RU2115271C1 - Device for lighting control - Google Patents

Abstract

FIELD: lighting control equipment. SUBSTANCE: the device additionally has in each channel: a synchronizing circuit, demodulator, integrator, comparator, AND gate, OR gate, inverter, flip-flop, multivibrator, interrupter, pulse-width modulators, timer, pulse-length selector, lighting ON signal conditioner, interruption signal conditioners. The given units in correlation with power transformer, first pulse shaper, second pulse shaper, first thyristor, second thyristor make it possible to control the level of lighting and stabilize the output voltage across load in the conditions of noise in power mains. EFFECT: enhanced noise immunity and operate reliability. 2 dwg

Description

 The invention relates to control devices in multiphase electric networks of industrial frequency. The most appropriate application of the invention to control the level of illumination in the buildings of the houses.

 The closest analogue (prototype) of the proposed device is a lighting control device, known from the description of the USSR copyright certificate N 690459, class. H 05 V 37/02, 1979. The known device also contains three channels for controlling the supply phases, each of which has two thyristor switches connected to the supply phase, two pulse shapers and a power voltage transformer of the corresponding phase, the output of each pulse shaper connected to the input control the corresponding thyristor key, the anode of each of which is connected to the cathode of the other.

 The disadvantage of this device is that it is impossible to stabilize the voltage on the load during surges in the amplitude of the supply voltage and it is impossible to operate smoothly turn on and off the voltage on the load.

 The objective of the invention is to increase noise immunity, expanding functionality and operational reliability.

 This problem is solved due to the fact that the lighting control device, which consists of three power phase control channels, each of which contains two thyristor switches in parallel, connected in parallel to the corresponding phase, two pulse shapers and a voltage power transformer of the corresponding phase, the output of each pulse shaper connected to the control input of the corresponding thyristor key, three pulse-width modulators, a pulse width adjuster, outputs connected to the control the input inputs of the above-mentioned modulators, a shaper of the light-on signal, a timer and three shapers of the interrupt signal when the frequency of the supply voltage changes beyond the specified limits, and each control channel is equipped with a synchronization circuit, a demodulator, a trigger, a comparator, a multivibrator, an integrator, AND and OR logic circuits, and an inverter and an interrupt key, while in each control channel the secondary winding of the voltage transformer is connected to the input of the synchronization circuit, the direct output of which is connected to the input the flip of the trigger to the input of the integrator, and its first and second inverse outputs are connected to the locking inputs of the first and second pulse shapers, respectively, the output of the demodulator is connected to the reference input of the comparator, the signal input of which is connected to the output of the integrator, and the output to the first input of the logic circuit AND output connected to the first input of the OR logic circuit, the output of which is connected to the inverter input, the output of the trigger connected to the installation input, the output of which is connected to the multivibrator enable input , outputs connected to the inputs of the power amplifiers of the first and second pulse shapers, the synchronization input of each pulse-width modulator is connected to the direct output of the synchronization circuit of the corresponding control channel, and the output to the input of the demodulator and the second input of the logic circuit OR of the same channel, the input of the enable signal shaper lighting is connected to the timer output, and the output to the second input of the logic circuit AND of each control channel, each of the above-mentioned interrupt driver is connected to direct output of the synchronization circuit of the corresponding channel, and the output to the input of the interrupt key of the same channel, and the output of the second pulse shaper of each channel is connected to the control input of the second thyristor key through the interrupt key.

 In FIG. 1 shows a structural diagram of a device for controlling lighting; in FIG. 2 is a diagram of stresses at characteristic points of a circuit of a device for controlling lighting.

 The device contains three channels (A, B, C), a power transformer 1 of the voltage of the corresponding phase, a synchronization circuit 2, a demodulator 3, an integrator 4, a comparator 5, a logic circuit And 6, a logic circuit OR 7, an inverter 8, a trigger 9, a multivibrator 10 , the first pulse shaper 11, the second pulse shaper 12, the interrupting key 13, pulse-width modulators 14, 15, 16, the timer 17, the pulse duration adjuster 18, the shaper of the light-on signal, shapers 20, 21, 22, the interrupt signal, the first thyristor VS1, second thyristor VS2, off Tel S1 and Rn load. The secondary winding of the transformer 1 is connected to the input of the synchronization circuit 2. The direct output of the synchronization circuit 2 is connected to the reset input of the trigger 9 and to the input of the integrator 4. The first and second inverse outputs of the synchronization circuit are connected to the locking inputs of the first and second pulse shapers 11, 12, respectively. The output of the demodulator 3 is connected to the reference input of the comparator 5, and the signal input of the comparator 5 is connected to the output of the integrator 4. The output of the comparator 5 is connected to the first input of the logic circuit And 6. The output of the logic circuit And 6 is connected to the first input of the logic circuit OR 7, the output of which is connected with the input of the inverter 8. The output of the inverter 8 is connected to the installation input of the trigger 9, the output of which is connected to the enable input of the multivibrator 10. The multivibrator 10 outputs are connected to the inputs of the power amplifiers of the first and second pulse shapers 11, 12. The synchronization input of each pulse-width modulator 14, 15, 16 is connected to the direct output of the synchronization circuit 2 of the corresponding control channel, and the output of each pulse-width modulator 14, 15, 16 is connected to the input of the demodulator 3 and the second input of the logic circuit OR 7 same channel. Each pulse-width modulator 14, 15, 16 is connected to a pulse width adjuster 18, which is connected to a timer 17. The input of the driver of the lighting on signal 19 is connected to the output of the timer 17, and the output to the second input of the AND 6 logic circuit of each control channel. Each driver of the interrupt signal 20, 21, 22 is connected by an input to the direct output of the synchronization circuit 2 of the corresponding channel, and by the output - to the input of the interrupt key 13 of the same channel. The output of the second pulse shaper 12 of each channel is connected to the control input of the second thyristor switch VS2 through the interrupt key 13.

