RU2382434C1 - Improved hybrid dc switching device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is related to electric engineering. The first version of improved hybrid DC switching device comprises the first electromechanical commutator with control system, the second electromechanical commutator with control system, two transistors with control system, current relay, on and off buttons, protective cutout device, relay of control and information unit, at the same time the first electromechanical commutator is connected serially to current relay and load, the second electromechanical commutator and two transistors are connected into a single serial circuit and parallel to the first electromechanical commutator, protective cutout device and off button are connected to control systems of the first and second electromechanical commutators and system of transistor control, control relay is connected to transistors, to system of the second electromechanical commutator control and to information unit. The second version of proposed device instead of the second transistor comprises safety fuse connected serially with transistor. The third version of proposed device instead of the second transistor comprises thermistor with positive temperature coefficient of specific resistance, connected serially to transistor.

EFFECT: improved reliability and simplification of device.

3 cl, 3 dwg

Description

The present invention is an improved hybrid DC switching device relates to electrical engineering, namely to switching DC electric devices, and can be used for switching DC electric circuits in load modes, overload modes and emergency modes of load short circuit.

It is known that when a DC inductive load is disconnected between the main contacts of an electromechanical electrical apparatus, an electric arc arises that melts these contacts, which significantly reduces the switching wear resistance of an electromechanical electrical apparatus compared to its mechanical wear resistance (L.1, Chunikhin A.A. Electrical apparatuses : General course. Textbook for high schools. - 3rd ed., Revised. And add. - M .: Energoatomizdat, 1988).

To increase the life of electrical apparatuses, it is known to use semiconductor non-contact electrical apparatuses in which there is no electric arc and switching wear (L.2, Mogilevsky GV and other semiconductor protection apparatuses. - M .: Energy, 1980). However, semiconductor devices have an increased voltage drop when direct current is transmitted in the on state, which increases their heating and reduces the efficiency, and also does not provide galvanic isolation of the load from the mains in the off state.

The desire to combine the positive qualities of contact devices in electrical apparatuses - small power losses in the on state and galvanic isolation of the load from the power source in the off state - and the positive qualities of semiconductor electrical apparatuses - increased switching wear resistance and, therefore, lower operating costs - led to the development and creation hybrid electrical apparatus, in which the current in the on state of the apparatus passes through the electrical contacts electromechanical apparatus, and the switching of this current is performed by power semiconductor devices connected in parallel with the contacts of the electromechanical apparatus (L.3, GV Mogilevsky Hybrid low-voltage electrical apparatus. - M .: Energoatomizdat, 1986).

It is known that the greatest duration of burning of an electric arc, therefore, the greatest destruction of contacts occur when disconnecting constant inductive currents. Therefore, a number of hybrid DC switching devices are known, which are analogous to the proposed hybrid DC switching device (Appendix 1, L.3, p. 64, Fig. 1.21). However, they all have drawbacks, since these devices are made on single-operation thyristors, which, when implemented, require the use of pre-charged switching capacitors C, which complicates the known analogues, increases their dimensions and reduces their reliability. With this in mind, a closer analogue is a DC switching device with a parallel connection of an electromechanical device and a transistor (Appendix 2, L.4 Electrical and electronic devices: a textbook for high schools / Edited by Yu.K. Rozanov. - M.: Energoatomizdat, 1998, p. 573, fig. 11.14.).

However, the claimed technical result is not achieved in the aforementioned analogue — an increase in reliability and simplification of the hybrid DC switching device, since the analogue has the following disadvantages.

Firstly, there is no electromechanical switchboard for galvanically decoupling the load Z _n from the constant voltage source E with the transistor of the hybrid DC switching device turned off. Secondly, there is no transistor health monitoring relay, which also reduces the reliability of a hybrid DC switching device. Thirdly, there is no information block about the malfunction of the transistor of the hybrid DC switching device.

