CS246192B1 - Connection of the diodorel selector circuit - Google Patents

Abstract

The connection of the selector circuit is applicable for various selection functions and a large number of selection points. It allows the construction of entire type blocks, while the amplifying relay and logic can be made as separate blocks, easily interconnected with type cables. The connection is easily expandable to obtain additional, galvanically isolated outputs, as is often required in complex control systems with either conventional logic or microprocessors.

Description

The object of the invention is the connection of a long-range selector circuit, which can be used to select taps for all types of MV and wn substations, where the selector circuits are still used in pure relay, while also solving the separation of signals for different applications and their amplification.

Until now, the selection circuits are solved individually using electromagnetic relays and are used only for selecting control paths.

The disadvantages of these connections are their higher demands on space and consumption as well as their lower service life with a limited range of functions, so that they cannot be used in complex control systems. Also their cabling requirements are higher.

These disadvantages are overcome by the wiring of the long-range selector circuit according to the invention, which is designed from the same components as the control systems and logic used, and yet performs more functions. It consists of at least two switches, one relay, one signal barrier, one signaling button, one resistor, three diodes, one fuse and one disconnecting plug. It is based on the fact that the power supply output of the wiring is connected to the wiring select busbar and to one operating contact pole of the select button, the other of which is connected to the anode of the other diode.

The cathode of the second diode is connected to one pole of resistance, to the first wiring input, to the excitation input of the first switch, and to the cathode of the first diode, the anode of which is connected to the excitation input of the second switch and to the first output of the first switch. The first power input of the first switch is connected to a wiring lubrication busbar whose blocking busbar is connected to the second output of the first switch. The second power input of the second switch is coupled to the second power busbar of the wiring and to the first power input of the second switch, the first output of which is coupled to one pole of the boost relay coil, both the cathode of the third diode and the direct input of the signal barrier.

The barrier input of the signal barrier is coupled to a third wiring input, the fourth input of which is connected to the second power input of the second switch. The second output of the second switch is coupled to a fourth wiring output, the third power of which is connected to one pole of the fuse. The second pole of the fuse is connected to one pole of the first operational contact of the boost relay, the other pole of which is connected to one pole of the second operational contact of the boost relay. The second pole of the second operational contact of the boost relay is connected to one pole of the disconnecting plug, the other pole of which is connected to the first wiring output.

The second wiring output is connected to one pole of the third operational contact of the boost relay, the other of which is connected to the fourth power busbar of the wiring. The first power busbar of the wiring is connected to the third power input of the first switch, the third power input of the second switch, the power input of the signal barrier, the anode of the third diode, the second pole of the amplifier relay coil and the signal element. whose second pole is connected to the second resistance pole.

The advantage of connecting the long-range selector circuit according to the invention is, in particular, that it is applicable to all types of substations unchanged and therefore it is not necessary to individually design it and furthermore it can be used not only for control paths but also for signals for switchable blocking logic etc. Another advantage is its lower demands on space, consumption, maintenance, design and construction work in production. It can be assembled from the same logic circuits and units that are commonly used for other logic.

The wiring permits the construction of stereotyped selection blocks that include a logical partition, as well as stereotyped booster blocks containing booster relays, fuses, disconnect plugs. Interconnection of both types of blocks is made using the same type cables as used for other logic, which is also an advantage.

In the drawing, the connection is repeated with solid lines and it is repeated several times and with dashed lines of the common part for lubrication and blocking, as well as possible extension with other outputs.

The individual sub-blocks can be briefly characterized as follows:

The sub-blocks 6, 6, 10 are common bilingual relays, which are commonly used in logic units of diodorant logic systems. Its coils are usually arranged in series with a resistor and bridged by a quench diode connected in the opposite direction of the control signal directly to the coil.

Sub-block 3 is a signaling barrier, which is typically used in logic systems as a conditional signaling element without output, and is only implemented using a signal diode, diodes, and resistors, without active elements.

The sub-block 6 is a conventional electromagnetic relay with three operating or switching contacts, preferably of a feeder type and of small size.

