SU1003188A1 - Device for switching power electric circuits - Google Patents

Description

The invention relates to the remote control of power electrical circuits, in particular, to the design of a device for switching power electrical circuits, and can be used in various industries for selectively switching a large group of power electrical circuits. A device for switching high-voltage equipment is known, comprising contacts located circumferentially on a fixed panel, an electromagnetic actuator whose executive member rotates around an axis passing through the center of this circle and the perpendicular plane of the contacts, and also reciprocates along this axis . The device also contains a switching node, which is rigidly connected to the executive body of the electric drive and commuting the contacts when the electric drive is activated. In this device, on the cortex of the electromagnet, which is the executive body, there is mounted a copier in the form of a coupling, on a cylindrical surface of which a variable depth groove is made, in which a pin mounted on the body of the electromagnet C 11 moves. other auxiliary switching elements in the management of a group of power electrical circuits, since it does not allow the selective inclusion of individual circuits, eliminates the possibility of belt-on all circuits and does not provide zero protection. It is also known a device for switching electrical circuits, containing main contact pairs formed by fixed contacts located around the insulating panel and moving contacts, auxiliary contact pairs for switching control circuits of the device, mechanisms for individual switching of contact pairs, provided with last-state locking devices. The device also contains a contactor having at least one protrusion acting on the mechanisms for activating contact pairs, rotating an electromechanical drive, the shaft of which passes through the central hole in the insulating panel and which ensures the rotation of the contactor by a given angle. The device is equipped with an electromagnetic actuator having an electromagnet for closing the contact pairs, on the hollow bark of which, covering the shaft of the electromechanical actuator, the specified closure is fixed and which ensures the movement of the contactor along this shaft during the closing of the contact pairs. An electromagnetic actuator also has electromagnets for opening contact pairs, one of which is structurally made similarly to an electromagnet for closing contact pairs and sets the contact contact breaker in motion, and the other triggers when the electrical energy of the opening is removed. at the same time, all contact pairs provide zero protection. This device allows, when using a common drive for switching contacts in switched circuits, to selectively control a group of power electrical circuits and to bring switched circuits into a state in which one or more circuits of this group would be switched on. This ensures a significant reduction in the number of elements required for switching the specified group of circuits (for example, the number of electromagnets involved in switching the power circuits is halved). In addition, the presence in the device of a node that sets the angle of rotation of the switch and the breaker and provided with additional contacts, makes it possible to carry out the monitoring of all switched circuits with a single relay before switching them on 2. However, the use of this device in electrical devices operating in hazardous areas, does not make it possible to fully utilize its fundamental advantages. Thus, the presence of separate disconnecting electromagnet and zero protection electromagnet complicates the design and industrial development of the device. Difficult to quickly switch off switched circuits, because

To do this, it takes a certain time to search for a contact pair corresponding to the circuit to be disconnected. In addition, this device is not implemented protection against loss of controllability.

For example, when an electromagnet is removed from the contact opening, the possibility of selectively disconnecting switched circuits is lost.

The purpose of the invention is to increase the reliability and security of switching of POWER electrical circuits. The goal is achieved by the fact that in the device for switching power electrical circuits, containing the main contact pairs formed by fixed contacts located around the circumference on the insulating panel, and moving contacts, auxiliary contact pairs for switching control circuits of the device, mechanisms for the individual activation of contact pairs are provided |, with latches of state of the latter, a contactor having at least one protrusion acting on the mechanisms for the activation of contact pairs, rotating Electromechanical actuator, the shaft of which passes through the central hole in the insulating panel and which rotates the switch at a given angle, an electromagnetic actuator having an electromagnet for closing the contact pairs, on the hollow crust of which surrounds the shaft of the electromechanical actuator. the specified contactor is fixed and which ensures the movement of the contactor along the specified shaft, as well as electromagnets for opening contact pairs, the number of electromagnets for opening contact pairs is equal to the number of contacts state clamps, and each of the electromagnets for opening contact pairs is connected to one of the state clamps contacts with the possibility of opening the corresponding contact pair.