Therefore, a hybrid DC switching device with an additional electromechanical switch was chosen as a prototype. (Appendix 3. Utility Model Patent No. 75787 “Hybrid DC Switching Device”, authors: Muradov E.Sh., Shipitsyn VV, Morozov AG Published on 08/20/2008, bull. No. 23). In this prototype, there is an additional electromechanical switch for galvanic isolation of the load from the mains when the transistor is off, there are transistor health monitoring relays and a transistor malfunction information block, which ensures the normal operation of the prototype device when disconnecting the nominal and less than the nominal value of direct inductive currents. However, the prototype also has the disadvantage that in the event of a sudden short circuit during shutdown and the appearance of overvoltages, the likelihood of non-shutdown of the short circuit current by the second electromechanical switch increases significantly, since it is advisable to use a DC contactor as this switch, which is much cheaper than an automatic DC circuit breaker and has significantly greater cycle resistance. All this leads to non-shutdown of the short-circuit current and, consequently, to a serious accident in the DC electrical device, especially if this is an electrical device - passenger electric transport.

The present invention, an improved hybrid DC switching device, solves the problem of developing and creating a hybrid DC switching device, the implementation of which allows to achieve the claimed technical result, which consists in increasing the reliability and simplification of this device.

The essence of the invention, an improved hybrid DC switching device, is that in a hybrid switching device having a first electromechanical switch with a control system including a button, a disconnecting button, a residual current circuit breaker and a current relay connected in the forward direction with respect to polarity supply voltage, the first transistor with a control system, the second electromechanical switch with a control system, a control relay and an inf of the first electromechanical switch connected to the current relay and the load, including a button, a residual current device and a disconnecting button connected to the control circuit of the first electromechanical switch, the second electromechanical switch is connected in series with the first transistor, while the resulting serial circuit is connected in parallel with the first electromechanical switch , residual current device, tripping button and current relay connected to transi control systems Operations and second electromechanical switch, and the transistor is connected to the relay control information unit and the second electromechanical switch control system which is connected to a current relay. In the first embodiment, a second transistor is additionally introduced, having two power terminals, one input and one output terminals, the second transistor being connected in the forward direction with respect to the polarity of the DC supply network, the second output terminal being introduced into the transistor control circuit, and the monitoring relay the second input terminal is introduced, while the first power terminal of the second transistor is connected to the second power terminal of the first transistor, the second terminal of which is connected to the second main contact of the first electron mechanical switch, and the input terminal of the second transistor is connected to the output terminal of the second transistor control system, and the output terminal of the second transistor is connected to a second input terminal of the control relay. In the second embodiment, a fuse is additionally introduced having two power terminals and one output terminal, the second input terminal being introduced into the monitoring relay, while the first power terminal of the fuse is connected to the second power terminal of the transistor, the second power terminal of which is connected to the second main terminal of the first electromechanical switch while the output terminal of the fuse is connected to the second input terminal of the monitoring relay. In the third embodiment, a thermistor with a positive temperature coefficient of resistivity is introduced, which has two power leads and one output lead, and a second input lead is introduced into the control relay, while the first power lead of the thermistor is connected to the second power lead of the transistor, the second power lead of which is connected to the second main contact of the first electromechanical switch, while the output terminal of the thermistor is connected to the second input terminal of the monitoring relay.

