CH128576A - Installation of electrical control of sets of devices in a substation from a remote control station. - Google Patents

Description

  

  Installation of electrical control of sets of devices in a substation from a remote control station. The present invention relates to an installation for the electrical control of sets of apparatus in a substation from a remote control station, in which a plurality of sets of apparatus of the substation are controlled. by means of corresponding operating keys provided at the control station and in which the operation of a set of devices at the substation causes a corresponding signaling at the control station, for example in dependence on the operation of keys at the control station or automatically, depending on the load or other predetermined conditions,

   by means of an apparatus for transmitting signals with a conventional code and with an apparatus for receiving signals with a conventional code both at the control station and at the substation.



  According to the invention, a safety relay is provided at the control station and is connected in such a way to the circuit of the installation that it is actuated by the first pulse from the device transmitting signals with conventional code to the sub -station for the apparatus receiving conventional code signals at the control station -depend on the operation of a set of devices at the substation due to the operation of a key at the control station , said safety relay being established so that its operation stops the operation of the conventional code signal transmitting apparatus at the control station,

    unless the key is released and the operation is restarted by a new operation of the key, which makes it possible to prevent repeated operation of a set of devices if the control conditions automatic devices at the substation oppose the operation of the set of devices initiated by the operation of the key at the control station.



  An embodiment of the object of the invention is shown, by way of example, in the accompanying schematic drawing, in which FIGS. 1, 2, 7 and 8 show the connection diagrams of the circuits at the control station and figs. 3, 4, 5 and 6 connection diagrams (circuits at the substation.



  Fig. 1 shows in particular a diagram of the monitoring panel with individual relay equipment for each operating key; Fig. 2 is a diagram of the connection of an apparatus to the control station for the transmission of control signals to the substation with a view to producing the desired function therein, this apparatus being able to be called a "code transmitter apparatus. control "and comprising an expensive switch and conventional code transmission devices;

    Figs. 3 and 4 are diagrams (the connection of an apparatus to the substation which cooperates with the aforementioned command transmitting apparatus at the command post and receives the control signals therefrom, this apparatus being able to be called "receiving apparatus. control code "; Fig. 5 is a schematic of control switches and individual monitoring equipment for them at the substation;

    Fig. 6 is a connection diagram of an apparatus at the substation for the transmission of monitoring signals to the control station depending on the operation of the parts at the substation, this apparatus being able to be designated "transmitting apparatus. conventional code monitoring signal generator "; Fig. 7 is a connection diagram of an apparatus at the control station cooperating with the aforementioned conventional surveillance signal transmitting apparatus to the substation to receive the monitoring signals sent by the latter, this apparatus which may be called a "conventional code monitoring signal receiving apparatus".



  Before going into details, it is convenient to briefly describe the operation of the installation shown. To cause the operation of the installation shown, the supervisor at the control station activates an operating key to determine the rotational movement of a seeker switch. The stop position of this seeker switch is determined by the particular action key.

   When the seeker switch has turned off, a conventional code signal transmitting device is turned on and a conventional 25 pulse signal with three rest periods is thus transmitted to the remote substation, the relative position of the three periods of rest. rest among the 25 pulses being the differentiating factor between the different signals of the conventional code adopted. These rest periods are determined by the stop position of the seeker switch.



  At the substation, the first rest period determines the selection of a relay from a group of relays each of which controls groups of sets of devices. The second rest period determines the selection of a relay from a group of relays each of which controls a circuit in each of the aforementioned groups of sets. A third period of rest or pause occurs when the code transmitting device is in the 25th position, that is to say before the 25th pulse which returns it to the starting position.

   If this pause occurs before the 25th pulse, simultaneously at the two stations (control station and substation), the circuit prepared as indicated above is completed up to the equipment which is to be activated. This pause before the 25th pulse therefore determines a safety or guarantee against false operations, since the pause will fail to occur before the 25th pulse simultaneously at both stations, if either of the latter has fallen out. rate during the code transmission opera tion.



  The monitoring equipment acts in the same way as described above to transmit monitoring signals. When the supervisor wishes to order certain control equipment at the substation, he actuates one of the keys of my work corresponding to the particular equipment and to the desired operation. These keys are associated with each key - pairs of relays, one for triggering and the other for closing switches or for starting and stopping the rotational movement of devices, depending on the particular case.

   If one of these relays is energized, it prepares a circuit passing through one of its armatures to one of the contacts on the first contact ramp and it closes through another of its armatures a circuit for a stopping electromagnet.



       The stopping electromagnet is arranged so as to be excited and, intermittently de-energized, by making step by step a group of ramps of contacts until the contact lever reaches the particular contact of the aforementioned particular contact ramp. At this point, one of the searcher relays finds a prepared excitation circuit passing through the armature and breaks the circuit of the advancement electromagnet so that these contact levers are now kept fixed at this place.



  Circuits are prepared simultaneously for the code transmission relay and the advancing electromagnet of the second set of contact levers and therefore the code transmission contact levers are now gradually rotated d 'in a similar way to the first group. The contacts of one of the contact ramps of the code transmitting device are connected with contacts on the contact rams of the searcher switches so that, when the code transmission contact lever reaches the particular contact connected with the latter at which the researcher has stopped, a circuit is prepared to temporarily stop the operation of the code transmission device and to produce a period of rest or pause.

    



  The line relay, which controls the opening and closing of a line between the monitoring station and the substation, is energized, simultaneously with the intermittent energization of the advancement electromagnet. code transmission device, in a parallel circuit with the relay controlling the advancement electromagnet of the switches of the code transmitting device. When the first rest period or long break is reached, this line relay remains energized to keep the circuit closed during this period.



  After this rest period, the switches of the code transmitting device continue to advance until a contact for a second rest period or pause is reached. The periods when the pauses occur depend, as indicated above, on the position at which the searcher switches stopped. After the second rest period has arisen, the contact levers continue to advance until they reach the 25th contact where the third rest or pause period occurs.



  At the receiving control unit, a relay in the line circuit is energized intermittently by the closing of the above-mentioned circuit; it in turn controls an advancing electromagnet which gradually advances a similar series of contact levers. During the first rest period, a delayed tripping relay which had remained energized during the normal opening and closing of the 4th line relay is now de-energized due to the rest or pause period and closes a circuit. going to a group of relays each of which controls a group of circuits, the particular relay energized depending on the position of the contact levers when the first long period of rest or pause is reached.