 The device operates as follows.

The device comprises a pulse width adjuster 18, which, through pulse-width modulators 14, 15, 16, sets the turn-on angle of the thyristors of each channel from 0 to 180 ^o (plot 27, Fig. 2).

 The on / off time of the lighting and the current time are determined by the timer 17. At the on and off times, the illumination level gradually increases and decreases due to a smooth change in the opening angle of the thyristors, determined by the algorithm of the pulse width setter 18.

 The number of control channels is equal to the number of phases used in the supply network. Channels are identical and interchangeable.

 In each control channel, negative half-periods of voltage from the secondary winding of the power transformer 1 (plot 23), through the first and second inverse outputs of the synchronization circuit 2, are supplied to the first 11 (plot 24) and second 12 (plot 25) pulse shapers, closing them alternately.

 As the mains voltage approaches zero in synchronization circuit 2, narrow rectangular pulses with a frequency of 100 Hz (plot 26) are formed, which are fed to the corresponding inputs of the pulse-width modulator 14, 15, 16 at the beginning of each half-cycle and simultaneously reset trigger 9. Depending on from a given level of illumination, the pulse width adjuster 18 together with the pulse-width modulator 14, 15, 16 generates pulses of the corresponding duration, which are fed to the input of the demodulator 3 and to the first input of the OR circuit 7.

 The demodulator 3 of the pulses that determine the opening angle of the thyristors generates an exemplary voltage proportional to the duration of these pulses, which is applied to the reference input of the comparator 5. Since the opening angle of the thyristors does not depend on changes in the supply voltage, the level of the reference voltage will be determined by the duration entered pulses 18 value of the level of illumination.

 Pulses with a frequency of 100 Hz from the direct output of the synchronization circuit 2 also go to the input of the integrator 4, the output of which is formed pulses of a sawtooth shape with a repetition rate of 100 Hz (plot 33). Pulses of a sawtooth shape from the integrator 4 are fed to the signal input of the comparator 5, to the reference input of which an exemplary voltage is supplied from the output of the demodulator 3. When the sawtooth voltage decreases to the level of the exemplary voltage, the logic unit level is formed at the output of the comparator, after it reaches the smallest voltage, it starts to increase again and when raised to a level exemplary at the output of the comparator, a logical zero level is formed. Thus, rectangular pulses with a frequency of 100 Hz are formed at the output of the comparator (plot 28), the trailing edges of which are rigidly attached to the leading edges of the pulses from the direct output of synchronization circuit 2.

 The pulses from the output of the comparator 5 are fed to the first input of the And 6 circuit, the second input of which receives a signal from the driver of the lighting on signal 19. The pulses from the comparator 5 will appear at the output of the And 6 circuit only when the level of the logical unit from the former 19 arrives at the second input , which is formed under the control of timer 17.

 The pulses from the output of the AND 6 circuit arrive at the second input of the OR 7 circuit, and depending on which pulse arrives first at the inputs of the OR 7 circuit, such a pulse will also be at the output of the OR 7 circuit.

 The pulses from the output of the OR circuit 7 through the inverter 8 are fed to the input of the trigger 9 installation, while the output of the trigger 9 is set to the level of the logical unit that triggers the multivibrator 10. The multivibrator 10 works until a logic zero signal appears at the output of the trigger 9. Pulses with a frequency of 6 kHz and 150 μs in duration from the multivibrator 10 (plot 30) are supplied to the second inputs of the pulse shapers 11 and 12. Positive pulses are amplified only by the power amplifier of the pulse shapers 11 and 12, where there is no closing negative atelnoe voltage from the timing circuit 2 supplied to the first inputs of pulse shaping. Therefore, one of the on-board thyristors VS1 and VS2 will turn on, for which the voltage at the anode with respect to the cathode is positive in the half-period under consideration. At the end of the half-cycle, the thyristor closes, and in the next half-cycle of the mains voltage, the second thyristor of the switch opens.