A group of auxiliary contact pairs may be associated with electromagnets for opening contact pairs with the possibility of switching the latter when the said electromagnets are triggered. Electromagnets for breaking contact-pairs can be made in the form of zero-voltage releases with the possibility of affecting the contact state clamps when the voltage is removed from the coils of these electromagnets. The part of the auxiliary contact pairs associated with the electromagnets for opening the contacts can be included in the control circuit of the rotating electromechanical actuator. The coils of the disconnecting electromagnets of the clamps of the contact state are selected with parameters that provide intrinsically safe switching. The proposed implementation of the devices provides quick, reliable and quick disconnection and emergency shutdown of any of the switched power circuits in the event of a fault in the control circuit or in the electromagnet for opening the contacts, thereby providing protection against loss of controllability and improvement of the device’s performance. Smart on the device height in height. In the case when the group of auxiliary X contact pairs is connected with electromagnets for opening contact pairs with the possibility of commutation of the latter when these electromagnets are triggered, there is no need to use intermediate relays, since the electromagnet for opening contacts connected to the auxiliary contact pairs is functionally identical to these ften. FIG. 1 shows a device for switching power circuits in a disconnected state, a vertical section; in fig. 2 — latch of contact pair; in fig. 3 sections AA, BB and B. In fig. one; in fig. t is a control circuit for power circuits using the proposed device. The device for switching electric power circuits comprises four panels each made in the form of a disk. On the upper insulating panel 1 (FIG. 1), fixed contacts are arranged evenly around the circumference. In this case, vacuum arcing chambers are used as the main contact pairs 2. The number of contact pairs 2 is determined by the number of switched circuits. The described version of the device is designed to control fifteen single-phase power electrical circuits. The movable contacts 3 of the contact pairs 2 are connected by flexible conductors 4 to buses 5 and 6, interconnected by jumpers 7 (Fig. 3). Tires are connected to contact sockets 8 (Fig. 1), designed to connect the device to the mains. The pins from the fixed contacts 9 contact pairs 2 are also made in the form of contact sockets 10. Tires 5 and 6 are mounted on an intermediate insulating panel 11. On its lower side, mechanisms 12 are fixed to enable contacts, the number of which is equal to the number of contact pairs 2. Each of the mechanisms 12 It includes a housing 13 in which a pivoting arm 14 is mounted, mounted on an axis 15 and provided with a pressure roller 16. Lever I and through a sleeve 17 a hairpin .18 is connected with a movable contact 3.. On the upper side of the intermediate panel 11, clamps 19 of the contact pairs are fixed. The latch 9 is a cylindrical body 20 comprising a spring-loaded rod 21 with a roller 22 and a latch 23 mounted in the recess of the body 20 on the 2k axis and provided with a return spring 25. The ball bearing is used as a roller 22 to reduce friction ball bearing 26. The rod 21 in its outer part is equipped with a pressure plate 27, designed for. acting on the microswitch 28, used as auxiliary contacts and mounted on the upper insulating panel 1. The spring 29 of the clamp 19 is intended to act through the rod 21, the sleeve 17 and the pin 18 on the movable contact 3 of the contact pair 2. Each clamp 19 is connected to an electromagnet 30 for uncoupling contact pairs (Fig. 2), designed to act on the latch 23 by means of a rod 31 with a spring 32 connected to the core of the electromagnet 30, Each electromagnet 30 is provided with a microswitch 33t acting as an auxiliary nyh contacts and interacts with the rod 3. Fig. 1, the electromagnet is shown in the disconnected position. The position of the parts of the latch 19 with the contact pairs turned on (the cocked position is shown in Fig. Z. In the proposed device, the electromagnets are made in the form of zero releasers. Other versions of these electromagnets are possible, for example, in the form of independent releasers. An electromagnet 35 is installed on the insulating panel 11 solenoid type for zamy | kani contact pairs. Due to the presence of clamps 19, the coil 36 of the electromagnet 35 is designed to work in a short-term mode and therefore has small dimensions. Anchor 37 electr Bended 35 is made in the form of a hollow cylinder, on one end of which is a slot 38 and a lock 39 is rigidly fixed. Closure 39 is provided with kG protrusions that are acting with levers 14 Projection 40 depends on the number of simultaneously switched circuits and their type (multiphase, single-phase, direct current circuits) In the proposed device, designed to operate in single-phase circuits, the contactor 39 contains one protrusion. The armature 37 is equipped with a return spring 41. The drive shaft 42 is placed in holes made in the contactor 39 of the housing and the bark of the electromagnet 35, and mounted in ball bearings 43, located on the top insulating panel 1 and the bottom panel 44. The drive shaft 42 is connected to the bark 37 by means of a pin 45 passing through the slot 38 and the measles 37. Thanks to this design, rotation is provided the closure 39 together with the shaft 42 and the translational movement of the closure 39 with the core 37 when the electromagnet 35 is actuated.

