CS223941B1 - Connection of the source of control signals for divided switch rooms - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to a control circuit for split substations, which solves a new, very simple stereotyping circuit, evaluating control signals for logically modifying common release signals in split substations based on the condition of longitudinal separating electrical apparatus. substations also for circuit substations.

So far, control signal sources are not used for split substations. To ensure the proper operation of the interlock and release circuits, the signal switch contacts of the individual devices in the longitudinal section of the switchgear or the contacts of the relays connected to them are connected directly to the serial parallel chains of the individual interlock and release circuits. Such connections are disadvantageous in that they must always be individually designed and implemented, except for assembly, at the expense of expensive cabling between the control boxes of the individual switchgear boxes.

In addition, they are less reliable due to the large number of series-connected contacts and maintenance of such wiring is difficult and laborious.

These disadvantages are completely eliminated by the wiring of the control signal source for the split substations, which consists of at least two summation and three product circuits. It is characterized in that the first input of the third product circuit is connected to the output of the second summing circuit, the first input of which is connected to the tenth input of the circuit and to the first input of the first summing circuit. The output of the first summation circuit is connected to the first input of the first product circuit, the output of which is connected to the first input of the second product circuit and to the first output of the wiring. The second wiring output is coupled to the output of the second product circuit, the second input of which is coupled to the third wiring output and the output of the third product circuit. The second input of the third product circuit is coupled to the sixth input of the circuit, the fifth input of which is connected to the third input of the second summing circuit.

The second input of the second summation circuit is connected to the fourth input of the circuit, the second input of which is connected to the third input of the first summation circuit. The second input of the first summation circuit is connected to the first input of the circuit, the third input of which is connected to the second input of the first product circuit. The power terminal of the first power circuit is coupled to the power terminal of the second and third power circuit and the power terminal of the wiring.

The advantage of connecting the control signal source for the split substations according to the invention is that it is still the same for the individual types of two-system substations, regardless of the number of substations dividing and the possible twisting, and that they can be easily extended to three-system substations. This results in savings in design work, simple manufacturing and assembly, the possibility of typing, and a significant increase in reliability while reducing investment and maintenance costs. The advantage is that the wiring can be realized using common logic circuits, while the remaining logic circuits can be used in individual logical units. However, they, together with other repeating circuits, can advantageously be built into specialized interchangeable blocks, further enhancing wiring transparency and maintenance.

An example of wiring the control signal source for split wiring is shown in the block diagram. The individual wiring blocks can be characterized as follows:

For example, both the summation circuits 6 and 2 may be simple passive diode summation logic circuits as commonly used, but it is advantageous to duplicate them, i.e. to shift two diodes in succession, with a view to reducing the risk of false-backloading. in case of diode transition. Similarly, the third additive circuit X is implemented in the case of wiring expansion.

All three product circuits χ, £, χ are most easily realized using reed relays with one or two contacts, where one pole of the contact forms one of the two inputs, the other pole of the contact forms the output and one pole of the coil forms the other of both inputs. the coils are usually connected to the power supply despite the resistance. If the contacts are dv8, it is advantageous to connect them in series with respect to any bonding. In the extended connection, other product circuits are usually implemented in the same way, namely the third to fifth X, X, χ.

In the example, the individual subunits are connected as follows: The first input 51 of the third product circuit X is connected to the output 24 of the second total circuit 2, the first input 21 of which is connected to the tenth input 10 and the first input 11 of the first total circuit. The output 14 of the first summation circuit 4 is connected to the first input 31 of the first product circuit X, whose output 33 is connected to the first input 41 of the second product circuit 8 and to the first output 111 of the circuit. The second wiring output 112 is coupled to the output 43 of the second product circuit 86, the second input 42 of which is connected to the third wiring output 113 and to the output 53 of the third product circuit χ. The second input 52 of the third product circuit X is coupled to the sixth input circuit 106, the fifth input 105 of which is coupled to the third input 23 of the second summing circuit χ. The second input 22 of the second summation circuit χ is coupled to the fourth wiring input 104, whose second input χοχ is coupled to the third input 13 of the first summation circuit χ. The second input 12 of the first summation circuit X is coupled to the first wiring input 101, the third input 103 of which is connected to the second input 32 of the first product circuit χ. The power terminal 39 of the first power circuit 40 is coupled to the power terminals 49 and 59 of the second and third power circuit 36 and X and the wiring power terminal 100.

