RU144394U1 - ELECTROMAGNETIC MAXIMUM DISCONNECTOR (OPTIONS) - Google Patents

Abstract

1. An electromagnetic maximum release containing current-carrying plates, a core, an anchor, characterized in that the core is made U-shaped and rigidly connected to the current-carrying plate, and the armature is a curved spring-loaded plate. An electromagnetic maximum release containing current-carrying plates, a core, an armature, characterized in that the core is made U-shaped and rigidly connected to a current-carrying plate, and the armature is a plate inseparably connected to a disconnecting rail attached to the housing.

Description

The utility model relates to electrical appliance construction, namely to electromagnetic maximum releases.

According to the application for the invention RU 78985, an electromagnetic trip device of a circuit breaker is known, comprising a magnetic circuit with a magnetizing winding located on the frame, an armature interacting with a moving pusher, which is spring-loaded relative to the magnetic circuit and acts on the rail of the free trip mechanism, characterized in that it contains a magnetic circuit made of upper and lower parts, free trip mechanism, made in the form of a system of pivotally connected levers connecting buttons including switching and disconnecting a switch with a movable contact, as well as an output terminal and a terminal with which it is electrically connected to the wire of a three-phase electric circuit through a thermal release

The disadvantages of the known release are the complexity and high metal construction.

Closest to the claimed technical solution is the combined electromagnetic maximum release known from the patent RU 2039389, comprising a magnetic core in the form of a bracket, an armature, a core, a disconnecting spring and a winding, where the core is made with an internal cavity bounded from one end of the core by its wall with a hole, and from the opposite end a sleeve of non-magnetic material with a hole, the sleeve is placed in the threaded hole of the core, a ferromagnetic plunger with a push rod is installed in the core cavity s of a nonmagnetic material, wherein between the end face of the plunger and the nonmagnetic sleeve arranged introduced compression spring and pushers protrude on both sides beyond the core and set a working gap relative to the anchor and the actuator.

The disadvantages of the known release are the complexity and high metal construction.

The technical result of the claimed utility model is to reduce the metal consumption and simplify the design.

The technical result is achieved in that in an electromagnetic maximum release containing current-carrying plates, a core, an armature, according to the first embodiment of the utility model, the core is made U-shaped and rigidly connected to a current-carrying plate, and the armature is a curved spring-loaded plate.

The technical result is also achieved by the fact that in the electromagnetic maximum release containing current-carrying plates, the core, the armature, according to the second embodiment of the utility model, the core is made U-shaped and rigidly connected to the current-carrying plate, and the armature is a plate inseparably connected to the disconnecting rail, attached to the body.

The implementation, according to the first and second variants of the utility model, of a core with a U-shape and rigidly connected to a current-carrying plate, allows to exclude from the design a magnetization coil and a magnetic circuit that create a magnetic field, due to the fact that the U-shaped core is not closed between it and the armature , when passing through the core of the current, an electromagnetic field appears and they are attracted to each other, thus simplifying the design and reducing its metal consumption.

The execution, according to the first embodiment of the utility model, of an anchor in the form of a curved spring-loaded plate allows the pusher to be excluded from the structure, since the anchor acts on the disconnecting rail at one end and interacts with the core at the other end, which simplifies the design and reduces its metal consumption.

The implementation, according to the second embodiment of the utility model, of an anchor in the form of a plate, one-piece connected to the trip rail, allows to exclude from the design "intermediary elements" between the electromagnetic release and the trip mechanism of the circuit breaker, such as a pusher and staples that transmit movement from the anchor to the trip rail , while two elements are combined into one part, which simplifies the design. In this case, the armature plate is soldered into a trip rail made of dielectric material. The claimed implementation of the anchors and rails, which, in fact, are one part, simplifies its installation in the housing during assembly of the device.

The essence of the claimed utility model is illustrated by the drawings:

In FIG. 1 shows the electromagnetic maximum release, made according to the first embodiment of the utility model.

In FIG. 2 shows the electromagnetic maximum release, made according to the second embodiment of the utility model.

An electromagnetic maximum release containing current-carrying plates 1, core 2, anchor 3, bimetal plate 4, where core 2 is made U-shaped and rigidly connected to current-carrying plate 1, according to the first embodiment, the armature 3 is a curved plate, spring-loaded with a spring 5 attached, the anchor 3 is fixed with its central part to the current-carrying plate by means of bent stops, one end of the arm interacts with the core, and the other with the disconnecting rail, according to the second option, the armature 3 pre resents a plate fixedly connected to the tripping rack 6 attached to the housing 7.

When short-circuit currents flow through an electromagnetic release made in the first embodiment, the armature, made in the form of a curved spring plate, interacts with the core with one end and acts on the rail of the trip mechanism with the other free end (not shown).

When short-circuit currents flow through an electromagnetic release made in the second embodiment, the armature, one-piece connected to the trip rail, interacts with the core at one end, and interacts through the free trip with the other free end fixed in the trip rail. The anchor returns to its original position due to the spring mounted on the axis of the trip rail.

Claims (2)

1. The electromagnetic maximum release containing current-carrying plates, core, anchor, characterized in that the core is made U-shaped and rigidly connected to the current-carrying plate, and the anchor is a curved spring-loaded plate. 2. An electromagnetic maximum release containing current-carrying plates, a core, an armature, characterized in that the core is made U-shaped and rigidly connected to a current-carrying plate, and the armature is a plate inseparably connected to a disconnecting rail attached to the housing.