  Between the first and the second rest or pause period, the advancing electromagnet is again energized intermittently to advance the contact levers and at the second rest period, the delayed release relay is energized again. again de-energized and now closes the circuit of a relay of a group of relays, each of which controls a particular circuit among the circuits of the aforementioned groups, the particular relay energized depending on the position of the contact lever, when the second period of rest presents itself. Although these two operations perform the selection of the device to be operated, no action takes place during this time.



       The advancing electromagnet will now continue to advance the contact levers until they reach the 25th contact, and before the 25th pulse there is a third rest period. At this point, the particular circuit of the particular group previously chosen is completed in order to actuate the selected control equipment; this circuit however depends on whether the rest period occurs at the 25th contact. Otherwise no operating circuit is completed.



  Pairs of relays are associated with each control equipment, one of each pair corresponding to an open circuit and the second to a closed circuit or for starting and stopping the devices. Changes in the control equipment affect these relays in a manner similar to the scheme described above for the activation of the code transmitting apparatus at the control station.

   Pulses are now transmitted using the surveillance code transmitting apparatus to the receiving surveillance apparatus, where a particular circuit of a particular group of circuits is closed in a manner similar to that above. - described at the substation and a monitoring indicator device is actuated to indicate the change in condition of the controlled switch. In this way, the supervisor is informed of the successful operation at the substation.



  There is therefore a circuit arrangement to the watchdog code transmitting apparatus by which watchdog signals are repeatedly transmitted until they are properly received by the watchdog code receiving apparatus. There is also a special provision to prevent repeated closing of a switch if the conditions are such that it does not remain closed, whereby as soon as the first pulse of the monitoring code transmitter device is received at the control station, the conventional code transmitting device placed at the main station is rendered inoperative to repeat the transmitted code.

   In particular, when the relay 704 is energized, the relay 212 is energized and its lower armature releases the code transmitting apparatus and lets it return to the normal state.



  There is further a circuit arrangement at the control station, whereby the master control key must be held closed until completion of the operation or point of operation at all occurs at the control station. substation. In this way, code tampering or accidental operation is prevented.



  Circuit arrangements are furthermore provided, whereby, as soon as the correct supervisory signal has been received at the main station, the supervisory code transmitting apparatus is returned to the normal position and stops the repetition of the trans code. put. The circuit for this purpose is completed by the supervisory code transmitting apparatus, the monitoring code receiving apparatus and the supervisory code transmitting apparatus, all of which must first have functioned correctly.



  It goes without saying that only one battery is used at each station. The lines connecting the main station with the substation are arranged in such a way that in the event of an accidental crossing of one line with another, no wrong operation will occur. This is ensured by the connection of cir special cooking - from the battery to each station.



  In order to facilitate understanding of the installation shown, a brief description will now be given of the operation of each mechanism in relation to the operation of the other parts of the installation.



  Pairs of relays are associated with each operating key on the supervisor panel, such as relays 5 and 9, one for the tripping operation, the other for the closing of the switch-breakers. Each of these relays has three frames; one for an automatic locking circuit, for example 5c of relay 5, one for closing a circuit for an advancing electromagnet 208 which controls a series of contact levers <I> A </I> <B>. .. </B> <I> D, </I> for example 5b of relay 5, and a third armature, such as 5a of relay 5, which is connected with a terminal of one of the contact levers at a point and with one relay 210 or 211 to the other in the case of the trip relay as well as the close relay.



  The seeker switch comprises a relay 211 or 210 which is connected with the aforementioned third armature and is energized when the seeker switch contact lever reaches the corresponding contact. By a contact, one or the other of these relays transfers the circuit of the advancement electromagnet of the searcher switch to the start relay 214 of the conventional code transmitting apparatus. In this way, the seeker switch is rotated until it arrives opposite the desired contact on its contact ramp where it is stopped, this position being that given to the particular key operated by the supervisor. .



  The relationship between the relay 209 and the advancing electromagnet 208 is such that the circuit of the advancing electromagnet 208 is open when this relay is energized, and the electromagnet of advancement. advancement opens after its de-energization the circuit of the relay 209, which, when it is de-energized, again closes the circuit of the advancing electromagnet, and so on. The advancing electromagnet is in this manner energized and de-energized intermittently to advance the contact levers.

      By its lower frame, the relay 212 controls the connection of the battery with the advancing electromagnet and is energized after the reception of the first pulse from the device transmitting the surveillance code to the substation to cut off. the connection of the battery with the advancement electromagnet and consequently to prevent any subsequent operation of the seeker switch.



  To the code transmitting apparatus, the relay 214 is put to the battery as explained above, when the relay 211 is energized, by the fact that the levers of the expensive switch have reached the mentioned particular position. Relays 214, 215 and 216 prepare the code transmitting apparatus for operation.



  Relay 216 causes relay 220 to de-energize, which interrupts the direct connection of the battery to the feed solenoid 218 in a pulse circuit and connects the battery to the feed solenoid to cause its actuation in term, as in the case of the first mentioned advancement electromagnet. In this case, the relay 217 cooperates with the advancement electromagnet in the same way as the relay 209 with the relay 208.

   Relay <B> 217 </B> and relay 219 are connected in parallel and, like relay, 217 is energized and de-energized intermittently, relay 2; 19 is similarly energized and de-energized intermittently, and since this re lais 219 controls the opening and closing of the line, current pulses are transmitted by the line. The relays 221, 222 and 223 control the rest periods or breaks, which will be described below.



  As-already mentioned, each. contact of the contact ramp A is associated with a different key, so as to determine the stopping point. The contact ramp is subdivided into contact groups, each group being connected with a different contact from the contact ramp F. The contact ramps <I> C and D </I> represent units of each of the aforementioned groups and each contact of a group is connected with a different contact on the ramp of contacts F, such milar contacts of different groups being united together.



  As the contact levers of contact ramps <I> E to H </I> move in a rotational motion, they reach the contact connected with the particular group on contact ramp B, where the levers contact on the contact ramps A to D stopped. The first rest period occurs at this point after which the contact levers continue their rotational movement until they reach the contact on the contact ramp F, which is connected with the particular contact on the contact. contact ramp C, and there the levers are stopped and the second rest period occurs. A third rest period always occurs at the 25th contact before the last pulse.



  At the receiving apparatus of the control station, a line relay 300 is energized by the aforementioned pulses. It controls the circuit of the advancing electromagnet 301 at its armature 300a. At its armature 300b, it causes the excitation of the relay 302. The relay 302 opens the pulse circuit of the electromagnet at its armature 302a. advance and closes the circuit for the delayed tripping relay 303 to its frame 302a.



