CS205649B1 - Connection of logical circuit for realization of the engagement of reserves - Google Patents

Description

It is an object of the present invention to provide a reserve logic block, consisting of thirty-one elements, which allows all types of backups to be performed in a uniform and simple manner with a simple logic block with high reliability and availability.

Until now, the implementation of reserve backups has been carried out in various ways by means of relay, diodorel or contactless logic circuits or their combination, always using a larger number of basic universal logic circuits. The disadvantages of these engagements are their great diversity, the necessity of individual designs and the consequent! inconsistency in design and unnecessary wiring complexity, resulting in more difficult manufacturing, animation and maintenance, and lower reliability and availability, resulting in significant consequent damage to the controlled technology if the required function is not met.

These disadvantages are overcome by the connection of the logic block for the provisioning of reserve reserves according to the invention, which essentially consists in the fact that the second output of the converter is connected to the ninth output of the circuit, the 21st input being connected to the second input of the second summing circuit. The first input of the second summation circuit is connected to the second terminal of the third pushbutton, the first output of which is connected both by the inverse input of the eighth barrier circuit, the β positive power supply pole, and the first wiring output and second fuse terminal. The first fuse terminal is connected and the first input is connected, the second output

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205 849 is coupled to the output of the eighth barrier circuit. The direct input of the eighth barrier circuit is coupled to the second input circuit, the third input of which is connected and the first direct input of the first barrier circuit. The second direct input of the first barrier circuit is connected to both the fourth input of the circuit, the first direct input of the second barrier circuit, and the second direct input of the third barrier circuit, and the β cathode of the first diode whose anode is connected β by the second terminal. The first terminal of the first button is connected to the fifth input of the wiring and to the first terminal of the second button, the second terminal of which is connected to the anode of the second diode. The cathode of the second diode is connected, on the one hand, to the inverse input of the Sixth barrier circuit, and to the first direct input of the fifth barrier circuit, to the second input of the first sum circuit and to the sixteenth wiring input, the sixth input being connected to the third terminal of the first button; buttons j? connected to the seventh input of the circuit, the eighth of which is connected to the second direct access of the second barrier circuit. The outlet of the second barrier circuit is connected to the second input of the fourth summing circuit, the first input of which is coupled to the output of the first barrier circuit. The inverse input of the first barrier circuit is connected to the inverse input of the second barrier circuit and the β inverse input of the third barrier circuit to the output of the first sum circuit whose first input is connected and the fifteenth input is connected. the output circuit being connected by the first direct access of the third barrier circuit. The output of the third barrier circuit is coupled to the fifth circuit output, the fourth output of which is coupled to the cathode of the third diode. The anode of the third diode is coupled to the ninth input wiring and the third input of the fourth summation circuit, the output of which is connected to the third wiring output. The tenth wiring input is coupled to the first direct access of the fourth barrier circuit, the second direct input of which is connected to the eleventh wiring input. The twelfth wiring input is coupled to the inverse input of the fourth barrier circuit, the output of which is connected to the input of the first timing circuit. The first auxiliary input of the first time circuit is connected and the thirteenth input of the circuit, whose seventeenth input is connected to the second direct input of the fifth barrier circuit. The output of the fifth barrier circuit is connected to the first input of the fifth total circuit, and to the memory input of the memory circuit, the output of which is connected to the first input of the first product circuit, to the direct input of the seventh barrier circuit and the pulse circuit. The output of the pulse circuit is coupled to the first input of the third summation circuit, the second input of which is connected to both the three and three wires input, and to the second and second outputs of the first product circuit. The output of the first product circuit is connected to the first input of the seventh total circuit, the output of which is connected by the first input of the sixth total circuit to the input of the next circuit. The discharge of the next circuit is connected to the negative supply pole of the circuit, the seventh output of which is connected to the second terminal of the resistor.