The claimed technical result is achieved as follows. When disconnecting direct inductive currents equal to or less than the rated current, the normal shutdown process is ensured by transferring the current to the transistor circuit and then locking them, and then providing galvanic isolation of the load from the DC mains with the cheapest DC contactor. If a short-circuit current suddenly arises during an operative disconnection or disconnection from a residual current circuit breaker and the appearance of overvoltages, an increase in reliability in the first embodiment of an improved hybrid DC switching device is achieved by the fact that when the two transistors are connected in series, the probability of failure of each of them decreases, therefore, the probability increases disconnecting a sudden short circuit with an undamaged transistor. In the second embodiment of the improved hybrid DC switching device in the above mode, an increase in reliability is achieved by the fact that when the transistor is destroyed, the short circuit current is switched off by a fuse connected in series with the transistor, while the fuse in normal mode must pass a current of no more than the rated current for about 1 second therefore, the fuse can be selected with a rated current less than the rated current of the hybrid switching device, and at in the event of a short circuit, the fuse will operate in a substantial overload mode and will ensure that the short circuit current is disconnected in a few milliseconds. In the third embodiment of the improved hybrid DC switching device in the above mode, an increase in reliability is achieved by the fact that when the transistor is destroyed, the short circuit current is significantly limited by the thermistor connected in series with the transistor and is turned off by the second electromechanical switch, which uses a cheap DC contactor. Thus, in all three versions of the proposed improved hybrid DC switching device, the likelihood of breaking the short circuit current is increased, that is, the emergency mode is prevented when the cheapest DC contactor is used as the second electromechanical switch, rather than an expensive automatic high-speed DC switch, while in all three cases, a signal about the failure of t of an element that can prevent the inclusion of faulty operation of the switching device.

The proposed improved hybrid DC switching device, as noted above, has three options and is shown in figure 1, figure 2, figure 3. The device, made according to the first embodiment, is shown in Fig. 1 and contains a first electromechanical switch 1 having a first 2 and a second 3 main contacts, a control system 4 of a first electromechanical switch 1 having four input terminals 5, 6, 7, 8 and mechanically connected with the first electromechanical switch 1, and each output in the elements and control circuits means two wires, the second electromechanical switch 40, having the first 41 and second 42 main contacts, the control system 43 of the second electromechanics a physical switch 40 having four input terminals 44, 45, 46, 47 and mechanically coupled to the second electromechanical switch 40, a first transistor 9 having two power terminals 10, 11, one input terminal 12 and one output terminal 13, a second transistor 48, having two power terminals 49, 50, one input terminal 51 and one output terminal 52, a control system 14 of transistors 9, 48, having three input terminals 15, 16, 23 and two output terminals 17 and 53, connected in series with the load 18 of the current relay 19, having two power terminals 20, 21 and an output terminal 22 including a button 24 having one output terminal 25, a residual current circuit breaker 26 having three output terminals 27, 28, 29, a trip button 30 having three output terminals 31, 32, 33, a monitoring relay 34 of transistors 9, 48 having two input terminals 35, 54 and two output terminals 36, 37, an information block 38 having one input terminal 39. The first main contact 2 of the first electromechanical switch 1 is connected to the first positive pole of the DC power supply E and mechanically connected to the control system 4 of the first electromechanical switch 1, the second main contact 3 of which is connected to the first power terminal 20 of the current relay 19, the second power terminal 21 of which is connected to a load 18 connected to the second negative pole of the DC power supply E, the first main contact 41 of the second electromechanical switch 40 is connected to the first main contact 2 of the first electromechanical switch 1, the second main contact 42 of the second electromechanical switch 40 is connected to the first power output 10 of the first transistor 9, the second power output 11 of which is connected inen with the first power terminal 49 of the second transistor 48, the second power terminal 50 of which is connected to the second main terminal 3 of the first electromechanical switch 1, the first output terminal 22 of the current relay 19 is connected to the first input terminal 8 of the control system 4 of the first electromechanical switch 1, the output terminal 25 switching buttons 24, the first output terminal 27 of the residual current device 26, the first output terminal 31 of the disconnecting button 30 are connected respectively to the second input terminal 5, to the third input terminal 6 and to the fourth input the output terminal 7 of the control system 4 by the first electromechanical switch 1, the second output terminal 28 of the residual current circuit breaker 26, the second output terminal 32 of the disconnecting button 30 are connected respectively to the first input terminal 15 and to the second input terminal 16 of the control system 14 of transistors 9 and 48, the third output terminal 29 of the residual current circuit breaker 26, third output terminal 33 of the tripping button 30, output terminal 22 of the current relay 19, first output terminal 36 of the monitoring relay 34 transistors 9 and 48 are connected respectively to the first input terminal m 44, with a second input terminal 45, with a third input terminal 46, with a fourth input terminal 47 of the control system 43 of the second electromechanical switch 40, the output terminal 22 of the current relay 19 is also connected to the third input terminal 23 of the control system 14 of the transistors 9, 48, output the terminals 17 and 53 of the control system 14 of the transistors 9 and 48 are connected respectively to the input terminals 12 of the transistor 9 and 51 of the transistor 48, the input terminals 35 and 54 of the control relay 34 of the transistors 9 and 48 are connected respectively to the output terminals 13 of the transistor 9 and 52 of the transistor 48, output one output 37 of the monitoring relay 34 of the transistors 9 and 48 is connected to the input terminal 39 of the information block 38.

