RU2007863C1 - Device for code conversion with possibility of self-test - Google Patents

Abstract

FIELD: computer engineering. SUBSTANCE: device has two information channels. Each of them has four decoders, two comparison units, two AND gates, four registers two flip-flops, four groups of matching units, six matching units, two relay-based counters, two zero-set levels, four groups of electromagnetic relays, four electromagnetic relays, for matrix decoders. Device inhibits output of false signals into adjacent system when special environment conditions effects it. EFFECT: increased stability. 2 cl, 5 dwg

Description

 The invention relates to computer technology and can be used to interface computing devices with relay subscribers.

 Known switch containing the first and second decoders, the first, second and third elements OR, delay element, N keys and N blocks of correction, each of which consists of three elements AND and two elements OR.

 The disadvantage of this device is that with one possible malfunction in any circuit element except the decoder, the device becomes inoperative.

 Closest to the proposed invention is a device for converting codes with self-control, containing decoders, zeroing blocks, the first and second group of correction blocks, each correction block of the first and second groups contains the AND element, the first, second and third OR elements, triggers, matching blocks, key elements, electromagnetic relays and a bus of zero potential, outputs of the first, second and third elements OR are connected respectively with the first inputs of the same triggers, the output of the first trigger is connected through the first matching block with the control input of the first key element and directly with the inverse input of the And element, the output of the second trigger is connected through the second matching block with the control input of the second key element, the output of the third trigger is connected to the direct input of the And element, the output of which is connected to the third matching element with the first terminal of the electromagnetic relay winding, the second terminal of which is connected to the zero potential bus, the first terminals of the first and second key elements are combined, the first outputs are not the first decoder is connected to the first inputs of the first OR elements of the corresponding correction units of the first group, the second outputs of the first decoder are connected to the second inputs of the first triggers and to the first inputs of the third elements of the corresponding correction units of the first group, the third outputs of the first decoder are connected to the second inputs of the third triggers and the first inputs of the second elements OR the corresponding blocks of the correction of the first group, the fourth outputs of the first decoder are connected to the second inputs of the second trigger Of the corresponding correction blocks of the first group, the output of the first zeroing block is connected to the second inputs of the first OR elements of the correction blocks of the first group, the output of the second zeroing block is connected to the second inputs of the second and third elements OR of the correction blocks of the first group, the first outputs of the second decoder are connected to the first inputs of the first OR elements of the corresponding correction units of the second group, the second outputs of the second decoder are connected to the second inputs of the first triggers and to the first inputs of the third elements OR with corresponding correction blocks of the second group, the third outputs of the second decoder are connected to the second inputs of the third triggers and to the first inputs of the second elements OR of the corresponding correction blocks of the second group, the fourth outputs of the second decoder are connected to the second inputs of the second triggers of the corresponding correction blocks of the second group, the output of the third reset block is connected with the second inputs of the first elements OR correction blocks of the second group, the output of the fourth zeroing unit is connected to the second inputs of the second and third x elements of the correction blocks of the second group, the second terminals of the first key elements of the correction blocks of the first group are connected to the first contacts of the electromagnetic relays of the same correction blocks of the second group, the second terminals of the first key elements of the correction blocks of the second group are connected to the first contacts of the electromagnetic relay of the same correction blocks of the first group, the second contacts of the electromagnetic relay of the correction blocks of the first group are combined with the second contacts of the electromagnetic relay of the same blocks the second group of outputs are the corresponding first outputs of the device, the second outputs of the second key elements of the correction units of the first group are combined with the second outputs of the second key elements of the same correction units and are the corresponding second outputs of the device, the information inputs of the first and second decoders are the first and second information inputs of the device , the gate inputs of the first and second decoders are the gate inputs of the device.

 The disadvantage of this device is the insecurity from issuing false commands when exposed to special factors.

