CS203641B1 - Connection of the controlling circuit - Google Patents

Description

It is an object of the present invention to provide a control circuit which processes up to fifteen input quantities, has two outputs and is intended for the uniform execution of control functions of electrical devices in MV and MV substations.

At present, unified control circuits are not used in HV and HV substations and control is carried out in various ways by combining electrical relay circuits with compressed air or mechanical systems. Individual circuits are designed for individual electrical devices, which are available in several types in each substation. These connections have a number of drawbacks, in particular the high demands on the number of auxiliary contacts and multiplication relays, the complex interconnection and cabling, the difficult design and the demanding maintenance, and they show little reliability in operation. These disadvantages lead, on the one hand, to higher demands and maintenance costs, do not allow for the introduction of automation and are the cause of frequent failures which result in considerable economic damage. A major disadvantage is also the impossibility of introducing modern electronic interlocking systems which, when using the control option, allow the economical execution of double or even triple interlocking systems, double signal processing and brings the possibility of increasing the reliability of interlocking by one or two orders. This gives the possibility of minimizing operating disturbances to a minimum, which is not possible with previous wiring.

These disadvantages are overcome by the wiring of the control circuit according to the invention, which consists of five inverters and seven product negation circuits. It is characterized in that the fifth input of the sixth negation product circuit is connected to the output of the first negation product circuit, the second input of which is the fifth connection of the circuit. The tenth wiring input is coupled to the second input of the seventh product negation circuit whose output is connected both to the first wiring output and to the fourth inverter input. The output of the fourth inverter is coupled to the first input of the second product of the negation circuit, the second input of which is connected to the fourteenth input of the circuit. The fifteenth input of the circuit is connected to the second input of the third Product Circuit with negation, the first input of which is connected to the output of the fifth inverter. The input of the fifth inverters is connected both with the output of the second product circuit with negation and with the second output of the circuit whose thirteenth input is connected with the fifth input of the seventh product circuit with negation. The fourth input of the seventh product negative circuit is connected to the output of the third inverter whose input is connected to the twelfth input of the circuit. The eleventh wiring input is coupled to the second inverter input, whose output is coupled to the third input of the seventh negative product circuit. The first input of the seventh product of the negation circuit is connected to the output of the fifth product of the negation circuit, the second input of which is connected to the sixth input of the circuit. The seventh input of the circuit is connected both to the first input of the fourth negation product and to the second input of the sixth negation product circuit, the third input of which is connected to the second input of the circuit. The first wiring input is coupled to the first input of the sixth negation product circuit and the second input of the fourth negation product circuit whose third input is connected to the eighth input circuit. The ninth input of the circuit is connected to the input of the first inverter, the output of which is connected to the fourth input of the fourth product circuit with negation. The output of the fourth negation product circuit is coupled to the third input of the fifth negation product circuit, the first input of which is connected to the output of the sixth negation product circuit. The fourth input of the sixth negation product circuit is coupled to the third wiring input, the fourth input of which is connected to the first input of the first negation product circuit. The fifth input of the fifth product negation circuit is coupled to the output of the third product negation circuit.

The advantage of wiring the control circuit according to the invention is that it combines all the command functions of electrical devices of different types with a single unit circuit, and can be easily supplemented with other circuits and combined with other wiring to form compact interchangeable blocks. The reliability of such blocks is then considerably higher than the individual wiring used up to now, maintenance faster and easier, construction and maintenance costs considerably lower. The failure rate of the control and automation equipment is therefore less and the damage caused by faulty handling is considerably less.