The second variant of the proposed improved hybrid DC switching device is shown in Fig. 2 and is made basically the same as the first, except that instead of the second transistor 48 (see Fig. 1), a fuse 55 is inserted with power terminals 56, 57 and output terminal 58, while the second power terminal 56 of the fuse 55 is connected to the second power terminal 11 of the transistor 9, the second power terminal 57 of which is connected to the second main terminal 3 of the first electromechanical switch 1, while the output terminal 58 redohranitelya 55 is connected to the second input terminal 59 controls relay 34, which in this embodiment is common to the control transistor 9 and serviceability of the fuse 55.

The third version of the proposed improved hybrid DC switching device is shown in Fig. 3 and is made basically the same as the first option, except that instead of the second transistor 48 (see Fig. 1), a thermistor 60 with a positive temperature coefficient of resistivity with power terminals 61 is introduced , 62 and output terminal 63, while the first power terminal 61 of the thermistor 60 is connected to the second power terminal 11 of the transistor 9, the second power terminal 62 of which is connected to the second main terminal stroke 3 of the first electromechanical switch 1, while the output terminal 63 of the thermistor 60 is connected to the second input terminal 64 of the monitoring relay 34, which in this embodiment is common for monitoring the health of the transistor 9 and the thermistor 60.

The proposed hybrid DC switching device operates as follows. Since a DC disconnecting device is proposed, we will not consider the process of connecting the load to the DC network, assuming that at some point in time t _0, load 18 is switched on via channel 25.5 through channel 25.5 and the first electromechanical switch 1 flows through it current I _load along the circuit: "+" - 1-19-18 - "-".

The process of disconnecting DC can be of three types. The first type occurs when the overload currents or short circuit currents are disconnected at an arbitrary point in time. The second type occurs when the operator or the protective device trips small inductive currents and all currents that do not exceed the rated value of the load current. The third type occurs when disconnecting overload currents and short circuit currents that occurred when the operator or the protective device trips small inductive currents or any currents less than or equal to the rated current, and this type of shutdown has three options, depending on the version of the proposed improved hybrid DC switching device.

The process of turning off the direct current of the first kind in the first embodiment is as follows. When an overload current appears in the load circuit 18 or when a load 18 short-circuit occurs, information about this from the current relay 19 through channel 22, 8 enters the control system 4 of the first electromechanical switch 1, which, in accordance with its purpose, provides DC shutdown in the considered mode In this case, of course, increased arcing and increased electrical wear of the main contacts 2, 3 of the first electromechanical switch occur. However, according to statistics, the considered mode is rare and does not affect the overall life of the electromechanical switch. Information about the short circuit is received through channel 22, 46 to the control system 43 of the second electromechanical switch 40 and through channel 22, 23 to the control system 14 of transistors 9, 48, but in this mode, the second electromechanical switch 40 and transistors 9, 48 are respectively located in turned off and closed, so they do not affect the shutdown process.

In the second and third embodiments of the improved hybrid switching device, the first-type disconnection process is completely similar to the first-type disconnection process of the first embodiment, since the disconnection is performed only by the first electromechanical switch.