 The essence of the invention lies in the fact that in a device containing in each of the information channels the first and second matching blocks, two zeroing blocks, two And elements, the first and second electromagnetic relays, the first and second registers and the first decoder, characterized in that for the purpose to increase the noise immunity of the device from the influence of special factors, buses of positive and negative potentials, third to sixth matching blocks, comparison blocks, third and fourth electromagnets are introduced into each information channel of the device tn relays, relay counters, third and fourth groups of matching blocks, groups of electromagnetic relays, triggers, third and fourth registers, second and fourth decoders and matrix decoders, containing rectifier elements and electromagnetic relays, anodes of rectifier elements at the intersection nodes of horizontal and vertical half-selection buses and the first terminals of the electromagnetic relay windings are connected respectively to the horizontal and vertical half-selection buses, the second terminals of the electromagnetic relay windings are connected to by rectifier elements, the outputs of the second and fourth decoders are connected to the information inputs of the same registers, the outputs of the third and fourth registers are connected to the corresponding inputs of the matching blocks of the same groups, the outputs of the matching blocks of the first and fourth groups are connected to the first outputs of the electromagnetic relay coils of the same groups, the first conclusions of the windings the third and fourth electromagnetic relays are combined with the first terminal of the winding of the first electromagnetic relay, with the second terminals of the windings electromagnetic relay groups and are connected to the bus of positive potential, the output of the first comparison unit is connected to the first input of the first element And, the output of which is connected to the gate inputs of the first and third registers and the first trigger, the output of which through the first matching unit is connected to the second terminal of the winding of the first electromagnetic relay , the output of the second comparison unit is connected to the first input of the second element And, the output of which is connected to the gate inputs of the second and fourth registers and the second trigger, the output One of which through the second matching unit is connected to the second terminal of the winding of the third electromagnetic relay, the output of the first zeroing unit through the third matching unit is connected to the first input of the first relay counter, the output of which is connected to the second terminal of the winding of the second electromagnetic relay, the input of the first zeroing unit is combined with the input of the fourth matching unit, the output of which is connected to the second input of the first relay counter, the output of the second zeroing unit through the fifth matching unit is connected to the first input the second relay counter, the output of which is connected to the second output of the winding of the fourth electromagnetic relay, the input of the second zeroing unit is combined with the input of the sixth matching unit, the output of which is connected to the second input of the second relay counter, the vertical half-buses of the first and third matrix decoders are connected to the first outputs of the first and second make contacts of the corresponding electromagnetic relays of the third group, the second conclusions of which are connected respectively to the opening and to the pins of the first switching contact of the third electromagnetic relay, the horizontal half-buses of the first and third matrix decoders are connected to the first outputs of the first and second closing contacts of the corresponding electromagnetic relays of the first group, the second conclusions of which are connected respectively to the opening and closing terminals of the first switching contact of the first electromagnetic relay, the vertical bus half selection of the second matrix decoder connected to the first conclusions of the third making contacts of the corresponding electromagnetic relays of the fourth group, the second terminals of the first making contacts of which are connected to the disconnecting terminal of the second switching contact of the third electromagnetic relay, the horizontal half buses of the second matrix decoder are connected to the first conclusions of the first making contacts of the corresponding electromagnetic relays of the second group, the second conclusions of the first making contacts which are connected to the disconnecting terminal of the second switching contact of the first electro of an electromagnetic relay, the output of the first switching contact of the third electromagnetic relay through the make contact of the second electromagnetic relay is connected to the opening output of the switching contact of the fourth electromagnetic relay, the making output of which is connected to the output of the second switching contact of the third electromagnetic relay, the output of the first switching contact of the first electromagnetic relay is connected to the making output switching contact of the second electromagnetic relay, the disconnecting output of which through the closing contact of the fourth electromagnetic relay is connected to the output of the second switching contact of the first electromagnetic relay, the conclusions of the switching contacts of the second and fourth electromagnetic relays are connected respectively to the bus of the positive and to the bus of negative potentials, the first conclusions of the closing contacts of the same relay, respectively, of the first and third, second and fourth matrix decoders pairwise combined, the inputs of the third decoder are connected to the second information inputs of the first group information inputs, which is connected to the first inputs of the first and second comparison blocks, the inputs of the second and fourth decoders are connected respectively to the first and second information inputs of the second group of information inputs, which are connected to the second inputs of the first and second comparison blocks, information inputs of the first and second triggers are connected respectively, with the first and second information inputs, the second inputs of the first and second elements AND are connected respectively with the first and second control inputs, the passages of the first and second nulling blocks are connected respectively to the third and fourth control inputs, the make-up terminal of the second switching contact of the third electromagnetic relay is connected to the first outputs of the second make-up contacts of electromagnetic relays of the fourth group, the second conclusions of the second make-up contacts of electromagnetic relays of the fourth group of the first information channel are connected the vertical buses of the half selection of the fourth matrix decoder of the second information channel, sec e conclusions of the second make-up contacts of electromagnetic relays of the fourth group of the second information channel are connected to the corresponding vertical half-selection buses of the fourth matrix decoder of the first information channel, the make-up output of which of the switching contact of the first electromagnetic relay is connected to the first conclusions of second make-contact contacts of the electromagnetic relays of the second group electromagnetic relays of the second group of the first information channel are connected to with the corresponding horizontal half-selection buses of the fourth matrix decoder of the second information channel, the second terminals of the second closing contacts of the electromagnetic relays of the second group of the second information channel are connected to the corresponding horizontal half-selection buses of the fourth matrix decoder of the second information channel, the first and second information inputs of the first and second groups of information inputs of the first and second information channels are respectively the first, second, third and even the fourth information inputs of the device, the first and second information inputs of the first and second information channels are the fifth, sixth, seventh and eighth information inputs of the device, the first and fourth control inputs of the first and second information channels are the first and eighth control inputs of the device, the second conclusions contacts of the same relay, respectively, of the first and third, second and fourth matrix decoders of the first information channel are connected with the outputs of the same name of the closing contacts of the relay of the matrix decoders of the second information channel and are the outputs of the device.