The function of the control signal source for the split switchgear is as follows: The first wiring input 101 receives the open state signal of the first busbar disconnector of the longitudinal busbar clutch in the left section of the substation; busbar couplings in the right section of the substation. The fourth wiring input 104 receives the off-state signal of the second busbar disconnector of the longitudinal busbar coupling in the left section of the substation, and the fifth wiring input 105 receives the off-state signal of the second busbar disconnector along the busbar switch in the right section of the substation. An off-state signal is provided to the tenth wiring input 110 to switch longitudinal busbar couplings, which is common to both sections.

The third wiring input 103 receives a trip state of the first elongated disconnector between the two substations, and the six wiring input 106 receives the off state of the second elongate disconnectors between the two substations. Similarly, when the wiring is expanded, the seventh wiring input 107 receives the OFF signal of the third busbar disconnector of the longitudinal busbar coupling from the left section, and the eighth wiring input 108 receives the OFF signal of the third busbar disconnector of the longitudinal busbar coupling of the right section. The ninth wiring input 109 receives an off-state signal from the third longitudinal disconnector between the two sections of the substation.

If the signal is on the first or second or tenth input 101, or 102 or 110, and the current signal is on the third wiring input 103, the signal appears on the first wiring output 111. Similarly, if a signal at the fourth or fifth or tenth input > 04 or 105 or 110 is wired while the signal is at the sixth wiring input 106, the signal will also appear at the third wiring output. If there are simultaneously signals on the first and third wiring outputs 111 and 113, the signal also appears on the second wiring output 112. The same is true for wiring expansion where the signal at the fifth wiring output 115 is dependent on the signals on the seventh or eighth or tenth wiring input 107 or 108 or 110 and the simultaneous presence of the signal on the ninth wiring input 109. Also, the signal at the fourth wiring output 114 is dependent on the simultaneous presence of the signals on the third and fifth wiring outputs 113 and 115, and likewise the signal at the sixth wiring output 116 is dependent on the simultaneous presence of the signals on the first and fifth wiring outputs T11 and 115.

The wiring is used in the construction of special pre-wired type blocks used for control systems of two- and three-system substations, which can be assembled in a modular manner.

Claims (2)

SUBJECT OF THE INVENTION Wiring of a control signal source for split substations, comprising at least two summation and three product circuits, characterized in that the first input (51) of the third product circuit (5) is connected to the output (24) of the second summing circuit (2), the first input (21) is connected to the tenth input (110) of the wiring, and the first input (11) of the first summation circuit (1) whose output (14) is connected to the first input (3Ό of the first product circuit (3) whose output ( 33) is connected to a first input (41) of the second product circuit (4) and to a first circuit output (111), the second output (112) of which is connected to the output (43) of the second product circuit (4), the second input (42) is coupled to the third wiring output (113) and the output (53) of the third product circuit (5), the second input (52) of which is connected to the sixth input circuit (106) of which the fifth input (105) is connected to the third input (23). ) of the second total circuit (2), j wherein the second input (22) is coupled to the fourth wiring input (104), the second input (102) is coupled to the third input (13) of the first summation circuit (1), whose second input (12) is coupled to the first input (101) a circuit, whose third input (103) is connected to the second input (32) of the first power circuit (3), whose power terminal (39) is connected to the power terminal (49 and 59) of the second and third product circuits (4 and 5); the power terminal (100) of the wiring. Wiring according to claim 1, characterized in that the first input (41) of the second product circuit (4) is connected to the second input (92) of the sixth product circuit (9), whose output (93) is connected to the sixth output (116) a circuit having a seventh input (107) connected to a second input (62) of a third summation circuit (6) whose third input (63) is connected to an eighth input (108) of a circuit whose ninth input (109) is connected to a second input (82) a fifth product circuit (8) whose output (83) is coupled to a fifth circuit input (115), the fourth output (114) is coupled to an output (73) of the third product circuit (7), whose first input (71) is connected to a third wiring output (113), the tenth input (110) of which is connected to the first input (61) of the third summation circuit (6), whose output (64) is connected to the first input (81) of the fifth product circuit (8). ), whose power terminal (89) is connected to the power terminal (59, 79 and 99) of the third, th and the Sixth Product Circuit (5, 7 and 9). 1 drawing