  Relay 401 and its associated relays control circuit groups. Relay 406 and its associated relays control particular circuits of each of these groups. At the first rest period or break mentioned above, the relay 401 or one of its associated relays will be exited. At the second period of rest or pause there will be the energization of relay 406 or one of its associated relays, and these two together will determine the operating circuit. particular.



       Obviously, it is necessary to prevent the action of relay 406 or its associated relays until a period of rest or pause occurs. This is accomplished by energizing relay 308, which, in turn, controls relays 306 and 307. As the circuits for relays 401 or 406 or their associated relays are closed by relay armatures 306 or 307 currently held open, these circuits cannot be completed until a period of rest causes relay 306 or relay 307 to de-energize.



  It is also desirable, after the selection has been made, to prevent the operation of the particular mechanism selected until it is certain that it has been selected correctly. This correct selection is determined if the contact ramp levers <I> E </I> <B> ... </B> <I> H </I> and <I> I </I> <B > ... </B> <I> L, </I> so many times reach the 25th contact. The relay 303 maintains by its armature 303a the control circuit of the selected or green mechanism until the 25th pulse and, if the combination of increments is correct, the third rest period causes the de-energization of the relay 303 and the de-energization circuit. order is closed.



  The relay, 304 operates to lock by its armature 304a the relay in the group associated with the relay 401 and the relay in the group associated with the relay 406, in their energized position.



  Relay 403 operates to prevent any other relay in the same group from operating after relay 401 has been actuated to select the particular group, as long as all of its contacts are or green when energized. Relay 305 operates to prevent any other relays in the group from functioning after relay 406 or one of its associated relays has operated.



  The mechanism of the surveillance code transmitting apparatus, consisting of a seeker switch and code transmission devices and of the surveillance code receiving apparatus is identical to that which has just been described and it is therefore inu tile to repeat the description. The relay 704 of the surveillance code receiving apparatus performs, in addition to the function of latching one of the group relays 806, or its associated relays, that of quoting the relay 212 which, as has already been explained, cuts the connection between the battery and the searcher switch advancement electromagnet and prevents any subsequent operation of the code transmitting device to transmit the previously established code.



  The detailed description which follows will provide a better understanding of the operation which occurs when the supervisor brings an operating key into the closed position to operate a desired mechanism. The circuit breakers at the substation are in the closed position, as shown in the drawing.



  It will be assumed that the supervisor wishes to trip circuit breaker No 1 C Bl at the substation. The closing condition of circuit breaker No 1 is indicated to the supervisor by the red lamp B on the monitoring panel, the battery failing circuit by the rest contact of the armature la and the red lamp B of circuit breaker No 1 to earth.



  The supervisor now closes the main control key Ii and moves the key K 'corresponding to circuit breaker No. 1 to the right or to the trip position. As a result, a circuit will be completed for relay 2 passing from the battery through the coil of relay 2, the rest contact and armature 3b and through the closed contact of the main control key to earth.



  As a result of the excitation of relay 2, a circuit will be completed, which passes from the battery through coils 2 and 3 in series, the contact pin and armature 2b, the rest contacts and armature 4a To the earth. This circuit will not be in active state for the moment due to the short circuit in 3b.



  Another circuit is completed, passing from the battery through the armature 1a and its rest contact, relay 5, the closed right contact of key K 'of circuit breaker No 1, the rest contact and armature 3a, the contact pin and the frame 2a to earth.



  Relay 5 is energized and closes the con tacts of its armatures 5a, 5b and 50. A locking circuit for relay 5 is now completed, passing from the battery through the armature 1a and its contact pin, the coil 5, frame 5o and its contact pin, line 6 to frame 3a and frame 2a to earth. Following the closing of the contact of the armature 5b, the line 6 is connected by the line 7. Following the closing of the contact of the armature 5a a circuit is prepared, which passes from a contact of the ramp of contacts A (fig. 2) to relay 210.

   As already mentioned, the armature 5b connects the positive pole of the line 6 to the line 7 thus closing the circuit for the advancing electromagnet 208 grazing from the battery by the mature arm 21'2a and its rest contact, armature 212b and its rest contact, armature 210b and its rest contact, armature 209a and its rest contact, feed electromagnet 208, line 7, the frame 5b and its contact pin, the line 6, the frame 3a and the frame 2a to the earth.



  The excitation of the advance electromagnet 208 acts on the pawl to put it in a position to advance the levers of the contact rams <I> A </I> <B> ... </ B > <I> D. </I> As a result, by energizing relay 208, a circuit is completed, passing from the battery through the armature 212a and its rest contact, the armature 211k and its contact normally closed, armature 210b and its normally closed contact, closed contact of armature 208a, coil of delayed tripping relay 209, and armature 212b and its closed contact to earth.



  As a result of the energization of the relay 209, the circuit for the advancing electromagnet 208 is opened at the armature 209a. The advancement electromagnet 208 is de-energized so as to advance the levers of the contact ramps <I> A </I> <B> ... </B> <I> D, </I> from from first contact to second contact. At the same time, the circuit that has just been drawn for the relay 209 is open to the frame 208a. After an interval of time, the relay 209 is de-energized and again closes the circuit for the advancement electromagnet 208.

   The advancement electromagnet 208 is in this way excited and de-energized intermittently to cause the advancement of the contact ramp levers <I> A </I> <B> ... </B> I) , from one contact to another. When the lever on the contact ramp A reaches its second contact, a circuit is completed passing from the battery through the coil of relay 210, the armature 5a and its contact pin, the second contact of the contact ramp A and by the lever of the contact ramp A to the earth.



  As a result of the excitation of the relay 21.0, its armatures 210b and 210a are moved from their work contact to their rest contact and close the contacts of the armatures 210a and 210c. The circuit for the advancing electromagnet 208 is open at the rest contact of the armature 210b and the circuit for the relay 214 is closed from the battery by the armature 212a and its rest contact, the ar mature 211b and its rest contact, the armature 210b and its contact pin, the relay 214 and the lever of the contact ramp E to earth.



  As a result of the energization of relay 214, the latter closes the work contact at its mature ar 214a and produces the energization of relay 215 by a current flowing from the battery through the coil of relay 215, the work contact and frame 214a to ground. As a result of energizing relay 215, relay 216 is energized by current in a circuit from the battery through the coil of relay 216, the NO contact, and the armature 215b to ground. The energization of the relay 216 opens the circuit for the relay 220 to the rest contact of the armature 216a and closes the work contact of its armature 216b which at this time has no effect.