 The relay counter contains three electromagnetic relays and discharge cells, each of which is made on four electromagnetic relays, the first terminals of the windings of which are connected to the negative potential bus, the second terminal of the winding of the first electromagnetic relay is connected to the closing output of the switching contact of the first electromagnetic relay and to the closing output of the first switching the contact of the third electromagnetic relay, the disconnecting terminal of which is connected to the second terminal of the winding of the second electromagnetic relay and by the poking output of the first switching contact of the second electromagnetic relay, the switching contact of which is connected to the output of the switching contact of the first electromagnetic relay, the second terminal of the winding of the third electromagnetic relay is connected to the closing output of the second switching contact of the third electromagnetic relay and to the closing output of the second switching contact of the second electromagnetic relay, the output of which is connected to the second output of the winding of the fourth electromagnetic relay and with by the poking output of the switching contact of the fourth electromagnetic relay, the output of the switching contact of which is connected to the output of the second switching contact of the third electromagnetic relay, the disconnecting outputs of the switching contacts of the first, fourth and disconnecting output of the first switching contact of the second electromagnetic relay are combined with the disconnecting output of the second switching contact of the third electromagnetic relay and connected to the conclusion of the third switching contact of the third electromagnetic relay, p The first terminals of the windings of the first and second electromagnetic relays are connected to the bus of positive potential and to the first terminal of the NC contact of the second electromagnetic relay, the second terminal of which is connected to the terminal of the switching contact of the first electromagnetic relay, with the first terminal of the fourth terminal of the third electromagnetic relay of the first discharge cell and with the terminals of the third the switching contact of the third electromagnetic relay of all discharge cells, the closing output of the switching contact of the first electromagnet relay is connected to the terminal of the first switching contact of the third electromagnetic relay of the first discharge cell, the disconnecting terminal of the switching contact of the first electromagnetic relay is connected to the terminal of the second switching contact of the second electromagnetic relay of the first discharge cell, closing and opening the conclusions of the third switching contact of the third electromagnetic relay of each discharge cell, except the latter are connected respectively to the output of the first switching contact of the third electromagnet oh relay and with the output of the second switching contact of the second electromagnetic relay of each subsequent discharge cell, the second output of the fourth contact of the third electromagnetic relay of each discharge cell, except the last, is connected to the first terminal of the closing contact of the same relay of each subsequent discharge cell, the second terminal of the closing contact of the third electromagnetic relay the last discharge cell is connected to the first terminal of the winding of the third electromagnetic relay, the second terminal which is connected to the bus about -negative potential and to a first terminal of the third switching contact of the electromagnetic relay, the second output of which is the output of the relay meter, the second terminals of the windings of the first and second electromagnetic relays are respectively first and second inputs of the relay counter.

 The significance of the differences in the proposed technical solution lies in improving protection against issuing false commands when exposed to special factors by controlling the power supply to the matrix decoders using relay counters and the inability to simultaneously supply power to more than one matrix.

 In FIG. 1, 2, 3, 4 presents a functional diagram of the device; in FIG. 5 is a functional diagram of a relay counter.

The device for converting codes with self-control contains the first and second information channels 1 and 2, each of which consists of the first 3, second 4, third 5 and fourth 6 decoders, the first 9 and second 10 blocks of comparison, the first 11 and second 12 elements And the first 13, second 14, third 15 and fourth 16 registers, the first 17 and second 18 triggers, the first 19 and second 20 groups of matching blocks, each of which consists of matching blocks 21.1. . . 21. K and 22.1. . . 22. To, respectively, the third 23 and fourth 24 groups of matching blocks, each of which consists of matching blocks 25.1. . . 25. l and 26.1. . . 26. l, respectively, of the first 27, second 28, third 31, fourth 29, fifth 32 and sixth 30 matching blocks, the first 33 and second 34 relay counters, the first 35 and second 36 zeroing blocks, the first 37 and second 38 groups of electromagnetic relays, each of which consists of electromagnetic relays 39.1. . . 39. K and 40.1. . . 40. K, respectively (positions 39.1 ₁ ... 39. K ₁ and 40.1 ₁ ... 40. K _1, the first closing contacts of the relay 39.1... 39. K and 40.1... 40. K, respectively, positions 39.1 ₂ ... 39. To ₂ the second closing contacts of the relay 39.1... 39. To, by positions 40.1 _2.1 ... 40. To _2.1 and 40.1 _2.2 ... 40. To _2.2 the second closing contacts of the relay 40.1... 40 To respectively the first 1 and second 2 information channels), the third 41 and fourth 42 groups of electromagnetic relays, each of which consists of electromagnetic relays 43.1. . . 43. l and 44.1. . . 44. l, respectively (positions 43.1 ₁ ... 43. l ₁ and 44.1... 44. l ₁ indicate the first closing contacts of the relay 43.1... 43. l and 44.1... 44. l, respectively, positions 43.1 ₂ . .. 43. l ₂ the second closing contacts of the relay 43.1... 43. l are marked, 44.1 _2.1 ... 44. l _2.1 and 44.1 _2.2 ... 44. l _2.2 the second closing contacts of the relay 44.1.. 44. 1 l, respectively, the first and second information channels 2), the first 45, second 47, third 46 and the fourth electromagnetic relay 48 (reference numerals 45 ₁ and 45 ₂ denote first and second switching relay contacts 45, reference numerals 47 ₁ and 47 ₂ denote switching aspirants and closing relay contacts 47, reference numerals 46 ₁ and 46 ₂ denote first and second switching relay contacts 46, reference numerals 48 ₁ and 48 ₂ denote switching and closing relay contacts 48), the first 51, second 52, third 53 and fourth 54 matrix decoders containing rectifier elements 55i at the intersection points of the horizontal and vertical half-lines. j (i is the number of the horizontal half-selection bus, j is the number of the vertical half-selection bus) and electromagnetic relays (positions 49.1i. j and 49.2i. j indicate the on and off windings of the corresponding relays belonging to the first 51 and third 53 matrix decoder, positions 50.1i .j and 50.2i.j indicate the on and off windings of the corresponding relays belonging to the second 52 and fourth 54 matrix decoders, i is the number of the horizontal half-selection bus; j is the number of the vertical half-selection bus).