The first output of the resistor is connected by the β output of the sixth summing circuit. Whose second input is connected by β twenty-five input input. The nineteenth wiring is connected to the third terminal of the second button, the fourth terminal of which is connected and the twenty input of the connection, the twenty-fourth connection of the connection is connected and the second to the second product circuit, the first

205 649 connected to the β output of the seventh barrier and to the converter's input. The first output of the converter is connected to the eighth output of the wiring, the tenth output of which is connected to the first output of the second time circuit. The second output of the second time circuit is coupled to the eleventh circuit output, the eighteenth input of which is connected directly to the sixth barrier circuit. The output of the sixth barrier circuit is coupled to the second output of the fifth total circuit, the output of which is coupled to the sixth output circuit. The twenty-second wiring input is coupled to the second timing circuit input, and the second summing circuit output is coupled to the memory input erasing input. The output of the third summation circuit is connected to the inverse input of the seventh barrier circuit, and the output of the second product circuit is connected to the second input of the seventh summation circuit.

The advantage of connecting the logic block for reserve stand-offs is its uniform and simple connection, suitable for versatile use, simple design, production, assembly, commissioning, testing and maintenance and especially its substantially higher reliability and availability. They can be used for all types of stand-ups that are commonly found in the automation of technological processes.

An example of the connection of a logical block for the implementation of reserve backups is shown in the attached diagram and the interconnection of individual elements is done as follows:

The second terminal 148 of the converter 26 is connected to the ninth output output 65, the twenty-first of which 51 is connected to the second input 78 of the second summation circuit 5. The first input 77 of the second summation circuit 5 is connected to the second terminal 145 of the third button 25. connected to the inverse input 123 of the eighth barrier circuit 18, the positive power pole 163 of the circuit, the first output 57 of the circuit, and the second terminal 162 of the fuse 160. The first terminal 161 of the fuse 160 is connected to the first circuit 31 58 is connected to the output 124 of the eighth barrier circuit 18. The direct input 122 of the eighth barrier circuit 18 is connected to the second wiring port 32, the third input 33 of which is connected to the first direct input 96 of the first barrier circuit 11. The second direct inlet 97 of the first barrier circuit 11 is connected to the second inlet circuit 34 and the first direct inlet 100 of the second barrier circuit 12 to the second direct inlet 105 of the third barrier circuit 13 and to the inverted input 114 of the fifth barrier circuit 15. with the cathode 69 of the first diode 6, the anode 68 of which is connected 8 by the second terminal 137 of the first button 23. The first terminal 136 of the first button 23 is connected and connected via the fifth port 35 and the first terminal 140 of the second button 24. The second diode 2 cathode 71 of the second diode 2 is connected to the inverted inlet 117 of the sixth barrier circuit 16, to the first direct input 112 of the fifth barrier circuit 15 and to the second inlet 75 of the first total circuit 4 and to the sixteenth circuit 46 the sixth input 36 is coupled to the third terminal 138 of the first button 23. the fourth terminal 13 9 of the first pushbutton 23 is coupled to the seventh wiring port 37, the third wiring 38 is connected and the second direct access port 101 to the second barrier circuit 12. The output 103 of the second barrier circuit 12 is connected and the second input 84 of the fourth summation circuit 7 whose first input 83 is connected to the output 99 of the first barrier circuit 61. Inverse

