CN201173944Y - Optocoupler isolation control interface circuit structure - Google Patents

Abstract

The utility model relates to an optocoupler isolation control interface circuit structure, in particular, in high-sensitivity DC system insulation monitoring devices such as substations or power plants, on-line high-speed measurement of main and backup power supply voltages and total circuit bridges of 220V DC systems When the voltage and the voltage of each sub-circuit bridge are used for data transmission between the computer and the A/D analog-to-digital conversion circuit. The feature is that the first to eighth isolation resistors RG1 to RG8 are respectively connected to the first to fourth optocoupler tubes GO0 to GO3, and the computer bus controls the light emitting diodes of the first to fourth optocoupler tubes to emit light and Does not emit light, and controls whether there is current in the phototransistor from the first optocoupler tube to the fourth optocoupler tube; the utility model has fast data transmission and electrical isolation speed, less transmission lines, small volume, and high withstand voltage; it can meet different voltage levels of isolation, High-precision, large dynamic range voltage measurement, high-speed communication between computer and A/D integrated block and electrical isolation requirements.

Description

Optocoupler isolation control interface circuit structure

technical field

The utility model relates to an optocoupler isolation control interface circuit structure, in particular, in high-sensitivity DC system insulation monitoring devices such as substations or power plants, on-line high-speed measurement of main and backup power supply voltages and total circuit bridges of 220V DC systems When the voltage and the voltage of each sub-circuit bridge are used for data transmission between the computer and the A/D analog-to-digital conversion circuit, the interface circuit that requires electrical isolation.

Background technique

At present, in the known DC system insulation monitoring devices, voltage measurement is required for insulation monitoring and finding ground faults. During the measurement, data transmission between the computer and the A/D analog-to-digital conversion circuit is required, and the electrical isolation between each other is required. The speed should be fast, and the general method of using relays to isolate can no longer meet the requirements of A/D conversion of more than 20 times per second.

The production site urgently needs to be able to perform high-speed measurement of the main and backup power supply voltages of the DC system and the voltage of the main and backup bridges when the DC system is running normally; Electrically isolated between.

Contents of the invention

The purpose of this utility model is to overcome the above disadvantages, thereby providing an optocoupler isolation control interface circuit structure, which can meet the requirements of different voltage level isolation, high precision, and large dynamic range voltage measurement between the computer and the A/D integrated block. Communication and electrical isolation requirements.

The main solution of the utility model is achieved in this way:

The connection relationship of the optocoupler isolation control interface circuit components of the utility model is as follows:

One end of the first isolation resistor RG1 is connected to +5V0, and the other end is connected to the anode of the first optocoupler tube GO0 diode; one end of the seventh isolation resistor RG7 is connected to +5V0, and the other end is connected to the collector of the second optocoupler tube GO1 photosensitive tube; the third One end of the isolation resistor RG3 is connected to +5V0, and the other end is connected to the anode of the third optocoupler GO2 diode; one end of the fourth isolation resistor RG4 is connected to +5V0, and the other end is connected to the anode of the fourth optocoupler GO3 diode; the second isolation resistor RG2 One end is connected to +5V3, and the other end is connected to the anode of the second optocoupler tube GO1 diode; one end of the fifth isolation resistor RG5 is connected to +5V3, and the other end is connected to the collector of the fourth optocoupler tube GO3; one end of the sixth isolation resistor RG6 is connected to +5V3, the other end is connected to the collector of the third optocoupler GO2 photosensitive tube; one end of the eighth isolation resistor RG8 is connected to +5V3, and the other end is connected to the collector of the first optocoupler GO0 photosensitive tube; computer serial data input terminal P1.0SDI is connected to the cathode of the first optocoupler GO0 diode; A/D analog-to-digital conversion serial data output terminal SDO is connected to the cathode of the second optocoupler GO1 diode; computer serial data clock pulse terminal P1.2SCLK is connected to the third The cathode of the optocoupler GO2 diode; the computer serial data chip selection terminal P1.3CS is connected to the cathode of the fourth optocoupler GO3 diode; the emitter of the first optocoupler GO0 photosensitive tube and the third optocoupler GO2 photosensitive tube The emitter and the emitter of the fourth optocoupler GO3 photosensitive tube are respectively connected to the ground G+5V3 of the +5V3 power supply; the emitter of the second optocoupler GO1 photosensitive tube is connected to the ground G+5V0 of the 5V0 power supply; the computer bus P1.0~P1.3 is realized by controlling the light-emitting diodes from the first optocoupler tube to the fourth optocoupler tube GO0~GO3 to emit light or not, and to control whether the first to fourth optocoupler tubes GO0~GO3 have current or not. Transmit A/D conversion data and meet the requirements of electrical isolation.