 In addition, in FIG. 1, 2, 3, 4, positions 56 and 57 indicate the first and second group of information inputs of the first information channel 1, which are the first and second inputs of the device, positions 58 and 59 - the first and second groups of information inputs of the second information channel 2, which are the third and fourth information inputs of the device, positions 60, 61, 64, 65 - the first, second, third and fourth control inputs of the first information channel 1, which are the first, second, third and fourth control inputs of the device, positions 62, 63, 66 and 67 - the first, at the second, third and fourth control inputs of the second information channel 2, which are the fifth, sixth, seventh and eighth control inputs of the device, positions 7 and 8 - the first and second information inputs of the first 1 information channel, which are the fifth and six information inputs of the device, positions 68 and 69 - the first and second inputs of the second 2 information channels, which are the seventh and eighth information inputs of the device, positions 70 and 71 are the inputs of the device.

 In FIG. 5 relay counter contains discharge cells 72.1. . . 72. P, each of which consists of the first 73, second 74, third 75, fourth 76 electromagnetic relays (positions 73.1 and 76.1 indicate the switching contacts of the relay 73 and 76, positions 74.1, 74.2 - the first and second switching contacts of the relay 74, positions 75.1 , 75.2, 75.3 and 75.4 - the second, first, third switching contacts and the fourth contact of relay 75) and the first 77, second 78 and third 79 electromagnetic relays (position 77.1 denotes the switching contact of relay 77, positions 78.1, 79.1 - closing contacts of relay 78, 79). The first and second inputs of the relay counter are the second outputs of the relay windings 78 and 77, respectively, and the output of the relay counter is the second output of the make contact 79.1 of the third electromagnetic relay 79.

 The device operates as follows.

 To issue a command to one of the relay subscribers to the first and second groups of information inputs 56, 57 of the first information channel 1 and 58, 59 of the second information channel 2, a command corresponding to this relay subscriber is received simultaneously with a parallel n-bit code, and the first and second information inputs 7, 8 of the first information channel 1 and 68, 69 of the second information channel 2 receives a zero signal.

 The command from the first group of information inputs of the channel goes to the first inputs of comparison blocks 9, 10, r bits of the command go to the input of the third decoder 5, n - r bits of the command go to the input of the first decoder 3. Deciphering, the command goes to the j-th output of the third decoder 5 and the i-th output of the first decoder 3 (j varies from 1 to l, i - varies from 1 to K) and then to the corresponding information inputs of the third register 15 and the first register 13.

The command from the second group of information inputs of the information channel is supplied to the second inputs of the comparison blocks 9 and 10, r bits of the command go to the input of the fourth decoder 6, n - r bits of the command go to the input of the second decoder 4. Deciphering, the command goes to the j-th output of the fourth decoder 6 and the i-th output of the second decoder 4 (j varies from 1 to l, i varies from 1 to K) and then to the corresponding information inputs of the fourth register 16 and second register 14 (values n, m, k, l and r must satisfy simultaneously the following soo relations: m≅k˙l, 2 ⁿ ≥m, 2 ^r ≥l, 2 ^-r ≥K, (where m is the number of relay subscribers).

 If the codes at the first and second inputs of the comparison blocks 9 and 10 are equal, the unit signals from their outputs go respectively to the first inputs of the first 11 and second 12 elements I. When the control signals are fed to the first 60, 62 and second 61, 63 control inputs of the first and second information channels at the outputs of the first 11 and second 12 AND elements, single signals are generated that enter the gate inputs of the first register 13, third register 15, first trigger 17 and second register 14, fourth register 16, second trigger 18, p, respectively which triggers 17 and 18 are set to zero, and information from the outputs of the first 3, third 5, second 4 and fourth 6 decoders is recorded in the first 13, third 15, second 14 and fourth 16 registers, respectively, and then goes through the matching blocks of the first 19, third 23, second 20 and fourth 24 groups of matching blocks on the first 37, third 41, second 38 and fourth 42 groups of electromagnetic relays.

 The signal from the matching blocks 21. i, 25. j, 22. i, 26. j corresponding to the excited outputs of the decoders, respectively, relays 39. i, 43. j, 40. i, 44. j.

The first and second make contacts 39. i ₁ and 39. i _{2 of the} electromagnetic relay 39. i connect the horizontal half-bus of the first matrix decoder 51 and the third matrix decoder 53 to the normally open and make conclusions of the first switching contact 45 _{1 of the} first electromagnetic relay 45. First and the second make contacts 43. j ₁ and 43. j _{2 of the} electromagnetic relay 43. j connect j the vertical half-line of the first matrix decoder 51 and the third matrix decoder 53 to the opening and closing, respectively the findings of the first switching contact 46 _{1 of the} third electromagnetic relay 46.

The first make contacts 40. i ₁ and 44. j _{1 of the} electromagnetic relay 40. i and 44. j connect the i horizontal half-select bus and j the vertical half-select bus of the second matrix decoder 52, respectively, to the disconnect terminals of the second switching contacts 45 ₂ and 46 _{2 of the} first and third electromagnetic relays 45 and 46. Second make contacts 40. i _2.1 and 44. j _2.1 electromagnetic relays 40. i and 44. j of the first information channel 1 connect a horizontal half-line and j vertical half-select bus of the fourth matrix decoder of the second information about channel 2, respectively, to the closing terminals of the second switching contacts 45 ₂ and 46 _{2 of the} first and third electromagnetic relays 45 and 46 of the first information channel 1.