20S 649 the input 98 of the first diaphragm circuit 11 is connected both to the invert input 102 of the second barrier circuit 12 and to the inverse input 106 of the third barrier circuit 13 and to the output 76 of the first summing circuit 4 whose first input 74 is connected to the fifteenth circuit 45 . The fourteenth input circuit 44 is connected and the second auxiliary input 156 of the first timing circuit 29, the output 154 of which is coupled and the first direct input 104 of the third barrier circuit 13. The output 107 of the third barrier circuit 13 is connected to the fifth circuit output 61 of the fourth output 60 The anode 72 of the third diode 3 is connected to the ninth input 39 and the third input 85 of the fourth summation circuit 7, the output 86 of which is connected to the third output 59, respectively. The tenth wiring input 40 is coupled to the first direct input 108 of the fourth barrier circuit 4, the second direct input 109 of which is connected to the eleventh wiring input 41. The twelfth wiring input 42 is coupled to the inverse input 110 of the fourth barrier circuit 14, whose output 111 is coupled to the input 153 of the first timing circuit 29. The first auxiliary input 155 of the first timing circuit 29 is coupled to the thirteenth wiring input 43 whose seventeenth input 47 is coupled with the second direct input 113 of the fifth barrier circuit 15. The output 115 of the fifth barrier circuit 15 is connected 8 through the first input 87 of the fifth summing circuit 8 and with the recording input 125 of the memory circuit 19 whose output 127 is connected to the first input 128 of the first product circuit 20; on the one hand by the direct input 119 of the seventh barrier circuit 17 and on the other hand by the input 134 of the pulse circuit 22. The output 135 of the pulse circuit 22 is connected to the first input 80 of the third summing circuit 6. input 52 connected and second input 129 of the first component The output 130 of the first product circuit 20 is connected to the first inlet 93 of the seventh total circuit 10, the output 95 of which is connected to the first inlet 90 of the fifth total circuit 9 and to the inlet 151 of the signaling circuit 28. the negative terminal 63 of the circuit, whose seventh output 63 is coupled to the second terminal 150 of the resistor 27. The first terminal 149 of the resistor 27 is coupled to the output 92 of the sixth total circuit 9, the second input 91 of which is coupled to the twenty-five circuit 55. The nineteenth wiring port 49 is connected to the third terminal 142 of the second pushbutton 24, whose fourth terminal 143 is connected to the twenty wiring port 50. Twenty-fourth wiring input 54 is coupled to the second input 132 of the second product circuit 21, the first input 131 of which is connected to the output 121 of the seventh diaphragm circuit 17, and to the input 146 of converter 26. The first output 147 of converter 26 is connected to the eight output the tenth output 66 is connected by the first output 158 of the second time circuit 30. The second output 159 of the second time circuit 30 is connected by the 11th output circuit 67, the eighteenth input 48 being connected and the direct input 116 of the sixth barrier circuit 16. is coupled to the second input 88 of the fifth summation circuit 8, the output 89 of which is coupled 8 through the wired output 62. The wiring input 56 is connected to the input 157 of the second timing circuit 30 and the output 79 of the second summing circuit 5 is coupled to the lubrication input 126 of the memory circuit 19. The output 82 of the third summing circuit 85 is coupled to the 133 of the second product circuit 21 is coupled to the second input 94 '

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Individual elements of the connection can be characterized as follows:

Diodes 1, 2, 3 are common semiconductor diodes and serve as isolation wiring.

The summation circuits 4 to 10 are common diode summation circuits used in relay, diodorel or transistor logic, wherein the ninth summation circuit 9 also includes an amplifier, e.g.

The barrier circuits 11 to 18 are conventional diodorant barrier circuits with one or two direct inputs and one inverse input, usually realized by a reed switch contact with the relay coil being connected to the first resistance terminal by its first terminal. The first direct input is connected via diode to the second relay coil terminal, the second direct input is connected to one relay contact terminal, whereby both direct inputs can be interchanged as required. The other terminal of the relay contact is connected as the output of the barrier circuit. The inverse input of the barrier circuit is routed via a diode to a first relay coil terminal and a resistor, the second terminal of which is connected to the negative supply pole 164 of the wiring. The logic product function applies between all inputs of the barrier circuits 11 to 18.

The memory circuit 19 is similar to a barrier circuit with one direct and one inverse input, in which a direct input is preceded by a sum of two diode input diodes, so that a logic circuit with two direct inputs and one inverse input is formed, between which the logic function applies: X «(A + Β) ϋ, where A, B are direct inputs, C is the inverse input and X is the output of the circuit. By introducing feedback from output X to one direct input, e.g.

B results in a common memory function with a predominant erasing, to which the following applies:

Xn (A + X). where input A is the recording input, input C is the erasing input and X is the output of the memory circuit 19.