A device for switching electric power circuits is equipped with a rotating electromechanical actuator 46, which provides rotation of the drive shaft 42 at a predetermined angle. The magnitude of this angle is determined by the position of the switched contact pair (vacuum, 1

30 for opening contact pairs, transformer 74, Stop buttons, diodes 81.-86, resistors 87-92, auxiliary contacts of electromagnets for opening contact pairs, auxiliary contacts of microswitches 28 of switching mechanisms, disconnecting contacts 105-110 8 of the camera on panel 1) . In the described embodiment of the device, the drive b comprises an electric motor 47 with a gearbox, the shaft of which is connected via a coupling half with a setting device t9 supporting the rotation angle of the drive shaft k2, which is necessary for finding the contact pair to be switched. The driver 9 is made in the form of a bracket 50 interacting via rollers 51 mounted on it with directional switches 52 placed around the circumference in the housing 53. The number of rollers 51 is determined by what is needed to construct a circuit for controlling the number of simultaneously switched contacts. The driver 50 of the driver is mounted on the coupling half 5 mounted in a ball bearing 55 and rigidly connected to the drive shaft C2. The driver is mounted on the upper metal panel 5b and connected to the drive shaft 42 by means of a key 57. Connection of panels 1, 11, kk and 5b between themselves carried out through three studs 58, placed around the circumference symmetrically about its center. A device for switching electrical circuits is provided with a threaded cylinder 59 designed to (fix the device in the shell of an electrical apparatus and mechanically act on it to ensure the connection of the contact sockets 8 and 10 with the contact fingers of a counter panel (not shown). The matching of the sockets with the contact fingers provided by catchers 60. The device is also equipped with a plug connector 61 for connecting control circuits to it. eskimi chains. For the purpose of simplicity only shows six control circuit chains. FIG. 4 marked Start buttons 62-67, 68-73 coils of electromagnets

limit switches, closing contacts 111-116 of limit switches power circuit components; Not shown.

The circuit uses a parallel connection of coils of electromagnets 30 to the transformer winding, in which the coil parameters are selected so that the flow of alternating current through the coil does not trigger the electromagnet, to activate it the coil must be eased by a diode brought into the console.

The device works as follows.

When one of the 62-6 Start buttons is pressed, for example 62, the coil 68 of the electromagnet 30 is powered along the circuit: the secondary winding of the transformer 7 the coil 68 - the button 62 - the button 75 Stop - the coil 68 - the secondary winding of the transformer 7.

The electromagnet 30 is triggered in this case, attracts its measles and thus prepares the lock for the platoon. Due to the resistor 87 shunting the button 62, the electromagnet 30 remains on after releasing the button 62, i.e. this electromagnet is switched to self-pickup mode. Instead of resistors 87-92, you can turn on the power contacts of the power circuit and also implement self-pickup mode. When tripping electromagnet 30 is triggered, it acts on microswitch 33 and thereby closes its auxiliary contacts 93, which supply power to the electric motor along the circuit: secondary winding of transformer 7A - contacts 93 disconnecting auxiliary contact 99 (or microswitch 28) disconnecting contact 105 of limit switch 52 - motor +7 secondary transformer winding 7.

i

The motor starts to rotate and drives the drive shaft 2. When the roller 51 reaches the limit switch 52, the corresponding button and the contact pairs are set, the limit switch switches, its contacts 105 open and disconnect the motor kj, and the closing contacts 111 of the same limit switch simultaneously The secondary coil of the transformer 7 is switched on by the coil of the electromagnet 35 via a rectifying bridge 117. At the same time, the electric motor stops, the electromagnet 35 is actuated, and the associated motor The actuator 39, acting on the lever 14, turns on the selected contact pair. At the very end of the stroke, the auxiliary contact 99 (or microswitch 28) opens, thereby de-energizing the coil 36 of the electromagnet 35.

From this point on, the device is prepared to search for and switch on other contact pairs as described above. The on state of each contact pair is fixed by latch 19 as follows. When the protrusion 40 closes on the end of the lever 1, the rod 21 connected to the lever rises upward, compressing the spring 29 and releasing the latch 23, which rotates around its axis under the action of the spring 25 and locks the rod 21 in this position (Fig. 2).