The second make contacts 40. i _2.2 and 44. j _{2.2 of the} electromagnetic relay 40. i and 44. j of the second information channel 2 connect the i horizontal half-selection bus and j the vertical half-selection splint of the fourth matrix decoder of the first information channel 1, respectively, to the closing terminals of the second switching contacts 45 ₂ and 46 _{2 of the} first and third electromagnetic relays 45 and 46 of the second information channel 2.

 Thus, in all four matrix decoders of both information channels, i horizontal half-selection bus and j vertical half-selection bus are selected.

Then, at the third control inputs 64 and 66 of the first and second information channels, S counting pulses are fed to the input of the first zeroing block 35 and through the fourth matching block 29 to the second input of the first relay counter 33. Upon receipt of S pulses, the relay counter gives a signal to the second The electromagnetic relay 47, which is activated, switches the switching contact 47 ₁ and closes the making contact 47 ₂ . Since the contacts 48 ₁ , 45 _1, and 46 ₁ are in the initial state, then the i horizontal half-line bus and j vertical half-line bus of the first matrix decoder 51 will be connected to the buses of positive and negative potentials, respectively, and no voltage will be applied to the remaining matrix decoders. Therefore, the relay, including the winding 49.1 _ij which is connected to the selected i horizontal half-selection bus and through the rectifier element 55i. j to the selected j vertical half-line of the first matrix decoder 51, will switch to the on state and make contact 49i. j of this relay closes.

After the end of the last of the S counting pulses, after a sufficient time interval for the relay to operate in the matrix decoder, the first zeroing block 35 generates a zeroing pulse signal, which, through the third matching block 31, enters the first input of the first relay counter and resets it. The second electromagnetic relay 47 is turned off, the switching contact 47 ₁ and the closing contact 47 _{2 are} returned to their original state and the voltage from the first matrix decoder is removed.

Then, at the fourth control inputs 65 and 67 of the first and second information channels, S counting pulses are fed to the input of the second zeroing unit 36 and through the sixth matching block 28 to the second input of the second relay counter 34. When S pulses are received, the relay counter gives a signal to the fourth the electromagnetic relay 48, which is activated, switches the switching contact 48 ₁ and closes the closing contact 48. Since the contacts 47 ₁ , 45 ₂ and 46 ₂ are in the initial state, then i is the horizontal half-length and j is vertical I, the half-selection bus of the second matrix decoder 52 will be connected respectively to the buses of positive and negative potentials, and the voltage will not be applied to the remaining matrix decoders. Therefore, a relay including windings 50.1 _{ij of} which is connected to the selected i horizontal half-selection bus and through the rectifier element 55i. j to the selected vertical half-line of the second matrix decoder 52 will switch to the on state, making contact 50i. j of this relay closes and thereby a relay signal output circuit is provided for outputs 70, 71 to this relay subscriber.

After the last of the S counting pulses has finished, after a sufficient time interval for the relay to operate in the matrix decoder, the second zeroing unit 36 generates a zeroing pulse signal, which, through the fifth matching unit 32, is supplied to the first input of the second relay counter and resets it. The fourth electromagnetic relay 48 is turned off, the switching contact 48 ₁ and the closing contact 48 _{2 are} returned to their original state and the voltage from the second matrix decoder is removed.

The operation of the device when removing a command from the relay subscriber is similar to the operation when issuing a command with the difference that the first and second information inputs 7, 8 of the first information channel 1 and 68, 69 of the second information channel 2 receive a single signal. Therefore, when a control signal is supplied to the first and second control inputs 60, 61 of the first information channel 1 and 62, 63 of the second information channel 2, the first 17 and second 18 triggers are set to a single state, the signals from the outputs of the triggers 17, 18 through the first 27 and second 28 matching blocks are supplied respectively to the windings of the first and third electromagnetic relays 45 and 46, which are activated, as a result of which their first and second switching contacts 45 ₁ , 45 ₂ and 46 ₁ , 46 _{2 are} switched.

Therefore, when the second electromagnetic relay 47 is activated, the voltage will be supplied to the third matrix decoder 53, which will turn off the relay, the disconnecting winding 49.2 _{ij of} which is connected to the selected i horizontal half-selection bus and through the rectifier element 55 _ij to the selected j vertical half-selection bus of the third matrix decoder 53 , opening the normally open contact of the relay 49 _ij, thereby breaking signal of the relay circuit issuing information in both channels 1 and 2, the outputs 70, 71 and the removal command to the corresponding D eynogo subscriber.

When the fourth electromagnetic relay 48 of the first information channel 1 is triggered, the voltage will be supplied to the fourth matrix decoder 54 of the second information channel 2, and when the fourth electromagnetic relay 48 of the second information channel 2 is triggered, voltage will be supplied to the fourth matrix decoder 54 of the first information channel 1. This will turn off the first and second information relay channels tripping winding 50.2 _ij are connected to the selected i poluvybora horizontal bus and through a 55 pryamitelny element _ij j to the selected vertical bus poluvybora fourth matrix decoders 54 of the first and second information channels, and opening of the contacts of these relays 50 _ij, thereby further tearing command issuing circuit for the corresponding subscriber on the relay outputs 70, 71.

 If, due to a malfunction or failure, only one relay 45 or 46 will operate, then when the second and fourth electromagnetic relays 47, 48 are activated, the positive potential will be applied to the i horizontal half-selection bus of one matrix decoder, and the negative potential to j will be the vertical half-selection bus of the other, then there is no relay matrix decoders will not change its state and the state of the output relay signals will not change.

