental validation and proposes corresponding engineering optimization solutions, aiming to provide valuable insights for research and engineering applications in related fields.

1. Introduction
Electrostatic field polarization technology, based on electrostatic principles, has found widespread applications in powder coating, electrostatic spinning, powder conveying, and other fields. The performance of the high-voltage power supply, as the core component driving the electrostatic system, directly influences the stability and efficiency of the entire system. Therefore, experimental validation and engineering optimization of the application of high-voltage power supplies in electrostatic field polarization technology are of paramount importance.

2. Experimental Validation
2.1 Selection of High-Voltage Power Supply
In electrostatic field polarization technology, the selection of the high-voltage power supply involves considerations such as output voltage range, stability, and ripple. After comparing and screening the performance of commonly available high-voltage power supplies in the market, a high-voltage power supply with high stability and a wide output range was chosen as the experimental platform.

2.2 Experimental Design
In the experiments, a series of experimental schemes were designed, involving parameters such as electrostatic field intensity and powder conveying speed, to assess the performance of the high-voltage power supply in electrostatic field polarization technology. Simultaneously, by comparing the experimental results under different power supply parameters, the impact of the high-voltage power supply on system output was analyzed.

2.3 Analysis of Experimental Results
The experimental results indicated that selecting an appropriate high-voltage power supply effectively enhances the working efficiency and stability of the electrostatic system. By adjusting the power supply output voltage and current, precise control of the electrostatic field intensity was achieved, providing robust support for the application of electrostatic field polarization technology.

3. Engineering Optimization
3.1 Enhancement of Power System Stability
Addressing the temperature rise and fluctuation issues observed during prolonged operation of the high-voltage power supply in the experiments, corresponding heat dissipation and stability optimization solutions were proposed to ensure the prolonged stable operation of the power supply system.

3.2 Energy Efficiency Improvement
Optimizing the control algorithm and circuit structure of the high-voltage power supply resulted in operating the power supply in a higher efficiency region, reducing energy consumption, and enhancing the overall system efficiency.

3.3 Safety Reinforcement
Considering the potential hazards of high-voltage power supplies in experimental and engineering applications, a series of safety reinforcement measures, including overload protection and leakage detection, were proposed to ensure the safety of operators and equipment.

4. Conclusion
Through the research on the experimental validation and engineering optimization of high-voltage power supplies in electrostatic field polarization technology, this article provides valuable insights for research and engineering applications in related fields. The optimized high-voltage power supply system exhibits higher stability, energy efficiency, and safety in electrostatic technology, offering reliable technical support for the development of related industries. Future research directions could delve further into areas such as intelligent control of high-voltage power supplies and advanced power supply designs.