  As a further consequence of the activation of the relay 210, a circuit for the relay 217 is closed which passes from the battery through the armature and the closed contact of the advancing electromagnet 218, the relay 217 , the NO contact and the 210th armature to earth. A parallel circuit produces the excitation of the line relay 219 by the make contact and the armature 215a.



  One of the effects of de-energizing the relay 220 is the closing of the circuit for the delayed release relay 221 passing from the battery through the armature 220b and its closed contact, through the coil of the delayed release relay 221, the re pos and frame 223a to earth. As a result of the energization of the relay 221, the energization of the relay 222 is caused by a dead circuit of the battery through the coil of the relay 22, the make contact and the armature 221a to earth.



  As a result of the energization of relay 2 22. a circuit is closed for the advancement electromagnet 218 passing from the battery through the armature and its rest contact, the lever of the contact ramp G, the advance electromagnet 218, the working contact and the armature 217a, the armature 222a and its working contact, the rest contact and the armature 223b to earth.



  The advancement electromagnet 218 moves its pawl to prepare the advancement of the levers of the <I> E </I> <B> ... </B> <I> H. </I> contact ramps It simultaneously opens the circuit for relay 217 and line relay 219, as mentioned above, at its armature contact 208a. De-energization of relay 217 in turn opens the circuit for the advancing electromagnet 218 to its armature and the levers of the contact ramps E to H are moved one step. As a result of the de-energization of the relay 218, the working contact of its armature is again closed and the relays 217 and 219 are energized again.



  This cycle of operations is then repeated and will continue until the lever of the contact ramp F reaches its contact 3 which is connected with the first group of contacts on the contact ramp B, at which point, as we see will recall, the research levers have stopped. At this point, a circuit is completed without the battery by the coil of relay 223, the contact lever and the third contact of the contact ramp F, the second contact and the lever of the contact ramp F, the second contact and the lever of the contact ramp B, line 7, armature 5b and its working contact, line 6, armature 32, and armature 2a to earth.

   As a result of the activation of relay 223, the circuit for the advancing electromagnet 218 will be open at the rest contact of the armature 223b and the circuit for the delayed tripping relay 221 will be open at the contact. mature ar rest 223a. As a result of de-energizing the delayed trip relay 221, the energizing circuit for the relay 222 will be or green, after an interval of time, at the working contact of its armature 221a. Consequently, the relay 222 will be de-energized and the armature 222a will fall on its rest contact.



  A circuit will now be completed again for the advancing electromagnet 218 which passes from the battery through the rest contact and the armature? 20b, the contact ramp G and its contact lever, the coil of l The advancing electromagnet 218, the working contact and the armature 217a, the armature 222a and its rest contact, the working contact and the armature 223b to earth.



  The excitation of the advancing electromagnet 21.8 prepares its pawl to advance the levers of the contact ramps E to H by a further step. As already described, the circuit for the relay 217 is simultaneously open, which, after an interval of time, will be de-energized and will open., At rest contact of its armature 217a, the circuit for the electromagnet. advancement 218 thus causing the levers to move from their contact 3 to the next contact with the contact ramp.

   The circuit for relay 223 will now be open and armature 223b will go back to its normally closed contact and the circuit through armature 223a will again energize relay 221 which, in turn, will energize relay 222 to prepare again a circuit for the advancing electromagnet 218 as originally drawn.



  So far, the operation has been described for the transmission of the first group of pulses and of the first rest period. It will be noted that, during this first rest period, the advancing electromagnet 218 is de-energized. Consequently, the relays 217 and 219 remain energized and the line between the two stations is closed. The advancing electromagnet 218 now continues to be intermittently energized and de-energized in the manner already described, until the contact ramp lever F reaches a contact on its contact ramp which is connected with the second contact on the contact ramp C, on which the searcher lever stopped.



  Remember that at the beginning of the first rest period, a circuit, corner. taking over 223, was completed with earth by the lever of the contact ramp B. This same battery circuit is now completed by the 223 relay, the lever and the fifteenth contact of the contact ramp F, the second contact and the lever of the contact ramp C, the make contact and the armature 210b to earth.



  The advance electromagnet circuit 218 is again opened at the rest contact of the armature 223b and the circuit for the relay 221 is de-energized on contact with the mature artery 223a. As a result, the circuit of relay 222 is de-energized. Since the relays 221 and 222 are delayed release, a period of time constituting the second rest elapses, before the relay 222 is de-energized to switch its armature to the rest contact and to close the circuit of the electro again. - advancement magnet 218.



       However, after an interval of time, this action occurs and the relay 218 is again energized by a circuit passing from the battery through the armature 220b and its rest contact, by the lever of the contact ramp G, the advancement electromagnet 218, the coi, working tact and the armature 217a, the armature 222a and its rest contact, the working contact and the armature 223u to the ground.



  The energization of the advance electromagnet 218 again puts its pawl in position to advance the levers of the contact ramps E to H and simultaneously opens the circuit for relay 217. After a time interval, relay 217 is de-energized and opens to its armature the circuit for the advancing electromagnet 218 which, after its de-energization, causes the levers of the contact ramps to advance on their next contact and open the circuit of relay 223. De-energizing relay 223 again closes a circuit for energizing relay 221, which in turn closes a circuit for relay 222 and the circuit for the advancing solenoid is again closed by the. primitive circuit described.

   Progress continues until the 25th contact is reached. The circuit for the advancing electromagnet 218 is then open at the contact ramp G. The relays 217 and 219 remain energized and a third rest period results.



  The operation described so far has produced, as a result of the operation of the key by the supervisor, a series of pulses transmitted by the main line 225 thanks to the intermittent excitation and de-energization of the relays 219 and 217. < B> There was </B> a first rest period during which the line was held closed for a period longer than the ordinary pulse periods followed by a second series of pulses, a second rest period, a third group of pulses and a third rest period at the 25th contact. We will now describe the effect of these pulses at the substation.



  After energizing relay 219 at the control or monitoring station, the. line is closed, as already described, to excite line relay 300 by a circuit passing from the battery through armature 219a, armature 7092 and its rest contact, line 225, armature 613a and its rest contact and the coil of relay 300 to earth, Following the energization of relay 300, the circuit is completed for the advancing electromagnet 301 which passes from the battery through the electromagnet advancement 301 and by the mature ar 300a and its working contact to the earth.



  A further consequence of the energization of the relay 300 is that the delayed tripping relay 302 is energized by a circuit passing from the battery through the coil of the delayed tripping relay 302, the armature 300h and the normally open contact. Earth.