 The same situation will occur if a malfunction or failure leads to the simultaneous operation of the second and fourth electromagnetic relays 47 and 48.

 Thus, the circuit for issuing a command to each relay subscriber consists of two parallel working channels, in each of which it is formed by the serial connection of the closing contacts of two relays. The on and off control of each of these relays in each channel is controlled by a separate path, and one of the relays forming the command circuit is turned off by its own channel and the other by the neighboring one. This ensures the issuance or removal of a command in the event of a failure or failure of one of the channels and protects against the issuance of a false command or incorrect removal of a command in the event of a failure or any one possible malfunction in the device.

 Protection from the effects of special factors is based on the fact that the matrix decoders are de-energized, and the voltage can be applied for a short time to only one matrix decoder, and power is supplied to the matrix decoder when the relay counter is triggered, for which a specific input must be applied the number of pulses S. During exposure to special factors, it is possible to supply false pulses to the input of the relay counter. The value of S is chosen so that it exceeds the number of possible false pulses at the input of the relay counter, thereby eliminating the operation of the relay counter if it was in the reset state before the special action, or only one of the relay counters can be triggered, if before the moment of special effects on its input one or more pulses were applied. Therefore, either the operation of both relays forming a serial chain of command issuance is excluded, or the operation of only one of them is possible, and thereby the issuance of a false command to the relay subscriber is excluded.

 The relay counter operates as follows.

 In the initial state, the windings of the first 77, second 78, third 79 electromagnetic relays of the relay counter and the windings of the first 73, second 74, third 75 electromagnetic relays of the discharge cells of the relay counter are de-energized. A voltage is applied to the winding of the fourth relay 75 of each discharge cell through the opening contact of the second switching contact 74.2 of the second discharge cell relay 74, the opening contact of the switching contact 77.1 of the first counter relay 77 (for the first discharge cell or the opening contact of the third switching contact 75.3 of the third relay of the previous cell given (for all discharge cells except the first) and NC 78.1 of the second relay 78 of the counter.

When a voltage pulse is applied to the second input of the relay counter, the first relay 77 is activated, its switching contact 77 ₁ switches (the relay 76 does not turn off, since voltage is supplied to its winding through the make contact of its switching contact 76.1 and the make contact of the second switching contact 75.1 of the third relay 75 discharge cell) and voltage is supplied to the winding of the second relay 74 of the first discharge cell through the make contact of the switching contact 77.1 of the first counter relay 77 and the make contact of the first first contact 75.2 a third relay 75 razryadovoy cell. Relay 74 is activated, its first and second switching contacts 74.1 and 74.2 are switched.

 At the end of the voltage pulse at the second input of the relay counter, the first counter relay 77 is turned off, its switching contact 77.1 is released (relay 74 is not turned off, since voltage is supplied to its winding through the make contact of its switching contact 74.1 and the make contact of switching contact 73.1 of the first relay 73 cell) and voltage is supplied to the winding of the third discharge cell relay 75 through the make contact of the second switching contact 74.2 of the second discharge cell relay 74 and the make contact 77.1 guide contact the first relay 77 counter. Relay 75 is activated, its first, second, third switching contacts 75.1, 75.2, 75.3 and fourth contact 75.4 are switched, the fourth relay cell relay 76 is turned off, its switching contact 76.1 is released.

 When a second voltage pulse is applied to the second input of the relay counter, the first relay 77 is activated, its switching contact 77.1 switches (relay 75 does not turn off, since voltage is applied to its winding through the making contact of its second switching contact 75.1 and the opening contact of switching contact 76.1 of the fourth relay 76 bit cell) and voltage is supplied to the coil of the first relay 73 of the bit cell through the make contact of the switching contact 77.1 of the first relay 77 of the counter and the make contact of the first switch contact 75.2 of the third relay 75 of the discharge cell. Relay 73 is activated, its switching contact 73.1 switches, as a result of which the second relay cell relay 74 is disconnected and its first and second switching contacts are released.

 At the end of the voltage pulse at the second input of the relay counter, the first counter relay 77 is turned off, its switching contact 77.1 is released (relay 73 is not turned off, since voltage is applied to its winding through the make contact of its switching contact 73.1 and the make contact of the first switching contact 74.1 of the second discharge relay cell 74) and voltage is supplied to the winding of the fourth discharge cell relay 76 through the opening contact of the second switching contact 74.2 of the second discharge cell relay 74 and the opening contact 77.1 kt switching contact of the first relay 77 counter. Relay 76 is activated, its switching contact 76.1 switches, as a result of which the third discharge cell relay 75 is switched off and its first, second, third switching contacts 75.1, 75.2 and 75.3 and the fourth contact 75.4 are released.

 When the next two voltage pulses are applied to the second input of the counter, the operation cycle of the first discharge cell is repeated, that is, the discharge cell is a modulo 2 counter. Since the subsequent after the first discharge cells are controlled by the third switching contact 75.3 of the third relay 75 of the previous discharge cell, the sequence bit cells forms a binary counter arriving at the second input of the pulse counter.

