Aiming at the problem that the control effect of traditional controller is not good, an energy-saving controller of electric automation control is designed. In the design and use of hardware, the energy-saving control power system is optimized to ensure the energy control power in the process of electrical automation control and reduce the energy consumption. The other energy-consuming hardware are optimized to ensure the minimum energy consumption in the use process. In the software design, the lowest power of power control is recalculated to ensure that there is no loss in the reserve process. The control power supply system is optimized to avoid the excessive loss of the traditional control system. The power automatic regulation is optimized and improved to ensure that the energy-saving controller in the electrical automation control can be effectively implemented. Reduce energy consumption. The experimental results show that the validity of the energy-saving controller in the electric automation control is verified by the validity of the experimental data. The rapid development of modern economy has greatly promoted the process of urbanization, and energy shortage in the world has been put on the agenda as a major issue. As the main energy and economic lifeline, power energy is also in constant urgency, so how to reduce energy consumption has gradually become the focus of attention.
Therefore, the energy-saving optimization of the electrical automation system can ensure the power of energy control in the process of electrical automation control, and greatly reduce the loss of energy.
Improving the energy conversion efficiency of the electrical automation system to ensure that the electrical automation equipment system is in a high-quality operation state can reduce the energy consumption of the system. However, this method has relatively strict requirements for the quality of the automation equipment, so it has relative limitations [2].
Aiming at the above problems, a design method of energy-saving controller in electrical automation control is proposed. The simulation results show that the proposed energy-saving controller design in electrical automation control can avoid the loss of redundant limit of traditional control system, and optimize and improve the power automatic regulation. The design scheme of energy-saving controller in electric automation control system designed in this paper has strict requirements on hardware system. It needs to collect the conventional energy consumption in electric automation control system. Its main purpose is to meet the requirements of control signal generation modulator and response judgment modulator. The ultimate strength circuit is implemented through these two modulators. In the process of optimizing the energy-saving controller of the electric automation system, the total energy consumption of the electric automation system is selected to obtain the dynamic change of the power energy demand rate and calculate the energy loss parameters of the power system under the operation and non-operation conditions. In the process of optimizing the energy-saving controller of electric power system, taking the operation efficiency, energy consumption and abnormal energy loss of electric automation system as reference, combining professional knowledge and fuzzy theory, the system energy-saving control principle is set up. Based on this, other hardware optimization of the energy-saving controller of electric automation system is carried out, which is more precise. Realize energy-saving control of electric automation system. The energy-saving controller in electric automation control designed in this paper is based on the principle of data acquisition and processing, thermostatic element and the SFT method. Its greatest characteristic is that it can transform and fuse the electric energy efficiency.
In order to ensure the instantaneity of the results, the tactile data acquisition iteration should be carried out before the efficiency conversion and fusion. The formula is as follows: It is the voltage during the operation of the power system, the running time of the electric automation system, the non-running time of the electric automation system, the phase coefficient of the reference data, the voltage during the period, and the entropy value of the immovable proton function. Formula: for the collection of miscellaneous data; for the collection of data miscellaneous and non-standard collection of data miscellaneous. The purpose of simplifying multiple instantaneous data into a single data is to eliminate the miscellaneous data quickly and efficiently. The conversion and fusion of power efficiency can be carried out by eliminating multi-parameter data, and then the lowest power of power control can be obtained [5?6]. Formula: for converting the fused high-order specific parameters of power data; for the conversion frequency of component current in the electrical automation system; for the effective parameters of the lowest power of the collected electric energy; for representing the output power of the automation system and the constants of the electrical automation system respectively; for the forward bias of the current direction through the data transmission process. The energy-saving controller of electric automation designed in this paper optimizes the design of the machine system. The standby system connects the related hardware of the energy-saving controller in the electric automation system and controls the energy of the controller when it is not working [7?8]. The system is in a state of high energy consumption when it is not in working state.
Optimal design of standby system can effectively reduce energy consumption, so it is convenient to reduce energy consumption. Formula: Frequency of total current conversion for electrical automation system operation; Sequence coefficients in available standard sample entropy value; Energy consumption data for history; Parameters to undertake data.
The number of ballasts in standby state can be confirmed by the above treatment. Formula: for the system in standby process can use the highest actual proportion of energy consumption; for the use of essential energy consumption; for the control of the number of systems. Formula: for the basic error threshold; for the current components of the data set. Through the above formulas, the optimization of power automatic regulation is completed, and the energy consumption is effectively reduced. In order to ensure the effectiveness of the energy-saving controller in the electrical automation control designed in this paper, the parameters are set. The actual acquisition and measurement values of bipolar limit data are within the range of [10.5,15.5]. The selection should be appropriate, not too much or too little. The setting process parameters should be between [72.
9,90.0], which guarantees that the data parameters are 15.0; and the output power of the automation system should be between [3,100,4,500]. This paper designs the experiment to set up a certain proportion in the use of operation control, and the relevant proportion relationship is shown in Figure 1. In order to ensure the effectiveness of the energy-saving controller in the electric automation control system designed in this paper, it is necessary to optimize and adjust the data of the energy-saving error, and the data of the adjustment need to refer to the conventional limited data table. Reference data are shown in Table 1. Figure 2 is the result of the traditional method test. The dotted line is the selected two time nodes. It can be seen that the energy consumption of the traditional method is much higher than that of the design in this paper. Fig. 3 is a broken-line diagram of the energy dissipated by the traditional method and the present method. From these two diagrams, it can be seen that the energy consumption of the energy-saving controller in the electric automation control designed in this paper is much lower than that of the traditional method.
The energy-saving controller designed in this paper optimizes the energy-saving control power system in hardware design and application, and recalculates the lowest power of power control in software design. The validity of the energy-saving controller in the design of electrical automation control is validated by the experimental data.