Compared with the prior art, the utility model has the following advantages:

The utility model has a simple, compact and reasonable structure; due to the use of optocoupler tubes for data transmission and electrical isolation, and the use of serial communication, there are fewer transmission lines, small volume, and high withstand voltage; High-speed communication and electrical isolation requirements between the dynamic range voltage measurement computer and the A/D integrated block.

Description of drawings

Fig. 1 is a schematic diagram of the connection principle of the optocoupler isolation control interface circuit components of the utility model.

Detailed ways

Below the utility model will be further described in conjunction with the embodiment in the accompanying drawing:

The utility model mainly adopts the computer bus P1.0-P1.3 to control whether the light-emitting diodes of the first to the fourth optocoupler tubes GO0-GO3 emit light or not, and whether the photosensitive triodes of the first to fourth optocoupler tubes GO0-GO3 are present or not. Current, to achieve high-speed transmission of A / D conversion data and meet the function of electrical isolation.

The connection relationship of the main optocoupler isolation control interface circuit components of the utility model is as follows:

The first isolation resistor RG1 is the anode power supply resistor of the first optocoupler GO0, one end of them is connected to +5V0, and the other end is connected to the anode of the first optocoupler GO0 diode. The seventh isolation resistor RG7 is the positive power supply resistor of the second optocoupler GO1, one end of which is connected to +5V0, and the other end is connected to the collector of the photosensitive tube of the second optocoupler GO1. The third isolation resistor RG3 is the anode power supply resistor of the third optocoupler GO2, one end of which is connected to +5V0, and the other end is connected to the anode of the diode of the third optocoupler GO2. The fourth isolation resistor RG4 is the anode power supply resistor of the fourth optocoupler GO3, one end of them is connected to +5V0, and the other end is connected to the anode of the diode of the fourth optocoupler GO3. The second isolation resistor RG2 is the anode power supply resistor of the second optocoupler GO1, one end of which is connected to +5V3, and the other end is connected to the anode of the diode of the second optocoupler GO1. The fifth isolation resistor RG5 is the positive power supply resistor of the fourth optocoupler tube GO3, one end of them is connected to +5V3, and the other end is connected to the collector of the photosensitive tube of the fourth optocoupler tube GO3. The sixth isolation resistor RG6 is the positive electrode power supply resistor of the third optocoupler GO2, one end of them is connected to +5V3, and the other end is connected to the collector of the photosensitive tube of the third optocoupler GO2. The eighth isolation resistor RG8 is the power supply resistor of the first optocoupler GO0, one end of them is connected to +5V3, and the other end is connected to the collector of the photosensitive tube of the first optocoupler GO0. P1.0 SDI is the computer serial data input terminal, it is connected to the cathode of the first optocoupler tube GO0 diode. SDO is the A/D analog-to-digital conversion serial data output terminal, which is connected to the cathode of the second optocoupler tube GO1 diode. P1.2 SCLK is the computer serial data clock pulse terminal, which is connected to the cathode of the third optocoupler GO2 diode. P1.3 CS is the computer serial data chip selection terminal, which is connected to the cathode of the fourth optocoupler GO3 diode. The emitter of the photosensitive tube of the first photocoupler GO0, the emitter of the photosensitive tube of the third photocoupler GO2, and the emitter of the photosensitive tube of the fourth photocoupler GO3 are all connected to the ground G+5V3 of the +5V3 power supply. The emitter of the photosensitive tube of the second optocoupler GO1 is connected to the ground G+5V0 of the 5V0 power supply.

The working principle and action process of the utility model:

