CHNLGVF丨China Daqian Valve's product development and manufacturing based on research on dynamic characteristics and control of electric regulating valves
2024.10.04
Abstract
As a key control component in industrial automation, electric regulating valves’ dynamic characteristics and control accuracy directly affect the operating efficiency and stability of the system. This article conducts in-depth research on the dynamic characteristics of the electric control valve, analyzes its performance under different working conditions, and proposes an optimized control strategy and structural improvement plan to improve the response speed, control accuracy and stability of the control valve. These research results will provide a strong theoretical basis and technical support for the research and development and manufacturing of control valve products of CHNLGVF丨中國大乾閥門.
electric control valve; dynamic characteristics; control strategy; response speed; stability
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Introduction
Electric control valves are widely used in petroleum, chemical industry, electric power and other industrial fields. As the actuator in automatic control systems, the performance of the control valve is directly related to the precise control of the process flow and the safe and stable operation of the system. In recent years, with the increase in the complexity of industrial production, the requirements for electric control valves in terms of high precision, high response speed and anti-interference ability are increasing. Based on the actual needs of CHNLGVF丨中國大乾閥門丨China's large foreign trade, this article discusses the dynamic characteristics and control methods of electric control valves, aiming to provide technology improvement strategies for high-quality R&D and manufacturing of control valves.
Working principle and dynamic characteristics analysis of electric regulating valve
The electric regulating valve receives signals from the control system through the electric actuator and drives the valve actuator to adjust the flow, pressure or temperature of the medium. Its core components include electric actuators, regulating valve bodies, feedback devices and control systems. The dynamic characteristics of the regulating valve are mainly reflected in the system's response speed to input signals, accuracy and stability under different working conditions.
2.1 电动调节阀的动态响应
The dynamic response of the electric control valve includes the entire process from control signal input to valve opening change. In this process, the response speed of the actuator, the inertia of the motor, the resistance of the valve body and the nonlinear characteristics of the system will all affect the dynamic behavior of the regulating valve. Common dynamic features include:
Response time: The time from when the valve receives the command to when it reaches the set position is a key indicator of the performance of the regulating valve.
Overshoot and oscillation: During the valve adjustment process, too fast response may cause overshoot or oscillation, affecting system stability.
Stabilization time: The time required for the system to restore stability. Excessive stabilization time will affect the efficiency of the control system.
1. Operating conditions 2. Valve design characteristics
Type of actuator: The performance of the electric actuator directly affects the dynamic response of the regulating valve. Common actuators include stepper motors, servo motors, etc. Due to their precise control and high-speed response capabilities, servo motors are widely used in situations that require high dynamic performance.
Valve structural design: The design of the valve body, such as valve core shape, valve seat structure and flow channel design, directly affects the medium flow characteristics and dynamic response performance. Valves with different structures have obvious differences in their dynamic characteristics when handling high-speed or high-pressure media.
Feedback control system: The high-precision feedback control system can adjust the valve opening in real time to ensure the stability and response speed of the system. The control accuracy of electric regulating valves depends largely on the design of feedback control.
Dynamic characteristic testing and control strategy analysis
Test device and working condition settings
To study the dynamic characteristics of electric control valves, this paper has designed a simulation experimental system to test the response performance of the valve under various pressure, temperature, and flow rate conditions. The test includes the opening and closing response time, adjustment accuracy, and stability of the valve. The electric control valve used in the test is an existing product from CHNLGVF丨中國大乾閥門丨China Dagangyangmao, and the performance of different actuators (stepper motors and servo motors) was compared.
Test results and analysis of 3.2
Response time comparison: The response time of the control valve driven by the servo motor is significantly shorter than that of the control valve driven by the stepper motor. Especially under high-frequency switching operations, the servo motor shows superior performance.
Overshoot and oscillation: When the response speed of the actuator is too fast, overshoot and oscillation are prone to occur, especially during the adjustment process of high-pressure media. By adjusting the feedback control parameters, the overshoot phenomenon can be effectively suppressed.
Stability analysis: Under high-pressure and high-speed fluid media, the stability of the regulating valve is significantly affected. Optimizing the control parameters of the valve structure and actuator is an important means to improve stability.