• An example of wiring the control circuit according to the invention is in the attached figure. It consists of five inverters and seven product negation circuits and is characterized in that the fifth input 53 of the sixth product negation circuit 11 is connected to the protrusion 64 of the first product negation circuit 6, the second input 36 of which is connected to the fifth input 17. The tenth wiring input 22 is coupled to the second input 55 of the seventh product with a negation 12 whose output 70 is connected both to the first wiring output 28 and to the input 33 of the fourth inverter 4. The output 82 of the fourth inverter 4 is connected to the first input 37 a second negation circuit product 7, the second input 38 of which is connected to the fourteenth input 26 of the circuit. The fifteenth input 27 is connected to the second input 40 of the third product circuit with negation 8, whose first input 39 is connected to the output 63 of the fifth inverter 5. The input of the fifth inverter 5 is connected to output 65 of the second product circuit with negation 7 and a second wiring output 29 whose thirteenth input 25 is coupled to the fifth input 58 of the seventh product negation circuit 12. The fourth input 5.7 'of the seventh product negation circuit 12 is coupled to the output 61 of the third inverter 3 whose input 32 is coupled to the twelfth input 24 connection. The 11th input 23 is connected to the input 31 of the second inverter 2, whose output 60 is coupled to the third input 56 of the seventh product of the negation 12, and the first input 54 of the seventh product of the negation 12 is coupled to the output 68 of the fifth product. with the negation 10, the second input 46 of which is connected to the sixth input 18 of the circuit. The seventh wiring input 19 is coupled to the first input 41 of the fourth negation product 9 and the second input 5Ό of the sixth negation product 11, whose third input 51 is coupled to the second wiring input 14. The first wiring input 13 is connected, on the one hand, to the first input 49 of the sixth product negation circuit 11 and, on the other hand, to the second input 42 of the fourth product negation circuit 9, whose third input 43 is connected to the eight wiring input 20. The ninth wiring input 21 is coupled to the input 30 of the first inverter 1, whose output 59 is coupled to the fourth input 44 of the fourth product circuit with negation 9. The output 67 of the fourth product circuit with negation 9 is coupled to the third input 47 of the fifth product circuit. with the negation 10, the first step 45 of which is connected to the output 69 of the sixth product of the negation 11. The fourth input 52 of the sixth product of the negation 11 is connected to the third wiring input 15, the fourth input 16 is connected to the first input 35 of the first product. 6. The fifth input 48 of the fifth product of the negation 10 is connected to the output 86 of the third product of the negation 8.

The individual circuit elements according to the invention can be characterized as follows:

The inverters 1 to 5 are logic inverters, either realized by known circuits in diodorant or transistor logic, or preferably using integrated circuit negated product circuits, in which all inputs are combined into a single input.

The 6 to 12 negation product circuits are either conventional logic circuits, realized by logic diodorant circuits, or transistors using known circuitry, or preferably a commonly manufactured two to five input negation product circuitry.

In practice, the entire circuit of the control circuit according to the invention is preferably used in the construction of replaceable blocks, where the circuit is repeated several times, and can be supplemented with other logic circuits as required and combined with other circuitry. The first wiring input 13 is supplied with a logic signal that the operating conditions for control have been met. On. the second wiring input 14 connects a logic signal from the program control selection. A logic start signal from the program control is connected to the third wiring input 15. The fourth and fifth inputs 16 and 17 are connected to the logic signals of the program control of the individual electrical devices. A sixth input 18 is provided with a logic signal for direct control without selection, without a link to the program control. A tap-wired logic signal is applied to the seventh wiring input 19 and a permanent intermediate position logic signal to the eighth wiring input 20 is provided. The ninth input 21 is connected with a logic signal from the manual control to the selection. The tenth input 22 is provided with a logic signal about the end state of the controlled electrical apparatus. The 11th wiring input 23 and the 12th wiring input 24 are provided with logic blocking signals to prevent tampering. The thirteenth wiring input 25 receives a logic fault signal in the downstream logic and electrical circuits. A logic signal from the common level circuit is connected to the fourteenth wiring input 26 to ensure proper operation of the control circuit when power is applied. The 15th wiring input 27 is provided with a logic signal blocking the operation of the control circuit in a permanent intermediate position, switch pole mismatch, or any other fault.

At the first wiring output 28, a logic signal is taken for the internal logic links and blockages and between the individual control circuits, to evaluate the intermediate position and the like. At the second wiring output 29, a command signal for the controlled electrical apparatus is taken.