Much more often, a second type of DC disconnection occurs, namely, disconnection of small direct currents not exceeding the rated value of the load current 18. Consider this type of DC disconnection process when the trip signal appears from the residual current device 26 or from the disconnecting button 30, i.e. from the operator, for the first embodiment of the proposed device. In this case, information about the load shedding 18 is supplied from the residual current device 26 via channel 27, 6 to the control system 4 of the first electromechanical switch 1 and via channel 29, 44 to the control system 43 of the second electromechanical switch 40 or from the disconnecting button 30 through channel 31, 7 to the control system 4 of the first electromechanical switch 1 and via channel 33, 45 to the control system 43 of the second electromechanical switch 40, from the residual current circuit breaker 26 through channel 28, 15 or from the trip button 30 through channel 32, 16 to the system IU control transistors 9, 14 and 48 of the control transistors 9, 14 and 48 through the channels 17, 12 and 53, 51 to the transistors 9 and 48, wherein the logic portion of the control systems 4, 14 and 43 provides the following sequence of operations. At time t ₁ is switched second electromechanical switch 40, while through the load 18 and through the first electromechanical switch 1 takes the same current I _LOAD. At time t ₂ , transistors 9, 48 are turned on and the first electromechanical switch 1 is turned off, while the load current 18 flows along the contours

wherein at time t _3, the current first electromechanical switch 1 becomes equal to a zero value, and current of the second electromechanical switch 40 and transistors 9, 48 becomes equal to the load current I _LOAD. At time t ₄ with some delay with respect to time t _3, transistors 9, 48 are turned off, while the current of transistors 9, 48 and the second electromechanical switch 40 becomes equal to zero. The voltage at the transistors 9, 48 and at the first electromechanical switch 1 becomes equal to the supply constant voltage E. At time t ₅ with a certain delay relative to time t _{4 the} second electromechanical switch 40 is turned off, while the voltage on the transistors 9, 48 becomes equal zero value, and the voltage at the second electromechanical switch 40 becomes equal to the supply constant voltage E.

The second type of tripping processes for the second and third versions of the proposed improved hybrid DC switching device differs from the tripping process in the first embodiment only in that only one transistor is controlled instead of two, the rest of the tripping process is similar.

The third type of shutdown - shutdown of short circuits that occurred at the time of disconnection by the operator or the protective shutdown device of currents not exceeding the nominal value - is quite rare, but the most severe and has three options depending on the version of the proposed improved hybrid DC switching device.

First option. An improved hybrid DC switching device made in the first embodiment with an additional transistor (Fig. 1) works as follows. When a signal appears about disconnecting the load 18 from the residual current circuit breaker 26 or from the tripping button 30 at time t ₁ , a signal is generated to turn on the second electromechanical switch 43, which is turned on in a no-load mode. At time t ₂ , commands are formed to open the transistors 9, 48 and to turn off the first electromechanical switch 1, which turns off when the arc voltage is low, since it is shunted by a parallel circuit consisting of a second electromechanical switch 40 connected in series and open transistors 9, 48. If at time t ₂ there was no short circuit of the load 18, the shutdown process continues further in accordance with the above algorithm at time t ₃ , t ₄ and t ₅ . If, at time t ₂ , a short circuit of load 18 occurred, the shutdown process does not follow the optimal algorithm that ensures high cyclic resistance of the first 1 and second 43 electromechanical switches as follows. Channel 22, 8 receives a signal to turn off the first electromechanical switch 1, and this signal is duplicate, since at time t _{2 a} signal to turn off the first electromechanical switch 1 is already generated. In addition, signals are generated to disconnect the short circuit of the load 18 on channel 22, 46 for the second electromechanical switch 40 and on channel 22, 23 for locking transistors 9, 48, and there is a possibility of overvoltages on transistors 9, 48 and, accordingly, the probability of breakdown of these transistors. However, this probability decreases due to the additionally introduced transistor, which increases the likelihood of disconnecting this rare but severe case of disconnecting a short-circuited load 18. If one of the two transistors connected in series or both transistors 9, 48 fails, information on channels 13, 35 and 52 , 54 enters the monitoring relay 34, and from the monitoring relay 34 via channel 37, 39 to the information block 38.

