RU67332U1 - AUTOMATIC SWITCH VA 57-43 - Google Patents

Abstract

The automatic switch VA57-43 relates to low-voltage electric devices, namely, to low-voltage automatic switches, designed to turn on and / or turn off the current and protect electric circuits from overcurrents. The device contains a main cover 1; lids 1, 2, 3, 4, 5; block of maximum releases 6; base 7; free trip mechanism 8, controlled by handle 9. The contact system in each pole is divided into two main contacts 10 and 11, and one arcing contact 12 having an arcing chamber 13, mounted movably on a bracket 14, electrically connected in parallel by means of a flexible connection 27. Cover 1 made with grooves 15 for setting free contacts to perform the function of signaling the position of the main contacts 10 and 11, grooves 16 for making free contacts for performing the function of signaling automatic off openings, by a groove 31 for installation of an independent release or an undervoltage release (at the request of the client), made in one dimension. The free trip mechanism 8, controlled by the handle 9, consists of levers 17, shafts 18, 19, 20, 21, levers 22, 23, 24. A stand 25 is mounted on the bracket 14, levers 26 are fixed on the shaft of the lever 17. This embodiment of the proposed utility model allows to obtain an increase in the current rated maximum breaking capacity of the circuit breaker without increasing its overall, installation and connection dimensions due to the unified design of the device of the free trip mechanism and contact system, covers and base I for different types of maximum releases and additional assembly units. 5 ill.

Description

The utility model relates to low-voltage electric devices, namely, to low-voltage circuit breakers, designed to turn on and / or turn off the current and protect electric circuits from overcurrents.

A circuit breaker is known (RF patent No. 2095875, IPC ⁷ H01H 73/48, op. 1997.11.10), comprising a housing with a cover, a free trip mechanism with a rail, a contact system with arcing chambers, thermal and electromagnetic overcurrent releases in each pole, in addition, the thermal release is electrically connected to the electromagnetic one, and the electromagnetic release is electrically connected to the moving contact of the contact system by a flexible current lead. In addition, the current path of each pole is bifurcated, one part of it is rigidly fixed to one of the releases, and the other part passes bypassing the release, and is rigidly fixed to the node following the release, both parts of the current supply being electrically connected in parallel.

The disadvantages of the known technical solutions include the following.

With an increase in the rated current, there is an increased release of power, and, consequently, heat on the contact system. To ensure normal heat generation, it is necessary to increase the cross section of the current lead, and as a result, increase the drive mechanism of the switch.

The closest in technical essence to the claimed device is a circuit breaker (patent 53815 U1, op. 2006.05.27, IPC H01H 73/48 H01H 75/00 - prototype), comprising a housing with a cover, a mechanism for free tripping with a rail, a contact system with interrupter cameras, thermal and electromagnetic overcurrent releases in each pole, in addition, the thermal release is electrically connected to the electromagnetic one, and the electromagnetic release is electrically connected to the moving contact of the contact system with a flexible conductor, different characterized in that it contains two mechanisms of free trip, interconnected by a rail and controlled by one common handle, a contact system in each pole, divided into two parallel parts, each of which has its own arcing system, while there is one thermal release for each pole, The electromagnetic overcurrent release has a conductor made in the form of a flat bus connected to the parallel part by means of a flexible connection.

The disadvantage of such automatic circuit breakers is that with an increase in the currents of the maximum breaking capacity and the rated operating maximum breaking capacity flowing through the circuit breaker, it is necessary to increase the overall dimensions of the arcing chambers with a contact system and, as a result, the overall dimensions of the circuit breaker.

The utility model is based on the task of creating an automatic circuit breaker design, in which the possibility of using unified maximum releases and additional assembly units is achieved, as well as increasing operational reliability for a multi-pole circuit breaker design.

Technical result: increasing the current rated maximum breaking capacity of the circuit breaker without increasing its overall, mounting and connecting dimensions due to the unified design of the device of the free trip mechanism and contact system, covers and base for different types of maximum releases and additional assembly units.

This is achieved due to the fact that in a circuit breaker containing a base in the form of a housing with a cover, a free trip mechanism, a contact system with arcing chambers, overcurrent releases, electrically connected to the moving contact of the contact system by a flexible current lead, free trip mechanisms interconnected and controlled by one common handle, a contact system in each pole, divided into parts, an arcing system, while the overcurrent release has a current The gadget connected to the parallel part by means of a flexible connection is new in that it contains a main cover having slots for installing free contacts, which perform the functions of signaling the position of the main contacts, grooves for installing free contacts that perform the functions of signaling automatic shutdown, a groove for installation additional releases, made in the same dimensions, the block of maximum releases. The free trip mechanism is controlled by a handle, while the contact system in each pole is divided into two main contacts and one arcing contact having an arcing chamber, mounted movably on a bracket, electrically connected in parallel by means of a flexible connection. In addition, the main cover contains a groove for installing an independent release or undervoltage release.

