SU1374369A1 - Relay-pulse power regulator - Google Patents

Abstract

The invention relates to electrical engineering and is intended for use in electrothermal installations. The purpose of the invention is to increase the power factor and smoothness of the adjustment. The power control is performed by alternating the on state of the triacs 1, 2j connecting the load 3 to the line and phase voltages of the network, respectively. Synchronous pulse generator 17 synchronizes multiplexer 10 operation and generation of: triggering triac pulses 2; synchronic pulse generator 13 synchronizes the formation of triac trigger pulses 1. The invention provides relay-pulse power control of the load by cyclic alternating phase and linear voltages on its outputs. 2 Il.

Description

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The invention relates to electrical engineering and is intended for use in electrothermal installations,

The purpose of the invention is to increase the power factor and smoothness of the adjustment.

Figure 1 shows the functional diagram of the device; 2 shows graphs explaining the operation of the device.

The device (Fig. 2) contains two triacs I and 2, one of the outputs of which are connected together and through the load 3 are connected to terminal 4 for connecting the phase A of the mains supply. Another pin of the first triac 1 is connected to pin 5 for connecting phase B of the power supply network, and the other pin of the second triac 2 is connected to pin 6 for connecting the neutral conductor. Consistently with the triac 1 is enabled, the sensor 7 current. The address inputs of the storage unit 8 are connected to the corresponding buses 9 of the control signal code, and the information outputs to the corresponding information inputs of the multiplexer 10, the output of the multiplexer 10 is connected to the inverse input of the BAN 11 and the first input XI of the I 12 element.

The direct input of the BANCH element is connected to the output of the shaper of 13 clock pulses, the interphase voltage is switched on, and the output is connected to the input of the one-oscillator 14. The input of the switch 15 is connected to the input of the element

16 delay and shaper output

17 sync pulses connected to the phase voltage, and the output - with the input Sampling resolution of the storage unit 8 and with the input of the ring counter 18, the outputs of which are connected to the corresponding address inputs of the multiplexer 10. The output of the current sensor 7 is connected to the input of the inverter 19, the output of which is connected to. .the input of the second delay element 20

and the second input X2 of the And 12 element, the output of which is connected to the input of the one-shot 21. The outputs of the first 16 and second 20 delay elements are connected respectively to the third X and the fourth X4 inputs of the And 12 element. The output of the first one-vibrator 14 is connected to the input of the matching unit 22, the output of which connected to the control input of the triac 1. The output of the second one-shot 21 is connected to the input of the matching unit 23, the output of which is connected to the control input of the triac 2.

At the same time, the storage unit 8, the trigger 15, the multiplexer 10, the ring counter 18 form the control signal generator, delay elements 16 and 20, the AND element 12, the BAN 11 element, the matching 21 and 14, the matching blocks 22 and 23 form the trigger pulse shaper.

The device works in the following way.

When the voltage ABC appears at the terminals 4-6, the driver 17 generates the F1 clock pulses (Fig. 2) at the time of crossing the phase voltage U (p5 and the driver 13 generates the clock F3 at the time of passing through the linear voltage Zero and. The frequency of these pulses equal to twice the voltage of the pi-, thawing network f. The pulses from the generator 17 are fed to the input of the T-flip-flop 15, the output of which is F2 pulses with a tracking frequency equal to the voltage of the supply network fc. Pulses F2 from the output T-trig hera 15 is fed to the inlet ring the second counter 18, the outputs of which control the address inputs of the multiplexer 10, to the input of the ring counter 18, the outputs of which control the address inputs of the multiplexer 10, the input of which is fed to the bit information stored in the storage unit 8. The selection of the cell number recorded in its constant for the multiplexer 10 code is determined by the digital code set on the address inputs of the storage unit 8, the information is read from the storage unit 8 at the time of the pulse from the output of the T-flip-flop 15 to the input Addressing sample 8. The information storage unit finds conductive with a memory unit 8, the control algorithm determines Cu thermistor 1 and 2.

Let the enabled state of triac 1 correspond to O at the output of multiplexer 10, and the enabled state of triac 2 to 1 at the output of multiplexer 10, Then the simulator control algorithm provided by the storage unit 8 can be represented as a parallel digital code, for example, P. .. 100.

Consider the example of an 8-bit control system. Suppose that a digital code is supplied to the input of the storage unit 8 from the buses 9 of the code of the signal from the storage unit 8 to the information inputs of the multiplexer 1 O an 8-bit code 1111100 is fed. Then, at the output of the multiplexer 10 with a clock frequency F2, a parallel code from the memory block 8 is converted to a serial code on its output. .

When signal 1 appears at the output of multiplexer 10 (FIG. 2, G4) and closed triac 1, inputs 12 of the element XI, X2, X4 of the element 1 are set to 1. Simultaneously with the delay of the element 16 of the input delay of the X3 element 12, the clock pulses F1 from the output of the former 17. Time delays are necessary for the detuning from transients when switching to the T-trigger circuit 15 - multiplexer 10 and averages several tens of nanoseconds (depending on the speed of the element base used). The duration of the clock pulses F1, F2, F3 is (on average) several tens of microseconds. When a sync pulse appears at the input of the XZ element And 12, an F5 pulse appears at its output, which triggers the one-oscillator 21. The single-oscillator 21 generates a pulse F6 with a duration sufficient to reliably open the simulator 2. This pulse is fed to the driver input pulses, which generates either a single control pulse of the same duration as the F6 pulse, or a high-frequency and sound packet (20-40 kHz of the same duration. These pulses are fed to the control inputs of the triac 2, causing it to turn on (Figure 2, time t,) The subsequent appearance of the FI sync pulses at the input of the element And 12 causes the triac 2 to be turned on periodically, connecting the load 3 to the phase voltage of the supply mains.