The second option. An improved hybrid DC switching device, made according to the second embodiment with an additional fuse (Fig. 2), operates as follows. Until time t ₂ , the shutdown process algorithm is the same as in the previous case. After time t _2, when a load 18 short-circuit occurs, a shutdown signal is sent through channel 22, 8 for the first electromechanical switch 1, through channel 22, 46 for the second electromechanical switch 40, and through channel 22, 23 to lock the transistor 9. When the transistor is locked 9, the appearance of overvoltages and its failure. If the second electromechanical switch 40 fails to disconnect the short circuit, then the short circuit current will be turned off by the fuse 55. Since the fuse 55 must be selected for a current that does not exceed the rated value, and for an operating time of approximately 1 second (this is the operating time of the switching devices when the load 18 is disconnected by the shutdown button 30 or the load 18 is disconnected from the residual current circuit breaker 26), the rated current of the fuse 55 may even be less than the rated current switching device. Therefore, in the event of a short circuit of the load 18 that occurred during the operative disconnection of the load 18, the fuse 55 will operate in a large overload mode, which will ensure its quick burnout within a few milliseconds, and therefore, a quick disconnection of the short-circuited load 18. If the transistor 9 fails, the signal on channel 13, 35 will go to the control relay 34, if the fuse 55 fails, the signal on channel 58, 59 will also go to the control relay 34, and then both signals from the control relay 34 on channel 37, 39 will go to the information block 38.

The third option. An improved DC switching device, made according to the third embodiment with an additionally introduced thermistor 60 (Fig. 3) with a positive temperature coefficient, operates as follows. Until time t ₂ , the shutdown process algorithm is the same as in the previous case. After time t _2, when a short circuit occurs, load 18 likewise receives a signal to turn off the first 1 and second 40 electromechanical switches and to lock transistor 9. If transistor 9 is destroyed when an overvoltage occurs, the short circuit current flows through thermistor 60, which leads to its fast heating, since its rated current should not exceed the rated current of the switching device in a time interval of not more than 1 second, a rapid increase in resistance and quickly have substantially limit short circuit current path of the second electromechanical switch 40 - transistor 9 - thermistor 60, which significantly increases the probability of short-circuit current interruption second electromechanical switch. When the transistor 9 fails, the signal through the channel 13, 35 enters the control relay 34, when the thermistor 60 fails, the signal through the channel 63, 64 also enters the control relay 34, then both signals from the control relay 34 through the channel 37, 39 enter to the information block 38.

In conclusion, it should be noted that: firstly, transistors 9, 48 or transistor 9 in all three versions of the advanced hybrid DC switching device can be equipped with known protective circuits; secondly, when changing the polarity of the supply DC voltage E, the direction of the direct connection of transistors 9, 48 changes to the opposite; thirdly, if a current of the opposite direction is possible, transistors 9, 48 or transistor 9 must be connected to the circuit using a four-diode single-phase bridge rectifier, which is connected in series with the second electromechanical switch with a diagonal of alternating current, while transistors 9, 48 or transistor 9 connected to the DC diagonal of the specified bridge rectifier.

To implement the proposed invention, it is necessary to additionally introduce either a transistor, or a fuse, or a thermistor with a positive temperature coefficient into the known device. You can use the three proposed options for an advanced hybrid DC switching device in any combination. All this will be implemented at Technos LLC.