Optimization of control strategy
Through testing and analysis, a control optimization strategy for electric regulating valves is proposed:
Closed-loop control strategy: Using a high-precision closed-loop feedback control system to adjust the action of the actuator in real time can effectively reduce the system's response time and improve control accuracy. At the same time, closed-loop control can also suppress overshoot and oscillation of the system and improve dynamic stability.
Adaptive control algorithm: In view of the differences in dynamic characteristics of different working conditions, an adaptive control algorithm is introduced, which can adjust control parameters according to real-time working conditions to ensure the response and control effect of the valve.
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Transient simulation analysis and model optimization
To further study the dynamic characteristics of electric control valves, this article uses a transient simulation method that combines CFD (computational fluid dynamics) and FEM (finite element analysis) to simulate the dynamic response process of the valve under different flow rates and pressure conditions.
Construction of transient simulation model
This paper constructs a three-dimensional simulation model of an electric control valve, mainly simulating the fluid dynamics characteristics and structural deformation during the opening process of the valve. The boundary conditions used in the simulation are consistent with the actual test conditions, ensuring the accuracy of the simulation results.
Analysis of simulation results
Fluid characteristics: When the fluid passes through the valve, complex flow field changes occur. The flow instability of the high-speed fluid in the early stage of valve opening has a significant impact on the adjustment accuracy.
Structural deformation: The impact of high-pressure fluid may cause slight deformation of the valve's internal structure, which will further affect the dynamic response of the valve. Optimizing the valve body material and structural design can effectively reduce deformation and improve adjustment accuracy.
Through simulation analysis, this article puts forward suggestions for optimizing the valve structure, including improving the valve core design, reducing flow channel resistance, and improving the impact resistance of the material, to further improve the dynamic performance of the regulating valve.
1. Enhance research and development capabilities. 2. Invest in cutting-edge technology. 3. Foster a culture of innovation within the organization. 4. Collaborate with industry experts and partners. 5. Regularly review and update technology infrastructure.
根据上述研究和分析,本文提出了一项技术改进策略,旨在提高CHNLGVF丨中國大乾閥門丨China Dagangyangmao调节阀产品的动态响应和控制精度,满足高端工业应用的需求。
Optimal design of actuator
High-performance servo motor: The introduction of high-precision servo motor further improves the response speed and control accuracy of the actuator while reducing energy consumption during operation.
Modular design: Design modular actuators according to different working conditions, so that they can be flexibly configured according to actual applications and adapt to a variety of industrial scenarios.
Valve structure optimization
Improve valve core and valve seat design: By optimizing the valve core shape and valve seat structure, the fluid resistance is reduced and the dynamic response speed of the regulating valve is improved.
Improve valve body material performance: Use high-strength, corrosion-resistant materials to enhance the stability and durability of the valve in high-pressure and high-temperature environments.
Intelligent upgrade of control system
Intelligent feedback control: Combining the real-time data feedback system with artificial intelligence algorithms to dynamically adjust valve control parameters to improve the valve's response speed and adjustment accuracy.
Adaptive control algorithm: For complex working conditions, an adaptive control algorithm is developed, which can automatically adjust the control strategy according to the actual operating status and achieve precise adjustment for different working conditions.
CHNLGVF | China Daqian Valve Product R&D and Manufacturing Process Improvement
Based on the research results of this article, CHNLGVF will implement the following improvements in the R&D and manufacturing process of control valves:
The integration of the modular design of the actuator and the intelligent control system improves the performance of the control valve in high-precision applications.
Improvement of materials and manufacturing processes, using high-strength, high-temperature, and corrosion-resistant materials to enhance product reliability and service life.
Precision control during the manufacturing process improves production efficiency while ensuring product consistency and high quality.
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Conclusion
Through in-depth research on the dynamic characteristics and control strategies of electric control valves, this article proposes a number of technology improvement strategies, aiming to improve the dynamic response capabilities and control accuracy of CHNLGVF | China Dagangyangmao control valve products. Through closed-loop feedback control, intelligent algorithm optimization, and improvements in valve structural design, the performance of regulating valves in industrial applications has been significantly improved. This research result will provide technical support and market competitiveness for CHNLGVF | China Dagangyangmao's high-quality development in the research and development and manufacturing of regulating valve products.

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