When a signal O appears at the output of the multiplexer 10 (Fig. 2, time t,) the signal O is set at the output of the element 12, which

causes the triac 2. to close. At the same time, an inverse output of the BANCH 11 element establishes a signal. O, disrupting the operation of the triac control channel 1. When a BAN 11 11 element appears on the direct input of the Former 13, the output of the BANNER 11 element appears

pulse F7, triggering the one-shot 14. The one-shot 14 generates pulse F8, which is fed to the input of block 22. Control pulses from the output of block 22 are fed to control inputs

triac 1. Triac 1 turns on

(fig.Z, moment t), connecting the load 3 to the linear voltage of the mains supply. In this case, the output of the current sensor 7, which controls the current in the circuit of the triac 1, appears the signal I (Fig.2, F9), and the output of the inverter 19 - O (Fig.2, FIO), which is fed to the inputs X2, X4 , element And 12, prohibit the inclusion of the simistsr 1.

When signal 1 is reappeared at the output of multiplexer 10 (Fig. 2, time t,), the control signal is removed from the triac 2. After it is closed, the output of the inverter 9 is set

Signal 1 is fed in, which is fed to input X2 of the element 12 and to the input of the delay element 20. With a time delay of the delay element 20 at the input X4 of the element 12, signal 1 is established (FIG. 2, time tg), enabling the operation of the control channel of the triac 2. The time delay is approximately 60-120 al-degrees. (3.33-6.66 ms) and necessary to exclude the constant component of the current in load 3. The appearance at the input of the X3 element And 12 of the sync pulse F1 in the subsequent moment (Fig. 2, moment t) causes the triac 2 to turn on as described by you. Further, the operation of the circuit is cyclically repeated.

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formula of invention

A relay-relay power control device containing a first triac connected between the output for connecting the neutral conductor and the output for connecting the load, another output for connecting which is connected to the output for connecting one of the mains phases, an impregnation signal generator whose information input is connected to the buses control signal code and input

synchronization with the output of the first sync pulse generator, the input of which is connected to the terminals for connecting the neutral wire and the mains phase associated with the load, in addition, a trigger pulse generator, characterized in that, in order to increase the power factor and smoothness of regulation, a second a triac connected between the output to connect another phase of the network and the output of the first triac connected with the load, the current sensor connected in series to the power circuit of the second triac, the second driver The sync pulses connected between the terminals for connecting the phases of the network connected respectively to the load and the second triac, the control signal generator contains a storage unit whose address inputs are the information input of the control signal generator, a multiplexer whose information inputs are connected to corresponding information outputs of the storage unit and its address inputs with the outputs of the ring counter, the input of which

connected to the output of the T-flip-flop and to the input of the memory sampling resolution, and the input of the T-flip-flop is the synchronization input of the control signal generator, the trigger pulse generator contains two delay elements, the BANNER element, the And element, two one-oscillator, two matching blocks and an inverter, wherein the output of the control signal generator is connected to the inverse input of the BAN AND the first input of the element And, the output of the current sensor through the inverter is connected to the second input of the And circuit, the output of the first driver sync pulses through the first delay element connected to the third input of the element I, the output of the inverter through the second delay element connected to the fourth input of the circuit AND, the output of the circuit AND through the first one-oscillator and the first matching unit connected to the control input of the first simistor, the output of the second sync pulse generator is connected to the direct input of the BANCH element, the output of which through the second one-shot and the second matching unit is connected to the control input of the second triac.

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VNSh1PI Order 614/52

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Circulation 665

Subscription

Claims (1)

Claim A relay-pulse power control device, comprising a first triac connected between the terminal for connecting the neutral wire and the terminal for connecting the load, the other terminal for connecting it is connected to the terminal for connecting one of the network phases, the driver of the control signal, the information input of which is connected to the buses control signal code, and input ό synchronization - with the output of the first driver of the clock pulses, the input of which is connected to the terminals for connecting the neutral wire and the phase of the network associated with the load, in addition, the driver of the triggering pulses, characterized in that, in order to increase the power factor and smoothness of regulation, a second triac is introduced, connected between the terminal for connecting another phase of the network and the terminal of the first triac connected to the load, a current sensor connected in series to the power circuit of the second triac, the second driver pulse pulses connected between the terminals for connecting the network phases associated with the load and the second triac, the control signal generator comprises a memory block, the address inputs of which are the information input of the control signal generator, multiplexer 25, the information inputs of which are connected to the corresponding information outputs of the memory block ·, and its address inputs with outputs of the ring counter, the input of which is βθ Rogo connected to the output of the T-flip-flop and to the input of the other device, and the input of the T-trigger is a synchronization input ³ of the control signal driver, the trigger pulse generator contains two delay elements, the PROHIBIT element, the AND element, two one-shot IQ drivers, two matching units and an inverter, while the output of the control signal generator with an inverse input of the circuit FORBID and with the first input of the element AND, the output of the current sensor through an inverter is connected to the second input of the circuit And, the output of the first driver of the clock through the first delay element is connected to the third by the element'I, the inverter output 20 through the second delay element is connected to the fourth input of the And circuit, the output of the And circuit through the first one-shot and the first matching unit is connected to the control input of the first triac, the output of the second driver of the clock is connected to the direct input of the FORBID element which through the second one-shot and the second matching unit is connected to the control input of the second triac. 1 --------------- ~~ ---- G- 1 .... 1 - I I II eleven I 1 10 P P I ι i 1 —G II nn ι! 1 eleven and lit ΓιΤ 6 fie. 2 1 1 1 4 's G'I Ί 1 1 1 1 1, ic, is tf 6 ВНИИПИ Order 614/52 Circulation 665 Subscribed Custom polygr. ave, city of Uzhhorod, st. Project, 4