 The circuit formed by the serial connection of the fourth contacts 75.4 of the third relay 75 of all bit cells closes at the end of the last of the S pulses at the second input of the relay counter (pin 75.4 in this bit cell must be short-circuit if in the binary representation of the number S in the bit corresponding to this bit cell , costs 1 or opening, if in the binary representation of the number S in the discharge corresponding to the given bit cell, it is 0). In this case, the voltage is supplied to the winding of the third counter relay 79 through the opening contact 78.1 of the second counter relay 78 and the fourth contacts 75.4 of the third relay 75 of the discharge cells connected in series. Relay 79 is activated, its make contact closes, and a negative potential is applied to the output of the relay counter.

 In order to reset the counter to zero, a voltage pulse is applied to its first input, the second counter relay 78 is activated, its normally open contact 78.1 opens, all the relay cell relays and the third counter relay 79 are turned off. At the end of the pulse at the first input of the counter, the second counter relay 78 is turned off, its normally open contact 78.1 closes, and voltage is supplied to the winding of the fourth relay 76 of each discharge cell through the normally open contact of the second switching contact 74.2 of the second relay 74 of the discharge cell, and the opening contact of the switching contact 77.1 of the first relay 77 counters (for the first discharge cell) or NC contact of the third switching contact 75.3 of the third relay of the discharge cell preceding this (for all discharge cells to first OMe), 78.1 and break contact of the second relay 78 counter. Thus, the counter returns to its original state and is ready for operation.

The number of discharge cells P and the value of S are related by the following relation -S ≅2 ^P.

 Using the proposed solution allows to exclude the issuance of false commands during special actions on the relay subscribers with whom the device is connected. (56) Copyright certificate of the USSR N 1254585, cl. H 03 M 5/00, 1985.

 USSR author's certificate N 1591190, cl. H 03 M 7/00 // H 03 M 13/00, 1988.

Claims (2)