The product circuits 20, 21 are similar to the two direct input barrier circuits in which the inverse input is not used and therefore need not be discharged.

The pulse circuit 22 is a conventional pulse RC circuit, consisting of a capacitor and resistors, which, when a continuous signal is applied to the leakage filter, only the pulse signal, i.e., time-limited, is output. If necessary, additional auxiliary inputs may be provided for connecting an external capacitor to potentially increase the output pulse length. If necessary, it can also include an amplifier, eg reed relay.

Buttons 23, 24 are miniature buttons with a locked position, each having at least two switching contacts.

Button 25 is a miniature button without locking the depressed position with at least one make contact.

Converter 26 is a conventional relay converter with at least one make contact, realized by either a reed or other miniature relay.

Resistor 27 is a conventional low current resistor used to protect the reed contact when closed.

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The display circuit 28 is a conventional signal circuit consisting of a light emitting diode or a miniature bulb and a series resistor.

The first timing circuit 29 is a conventional timing circuit, delaying the start and end of the signal at output 154 relative to the signal at input 153. Both of the two auxiliary inputs 55, 156 can be used to increase the time range by connecting an external capacitor.

The second timing circuit 30 is a contact output timing circuit, realizing a start signal delay. at both outputs 158, 159 as opposed to the signal at input 157. Both time circuits 29, 30 can be easily realized using transistors in conjunction with RC circuits, or at short times using reed relays.

Fuse 160 is a conventional device fuse used to protect logic circuits in replaceable device blocks.

The function of engaging the logic block to realize reserve reserves according to the invention is the first in the wiring part, which includes the first, second and twenty-fourth stages 31, 32, wiring, first and second wiring outputs 57, 58, fuse 160 and eighth barrier circuit 18 connected circuits. A positive supply voltage is applied to the first wiring input 31 which is fused by fuse 160 and is distributed throughout the wiring via the positive wiring pole 163 and is also applied to the first wiring output 57 for supplying downstream circuits such as transmitter contacts and sensors.

Its possible loss is monitored by the eighth barrier circuit 18, and by means of the control voltage applied to the second wiring input 32 is reported on the second wiring output 58. Negative supply voltage! it is not fused and is distributed throughout the wiring through the negative wiring pole 164 of the wiring. The oscillating voltage for the purpose of fault indication, which is not fused within the wiring, is applied to the twenty-fourth wiring circuit 54 and is used to signal the fault on the wiring circuit 28 of the wiring as well as off wiring.

Another part of the connection provides two main modes of function, which are selected by pressing either the first or second buttons 23 or 24 or also by external signals on the fourth or sixteenth input 34 or 46, the current operation of both modes of operation being mutually blocked by inverse inputs 98, 102, 106, 114, 117 of the first, second, third fifth and sixth barrier circuits 11, 13. 15 and 16. The state of the two buttons 23, 24 can be connected, and using the sixth, seventh, nineteenth and twentieth inputs 36, 37, 49, 50, for example, to external signaling or interlock circuits. The selection of the first second mode of operation by the buttons 23, 24 is further conditioned by the presence of a signal at the fifth input 35, which is used in the remote control to block the mode selection by the buttons 23, 24. The wiring evaluates the signal for the replacement drive start, either the first button 23 must be pressed and the signal on the fifth input 35 must be connected, or the signal on the fourth input 34 must be wired, while the signal on the 16th input 46 must not be wired and the second button 24. Another condition

