SU941970A1 - Capacitor bank power automatic adjustment method - Google Patents

Description

(5) METHOD FOR AUTOMATIC REGULATION OF CAPACITOR BATTERY POWER

one

The invention relates to the automation of the regulation of power supply systems, in particular, voltage and reactive power, using capacitor banks.

Methods are known for automatic voltage regulation, in which, for regulating a capacitor battery section, regulation is carried out on control channels, each of which reacts to a change in the sign of the signal of the corresponding output and affects the switching of sections D

The disadvantage of this solution is that it is necessary to measure the signs of the signals by each channel and independently, which makes it difficult to ensure the high stability of dead zones of control channels. go

Closest to the invention is a method for automatically controlling the power of a capacitor battery by switching its sections.

depending on the result of the comparison of the input signal, for example, the network voltage, with the section on and off settings. In this case, the commands for switching the section on and off are given with a time delay in order to adjust the voltage t2l from the fluctuations.

However, with the known control method, due to the need to compare the input signal simultaneously with two settings (on and off), which determines the presence of two executive elements in the automatic controller, respectively, the control of a capacitor battery having more than one section is impossible without the use of special software devices, and even if they are available, regulation can only be carried out according to a pre-set program.

Claims (2)

If it is necessary to control a capacitor battery having sections of different power, which is appropriate in many cases, it is impossible to automatically select the required power of the switched section, and the number of control stages provided does not exceed the number of sections of the capacitor battery. In addition, the presence of only one deadband, determined by the difference in the on and off setpoints, forces it to choose the width according to the power of the highest levection, due to which the quality of voltage regulation and reactive power deteriorates. The purpose of the invention is to improve the accuracy of the adjustment by the p-sections. The goal is achieved by the fact that according to the method of automatic control of the power of a capacitor-battery by switching its sections, carried out with a time delay and depending on the result of the comparison of the mains voltage with the voltage setting, the voltage is set additionally The settings for the voltage are directly proportional to the reactive power of the respective sections, and n time exposures are chosen inversely proportional to the reactive power of the respective sections, compare the voltage network with n settings for voltage and, depending on the result of comparison with the time delay corresponding to this section, gives a command to switch this section, and at the same time change the setting by setting the switched section by an amount corresponding to the change in network voltage commutation. FIG. 1 is a functional diagram of an automatic power control system for a two-section capacitor battery; FIG. 2 is a voltage and voltage diagram (actual control power during regulation. The automatic control system contains a capacitor battery 1 with a ratio of section powers 1: 2, and an automatic controller 2, containing, respectively, two control channels 3, each of which includes an element t of selecting and changing voltage settings, a comparison authority 5, a time element 6, two-way action and execution of 4 body 7. The common for all control channels are the converter 8 of the INPUT signal, the source 9 of the reference voltage and the summing element 10, which is necessary if the regulation is performed by the correction from the line voltage to the load current. The sum of signals proportional to the current the load and the network voltage at the output of the summed-up element 10, is converted into a constant voltage at the output of the converter 8, forming an input signal which is fed to one of the inputs of the comparison bodies 5. From the output of the source 9 of the reference voltage through the elements k of selecting and changing the voltage settings, specifying the sign and magnitude of the voltage additions ± (0.50, 6) corresponding to the steps of the section control, the voltage that is the sum of the reference voltage and the additive ± ( 0.5-0.6) AV, -, i.e. UI ± (0.50, 6) dV {is supplied to the second inputs of the comparison organs 5, with the output of which the signals whose signs are determined by the difference Ytz (0.5 + +0.6) AVyl are used to start the elements of time 6 and executive relay 7, respectively. The signs of voltage additions (0.50, 6) DU, - at the outputs of the selection and change setting items k, are determined by the state of the corresponding sections of the battery. With the sections turned off, these voltages are negative, with those turned on they are positive, which is determined by the position of the contacts of the respective executive relays. In the initial state, when both sections of the capacitor bank are disconnected, the signs of voltage additions (0.5+ f 0.6) are at the outputs of both selection elements and the settings change. Negative. If the mains voltage is such that the input signal