Claims (3)

1. An improved hybrid DC switching device comprising a first electromechanical switch having first and second main contacts, a control system of the first electromechanical switch having four input terminals and mechanically connected to the first electromechanical switch, and each terminal in the control elements and circuits means two wires, a second electromechanical switch having first and second main contacts, a second electromechanical control system a switch having four input terminals and mechanically connected to the second electromechanical switch, a transistor having two power terminals, one input and one output terminals, the transistor being turned on in forward direction with respect to the polarity of the DC voltage network, and the transistor control system having three input and one output terminal, a current relay having two power and one output terminal, including a button having one output terminal, a residual current device having three output terminals a, a disconnecting button having three output terminals, a monitoring relay having one input and two output terminals and an information block having one input terminal, wherein the first main contact of the first electromechanical switch is connected to the first pole of the DC voltage source and mechanically connected to the control system the first electromechanical switch, the second main contact of which is connected to the first power terminal of the current relay, the second power terminal of which is connected to the load connected to the second pole of the source dc voltage, with the first main contact of the first electromechanical switch connected to the first main contact of the second electromechanical switch, the second main contact of which is connected to the first power terminal of the transistor, the output terminal of the current relay is connected to the first input terminal of the control system of the first electromechanical switch, with a third input the output of the control system of the second electromechanical switch and with the third input terminal of the transistor control system, the output to the water of the enable button is connected to the second input terminal of the control system of the first electromechanical switch, the first output terminal of the protective shutdown device is connected to the third input terminal of the control system of the first electromechanical switch, the first output terminal of the disconnect button is connected to the fourth input terminal of the control system of the first electromechanical switch the control transistor is connected to the input terminal of the transistor, while the second output terminal of the device The protective shutdown is connected to the first input terminal of the transistor control system, the third output terminal of the protective shutdown device is connected to the first input terminal of the second electromechanical switch control system, the second output terminal of the disconnect button is connected to the second input terminal of the transistor control system, the third output terminal of the disconnect button is connected to the second the input terminal of the control system of the second electromechanical switch, the first output terminal of the monitoring relay is connected to the fourth the output terminal of the control system of the second electromechanical switch, the output terminal of the transistor is connected to the first input terminal of the monitoring relay, the second output terminal of which is connected to the input terminal of the information unit, characterized in that the second transistor is additionally introduced, having two power terminals, one input and one output conclusions, and the second transistor is connected in the forward direction with respect to the polarity of the DC supply network, and the second output is introduced into the control circuit of the transistors the output, and the second input output is introduced into the control relay, while the first power output of the second transistor is connected to the second power output of the first transistor, the second output of which is connected to the second main contact of the first electromechanical switch, while the input of the second transistor is connected to the second output of the system control transistors, and the output terminal of the second transistor is connected to the second input terminal of the monitoring relay. 2. An improved hybrid DC switching device comprising a first electromechanical switch having first and second main contacts, a control system of the first electromechanical switch having four input terminals and mechanically connected to the first electromechanical switch, and each terminal in the control elements and circuits means two wires, a second electromechanical switch having first and second main contacts, a second electromechanical control system a switch having four input terminals and mechanically connected to the second electromechanical switch, a transistor having two power terminals, one input and one output terminals, the transistor being turned on in forward direction with respect to the polarity of the DC voltage network, and the transistor control system having three input and one output terminal, a current relay having two power and one output terminal, including a button having one output terminal, a residual current device having three output terminals a, a disconnecting button having three output terminals, a monitoring relay having one input and two output terminals and an information block having one input terminal, wherein the first main contact of the first electromechanical switch is connected to the first pole of the DC voltage source and mechanically connected to the control system the first electromechanical switch, the second main contact of which is connected to the first power terminal of the current relay, the second power terminal of which is connected to the load connected to the second pole of the source dc voltage, with the first main contact of the first electromechanical switch connected to the first main contact of the second electromechanical switch, the second main contact of which is connected to the first power terminal of the transistor, the output terminal of the current relay is connected to the first input terminal of the control system of