205 649 is the absence of a signal at the fifteenth input 45 wiring, which is used to block the start of the replacement drive during repairs and the like. The replacement drive start signal is k. on the third output 59 wiring if the signal either comes to the third input 33 wiring, eg from a failure of the basic drive, or if the signal comes to the eight wiring input 38 eg from an electrical protection or technology sensor, or the input 39 of the wiring, eg from the basic drive technology protection, which can be functionally created directly in the wiring. In this case, connect! the ninth input wiring 39 with the fifth wiring output 61, the tenth wiring output 66 is coupled to the tenth input wiring 40. The twenty-second wiring input 56 is provided with a base drive operation signal and a process sensor from which the start of the replacement drive is to be derived, and at the same time switching off the base drive by a signal from the fourth wiring output 60 is connected either by a rest contact to the eleventh wiring 41 or a work contact to the twelfth input 42 wired. The first time circuit 29 provides damping of the potential oscillation of the contacts of the connected process sensor, and its time can be extended by connecting an external capacitor to the thirteenth and fourteenth wiring inputs 43 and 44. The second timing circuit 30 shifts the moment of switching on the replacement drive by a set time after switching on the basic drive and thus ensures correct operation in cases where the sensor contacts cannot be in the correct position when the basic drive is switched on but after the set time. If a second mode of operation is selected in which the base drive acts as a replacement for another drive then either the second button 24 must be pressed and the signal at the fifth input 35 must be present, or the signal at the sixteenth input 46 must be wired, the first button 23 must not be pressed nor the signal on the fourth input 34 of the wiring. The drive start signal is applied to the 17th wiring input 47 and is issued as a command on the sixth wiring output 62. The command is recorded by the memory circuit 19 and is timed by the pulse circuit 22. If the 12th input 52 does not receive a drive start message at the time set on the pulse circuit 22, an oscillating light fault is reported on the signal circuit 28 and on the seventh output 63 wiring and simply connecting the eighth and ninth outputs 64 and 65 wired by the output contact of the converter 26, which serves for another permanent fault signal or for other purposes, for example to start another reserve drive and the like. The acknowledgment of the memory circuit 19 is carried out either locally by pressing the third button 25 or remotely by applying a short-term signal to the twenty-first input 51 of the circuit. The timing of the pulse circuit 22 can also be accomplished by connecting an external capacitor, provided that the other two inputs of the pulse circuit 22 are similar to the first timing circuit 29 of the auxiliary inputs 155, 156, which is not indicated in the attached diagram.

The drive can also be started by a master controller according to its program by means of the wiring, via the eighteenth input 48 wiring and the sixth output 62 wiring, but only if it is not selected as reverse, ie it does not operate in the second mode of operation.

The twenty-fifth wiring input 55 serves for mass testing of the fault signal bulbs connected to the seventh wiring output 63. The thirteenth wiring input 53, which is interconnected by β two20S 649 by the wiring input 52 permanently, serves to easily interconnect the twelfth or thirteenth wiring input 52 6i 53 by the twenty-first wiring 56 when the above-described functional technological protection of the drive is wired.

The wiring is used in the construction of a special unit for controlling important groups of drives operating in automatic standby mode according to various conditions, eg in power stations, gas stations and the like.

Claims (1)

