SU1649459A1 - Electrical power consumption meter - Google Patents

Abstract

The invention relates to electrical measuring equipment and can be used in information-measuring systems for energy metering. The purpose of the invention is the expansion of the field of application - is achieved by introducing into the device an inverter 10, an element 8 and a shaper 9 current pulses that generate current pulses to control the successive operation of the sensors 5 pulses, the outputs of which are connected together. An information pulse from the output of the corresponding sensor is fed to the input of the matching unit 12 and then through the corresponding interrogation gate 3 and the trigger 6 to the receiving block 7 and information processing. In addition, the device contains a generator of 1 pulses, the distributor 2 pulses, the inverter 11. valves 4 reset and keys 13. 2 Cp. f-ly, 3 ill. J

Description

The invention relates to electrical measuring equipment and can be used in information-measuring systems for energy metering.

The purpose of the invention is to expand the functionality of the device.

FIG. 1 shows a diagram of the device; in fig. 2 - pulse sensor circuit; in fig. 3 is a time diagram of pulses, explaining the operation of the device.

The device for metering energy consumption contains a pulse generator 1, the output of which is connected to the input of the distributor 2 pulses N polling valves 3, N reset valves 4, N sensors 5, N flip-flops 6 and pulse receiving and processing unit 7, And 8 element, pulse shaper 9 current, two inverters 10-11, matching unit 12 and N keys 13, the output of the driver 9 current pulses connected to the input

the first sensor 5, the first output of each of the N-1 sensors 5 is connected to the input N of the sensor 5, the output of the 1M th sensor 5 is connected to the first input of the driver 9 current pulses, the second input of which is connected to the output of the element 8 And, the first input of which is connected to the output of the pulse generator 1, the second input of the And 8 element is connected to the input of the first inverter 10, whose input is connected to the N + 1 output of the distributor 2 pulses, the output of each of the N sensors 5 is connected to the input of the matching unit 12, the first output of which is connected through the second inverter 11 to the first entrance m N reset valves 4, whose second inputs are connected to the respective N outputs of the distributor 2 pulses, the output of each gate 4 is connected to the reset R-input of each flip-flop 6, the outputs of each of the N by N flip-flops 6 are connected to the keys 13 sootvetstvuyuO w ate of

The inputs of the receiving unit 7 and information processing, the first inputs N of the polling valves 3 are connected to the second inputs of the relief valves 4, the second inputs N of the polling valves 3 are connected to the BtopOMy output of the matching unit 12, the outputs of the polling valves 3 are connected to the S inputs of the trigger 6.

The electrical energy metering device also comprises a matching unit 12 in the form of a series-connected current generator 14, isolating 15 and matching key 16.

In the electricity consumption metering device, the sensor is made in the form of an isolating element 17, the output of which is connected to the input of power amplifier 18, the output of power amplifier 18 is connected to C-input of counter 19, the input of selector 20 of the reset pulse is connected to output of power amplifier 18, pulse selector output reset is connected to the R-input of the counter 19, the corresponding output of the counter 19 is connected to the input of the current amplifier 21, the output of the current amplifier 21 is connected to the input of the light source 22, the output of the light source 22 is connected optically through the surface di The ska 23 of the electricity meter, on which a freshly absorbing 24 spot is applied to the input of the photo sensor 25, the output of the photo sensor 25 is connected to the input of the output amplifier 26, while the selector 20 of the reset pulses is designed as an emitter 27 of the repeater, the output of which is connected to the key 28. 28 is connected to the capacitor 29 and the resistor 30, the input of the threshold element 31 is connected to the output of the key 28, another lead of the capacitor 29 is connected to the common bus, another lead of the resistor 30 is connected to the constant voltage source AND, the key 28 is connected to the common by bus.

The device works as follows. When the power is turned on, the generator 1 begins to generate pulses (Fig. 3a) of a given frequency. These pulses are fed to the input of the distributor 2 and to the first input of the element 8. At the outputs of the distributor 2, the individual polling signals appear alternately. So when the first pulse arrives at the input of the distributor 2, a single polling signal takes place at its first output (Fig. 3). Accordingly, the enable signal will be at the first inputs of only the first interrogation valve 3 and the reset valve 4.

While at the additional N + 1-m output of the distributor 2, the signal level is zero, the second input of the element I 8 from the output of the first inverter 10 receives an enabling signal, through which the frequency from the generator 1 passes to the input

driver 9 current pulses (Fig. 36). From the output of the former 9, current pulses of a given magnitude are simultaneously input to the isolating elements 17 of all

sensors 5 pulses, and from the outputs the pulses amplified by power amplifiers 18 simultaneously arrive at the input of the reset pulse selector 20 and at the counting inputs of counters 19. We assume that all counters 19 have been reset to the input of their first pulse. With the arrival of the first pulse at the input of all counters 19, signals appear at their first outputs, but only from the output of the first counter does the signal arrive at the input

5 amplifier 21, and from its output to the illuminator 22, transforming it into a beam of light. Reflecting from the surface of the disk 23 (if it is not on the spot 24), the light signal is received by the photosensor 25, amplified by a power amplifier 26 and creates an impulse current in the line, the value of which is determined by the current generator 14 of the matching unit 12.