The function of the control circuit according to the invention is such that it can be operated in essentially three ways:

It can be directly controlled by a logic signal at the sixth wiring input 18 without tap and program selection if the blocking conditions / logic signal at the eleventh ¹ and twelfth wiring inputs 23 and 24 are met and if there is no fault, ie if the logic signal is correct thirteenth input 25 wiring. The issued pulse command is automatically extended by coupling from output 66 of the third product circuit with negation 8 to the fourth input 48 of the fifth product circuit with negation 10. After reaching the final state of the controlled electrical device, the command is automatically terminated by logic signal on tenth input 22 a signal from an intermediate position of the actuated electrical apparatus at the fourteenth wiring input 27.

It can be programmatically controlled when a tap is selected with a logic signal at the seventh input 19, when programmatically selected by a logic signal at the second wiring input 14 and when the operating conditions are met by a logic signal at the first wiring input 13. The program commands arrive at the fourth or fifth input 16 or 17 of the wiring, the start of the control being determined by a logic signal at the third wiring input 15.

Manually with the selection can be controlled by a logic signal at ninth input 21 when a tap is selected by a logic signal at seventh input 19, this control being blocked by a continuous intermediate position of the controlled electrical device by a logic signal at the 8th input 20. As with both program and direct control, the blocking conditions, i.e., the effective logic signals on the eleventh and twelfth wiring inputs 23 and 24, as well as the blocking from failure on the thirteenth wiring input 25, again apply. Likewise, the command is automatically extended by coupling from output 66 of the third negation 8 and to the fourth input 48 of the fifth negation 10 and automatically terminated by a logic signal from the end of the controlled electrical apparatus at the tenth input 22.

The wiring is used in the construction of special control units intended for the control of power stations.

Claims (1)

P R E D Μ E T Control circuit wiring consisting of five inverters and seven negation product circuits, characterized in that the fifth input (53) of the 6th negation product circuit (11) is connected to the output (64) of the first negation product circuit (6), whose second input (36) is coupled to the fifth input (17) of the circuit, whose tenth input (22) is coupled to the second input (55) of the seventh product of the negation circuit (12), whose output (70) is connected to first input (28) of wiring and second input (33) of the fourth inverter (4), whose output (62) is connected to the first input (37) of the second product circuit with negation (7), whose second input (38) is connected to a fourteenth input (26) of the circuit, the fifteenth input (27) of which is connected to the second input (40) of the third product of the negation circuit (8), the first input (39) of which is connected to the output (63) of the fifth inverters (5); the input (34) of which is connected to the output (65) of the second product envelope The negative input (7) and the second output (2) 9) of the circuit, whose thirteenth input (25) is connected to the fifth input (58) of the seventh product of the negation (12), whose fourth input ('5 ^! 7) is connected to the output (61) of the third inverter (3), whose input (32) is connected to the twelfth input (24) of the circuit, whose eleventh input (23) is connected to the input (31) of the second inverter (2) whose output (60) is connected to the third input (56) of the seventh product circuit with negation (12), OF THE INVENTION whose first input (54) is coupled to the output (68) of the fifth negation product (10), whose second input (46) is coupled to the sixth input (18) of the circuit, the seventh input (19) being coupled to the first the input (41) of the fourth product of the negation (9) and second input (50) of the sixth product of the negation (11), the third input (51) of which is connected to the second input (14) of the circuit, the first input , (13) is connected to the first input (49) of the sixth negation product (11) and to the second input (.42) of the fourth negation product (9), the third input (43) of which is connected to the eighth input (20) a circuit whose ninth input (21) is connected to the input (30) of the first inverters (1), - whose output (59) is connected to the fourth input (44) of the fourth product circuit with negation (9), 67) is connected to the third input (47) of the fifth product circuit with negation (10), whose first input up to £ 45) is connected to the output (69) of the sixth negation product (11), the fourth input (52) of which is connected to the third wiring input (15), the fourth of which (16) is connected to the first input (35) ) of the first product circuit with negation. (6), wherein the fifth input (48) of the fifth product negation circuit (10) is connected to the output (66) of the third product negation circuit (8).