the first electromechanical switch, with a third input the output of the control system of the second electromechanical switch and with the third input terminal of the transistor control system, the output to the water of the enable button is connected to the second input terminal of the control system of the first electromechanical switch, the first output terminal of the protective shutdown device is connected to the third input terminal of the control system of the first electromechanical switch, the first output terminal of the disconnect button is connected to the fourth input terminal of the control system of the first electromechanical switch the control transistor is connected to the input terminal of the transistor, while the second output terminal of the device The protective shutdown is connected to the first input terminal of the transistor control system, the third output terminal of the protective shutdown device is connected to the first input terminal of the second electromechanical switch control system, the second output terminal of the disconnect button is connected to the second input terminal of the transistor control system, the third output terminal of the disconnect button is connected to the second the input terminal of the control system of the second electromechanical switch, the first output terminal of the monitoring relay is connected to the fourth by the second input terminal of the control system of the second electromechanical switch, the output terminal of the transistor is connected to the first input terminal of the monitoring relay, the second output terminal of which is connected to the input terminal of the information unit, characterized in that an additional fuse is provided having two power terminals and one output terminal, a second input terminal is introduced to the monitoring relay, while the first power terminal of the fuse is connected to the second power terminal of the transistor, the second power terminal of which is connected to the second an apparent contact of the first electromechanical switch, wherein the output terminal of the fuse connected to the second input terminal of the control relay. 3. An improved hybrid DC switching device comprising a first electromechanical switch having first and second main contacts, a control system of the first electromechanical switch having four input terminals and mechanically connected to the first electromechanical switch, and each terminal in the control elements and circuits means two wires, a second electromechanical switch having first and second main contacts, a second electromechanical control system a switch having four input terminals and mechanically connected to the second electromechanical switch, a transistor having two power terminals, one input and one output terminals, the transistor being turned on in forward direction with respect to the polarity of the DC voltage network, and the transistor control system having three input and one output terminal, a current relay having two power and one output terminal, including a button having one output terminal, a residual current device having three output terminals a, a disconnecting button having three output terminals, a monitoring relay having one input and two output terminals and an information block having one input terminal, wherein the first main contact of the first electromechanical switch is connected to the first pole of the DC voltage source and mechanically connected to the control system the first electromechanical switch, the second main contact of which is connected to the first power terminal of the current relay, the second power terminal of which is connected to the load connected to the second pole of the source dc voltage, with the first main contact of the first electromechanical switch connected to the first main contact of the second electromechanical switch, the second main contact of which is connected to the first power terminal of the transistor, the output terminal of the current relay is connected to the first input terminal of the control system of the first electromechanical switch, with a third input the output of the control system of the second electromechanical switch and with the third input terminal of the transistor control system, the output to the water of the enable button is connected to the second input terminal of the control system of the first electromechanical switch, the first output terminal of the protective shutdown device is connected to the third input terminal of the control system of the first electromechanical switch, the first output terminal of the disconnect button is connected to the fourth input terminal of the control system of the first electromechanical switch the control transistor is connected to the input terminal of the transistor, while the second output terminal of the device The protective shutdown is connected to the first input terminal of the transistor control system, the third output terminal of the protective shutdown device is connected to the first input terminal of the second electromechanical switch control system, the second output terminal of the disconnect button is connected to the second input terminal of the transistor control system, the third output terminal of the disconnect button is connected to the second the input terminal of the control system of the second electromechanical switch, the first output terminal of the monitoring relay is connected to the fourth by the second input terminal of the control system of the second electromechanical switch, the output terminal of the transistor is connected to the first input terminal of the monitoring relay, the second output terminal of which is connected to the input terminal of the information unit, characterized in that an additional thermistor with a positive temperature coefficient of resistivity is introduced, having two power terminals and one output terminal, and the second input terminal is introduced into the monitoring relay, while the first power terminal is connected to the second power terminal of the transistor d thermistor, a second power terminal connected to the second main terminal of the first electromechanical switch, wherein the output terminal of the thermistor connected to the second input terminal of the control relay.

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