The process of disabling the specified contact pairs is as follows. Click one of the Stop buttons. In this case, the power supply circuit is interrupted by one of the coils 68-73 of electromagnets 30, the latter is disconnected, and thanks to the return spring 32 with its bark, through the rod 31, it acts on the latch 23 of the retainer 19, opening the specified contact pair. At the same time, one of the auxiliary contacts is opened, thereby preparing the given circuit to the possibility of its subsequent switching on. At the same time, one of the auxiliary contacts 99-10 (microswitches 28) closes, also preparing the set target for the next switching on. After the button is released, Stop Electromagnet 30 is not re-enabled due to the presence of one of the resistors 87-92 in the circuit, i.e. the control circuit is broken.

For emergency or emergency disconnection of all consumers, you need to press the button 118 Total stop, which breaks the power supply circuit of all. The coils of the tripping electromagnets, as a result of which all main contact pairs are disconnected, and the electromagnet 7 and coils of the electromagnet 35 are de-energized.

Claims (2)

Zero protection of all groups of power contacts is carried out in the same way: when the network voltage disappears or decreases, they all turn off under the influence of coils 68-73 of electromagnets 30. The control circuits with coils 68-73 are made intrinsically safe thanks to the use of individual high-resistance secondary windings of the transformer 7 parallel to the inclusion of coils 68-73, the corresponding selection of their parameters: resistance and inductance. The same circuits have the property of self-monitoring of control circuits due to diodes 81-86 delivered to the remote control post. When a control circuit is closed or it is broken or the resistance of the circuit is increased, the electromagnets 30 are turned off if they were turned on, and they cannot be turned on by pressing buttons b2-b7 if they were turned off. It is possible and non-intrinsically safe execution and connection of these circuits, as well as execution without monitoring their integrity. The use of the device in the national economy will allow to obtain a significant economic effect. Thus, using the device only in explosion-proof control stations will significantly reduce metal consumption, labor intensity, weight, dimensions and cost of control stations such as SUV-350, SUV-1L-100, SUV-2L-120 SUVS-700., SUV-600, SUV -11 40 and other similar devices. . Reducing the size and cost of control stations is achieved as a result of the fact that the proposed device takes up about 3 times less space than the required group of contactors, as a result of which the consumption of materials and the complexity of the device shell are also reduced, and, moreover, use of control units (with an intermediate relay), since for each contactor one unit is required. The use of the device is associated with energy savings, since to keep the contacts in the on position it is not necessary that the switching coils be continuously energized, as in contactors. In addition, the device uses only one switching coil for a group of switched circuits, which for a very short 1 88 12 period of time is under voltage. Claims. 1, A device for switching power electric circuits, containing main contact pairs formed by fixed contacts located around the insulating panel and moving contacts, auxiliary contact pairs for switching device control circuits, mechanisms for the individual switching of contact pairs, equipped with state fixtures of the latter, a contactor having at least one protrusion acting on the mechanisms of the inclusion of contact pairs, rotating electromechanical drive shaft cat through the central hole in the insulating panel, which provides rotation of the contactor at a given angle, an electromagnetic actuator having an electromagnet for closing contact pairs, on the hollow bark of which, covering the shaft of the electromechanical actuator, the specified contactor is fixed, allowing the contactor to move along the specified, shaft, a Also electromagnets for breaking contact pairs, characterized in that, in order to increase the reliability and safety of switching power circuits, the number of el ktromagnitov for opening the contact pairs is the number of clamps state contacts, wherein the armature of each of the electromagnets for opening the contact pairs is associated with one of the retainers state of contacts with the possibility of unlocking the respective contact pair. 2. The device of claim 1, so that the group of auxiliary contact pairs is connected with electromagnets for opening contact pairs with the possibility of commuting these contact pairs when said electromagnets are triggered. 3. The device according to claim. 1 and 2, the fact that the electromagnets for opening contact pairs are made in the form of zero voltage releases with the ability to act on the clamps of the contact state when the voltage is removed from the coils of these electromagnets. 1310 k. Device by nn. 1-3, in that a part of the auxiliary contact pairs connected to the electromagnets for opening the contact pairs is included in the control circuit of the rotating electromechanical actuator. 5. A device according to claims 1- +, characterized in that the coils of the disconnecting electromagnets of fiks / 7 Z4 / 4/5 26 I contactors of the contact state are selected with parameters that provide intrinsically safe switching. Sources of information taken into account in the examination 1. The author's certificate of the USSR W, cl. H 01 H 43/02, 1971. 2.Assignment of the USSR on application. f 2195531, cl. H 01 H 43/02, 1975. 47 45 59 I I I 6/7 p n p n p 2 Phage.Z