SUBJECT OF THE INVENTION Connection of a logic block for the implementation of reserve backups, consisting of thirty-one elements, characterized in that the second terminal (148) of the converter (26) is connected and the ninth output (65) is connected, whose twenty-first vetup (51) is connected and the second input (78) a second summation circuit (5), the first input (77) of which is connected to the second terminal (145) of the third button (25), the first terminal (144) of which is connected to the invert vatupam (123) of the eighth defense device (18); having a positive power pole (163) of the wiring, on the one hand, and a first outlet (57) of the wiring, and on the other hand a second terminal (162) of the fuse (160), the first terminal (161) of which is connected to the first wiring input (31); 58) is connected by the 8 output (124) of the eighth barrier circuit (18), the direct input (122) of which is a spgen with the second circuit input (32), whose third input (33) is connected by the first direct input (96) of the first barrier circuit (11), whose second direct input (97) is connected on the one hand to the fourth input (34) of wiring, on the other hand to the first direct input (100) of the second barrier circuit (12) and secondly to the direct access (105) of the third barrier circuit (13) a fifth barrier circuit (15) and a cathode (69) of a first diode (1), whose anode (68) is connected to a second terminal (137) of the first button (23), the first terminal (136) of which is connected to the fifth input (35) connected and with the first terminal (140) of the second button (24), the second terminal (141) of which is connected to the anode (70) of the second diode (2), the cathode (71) of which is connected the first direct input (112) of the fifth barrier (15), the second input (75) of the first summation circuit (4) and the sixteenth input (46) connected, the sixth input (36) is connected to a third terminal (138) of the first button (23), the fourth terminal (139) of which is p coupled to a seventh circuit (37), the eighth input (38) of which is coupled to the second direct input (101) of the second barrier circuit (12), the outlet (103) of which is coupled to the eight of the fourth total circuit (7) whose first input (83) is connected to the output (99) of the first barrier circuit (11), the inverted input (98) of which is connected to the inverse input (102) of the second barrier circuit (12) and to the inverse vetup (106) the third barrier circuit (13) and the output (76) of the first summing circuit (4), the first of which (74) is connected with the fifteenth of the circuit (45), the fourteenth of the circuit (44) is connected with the second auxiliary input ) of a first time circuit (29) whose output (154) is connected by the first direct input (104) of the third barrier circuit (13), whose output (107) is connected by the fifth output (61) of the circuit, whose fourth output (60) is connected by a cathode (73) of a third diode (3), the anode (72) of which is connected ena 205 049 8 through a ninth input (39) and a third input (85) of a fourth summation circuit (7) whose output (86) is connected to a third output (59) by a wiring whose tenth input (40) is connected β by the first direct input (108) a fourth barrier circuit (14), the second direct input (109) of which is connected to the eleventh circuit (41), the twelfth input (42) of which is connected to the inverse input (110) of the fourth barrier circuit (14), the output of which (111) are connected to an input (153) of a first timing circuit (29), the first auxiliary input (155) of which is connected to a thirteenth circuit input (43), the seventeenth input (47) of which is connected to a second direct input (113) of the fifth barrier circuit ( 15), whose output (115) is coupled to the first input (87) of the fifth total circuit (8) and to the recording input (125) of the memory circuit (19), whose output (127) is coupled to the first input (128) of the first circuit (20) and 8 direct input (11) 9) a seventh barrier circuit (17) and an input (134) of a pulse circuit (22) whose output (135) is connected to a first input (80) of a third sum circuit (6) whose second input (81) is connected with a twenty-third input (53) connected, with a twenty-second input (52) connected, and a second input (129) of the first product circuit (20) whose output (130) is connected to the first input (93) of the seventh total circuit (10) whose output (95) is connected to a first input (90) of the sixth summation circuit (9) and an input (151) of the signaling circuit (28), the output (152) of which is connected to the negative supply pole (164) of which the output (63) is connected to a second terminal (150) of the resistor (27), the first terminal (149) of which is connected to the output (92) of the sixth total circuit (9), the second input (91) of which is connected to the 25th input ), whose nineteenth input (49) is connected to a third terminal (142) of the second button and (24) the fourth terminal (143) of which is coupled to the twenty input (50) of the wiring, the twenty-fourth input (54) of which is coupled to the second input (132) of the second product circuit (21); the output (121) of the seventh barrier circuit (17) and the input (146) of the converter (26), the first output (147) of which is coupled to the eighth output (64) of the circuit; 158) a second timing circuit (30), the second output (159) of which is coupled to the eleventh circuit (67) of the circuit, whose eighteenth input (48) is connected to the 8 direct input (116) of the sixth barrier circuit (16), is connected to the second input (88) of the fifth total circuit (8), the output (89) of which is connected to the sixth output circuit (62), whose twenty-six input (56) is connected to the input (157) of the second time circuit (30) wherein the output (79) of the second summation circuit (5) is coupled to the lubrication input ( 126) a memory circuit (19), the output (82) of the third sum circuit (6) is connected to the inverse input (120) of the seventh barrier circuit (17), and the output (133) of the second product circuit (21) is connected and second input (94) ) of the seventh totalizing circuit (10).