 To stabilize the output voltage at the load Rn, a unit is used, consisting of an integrator 4 and a comparator 5, which each half-cycle compares the input sawtooth voltage with the reference constant voltage and, when the sawtooth and reference signals are equal, generates a control pulse of logical 1, the duration of which is determined by the amplitude of the sawtooth voltage. With a decrease in the amplitude of the sawtooth voltage, the duration of the control pulse increases and vice versa. The change in the amplitude of the sawtooth voltage depends on the change in the amplitude of the voltage of the supply phase.

 So, if the output from the OR 7 circuit is a pulse from a pulse-width modulator, then the thyristor turn-on angle or the voltage at the load Rn is determined by the value of the illumination level entered into the pulse width adjuster 18, if the output of the 7 circuit is a pulse from the comparator 5, then the thyristor turn-on changes automatically depending on changes in the supply voltage, thereby maintaining a stable voltage at the load.

 The normal mode of operation of the device is the voltage stabilization mode at the load, the voltage amplitude is determined by the level of the reference voltage at the reference input of the comparator 5.

 However, when the supply voltage increases so much that the sawtooth voltage goes beyond the threshold of the comparator 5, the impulse from the pulse-width modulator begins to control the angle of the thyristors, which in the stabilization mode is fed to the input of the circuit OR 7 after the pulse from the comparator 5. Thus, with jumps the supply voltage, the voltage at the load does not decrease below a certain level, which is determined by the data entered into the setpoint pulse duration 18.

 The operating experience of the lighting control device shows that in the presence of strong interference in the supply network, a spurious resonant oscillation is formed, which breaks down when the control circuit of one of the thyristors breaks. For this purpose, an interrupt key 13 is used, which is turned on and off under the control of the shapers of the interrupt signal 20, 21, 22.

 The control unit of the lighting control device, consisting of a timer, a pulse width adjuster, pulse-width modulators, an illumination enable signal shaper, an interrupt shaper, can also be built on the basis of a single-chip microprocessor, for example, using an Inter AE89C51 microprocessor in conjunction with a KR580VV79 keyboard and display controller .

The microprocessor, running a built-in program, sets the angle of inclusion of the thyristors of each channel from 0 to 180 ^o . The necessary data are entered into the microprocessor through the keyboard and display controller: the time for lighting on and off, the current time and the level of illumination. The internal clock of the microprocessor, formed by software, is synchronized by an external timer, the output of the second pulses of which is connected to the microprocessor interrupt input. At times of switching on and off, the illumination level gradually increases and decreases due to a smooth change in the opening angle of the thyristors, determined by the microprocessor program.

 The proposed lighting control device has increased noise immunity, enhanced functional ability and operational reliability.

Claims (1)

 A lighting control device consisting of three power phase control channels, each of which contains two thyristor switches in parallel, connected in the corresponding phase, two pulse shapers and a power voltage transformer of the corresponding phase, the output of each pulse shaper is connected to the control input of the corresponding thyristor switch, characterized the fact that three pulse-width modulators, a pulse width adjuster, outputs connected to the control inputs are introduced into it removed modulators, a shaper of the light-on signal, a timer and three shapers of the interrupt signal when the frequency of the supply voltage changes outside the specified limits, and each control channel is equipped with a synchronization circuit, a demodulator, a trigger, a comparator, a multivibrator, an integrator, AND and OR logic circuits, an inverter and an interrupt key, while in each control channel the secondary winding of the voltage transformer is connected to the input of the synchronization circuit, the direct output of which is connected to the reset reset input and the integrator’s input, and its first and second inverse outputs are connected to the locking inputs of the first and second pulse shapers, respectively, the demodulator output is connected to the reference input of the comparator, the signal input of which is connected to the integrator’s output, and the output is connected to the first input of the logic circuit And, the output is connected to the first input of the OR logic circuit, the output of which is connected to the inverter input, the output connected to the trigger installation input, the output of which is connected to the multivibrator enable input, the outputs are connected connected to the inputs of the power amplifiers of the first and second pulse shapers, the synchronization input of each pulse-width modulator is connected to the direct output of the synchronization circuit of the corresponding control channel, and the output to the input of the demodulator and the second input of the OR logic circuit of the same channel, the input of the illumination enable signal shaper is connected with the timer output, and the output with the second input of the logic circuit AND of each control channel, each driver of the interrupt signal by the input is connected to the direct output of the synchronization circuit of the corresponding channel, and the output to the input of the interrupt key of the same channel, the output of the second pulse shaper of each channel being connected to the control input of the second thyristor key through the interrupt key.

Images