 1. DEVICE FOR TRANSFORMING CODES WITH SELF-CONTROL, containing in each of the information channels the first and second groups of matching blocks, the first and second matching blocks, two zeroing blocks, two And elements, the first and second electromagnetic relays, the first windings of which are combined, the first and second registers, the outputs of which are connected to the inputs of the respective matching blocks of the first and second groups and the first decoder, the outputs of which are connected to the corresponding information inputs of the first register, the inputs of the first encoders are connected to the first information inputs of the first group of information inputs, characterized in that, in order to increase the noise immunity of the device from exposure to special factors, buses of positive and negative potentials are introduced into each information channel of the device, the third and sixth matching blocks, comparison blocks, the third and fourth electromagnetic relays, relay counters, third and fourth groups of matching blocks, groups of electromagnetic relays, triggers, third and fourth registers, second to fourth encoders and matrix decoders containing rectifier elements and electromagnetic relays at the intersection of horizontal and vertical half-selection buses, rectifier element anodes and first conclusions of electromagnetic relay windings are connected respectively to horizontal and vertical half-selection buses, the second conclusions of electromagnetic relay windings are connected to the cathodes of rectifying elements, outputs second - fourth decoders are connected to the information inputs of the same registers, the outputs of the third and fourth p the registers are connected to the corresponding inputs of the matching blocks of the same groups, the outputs of the matching blocks of the first to fourth groups are connected to the first terminals of the windings of the electromagnetic relays of the same groups, the first terminals of the windings of the third and fourth electromagnetic relays are combined with the first terminal of the windings of the first electromagnetic relay, with the second terminals of the electromagnetic relay windings groups and are connected to the bus of positive potential, the output of the first comparison unit is connected to the first input of the first element And, the output of which connected to the gate inputs of the first and third registers and the first trigger, the output of which through the first matching unit is connected to the second terminal of the winding of the first electromagnetic relay, the output of the second comparison unit is connected to the first input of the second element And, the output of which is connected to the gate inputs of the second and fourth registers and a second trigger, the output of which through the second matching unit is connected to the second output of the winding of the third electromagnetic relay, the output of the first zeroing unit through the third matching the unit is connected to the first input of the first relay counter, the output of which is connected to the second output of the winding of the second electromagnetic relay, the input of the first zeroing unit is combined with the input of the fourth matching unit, the output of which is connected to the second input of the first relay counter, the output of the second resetting unit is connected through the fifth matching unit with the first input of the second relay counter, the output of which is connected to the second output of the winding of the fourth electromagnetic relay, the input of the second zeroing unit is combined with the input matching unit, the output of which is connected to the second input of the second relay counter, the vertical half-selection buses of the first and third matrix decoders are connected to the first outputs of the first and second closing contacts of the corresponding electromagnetic relays of the third group, the second conclusions of which are connected respectively to the opening and closing outputs of the first switching contact the third electromagnetic relay, the horizontal half-bus of the first and third matrix decoders are connected to by the first conclusions of the first and second making contacts of the corresponding electromagnetic relays of the first group, the second conclusions of which are connected respectively to the opening and making conclusions of the first switching contact of the first electromagnetic relay, the vertical half-selection buses of the second matrix decoder are connected to the first conclusions of the first making contacts of the corresponding electromagnetic relays of the fourth group, the second terminals of the first make contacts of which are connected to the disconnect terminal of the second about the switching contact of the third electromagnetic relay, the horizontal half-bus of the second matrix decoder is connected to the first outputs of the first make contacts of the corresponding electromagnetic relays of the second group, the second conclusions of the first make contacts of which are connected to the disconnecting output of the second switching contact of the first electromagnetic relay, the output of the first switching contact of the third electromagnetic relay through the make contact of the second electromagnetic relay is connected to the disconnect pin the house of the switching contact of the fourth electromagnetic relay, the closing output of which is connected to the output of the second switching contact of the third electromagnetic relay, the output of the first switching contact of the first electromagnetic relay is connected to the closing output of the switching contact of the second electromagnetic relay, whose opening through the making contact of the fourth electromagnetic relay is connected to the output of the second the switching contact of the first electromagnetic relay, the findings of the switching contacts in of the second and fourth electromagnetic relays are connected respectively to the bus of the positive and to the bus of negative potentials, the first outputs of the make contacts of the relays of the same name, respectively, of the first and third, second and fourth matrix decoders are paired, the inputs of the third decoder are connected to the second information inputs of the first group of information inputs, which are connected with the first inputs of the first and second comparison units, the inputs of the second and fourth decoders are connected respectively to the first and the second information inputs of the second group of information inputs that are connected to the second inputs of the first and second comparison blocks, the information inputs of the first and second triggers are connected respectively to the first and second information inputs, the second inputs of the first and second elements And are connected respectively to the first and second control inputs, the inputs of the first and second zeroing units are connected respectively to the third and fourth control inputs, the closing output of the second switching contact of the third elec a magnetic relay is connected to the first terminals of the second making contacts of the electromagnetic relays of the fourth group, the second conclusions of the second making contacts of the electromagnetic relays of the fourth group of the first information channel are connected to the corresponding vertical bus half selection of the fourth matrix decoder of the second information channel, the second conclusions of the second making contacts of the electromagnetic relay of the fourth group of the second information channel connected to the corresponding vertical bus half selection h of the fourth matrix decoder of the first information channel, the closing terminal of the second switching contact of the first electromagnetic relay is connected to the first terminals of the second closing contacts of the electromagnetic relays of the second group, the second terminals of the second closing contacts of the electromagnetic relay of the second group of the first information channel are connected to the corresponding horizontal half-buses of the fourth matrix decoder of the second information channel, the second conclusions of the second closing contacts of the electromagnet total relays of the second group of the second information channel are connected to the corresponding horizontal half-selection buses of the fourth matrix decoder of the first information channel, the first and second information inputs of the first and second groups of information inputs of the first and second information channels are the first, second, third and fourth information inputs of the device, the first and the second information inputs of the first and second information channels are respectively fifth, sixth, seventh and re information inputs of the device, the first and fourth control inputs of the first and second information channels are respectively the first and eighth control inputs of the device, the second conclusions of the closing contacts of the same relay, respectively, of the first and third, second and fourth matrix decoders of the first information channel are combined with the same conclusions of the closing contacts of the relay matrix decoders of the second information channel are the outputs of the device.  2. The device according to p. 1, characterized in that the relay counter contains three electromagnetic relays and discharge cells, each of which is made on four electromagnetic relays, the first terminals of the windings of which are connected to the negative potential bus, the second terminal of the winding of the first electromagnetic relay is connected to the closing the output of the switching contact of the first electromagnetic relay and with the closing output of the first switching contact of the third electromagnetic relay, the disconnecting output of which is connected to the second output of the winding ki of the second electromagnetic relay and with the closing output of the first switching contact of the second electromagnetic relay, the output of the switching contact of which is connected to the output of the switching contact of the first electromagnetic relay, the second terminal of the winding of the third electromagnetic relay is connected to the closing output of the second switching contact of the third electromagnetic relay and with the closing output of the second switching the contact of the second electromagnetic relay, the disconnecting terminal of which is connected to the second terminal of the winding h of a solid electromagnetic relay and with a closing terminal of a switching contact of a fourth electromagnetic relay, a terminal of a switching contact of which is connected to a terminal of a second switching contact of a third electromagnetic relay, the disconnecting terminals of a switching contacts of a first, fourth and a disconnecting terminal of a first switching contact of a second electromagnetic relay are combined with a disconnecting terminal of a second switching contact the third electromagnetic relay and are connected to the output of the third switching contact the act of the third electromagnetic relay, the first terminals of the windings of the first and second electromagnetic relays are connected to the positive potential bus and to the first terminal of the NC contact of the second electromagnetic relay, the second terminal of which is connected to the terminal of the switching contact of the first electromagnetic relay, with the first terminal of the fourth contact of the third electromagnetic relay of the first discharge cells and with the conclusions of the third switching contact of the third electromagnetic relay of all the discharge cells, closing the output switch contact of the first electromagnetic relay is connected to the output of the first switching contact of the third electromagnetic relay of the first discharge cell, the disconnecting terminal of the switching contact of the first electromagnetic relay is connected to the output of the second switching contact of the second electromagnetic relay of the first discharge cell, closing and disconnecting the conclusions of the third switching contact of the third electromagnetic relay of each discharge cells, except the last, are connected respectively to the output of the first switch contact of the third electromagnetic relay and with the conclusion of the second switching contact of the second electromagnetic relay of each subsequent discharge cell, the second output of the fourth contact of the third electromagnetic relay of each discharge cell, except the last, is connected to the first terminal of the closing contact of the same relay of each subsequent discharge cell, the second terminal of the closing contact the third electromagnetic relay of the last discharge cell is connected to the first terminal of the winding of the third electromagnetic relay, Torah output of which is connected to the bus and a negative potential to the first terminal of the third switching contact of the electromagnetic relay, the second output of which is the output of the relay meter, the second terminals of the windings of the first and second electromagnetic relays are respectively first and second inputs of the relay counter.

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