  The excitation of the advance electromagnet 301 puts its pawl in position to advance the levers of the contact ramps I to L. After opening line 225, relay 300 is de-energized and opens the circuit for the advancing electromagnet 301 to its armature 300a and consequently the levers of the contact ramps 1 to. <I> L </I> are advanced from their first contact to the second contact. A circuit is completed passing from the battery and through the coil 303, the contact pin and the armature 302e and the lever of the contact ramp J to earth.

   The energization of the relay 303 establishes a locking circuit for itself at the working contact of its armature 303u and opens a circuit to its armature 303a. This is the control circuit held open, until the 25th pulse period to ensure that only correctly selected devices are operated.



  A subsequent consequence of the de-operation of relay 300 is to close a circuit for relay 308 passing from the battery through the coil of relay 308, the make contact and armature 302b, the closed contact and the rear. 3001> to the earth. As a result of the energization of the relay 308, a circuit is completed for the energization of the relays 306 and 307 by the working contacts of the armatures 308b and 308a respectively.



  As a result of the advancement of the lever of the contact ramp I on its second contact, a circuit is closed <B> which </B> passes from the <B> battery </B> through the coil 304 and through the lever of the contact ramp 1 to earth. The closing of the contacts of the armatures of relay 304 has no effect during this time. When the selection has been made, the contacts of this relay will act to determine a latch circuit, as will be seen later.



  Upon arrival of the next pulse, relay 300 is energized again to energize the advancing electromagnet 301 as indicated. When the line is open, the relay 300 is de-energized and simultaneously the advancement electromagnet 301 is de-energized so as to advance the levers of the contact ramps <I> 1 to L </I> on their third contact.



  Upon receipt of the first pulse and the resulting excitation of relay 302, as already described, a circuit was completed which passed from the battery through the coil of relay 308, the make contact and the switch. armature 302e and by the lever of the contact ramp K to the earth. As already explained, the relays 307 and 306 are subsequently de-energized to keep their arming contact open.

   As soon as the contact ramp lever K moves from its first contact to its second contact, this circuit for 1P relay 308 is opened at the contact ramp lever 1ï and during the periods of activation of the. line, the circuit for the relay 308 is also open at the opening contact of the armature 300b. The relays 306 and 307 are however then energized alternately through the intermediary of the contacts of the contact ramp Ii, but due to the relatively rapid movement of the lever of the contact ramp, these delayed tripping relays are not de-energized during their periods. open circuit.



  When the first period of rest or pause occurs, the line, as previously described, remains closed and the relay 300 is therefore kept energized so that the advancing electromagnet 301 is energized. The contact ramp levers are not caused to advance during this period, and one of the relays 306, <B> 307 </B> is de-energized after a time interval due to its circuit being. open to the K con tacts ramp.



  As it has been assumed that the first pause occurs at the third contact, the relay 306 will be energized through the third contact of the contact ramp K and the circuit for the relay 307 will be opened at K.



  It goes without saying that during normal transmission of the pulses, the delayed tripping relays 306 and 307 are not de-energized during the small period of time that their circuits are open. As a result of the de-energization of relay 307, a circuit is completed which passes from the battery through the coil of relay 401, contact 400, line 310, and third contact. and the lever of the contact ramp L, the rest contact and the armature 305a, the rest contact and the armature 307a of the relay 307, the working contact and the armature 302a, by the third contact and the lever of the 1 earth contact ramp.

   The energization of the relay .101 closes all the contacts of its group of contacts 402, this also results in a latching circuit for the relay 401 passing from the battery through the coil of the relay 401, through the first contact of the group of contacts 402, the make contact and the armature 304a to earth.



  A circuit. is also completed which passes from the battery through the coil 403 and through the second contact of the group of contacts 402 to. Earth. Excitation of relay .103 opens contacts of contact group 400 to prevent energization of group 404 or 405 relays.



  At the end of the first rest or pause period, the line circuit is opened to de-energize relay 300 which, in turn, de-energizes the advancing electromagnet 301 and advances the levers of contact ramps 1 and L on the next ramp contact, the relay 307 then being again energized to open the rest contact of its armature 307a. The second series of pulses then follows, resulting in the levers of the contact ramps <I> 1 to L </I> advancing step by step until the second rest period occurs. .

   During this time, the same operation which took place at the first rest period, is repeated, the relay 306 or the relay 307 being de-energized after an interval of time to close the circuit to its armature.



  During this time, the lever of the contact ramp L has reached the second group of contacts shown. The second rest period occurs at the 15th contact and the circuit is completed as described above, from the battery by the coil of the relay 406, the 15th contact and the lever of the contact ramp L, the contact rest and armature 305a, rest contact and rear 307a, make contact and armature 30: 3a, the 15th contact and by the lever of the contact ramp I to earth .

   The excitation of the relay 406 closes the three contacts shown on its armatures. As a result of energizing relay 406, a latch circuit is prepared which passes from the battery through the coil of relay 406, the third armature contact of relay 406, and the contact pin and armature 304. at. Earth.



  As a further consequence of the energization of the relay 406, a circuit is completed which passes from the battery through the. coil of relay 305 and then the second arming contact of relay .1.06 to earth. The energization of relay 30.1 opens the contact of its armature 305a and prevents any selection of an ultralight group, since, as can be seen from the circuits previously traced, all the group selections were controlled by the current flowing through this contact. .

   Relay 305 closes a latch circuit for itself, which passes from the battery through the coil of relay 30: ï, the make contact and armature 305b, the make contact and armature 304b to. Earth.



  At the end of the second rest period, the relay 300 is de-energized to de-energize the advancement electromagnet 301 and keep them to advance the levers to the advanced on the next contact and consequently the relay 307 is energized again by the intermediary of the contact ramp K. The continuous advancement electromagnet and the contact ramps <I> I to L </I> are third or last rest period in which , as already described, arrives at 25nle contact.



  This 25th impulse is of great lift, because it offers a guarantee against false operations or in other words, because it acts as a control element for a correct selection. 5i, for some reason, the lever: Ramps of contacts I to L fall. out of synchronism with the lever of the contact ramps E <I> to H </I> during the advancing from the first to the 25th contact and consequently fail to reach the 25th contact at the same time, no operation takes place will produce, as we will see below.

   On the other hand, the device transmitting the code to the control or monitoring station will retransmit. its code and will continue, thus until the switches, during a cycle, that is to say during a period when the levers move from the first to the 25th contact, advance in synehronism, to reach in the two ramps: of contacts, <I> E to H </I> and I to <I> L, </I> the 25th contact simultaneously.



  It will now be assumed that the two levers of the contact ramps <I> E to H </I> and <I> I </I> to L reach the same contact simultaneously. As described above, a third rest period will occur at the monitoring code transmitter, when the contact ramp levers E <I> to. H </I> reach the 25th contact and relay 219 is kept energized.



