SU1226592A1 - Device for n-channel pulse controlling of power in m-phase load - Google Patents

Abstract

The invention relates to p-channel pulse power control devices in a t-phase load. The purpose of the invention is to ensure uniform network load and simplify the device. The device contains synchronizer 1 connected in series, a counter 2 and p-channels, including each valve control circuit (BHC) 3, key driver (KF) 4 and block 5 of controllable gates. The synchronizer input 1 is connected to the mains. On each m channel, the synchronous input of the VCS is connected to the output of the synchronizer i and the information input is connected with 6 control code. The clock input of the MCB of the first channel is connected to the output of counter 2. In each channel, the control input KF is connected to the output of the MCB, and the synchronizing input is connected to the output of the synchronizer 1. The output of each MCB of the previous channel, starting from the second, is connected to the clock input of the microwave of the subsequent channel. This combination of elements ensures the synchronous operation of all channels with .min. Distortions introduced into the network, equal to the distortions introduced into the network during the operation of one channel. Moreover, due to the fact that pulses are output from the output of one of any phases to the input of counter 2, and the clock pulses from the output of each phase are fed to the inputs of the CF, all phases of the network are automatically loaded. 2 Il. 9 i (L ГЧЭ О5 СЛ СО ND

Description

The invention relates to power control in single-phase and multi-phase networks and related quantities in multichannel electrothermal installations connected by their own loads to an industrial network.

The purpose of the invention is to simplify the device and uniformly load the network.

FIG. 1 shows a functional diagram of the device; in fig. 2 is a timing diagram of the network operation of the channel control device.

A device for p-channel power control in a t-phase load contains synchronizer 1 connected in series, counter 2 and n circuits 3., 3.2, ..., Z.p control of the valves, synchronizing the inputs of these circuits are connected to the output of the synchronizer, clock input the circuit of the first channel is connected to the output of the counter, and the clock inputs of each subsequent channel are connected to the outputs of the valve control circuit of the previous channel. The outputs of all control circuits through the key-drivers 4.1, 4.2, ..., 4.P are connected to blocks 5.1, 5.2, ..., 5.P of controlled gates. The information inputs of all valve control circuits are connected to 6.1, 6.2, ..., bp code of the control code, and all blocks of controllable valves are connected to blocks 7.1, 7.2, ..., 7.p of loads and network 8, to which is also connected to the synchronizer input 1.

The device works as follows.

Device operation at single-phase network, when rn 1.

The synchronizer generates sync pulses each time the network voltage changes sign, i.e., at the beginning of each half-percode. These pulses are sent to the first inputs of all key-drivers 4.i, which, when a single-phase network is a coincidence circuit, and the input of counter 2, which generates clock pulses controlling the entire circuit with frequency tf fc / N, where fc is the network frequency, N is the division factor of counter 2, which determines the duration of the interval Tc N, where Tc is the duration of the half period (or the period of the mains voltage).

These clock pulses, arriving at the input of the clock control circuit of the valves of the first channel 3.1, lead each time to recording into it the control signal X, with a pass code 6.1 of the control code. A subtractive counter is used as the control circuit of the valves. Therefore, after recording the number X ,, in it, a unit appears at its output of a single state, unlocking the driver-shaper 4.1 at the second input.

In this case, the sync pulses from the output of the synchronizer 1, which are formed by the key-drivers 4.1 according to the form and magnitude of the voltage, are transferred to the control of the valve of the unit 5.1 controlled by the valves.

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At the same time, the same pulses arrive at the counting input of the subtracting counter of the valve control circuit 3.1, each time reducing its content by one. When the pulse of H impulses arrives at the input of this counter, and hence at the input of the block 5.1 of controlled gates, the subtractive counter is zeroed, the key-driver 4.1 closes until the next clock cycle and the pulses do not flow to control the gates.

Thus, during the adjustment interval, from the N sync pulses, the control of the thyristors receives Hu pulses.

When the subtracting counter of the valve control circuit 3.1 is zeroed, a clock pulse is generated for the valve control circuit 3.2 by writing the signal from 6.2 of the control code of the second channel to the voltage of its unit state output from one to zero. Thus, the adjustment interval of the second channel is shifted in phase relative to the first channel by an amount, i.e., by a time duration X ,, i, T, thereby filling the voltage drop in the first 5 channel.

The beginning of the adjustment interval of the third channel is similarly shifted relative to the second channel by the time interval X, i-Tc, etc.

In this way, the voltage supplied to the loads of the respective channels is fitted, and thus the network is evenly loaded.

As an example (Fig. 2), time diagrams of a seven-channel single-phase regulator are shown with control signals in each channel, equal to: Xjii 4, X ,, 2 3, Huz 2, X, 4 4, у5 3, Hub 2, X ,, 7 4 and N 6. The presence of a pulse conditionally indicates the duration of the conductive state of the valves of each channel T,;, T2, ..., T "7. With the same load of all channels and the magnitude of the voltage when turned on for the load U for one channel, the total voltage consumed from the UT network introduces distortions from the single channel into the network, which is significantly less than during non-synchronous operation of the channels, when voltage fluctuations are observed from zero to seven, and seven times more.

0T - ,, With a multiphase load, the principle of operation remains the same, except that pulses from the output of one of any phases are connected to the input of counter 2, and to the inputs of 4.1-key driver circuits -

5 sync pulses from the output of each phase, respectively. Thereby, uniform loading of all phases of the network is automatically realized.

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Claims (1)

Invention Formula A device for p-channel pulse power control in a t-phase load, containing a block of controlled gates in each channel, a synchronizer, whose inputs are connected to pins for connecting a power supply network, a counter, the input of which is connected to the output of a synchronizer, control circuits of each valve the channel, the synchronizing input of each of which is connected to the synchronizer output, information inputs with buses the control code, the clock input of the control circuit of the valves of the first channel is connected to the output of the counter, and the key-drivers for the control valve block in each channel, the control inputs of which are connected to the outputs of the control circuits of the control valves, and the synchronization with the output of the synchronizer that differs in that, in order to evenly load the network and simplify the device, the output of each previous valve control circuit, starting with the second channel, is connected to the clock input of the subsequent control circuit.