The essence of the utility model is presented in figures 1-5.

Figure 1 shows the automatic switch VA57-43, section, side view.

Figure 2 is the same, local section, side view;

Figure 3 is the same, local section, front view,

Figure 4 is the same, local section, front view,

Figure 5 is the same, local section, rear view.

The positions in the figures indicate: main cover 1; covers 2, 3, 4, 5; overcurrent releases previously assembled into a functional unit in the form of a unit 6; base 7; free trip mechanism 8, handle 9; pins 10 and 11; arcing contact 12; arc chamber 13; bracket 14; grooves 15; grooves 16; lever 17, shafts 18, 19, 20, 21, levers 22, 23, 24; stand 25; levers 26; flexible connection 27; groove 28; bracket 29; spring 30; groove 31, cell 32 (for installing an independent release or undervoltage release).

The device comprises a housing consisting of a cover of the main 1, covers 1, 2, 3, 4, 5; overcurrent releases previously assembled into a functional unit in the form of a unit 6; base 7; free trip mechanism 8, controlled by handle 9. The contact system in each pole is divided into two main contacts 10 and 11, and one arcing contact 12 having an arcing chamber 13, mounted movably on a bracket 14, electrically connected in parallel by means of a flexible connection 27. Cover 1 the housing is made with slots 15 for installing free contacts (not shown in FIG.) to perform the function of signaling the position of the main contacts 10 and 11, grooves 16 for making free contacts (not shown in FIG.) for eniya automatic disconnection alarm function, a groove 31 for installing an independent release or undervoltage release (optional) made in one envelope. The free trip mechanism 8, controlled by the handle 9, consists of levers 17, shafts 18, 19, 20, 21, levers 22, 23, 24. A rack 25 is mounted on the bracket 14, levers 26 are fixed on the shaft of the lever 17.

When free contacts are installed in the grooves 16, the impact on them occurs during the operation of one of the releases, which turn the levers 22 and 23, disengaging the lever 17 and the shaft 19. Having disengaged, the lever 17 rotates the lever 26 rigidly fixed on its axis, which affects free contacts. When cocking the free trip mechanism 8, the lever 17 engages with the shaft 19, thereby the lever 26 returns to its original state. Thus, an automatic shutdown alarm function is achieved.

Installation of an independent release (or undervoltage release) is performed in the groove 31 so that the control levers of these releases are in the groove 28.

The operation of these releases is as follows.

When the release is activated, one of its control levers rotates the lever 23, thereby causing the mechanism 8 of the free trip, and the opening of the contacts of the main circuit. When cocking the mechanism 8 of the free trip, there is an impact of the bracket 29 of this mechanism on another control lever of these releases, bringing them to their original position.

The installation of overcurrent releases, pre-assembled into a functional unit in the form of a unit 6, is performed between the main cover 1 and the cover 3.

When installing overcurrent releases, for example, of the PTM type (thermomagnetic release), the lever 22 is engaged, when the RTM is activated, the lever 22 rotates, disengaging the shaft 21, thereby disengaging the lever 17 and shaft 21, causing the mechanism to trip 8 free tripping. When cocking the mechanism 8 of free disengagement, the lever 17 acts on the spring 30, rigidly mounted on the lever 22, turning it, and thereby there is a platoon of RTM and bringing it to its original state.

When the overcurrent releases are triggered, for example, type RE (electronic release), the lever 23 is affected, causing it to rotate. The lever 23 acts on the shaft 20, disengaging it from the lever 22, the lever 22 is rotated, disengaging from the shaft 21, thereby disengaging the lever 17 and the shaft 19, causing the triggering mechanism 8 to free release. When cocking the free trip mechanism 8, the lever 17 acts on the spring 30, rigidly mounted on the lever 22, turning it, and thereby engaging it with the shaft 20. The handle 9 acts on the lever 24, which restores the RE and the lever 23.

Claims (3)

1. The circuit breaker, comprising a housing in the form of a base with a cover, a free trip mechanism, a handle for controlling the free trip mechanism, a contact system at each pole, divided into two parallel parts with arcing chambers, overcurrent releases, electrically connected to the movable contact of the contact system flexible conductor, while the overcurrent release has a conductor connected to the parallel part by means of a flexible connection, characterized in that The whisker is made in the form of a main cover, the contact system at each pole is divided into two main contacts and one arcing contact, additional trip units are installed, or undervoltage releases made in the same dimensions, overcurrent releases are pre-assembled into a functional unit in the form of a block, and then installed in the switch, the main cover has slots for installing loose contacts that perform the functions of signaling the position of the main contacts, grooves for installing with free contacts that perform the function of an automatic shutdown alarm. 2. The automatic switch according to claim 1, characterized in that the main cover contains a groove for installing an independent release. 3. The automatic switch according to claim 1, characterized in that the main cover contains a groove for installing the undervoltage release.