This impulse passes through switch 15, key 16 and goes to the second inputs of all

5 interrogation valves 3. Only the first interrogation gate 3 can at the moment pass the signal received via the communication line to the trigger input 6. The trigger remembers this signal through the output key

0 13 transmits it to the unit 7 receiving pulses. On the second pulse of the generator 1, the distributor 2 is switched and all the counters 19 are synchronized with it to the second position (FIG. 3 d). With this polling signal

5 from the second output of the distributor 2 will open the first inputs of the second interrogation valve 3 and the second relief valve 4, and a signal of the appropriate level will enter the communication line only from the second sensor 5 of pulses.

0 As a result, if in the second sensor 5 the light beam hit the mirror surface of the disk 23, then the reflected signal will go to the switching input S of the second trigger 6, and then to the input of the block 7.

5 If the light beam hit the dark spot 24 of the disk 23, then the low level signal (no signal from the sensor 5) via the communication line through the inverter 11 and the second reset valve 4 will go to the reset input R of the trigger 0, 6

Similarly, synchronous switching of the distributor 2 and the counters 19 of all the pulse sensors to the following positions takes place and the corresponding 5 triggers 6 are turned on or off.

At the same time, each input pulse enters the input of the selectors 20 of each sensor 5 and passes through the repeater 27, opens the key 28. The capacitor 29 is completely discharged through the public key 28. During the pause between the pulses, when the key 28 is closed, the capacitor 29 is charged from the power supply And through the resistor 30 (Fig. ZJ). The parameters of the RC circuit and the duration of the pause between pulses are chosen so that during its operation the capacitor 29 does not have time to charge to the level necessary for the triggering of the threshold element 31.

Thus, the reset pulse selector 20 does not respond to N pulses arriving in sensor input 5.

When the N + 1 impulse arrives from the generator 1, the distributor 2 switches to the last N + 1th position (Fig. 3e). At the same time, the signals from N + 1-ro of its output by means of an inverter 10 close element 8. As a result, at its output the duration of the pause between pulses is increased by the time of the signal coming from the N + 1 output of the distributor 2.

An increase in the pause duration will lead to the fact that the capacitors 29 of all sensors 5 charge to a level above the threshold of the threshold elements 31 (Fig. Зж). As a result, from their outputs, the reset inputs R of all counters 19 receive reset signals (Fig. H, h), all counters 19 will be simultaneously reset.

Thus, after every N pulses of the generator 1, the counters 19 are reset in all the sensors of the 5 pulses, and thereby synchronizing their operation with the distributor 2.

Claims (3)

1. An electric energy metering device, comprising a pulse generator, the output of which is connected to the input of a pulse distributor, N polling valves, N reset valves, N sensors, N flip-flops and a pulse receiving and processing unit, characterized in that, in order to extend the functionality It is equipped with an And element, a current pulse driver, two inverters, a matching unit and N keys, the output of the current pulse driver is connected to the input of the first sensor, the first output of each of the N-1 sensors is connected on the sensor input, the sensor output is connected to the first input of the current pulse driver, the second input of which is connected to the output of the element And, the first input of which is connected to the output of the pulse generator, the second input of the element And connected to the output of the first invitor, whose input is connected to N + 1 5 outputs of the pulse distributor, the output of each of the N sensors is connected to the input of the matching unit, the first output of which is connected via the second inverter to the first inputs of the N reset valves. The second inputs of which are connected to the corresponding of the N outputs of the pulse distributor, the output of each reset valve is connected to R - at the entrance of each trigger, the outputs of each of the N triggers are connected via N keys to the corresponding inputs of the information receiving and processing unit, the first inputs of the N polling gates are connected to the second inputs of the reset valves, The second inputs of the N polling valves are connected to the second output of the unit. 0 matching, the outputs of the polling valves are connected to the S-inputs of the triggers. 2. A pop device, 1, characterized in that the matching unit is made in the form of a series-connected current generator, decoupling and matching key. 3. The device according to claim 1, characterized in that the sensor is designed as an isolating element, the output of which is connected to the input of the power amplifier, the output 0 the power amplifier is connected to the C-input of the counter, the input of the reset pulse selector is connected to the output of the power amplifier, the output of the reset pulse selector is connected to the R-input of the counter, corresponding 5 the output of the counter is connected to the input of the current amplifier, the output of the current amplifier is connected to the input, source of light source, the output of the light source is optically through the disk surface of the electricity meter on which is applied 0 is a light absorbing spot with a photo sensor input, the photo sensor output is connected to the output amplifier input, while the reset pulse selector is designed as an emitter follower, the output of which is connected to 5 key input, the key output is connected to a capacitor and a resistor, the threshold element input is connected to the key output, another capacitor lead is connected to the common bus, another resistor lead is connected to The source is equipped with a south-west voltage, the key is connected to the common bus. 21 sh№ (gzSJ) FIG. 2 123NN + 112 h pngminnnnr n n n g gp ch m  L -nnnng gp ch m