The sub-block 8 is a button with a working contact, further comprising a sub-element 05, for example a signal bulb or a diode.

Sub-block 6 is a conventional fuse or circuit breaker.

Sub-block Τ. 3 ^e conventional disconnect plug, preferably multipole, which allows disconnection of the controlled object during inspections, repairs and testing.

The sub-blocks 6 and 6 are conventional logic barriers used in diodorel logic. They are realized using reed relays in series with resistance, coils bridged by quenching diodes. Direct inputs consist of one coil pole and one contact pole, the output is identical to the other contact pole. The barrier input is formed by conducting a common coil point and a series resistance through the diode.

The busbars 20, 30, 40, 40, 60, 70, 80 are formed either as separate busbars or by sequentially connecting the individual points to which they are connected.

In the example of the diodorant circuit selection circuit, the individual sub-blocks are interconnected as follows:

The wiring power output 170 is coupled to the wiring select bus 50 and one operating contact pole of the select button 5, the other pole of which is connected to the anode of the second diode 02. The cathode of the second diode 02 is connected to one pole of resistor 04 and first input 110 the first input of the first switch 8 and the cathode of the first diode 01, the anode of which is connected to the excitation input 21 of the second switch 2 and the first output 14 of the first switch 6.

The first power input 12 of the first switch 6 is connected to the wiring lubrication busbar 60, whose blocking busbars 70 are connected to the second output 15 of the first switch 6. The second power input 13 of the first switch 6 is connected to the second power supply busbar 30 and to the first power input 22 of the second switch 2, the first output 24 of which is connected to the coil of the boost relay 4 and the cathode of the third diode 03. 31. The barrier input 32 of the signal barrier 6 is connected to a third wiring input 130, the fourth input 140 of which is connected to the second power input 23 of the second switch 6. The second output 25 of the second switch 2 is connected to a fourth circuit output 180 whose third power busbar 80 is connected to one pole of the fuse. The second pole of the fuse 4 is connected to one pole of the first operational contact 41 of the boost relay 4, the other pole of which is connected to one pole of the second operational contact 42 of the boost relay 4. 7, the second pole of which is connected to the first wiring output 150. The second wiring output 160 is coupled to one pole of the third working contact 43 of the boost relay 8, the other of which is connected to the fourth power supply busbar 40 of the wiring. The first power supply busbar 20 is connected to the third power input 19 of the first switch 6, the third power input 29 of the second switch 2, the power input 39 of the signal barrier 6, the anode of the third diode 03, and the second coil pole On the other hand, with one pole of the signaling element 05, the other pole of which is connected to the other pole of the resistance 04.

The function of wiring the diodorel-selector circuit according to the invention is as follows:

By pressing the selector button 8, the excitation input 11 of the first switch 8 is energized and the feedback from its output 14 via the first diode 01 is kept in the energized state even after releasing the button 5. At the same time the signaling element 05 usually illuminates. The power supply to the output 14 is via the first power input 12 of the first switch 8 from the wiring busbar 60, which is energized when the lubricating button 51 is not pressed, since the second barrier is energized at both direct inputs 91 and 92 from the second power busbar 30. live permanently.

By pressing the lubricating button 51, the barrier input 93 of the second barrier 9 is energized, this removes the voltage from the wiring lubrication bar 60 and the selected circuit is dropped because the feedback is de-energized. Then the same circuit or any other can be selected again. In order not to be able to select two or more circuits at the same time, the power supply is removed from the wiring busbar 60, which is secured at rest through the first barrier 13 at rest. This removes the power supply immediately after the switch 8 is energized, from whose second output 15 a signal arrives at the barrier input 83 of the first barrier 8 via the diode 05. This makes it impossible to select more than one circuit.