is greater than both the voltage settings U and Ul, the outputs of the comparison organs 5 are positive, the time elements 6 and the executive relays 7 are in the state corresponding to the disconnected battery sections. When the load current increases or the network voltage decreases, the input signal Vex becomes less than the first setpoint V V - (0.5 - 0.6) DU ,. The sign of the voltage at the output of the comparison unit 5 of the first control channel is changed to the opposite, the time element 6 is triggered in the direction of time delay tjf for activation, after which the operating relay 7 is activated, giving the command to activate the first section. The inclusion of the first section leads to an increase in the network voltage by the magnitude of the control step and to a corresponding increase in the input signal by the value of uV-. Therefore, in order to avoid switching off the first section, the voltage setting of the corresponding first control channel is increased by an amount slightly larger than V, for which, simultaneously with the command to turn on the first section, the polarity of the additive is changed by the contacts of the executive relay {0.5 - 0, 6) AV element 4 selects and changes the settings of the first control channel to the opposite than: the dead zone of the control channel of the first section is set. If the input signal, due to a sufficiently fast change in the mains voltage or load current, were below the setpoint voltage of the second control channel, both time elements 6 would operate, but the time element of the second control channel would since t C at Q 0 Q and, therefore, the second section would immediately turn on, having a large power required by the voltage regulation condition. Thus, the selection of the section power required by the voltage regulation conditions and the reactive power is automatically made. The system of automatic control of the reactive power of a capacitor battery in the direction of disconnecting a section occurs when the mains voltage is increased or the load current decreases in a similar way. The ability to automatically control the power of a capacitor bank with the number of stages of regulation exceeding the number of sections is explained in FIG. 2. When the input signal is slowly reduced to point A, the first section switches on and V increases by the value of dU, which corresponds to point B of the diagram. In this case, the switched on reactive power of the battery is Q 1. With a further decrease in the input signal Vgjj at point C, the second section turns on and the input signal Vg increases by the value of dU | (point D), Since the value of Vg exceeds the voltage setting of the first control channel, the first section shuts down, Vgy decreases to the value corresponding to point E. The battery’s reactive power is Qij 2. When Vgx decreases further, point K turns on again The first section and the total included reactive power of the battery is Q ", 1 + 2 + 3. Consequently, a three-step regulation is obtained with the number of battery sections equal to two. At the same time, the choice of section power is: 2L: B Vaeth regulation with a large number of steps when the number of sections of claim 2 than for selection, the condition of 1: 2: 2: 2. The automatic power control system of a capacitor battery is also operational when controlled by other parameters, such as full, or reactive current or reactive power. The economic efficiency of the application of the proposed regulation method is to reduce the electric power losses in the network due to regulation with a large number. steps than the number of sections, as well as due to the possibility of automatically selecting the section power required by the conditions. The quality of the voltage in the network is improved accordingly by regulating sections that are smaller in power and with correspondingly smaller dead zones than with known methods. In addition, the automatic control system is simplified when the number of sections is at least 3: by eliminating the use of software devices, as well as by simplifying the design of the control channels themselves, ensuring that there is only one voltage setting for each section. Claim 1, A method for automatically controlling the power of a capacitor battery by switching its sections, carried out with a time delay and depending on the result of comparing the mains voltage with a voltage setting, characterized in that, in order to improve the accuracy of the control n sections of the battery, In addition, a p-T voltage setting is set, and the values of n voltage settings are chosen directly proportional to the reactive powers of the respective sections, and n time exposures are chosen to be inversely proportional to the reactive powers of the respective sections are compared with the voltage, with the p-settings over the voltage and, in for 94 8; depending on the result of the comparison with the time delay corresponding to this section, a command is issued to switch this section, and at the same time the setting is changed according to the voltage of the switched section by an amount corresponding to the change in the network voltage during switching. Sources of information taken into account during the examination 1. USSR author's certificate №316151, cl. H 02 J 3/12, 1970. 2. Automatic device of ARKON-1 type. Technical description and operating instructions. Riga Experimental Plant Latvenergo, 1975. 7F / / h " /: / / 4 XT Ift Y