P1.0 SDI is the computer serial data input terminal, it is connected to the cathode of the first optocoupler tube GO0 diode, when it is low potential, the first optocoupler tube GO0 diode emits light, and the first optocoupler tube GO0 photosensitive tube has When the current passes through, the collector of the photosensitive tube of the first optocoupler tube GO0 is at a low potential, which is also sent to the A/D analog-to-digital conversion input terminal SDI at a low potential. If it is at a high potential, the first optocoupler tube GO0 diode does not emit light, and the first optocoupler tube GO0 photosensitive tube has no current passing through, so that the collector of the first optocoupler tube GO0 photosensitive tube is at a high potential and sent to the A/D module The digital conversion input terminal SDI is also high potential. SDO is the A/D analog-to-digital conversion serial data output terminal, it is connected to the cathode of the second optocoupler tube GO1 diode, when it is low potential, the second optocoupler tube GO1 diode lights up, and the second optocoupler tube GO1 photosensitive tube There is a current passing through, so that the collector of the photosensitive tube of the second optocoupler GO1 is at a low potential, and it is also sent to the computer bus P1.1SDO at a low potential. If it is at a high potential, the diode of the second optocoupler GO1 does not emit light, and the photosensitive tube of the second optocoupler GO1 has no current, so that the collector of the photosensitive tube of the second optocoupler GO1 is at a high potential and sent to the computer bus P1. 1SDO is also high. P1.2 SCLK is the computer serial data clock pulse terminal, it is connected to the cathode of the third optocoupler GO2 diode, when it is low potential, the third optocoupler GO2 diode emits light, and the third optocoupler GO2 photosensitive tube is on There is current passing through, so that the collector of the third optocoupler GO2 photosensitive tube is at a low potential, and the SCLK terminal sent to the A/D analog-to-digital conversion clock pulse terminal is also at a low potential. If it is at a high potential, the third optocoupler GO2 diode does not emit light, and the third optocoupler GO2 photosensitive tube has no current passing through, so that the collector of the third optocoupler GO2 photosensitive tube is at a high potential and sent to the A/D module The SCLK end of the digital conversion clock pulse end is also a high potential. P1.3CS is the computer serial data chip selection port, it is connected to the cathode of the third optocoupler tube GO2 diode, when it is low potential, the fourth optocoupler tube GO3 diode emits light, and the fourth optocoupler tube GO3 photosensitive tube has The current passes through, so that the collector of the photosensitive tube of the fourth photocoupler GO3 is at a low potential, and the CS terminal sent to the A/D analog-to-digital conversion chip selection terminal is also at a low potential. If it is at a high potential, the fourth optocoupler GO3 diode does not emit light, and the fourth optocoupler GO3 photosensitive tube has no current passing through, so that the collector of the fourth optocoupler GO3 photosensitive tube is at a high potential and sent to the A/D The analog-to-digital conversion chip selection terminal CS terminal is also a high potential.

Claims (1)

1. An optocoupler isolation control interface circuit structure, characterized in that the connection relationship of components is as follows: One end of the first isolation resistor (RG1) is connected to (+5V0), and the other end is connected to the anode of the first optocoupler (GO0) diode; one end of the seventh isolation resistor (RG7) is connected to (+5V0), and the other end is connected to the second optocoupler. The collector of the photosensitive tube of the coupling tube (GO1); one end of the third isolation resistor (RG3) is connected to (+5V0), and the other end is connected to the anode of the diode of the third optocoupler tube (GO2); one end of the fourth isolation resistor (RG4) Connect (+5V0), and the other end connects to the anode of the diode of the fourth optocoupler (GO3); one end of the second isolation resistor (RG2) connects to (+5V3), and the other end connects to the anode of the diode of the second optocoupler (GO1); the fifth One end of the isolation resistor (RG5) is connected to (+5V3), and the other end is connected to the collector of the photosensitive tube of the fourth optocoupler (GO3); one end of the sixth isolation resistor (RG6) is connected to (+5V3), and the other end is connected to the third optocoupler The collector of the coupling tube (GO2) photosensitive tube; one end of the eighth isolation resistor (RG8) is connected to (+5V3), and the other end is connected to the collector of the first optocoupler tube (GO0) photosensitive tube; the computer serial data input terminal ( P1.0 SDI) is connected to the cathode of the first optocoupler (GO0) diode; A/D analog-to-digital conversion serial data output terminal (SD0) is connected to the cathode of the second optocoupler (GO1) diode; computer serial data clock The pulse terminal (P1.2 SCLK) is connected to the cathode of the third optocoupler (GO2) diode; the computer serial data chip selection terminal (P1.3 CS) is connected to the cathode of the fourth optocoupler (GO3) diode; The emitter of the photosensitive tube of the coupling tube (GO0), the emitter of the photosensitive tube of the third optocoupler tube (GO2), and the emitter of the photosensitive tube of the fourth optocoupler tube (GO3) are respectively connected to the ground (G+) of the (+5V3) power supply 5V3); the emitter of the photosensitive tube of the second optocoupler tube (GO1) is connected to the ground (G+5V0) of the power supply (5V0); the computer bus (P1.0～P1.3) controls the first optocoupler tube To the fourth optocoupler tube (GO0~GO3) the light-emitting diode emits light or not; to control whether there is current in the phototransistor from the first optocoupler tube to the fourth optocoupler tube (GO0~GO3) to realize the transmission of A/D conversion data and Meet the needs of electrical isolation.

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