The selector circuit can also be selected from the outside via an input 110, wherein the external selector, such as a controller, is powered from the power supply output 170 of the wiring. A second switch 2 is energized directly from the output 14 of the first switch 6, which both energizes the boost relay 6 and has a direct output 25 connected to the first wiring output 180. Upon expansion of the circuit by a third switch 10, two more direct wiring outputs 220 and 240 are obtained, which can be separately powered or conditioned at the wiring inputs 210 and 230.

The boost relay 4 generates two additional outputs. One is power, where there are two p contacts of amplifier relay 6 in series. It is an output 150 wiring. This output is separately fused £. The other is also power-free, not fused, and is used to drive multiple logic circuits. The signal barrier serves to signal disagreement upon selection when the output 140 and the wiring input 130 are connected to each other for maintenance purposes. The power input 150 can be disconnected by a disconnecting plug for maintenance purposes.

The wiring of the diodoréléel selection circuit is used for automation and control of substations and whole electrical stations, or possibly in other technological objects where control is used in the selection.

Claims (4)

1. Wiring of a diodor relay selection circuit comprising at least two switches, one relay, one signal barrier, one signaling button, one resistor, three diodes, only one fuse and one disconnecting plug, characterized in that the power output (170) is connected to the selection busbar (50) and to one pole of the operating contact of the selection button (5), the other pole of which is connected to the anode of the second diode (02), the cathode of which is connected to one pole of resistor (04) and 110 / wiring, firstly with excitation input (11) of first switch (1), and secondly with cathode of first diode (01), whose anode is connected to excitation input (21) of second switch (2) and with first output (14) of first switch . (1), whose first power input (12) is connected to a lubricating busbar (60), the interlocking busbar (70) of which is connected to a second output (15) of the first switch (1), whose second power input (13) is connected with a second power busbar (30) and a first power input (22) of a second switch (2), the first output of which is connected both to one pole of the boost relay coil and the cathode of the third diode; with a direct input (31) of the signal barrier (3), the barrier input (32) of which is connected to a third input (130) of the circuit, the fourth input (140) of which is connected to a second power input (23) of the second switch the second output (25) is connected to a fourth output (180) of the wiring whose third power busbar (80) is connected to one pole of the fuse (6), the other pole of which is connected to one pole of the first operational contact (41) of the amplifier relay whose second pole is connected to one pole of the second operational contact (42) of the boost relay (4), the other pole of which is connected to one pole of the disconnecting plug (7), the other of which is connected to the first output (150) of the wiring, one pole of the third operational contact (43) of the amplifier relay (4), the second pole of which is connected to a fourth supply bus (40) of wiring whose first supply bus (20) is connected to the third supply input (19) of the first switch , on the one hand with the third power input (29) of the second switch (2), on the other hand with the power input (39) of the signal barrier (3), on the other hand with the anode of the third diode (03) one pole of the signal element (05), the other pole of which is connected to the other pole of the resistance (04). Wiring according to claim 1, characterized in that the second power supply busbar (30) is connected to a first second direct input (81 and 82) of the first barrier (8), the output of which (84) is connected to the wiring select busbar (50), whose blocking bus (70) is connected to the anode of the fourth diode (05), the cathode of which is connected to the barrier input (83) of the first barrier (8), the power input of which is connected to the first power busbar (20). 3. Connection according to claim 1, characterized in that the second supply busbar (30) is connected to the first and second direct inputs (91 and 92) of the second barrier (9) and to one pole of the lubricating push button (51) whose second pole is connected. with a second input (120) of wiring and an anode of a fifth diode (06), the cathode of which is connected to the barrier input (93) of the second barrier (9), the output of which (94) is connected to the lubrication busbar the busbar (2p) is connected to the power input (99) of the second barrier (9). 4. Connection according to claim 1, characterized in that the first output (14) of the first switch (1) is connected to the excitation input (101) of the third switch (10), the first output (104) of which is connected to the fifth output (230). whose fifth input (210) is coupled to the first power input (102) of the third switch (10), whose second output (105) is coupled to the sixth output (240) of the circuit, whose sixth input (220) is coupled to the second power input The third power input (109) is connected to the first power busbar (20) of the third switch (10). 1 drawing