  If the levers of the contact ramps 1 to L are now on their 25th contact, the relay 303 will be de-energized when the lever of the contact ramp I changes from the 294th to the 25th contact. As the relay 303 is delayed tripping, it will not have time to de-energize, unless a quiescent period occurs when its circuit is then open.

   As a result of the de-energization of relay 303, a circuit is completed which passes from the battery through relay 500, the last contact of group 402, through line 407, the first contact of the group controlled by relay 406, the rest contact and armature 303a, 25m (- contact, and the lever of the contact ramp J to, earth. As a result of the excitation of relay 500 by the circuit just described, a The circuit is completed which passes from the battery through the coil of the relay 501, the make contact and the armature 500a to earth.

   Excitation of relay 501 closes the circuit for relay 502 which trips circuit breaker 1; O1. This completes the operation performed by the supervisor.



  The operations described below are the monitoring operations which occur due to tripping of the circuit breaker. It goes without saying that the operations to be described are established in the same way, if the circuit breaker is tripped as a result of the action of the supervisor or by automatic means.

   Relays 503 and 504 are normally energized in series by a circuit which passes from the battery through the coil of relay 504, the delayed release relay 503, the make contact and armature 504b, armature 504a and its rest contact, the rest contact and armature 506b to earth, relay 504 having been (-. cited previously by a circuit that will be described later.



  Upon tripping of circuit breaker C Bl, relay 506 is energized by a circuit extending from earth through contact 506 on the circuit breaker, armature 503b and its make contact and the relay coil. 506 to the battery. Consequently, the circuit traced above for the relays 503, 504 is rendered inoperative by the fact that the battery is connected to the relay 503 only by a circuit extending from then the battery by the armature 500b and its working contact. , the make contact and the armature 506c at the midpoint between the relays 50.3 and 504. As a result of the potential applied at this point, the de-energization of the relay 504 occurs.

   As the relay 503 was energized in a circuit by the armature 5045, it will result in the de-energization of the relay 504 la. de-energization of relay 503.



  As a result of the de-energization of relay 504, a circuit is momentarily completed which passes from the battery to the coil of the delayed tripping relay 505, the armature 504e and its idle contact, the make contact and the rear. mature 506b to earth. A rusting worm circuit is formed for relay 505 by its frame 505b. As a result of the de-energization of relay 503 described above, a circuit is completed which passes from the. battery to armature 511b and its rest contact, armature 510a and its rest contact, armature 509a and its rest contact, the coil of the advancing electromagnet 608 and the contact rest and armor 503a to earth.

   The advancement electromagnet 608 is excited by this circuit to bring this pawl in a suitable position for advancing the levers of the ramps of the contacts M to P from the first to the second contact. As a result of the excitation of the electromagnet 608, a circuit is closed for the relay 609 which passes from the battery through the armature 611b and its rest contact, the mature artery 610a and its rest contact , the closed contact of armature 608a, coil of delayed release relay 609 and contact (rest and armature 611e to earth.

    As a result of the energization of the relay 609, the circuit of the advancing electromagnet is opened at the armature of the relay 609 and the pawl of the advancing electromagnet 608 advances said levers. from the first to the second contact.



  For the seeker switch at the supervisory control station, this cycle, as already described, will continue until the levers of the respective contact ramps reach contact, in this case the second, at which time a circuit will be completed which passes from the battery through the. coil of relay 610, the rest contact and armature 504a, and by the contact and the lever of the contact ramp F to earth. As a result of the energization of the relay 610, the circuit for the advancing electromagnet 608 is open to the rest contact of the armature 610a, and the levers are stopped in this right.



  As a further consequence of the excitation of the relay 610, the excitation of the relay 614 is produced by a circuit which passes from the battery through the armature 611b and its rest contact, the armature 610a and its working contact. , the coil of relay 614, the lever of the contact ramp R to. Earth. The energization of the relay 614 results in the excitation of the relay 615 by the work contact of its armature 614a, which relay produces at. in turn the excitation of relay 616.

   As a result of the energization of the relay 616, a locking circuit is formed for the relay 610, independently of its circuit previously drawn, which passes from the battery through the coil of the relay 610 and the working contact and the armature. 616a to, earth. A subsequent consequence of the excitation of the relay 616 is the opening of the excitation circuit of the relay 620 at the rest contact of the armature 616a.



  As a further consequence of the energization of relay 610, an excitation circuit for relay 616 is closed passing from the battery through the closed contact of the advancing solenoid 618, the coil 617, the contact pin and frame 610b to earth. Line relay 619 is closed by a parallel circuit containing armature 615a and its make contact.



  The relay 622 is energized by a circuit passing from the battery through the armature 620 and its closed contact, the coil of the delayed tripping relay 622, the armature 623a and its closed contact to earth. The excitation of the relay 622 closes an excitation circuit for the relay 621. A circuit is then completed for the advancing electromagnet 618 which passes from the battery through the ar mature 620b and its contact. rest, the contact and the lever of the contact ramp T. the advancement electromagnet 618, the make contact and the armature 617a, the armature 621a and its make contact, the rest contact and armature 623b to earth.



  The excitation of the advance electromagnet prepares its pawl for the advancement of the levers of the contact ramps R to. U, like already. describes, and simultaneously opens the circuits for the relays 617 and 619 on contact with their armature. The de-energization of relay 617 opens the circuit for the advancing electromagnet 618 in its armature.



  The code transmitting apparatus has now been sufficiently described to demonstrate its. resemblance to the code transmitting device of the monitoring station. As shown in this case, the line relay 619 will be intermittently energized with the advancing solenoid 618 until the lever of the. Ramp of contacts S reaches the third contact which is connected to the first group in O, at which point the circuit is completed for the relay 623 for the first rest period and the circuit for the advancement electromagnet is or green.

   As a result of energizing relay 623, the circuit for relay 622 is opened at the closed contact of actuator 623a and after a time interval relay 602 is de-energized to de-energize relay 621.

   As a result, an energizing circuit is again established for the advancing electromagnet 618, which in turn opens the circuit of the relays 617 and 619, which in turn turn on the relay. advance solenoid circuit 618 and the contact ramp levers R at I% continue to.

   advance until the second rest period is reached, at which time they initiate the same cycle of operations and thus continue until about the 2511st contact to arrive at the third rest or final rest. Intermittent excitation of relay 619 opens and closes the circuit of the line relay 700 which passes from the battery through the mature artery 619a and its make contact, the line 625 and through the coil of the relay 700 to ground.



