RU167449U1 - Electromagnetic contactor - Google Patents

Abstract

The utility model relates to the field of electrical engineering, namely to low-voltage electric devices, and can find application for remote control of electric drives, turning on and off electric power receivers, including DC motors with parallel and series excitation. The technical result consists in reducing the overall dimensions while improving the ease of maintenance of auxiliary and boost contact systems. To do this, in the electromagnetic contactor, the additional contact system is made in the form of separate modules of the auxiliary contact system and the boost contact system installed on opposite ends of the contactor, while the traverse of the auxiliary contact system is movably engaged with the armature through an additional lever fixed to it. 5 ill.

Description

The utility model relates to the field of electrical engineering, namely to low-voltage electric devices, and can find application for remote control of electric drives, turning on and off electric power receivers, including DC motors with parallel and series excitation.

Known electromagnetic switching apparatus according to patent RU No. 142947 U1, which is the closest analogue of the proposed technical solution, taken as a prototype. The known device comprises a U-shaped support bracket, an electromagnet with a rotary anchor, a housing in which a support bracket and an electromagnet are mounted, a crosshead with movable main contacts of the bridge type, contact pads with fixed main contacts, the ends of which are brought out to the side faces of the contact pads, fixed auxiliary and force contacts fixed on insulating blocks, an arcing chamber.

The main disadvantage of the prototype is its large dimensions, due to the fact that the movable contacts of the auxiliary contacts are mounted on the main traverse carrying the main contacts along its length, and therefore the device’s overall length increases, while the contact servicing complexity is difficult, because if necessary, maintenance (cleaning, replacement) of one of the additional auxiliary or force contacts requires disassembly and assembly of the entire product as a whole.

The technical result of the proposed technical solution is to reduce the overall dimensions while improving the ease of maintenance of the electromagnetic contactor.

The technical result of the proposed technical solution is achieved by the fact that in an electromagnetic contactor containing a U-shaped supporting bracket, an electromagnet with a rotary armature, a housing in which a supporting bracket and an electromagnet are installed, a traverse with movable main contacts of a bridge type, a contact block with fixed main contacts the ends of which are brought out to the lateral sides of the contact block, fixed auxiliary and force contacts fixed on insulating blocks, an arcing chamber y, an auxiliary contact system module has been introduced, containing an auxiliary contact beam, carrying movable auxiliary contacts of a bridge type, symmetrical insulation pads with fixed auxiliary contacts, a forced contact system module, containing a forced contact beam cross-section, forcing flat contact springs fixed to the circuit board in insulating pads, an additional lever is also introduced, mounted on a rotary anchor with the possibility of a movable hook electromagnet captive with cross auxiliary contact system, the input modules mounted on opposite ends of the housing.

The essence of the technical solution of the utility model lies in the fact that the implementation of the additional contact system in the form of separate modules of the auxiliary contact system and the boost contact system and the installation of these modules on opposite ends of the contactor housing allows to reduce the length of the main beam with movable main contacts and, accordingly, the length of the entire contactor while improving serviceability of auxiliary and boost contact systems.

The design of the proposed technical solution is illustrated by the drawings depicted in:

FIG. 1 - electromagnetic contactor, isometric view;

FIG. 2 - electromagnetic contactor, front view;

FIG. 3 - module auxiliary contact system;

FIG. 4 - module forcing contact system;

FIG. 5 - electromagnetic contactor, top view.

The electromagnetic contactor contains a U-shaped support bracket 1, an electromagnet consisting of yoke 2, cores 3, retracting coils 4, a rotary armature 5, a traverse of the main contacts 6 with movable main contacts 7 of the bridge type, a contact block 8 with fixed main contacts mounted on it 9, the auxiliary contact system 12 and the boost contact system 13. The bearing bracket 1, the anchor 5, the yoke 6 are pivotally connected to each other. The bearing bracket 1 with the contactor construction elements mounted on it is fixed in the housing 10, made in the form of a rectangular parallelepiped with a base, at the corners of which there are holes for mounting the contactor. The fixed main contacts 9 are made in the form of brackets with soldered contact parts. The conclusions 11 of the fixed main contacts are made in the form of flat tires and brought into open grooves on the side faces of the contact block 8.

Auxiliary and boost contact systems are made in the form of modules 12 and 13 and are installed on opposite ends of the housing 10.

The auxiliary contact system module 12 comprises a secondary contact system traverse 14 supporting the movable auxiliary contacts 15 of the bridge type, symmetrical insulation pads 16 with fixed stationary auxiliary contacts 17. The auxiliary contact system traverse 14 is movably engaged with the armature 5 through an additional lever 18 fixed thereon.

The forced contact system module 13 comprises a forcing contact system traverse 19, forcing flat contact springs 20 fixed to the circuit board 21. The forcing contact system traverse 19 is pressed by the spring 22 to the end of the main contact beam 6 and acts on the forcing flat contact springs 20.

The electromagnetic contactor operates as follows. In the initial position, the closing contacts are in the open state. When voltage is applied to the control circuit (to the switching coils 4), the armature 5 is attracted to the cores 3, which leads to the movement of the yoke 6 with the movable contacts 7 and their closure with the stationary contacts 9. At the same time, the yoke 14 of the auxiliary contact system is movably coupled to the armature 5 through an additional lever 18 fixed on it, and the movable auxiliary contacts 15 are closed with the fixed contacts 17. If there is voltage at the input terminals of the main contacts and the load is connected, for example, an electric motor contact, to the output contacts is its inclusion. When the voltage in the control circuit is turned off, the armature 5 moves away from the cores 3, the contacts open, and the load is disconnected from the network.

The implementation of the additional contact system in the form of separate modules of the auxiliary contact system and the boost contact system installed on opposite ends of the contactor made it possible to achieve a tight arrangement of the apparatus and, therefore, reduce overall dimensions while improving the convenience of servicing the auxiliary and boost contact systems.

The manufacture of contactor samples for rated currents of 25, 63 and 100 A according to the stated technical solution and performance tests confirmed the effectiveness of the technical solution.

Claims (1)

An electromagnetic contactor comprising a U-shaped support bracket, an electromagnet with a rotary armature, a housing in which a support bracket and an electromagnet are mounted, a traverse with movable main contacts of the bridge type, a contact block with fixed main contacts, the ends of which are led to the side faces of the contact block, fixed auxiliary and forcing contacts mounted on insulating blocks, an arcing chamber, characterized in that the auxiliary contact system module is introduced, containing supporting auxiliary contact beam, carrying movable auxiliary contacts of the bridge type, symmetrical insulating blocks with fixed auxiliary contacts, and a forced contact system module containing a forced contact beam cross-section, forcing flat contact springs fixed on the mounting plate in insulating blocks, an additional lever is also introduced, fixed on a rotary anchor with the possibility of movable meshing of the electromagnet with the traverse of the auxiliary link tnoj system, wherein the input units mounted on opposite ends of the housing.

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