  In the case of pulses received at the substation, the excitation of relay "r00 causes the excitation of relay 702 as well as the excitation of the advancing electromagnet 701. After opening of the line circuit, the de-energization of the relay 700 will cause the de-energization of the advancing electromagnet 701 and this results in an advancement of the levers of the contact ramps V to Z from the first to the second contact.



  The relays 706 and 707 are energized through the. Ramp of contacts Y. Relay 703 is energized by a non-active circuit by the opening contact of armature 702d and the ramp of contacts 1 and relay 704 is energized by means of the ramp of contacts V, d ' in a manner quite as similar to that described in the case of the operation of the receiving apparatus of the substation.



  When the V to Z contact ramp levers are gradually moved over their contacts, the excitation circuits for relays 706 and 707 are intermittently closed and, these relays being delayed release, they will maintain their circuits. cooked open to their frames. Relay 702, which is at: delayed launch, is not de-energized during periods of periodic energization of relay 700, although its circuit is open at the armature of relay 700.

    When, however, a rest period is reached, relay 700 remains energized for a longer period than usual, the levers do not advance and relay 706 or that 707, depending on the position of the lever on the Y contact ramp. , is excited.



  De-energization of relay 707 will close. in this case a circuit passing from the battery through the coil of relay 801, the first contact of group 800 controlled by relay 803, the third contact and the lever of the Z contact ramp, the rest contact and the armature 705a, the rest contact and the armature 707a, the work contact and the armature 702a, the lever of the contact ramp V to earth. This will result in the selection: c a group of circuits 802.



  The energization of relay 801 closes the contacts of the first group selection. Relay 801 simultaneously establishes a locking circuit for itself passing from the battery through the coil of relay 801, the first contact of relay 80'2, the working contact and the armature 704a to earth.



  The relay 803 is energized by a circuit passing from the battery through its. coil and the second contact of circuit group 802 to ground. The: 80: 3 relay energized opens its armature contacts to prevent further group selection.



  A. As the pulses then arrive through the line, the V to Z contact ramp levers continue to be advanced until the second rest period is reached. At this moment, the same cycle of operations occurs, which has already been described in the case of the first rest period, except that the lever of the contact ramp Z. instead of being connected with the first series Selection relay group, such as 801, is now connected with the second group and a circuit is completed for relay 806 similar to the circuit described for relay 801. Relay 806 also completes a latch circuit for itself if milaire to the described locking circuit. for relay 801.

   The pulses will now continue to pass through the line until the contact levers have reached the 25th contact.



  As already described for the control operation, it is a very important fact that, unless the levers of the monitoring code transmitter device reach the 25th contact at the same time due to the levers of the contact ramps V to Z of the monitoring receiver reach their 25th contact, no operation occurs and the monitoring code transmitter device only repeats the code until both sets of levers reach the 25th contact simultaneously .

   In this way, correct monitoring signaling is ensured, as has already been described for the case of control operation.



  In order to describe the present operation fully, it will be assumed that the two groups of levers simultaneously reach their contact point. A rest period similar to the first two rest periods occurs at this time. The circuit for relay 708 is open when the X contact ramp levers change from 24nie to 25th contact.

   After an interval of time, its frame 703a will be. released to close a circuit passing from the battery through the coil of relay 1 to the contact of group 802, through line 807, the relay contact <i selection of group 806, the rest contact and armature 703a, the 25th contact and the hcvier from the, contact ramp X to the end.



  Relay 1 establishes a locking circuit for itself by the armature <B> 11) </B> and opens the circuit for the red monitoring lamp at its armature, opens the locking circuit for the relay 5, previously described, and closes the circuit for a white lamp thereby: indicating to the sur- vantor the correct action of the circuit breaker at the substation.



  This completes the monitoring operations. Recall operations which occur as a result of the correct transmission of a control operation and the correct reception of the supervisory code will now be described.



       When the lever of the contact ramp E (fig. 2) reaches the 25th contact, a circuit is completed which passes from the battery through the coil of relay 212, its 25th contact and the lever of the contact ramp E to Earth.



  At the rest contact of its armature 212b, the connection is cut from earth to coil 209 so that this relay cannot be energized. At the armature 212a, the circuit for the advancing electromagnet 208 is open at the rest contact, but closed at the work contact through it and the mature arm '216b which is supplied by this neck. rant right now. The advancing electromagnet 208 is energized beforehand to move the levers a to d another step.



  As a further consequence of the movement of the levers of the contact ramps E to. H at their 25th contact, the circuit of relay 21.4 is open to the ramp of contacts E. The armature of relay 214 has a vibrating blade, so that after de-energization of relay 214 it will remain vibrating for a period of time. period of time, between its make contact and its break contact, thus maintaining the delayed tripping relays 215 and 216 energized for a prolonged time after the de-energization of the relay 214.



  .after a period of time, the armature of relay 214 stops halfway between its contacts and after a later period of time, relay 215 is de-energized. Deactivating relay <B> 215 </B> opens the circuit for relay 216 which is de-energized after an interval of time. De-energizing relay 216 opens the circuit for the advancing electromagnet 208 at its armature 2161) and closes the circuit for relay 220 at its mature arm 216a. As a result of the de-energization of the advancing electromagnet 208, the levers of the ramps .de contacts A to D advance from their second to their third contact.



  The energization of the relay 220 establishes an excitation circuit for the advancement electromagnet 218 which passes through the 220th armature and its working contact, the coil of the advancing electromagnet 218 , the working contact and the armature 220a, the 25th contact and the lever of the contact ramp H, the contact of the advancing electromagnet 218 to the battery. As a result of its excitation, the advancing electromagnet opens its own circuit to. his own touch. and the levers advance towards the first contact at which point the circuit for the advancing electromagnet is open at the contact ramp H.

        The opening of the locking circuit for the relay 5 previously described also opens the circuit for the relay 210 to its armature 5a. The relay 212 is de-energized when the lever of the contact ramp E moves from the 25th to the first contact. In a similar way, the levers of the contact ramps to the device transmitting the surveillance code and to the device receiving the surveillance code are recalled to. the normal position.



  In the event that the levers of the contact ramps E <I> to </I> II at the monitoring station do not turn off the 25th contact at the same time as the levers of the contact ramps I to L of the receiving device control reach their 25th contact, the third rest period would not occur when the levers of the contact ramps I to L are on their 25th contact, but, as the circuit for relay 500 can only be completed by with the contact ramp lever J on its 25th contact, the relay cannot be energized and no operation @ can take place.

   This circuit depends on the de-energization of relay 303 on the 25th pulse or when the third rest period occurs on the contact levers at their 25th contact, so as to give it sufficient time to de-energize.



  Under these circumstances, no supervisory signal is received back and, therefore, the relay assembly actuated by the operation of the master control key by the supervisor is not returned to the normal state. relay 1 not being energized, and when the code transmitting device at the monitoring station reaches the first contact, the searcher switches will move until they find the desired position and the code will be repeated. This will continue until an exact reception occurs.



  Receipt of the first pulse from the monitoring code transmitting apparatus to the monitoring code receiving apparatus indicates that the exact operation has occurred at the substation. If, after a switch has been actuated depending on the operation of its corresponding key to the control station, it returns to its original position, as could happen if a circuit breaker having been closed depending on a operation at the control station and following certain faults in the installation,

   the current can become so high that the circuit breaker opens again automatically, which is significant for the existence of a disturbance on the line, it is important in these circumstances to prevent a subsequent closing of the circuit breaker . This function of preventing back-and-forth movement of the circuit breaker is accomplished as follows:

    After receiving the first signal, which immediately indicates the exact operation to the substation, the relay 704 "as already described, is energized by means of the second contact of the V <I> Au </ I contact ramp. > working contact of its armature 704a is completed a circuit for the relay 212 which passes from the battery through the coil of 212, the work contact and the armature 704a to earth. It will be remembered that the relay 212 was de-energized when the contact ramp lever E returned to the normal state.

   The energization of the relay 212 prevents further energization of the advancing electromagnet 208 to its frame 212a and thereby prevents further movement of the seeker switch. Like relay 210, which is de-energized when the contact ramp lever A moves from the second; at the third contact, is not energized again, the code transmitting device cannot start for operation. Unless the supervisor purposely activates his key to repeat the original operation, the automatically opened circuit breaker will not close.



  When the lever of the Y contact ramp reaches its 2.5th contact, relay 709 is energized by means of this Y ramp. To the monitoring code transmitting device, relay 611 is energized when the lever switches it on. Contact ramp R reaches the 25th, a contact from which it follows that the relay 613 is energized by means of the working contact of the armature 611c.

   As a result of the multiple excitation of relays 212, 709, 613 and 611, a circuit will be completed which passes from the battery through the armature 611b and its working contact, the coil of the relay <B> 612, </ B> the work contact and the armature 613a, the line 225, the armature 709 and its work contact, and the work contact and the armature 212b to earth (fig. 2).



  The energization of relay 612 produces the closing of an excitation circuit passing from the battery through the coil of relay 504 to contact 2 and the lever of the <I> M contact ramp, through </I> the contact contact and armature 615c, work contact and armature 611a, work contact and armature 612a to earth. As a result, the relay 504 is energized to energize the relay 503 by a circuit passing from the battery through the coil of the relays 504 and 503 in series, the working contact and the armature 504b, the armature 505a and its contact: working dt, the working contact and the 500b armature to earth.

   The circuit for the relay 506 remains closed by the armatures 503d and 503b and the contact 510. The monitoring relays 504 and 503 are in this way brought back to the normal state at the 25th pulse.



  If, for any reason, the supervisor changes his mind during the transmission of a code and does not wish to maintain the operation of a particular equipment any longer or if the operation caused was accidental, any operation may be stopped by opening the main control key K. As a result of opening the main control key K, the circuit connecting the junction conductor of relays 2 and 3 to earth will be cut.

   Relay .3 will now be energized in series with relay 2 by a circuit passing from the battery through the coils of relays 2 and 3, the working contact and the armature 2b, the armature 4a and its normally-open contact. Earth. As a result of the activation of relay 3, the control circuit is opened at the rest contact of armature 3a. In this way, the excitation circuit for relay 5 is opened, which in turn will open the circuit for relay 211 or 210 as the case may be, which in turn opens the circuit for relay 214 on contact with work of its frame and no operation will occur.

   This provides a guarantee against a false operation if the supervisor, for some reason, had to operate the key in opening movement during the operation.



  The relay 300 at the substation is arranged to be energized by current from a battery at the monitoring station using line 225, the other end of the relay coil being set to. Earth; in this way, false operation of the relay cannot occur if the 22: 5 line is accidentally grounded as then both ends of the relay coil 300 are grounded. Similarly, accidental grounding of line 625 cannot cause false operation of relay 700. There is also no effect if the moons 225 and 695 intersect.

 

Claims (1)

CLAIM Installation for the electrical control of a set of apparatus in a substation from a remote control station, in which a plurality of sets of apparatus of the substation are arranged to be controlled by means of corresponding operating keys provided at the control station and in which the operation of a set of devices at the substation causes a corresponding signaling by means of a device transmitting conventional code signals and a conventional code signal receiving device both at the control station and at the substation, characterized in that a safety relay is provided at the control station and is connected in such a way to the circuit of the installation that it is actuated by the first pulse from the apparatus transmitting conventional code signals to the substation for the receiver of conventional code signals at the control station; dependence on the operation of a set of devices at the substation due to the operation of a key at the control station, said safety relay being established so that its operation stops the operation of the device transmitting conventional code signals to the control station, unless the key is released and the operation is restarted by a new operation of the key, which makes it possible to prevent repeated operation of: a set of devices if the automatic control conditions at the substation prevent the operation of the set, of devices initiated by operating the key at the control station. SUB-CLAIMS 1 Installation according to claim, in which the apparatuses transmitting code signals at the control station and at the substation are arranged to operate, respectively, the apparatuses receiving code signals at the substation and to the control station by transmitting, via a circuit containing a line connecting the control station to the substation, a series of pulses capable of causing the operation of the code signal receiving devices, a relay to operate the code signal receiving apparatus at the substation being established so that it can be energized as a result of its connection, by a line between the control station and the substation, with a battery fitted at the control station and a relay to operate the code signal receiving apparatus at the established control station. to be able to be excited as a result of: its connection, by a line between the control station and the substation, to a battery mounted at the substation, thanks to which an accidental earthing of one or the other lines or a short-circuit between the lines cannot cause the relays to malfunction. 2 Installation according to claim, charac terized in that a relay is provided at the substation to be able to be energized during the last operation of the device for transmitting code signals therein and that a relay is provided at the control station to be able to be energized during the last operation of the code signal receiving apparatus therein, a simultaneous energization of these relays having the effect of causing the establishment of a circuit between the control station and the substation to return the installation to the normal state, whereby it will not be returned to the normal state if the transmitting devices and the receiving devices of code signals do not are not in synchronism.