RU2604205C1 - Electromagnetic polarized switch - Google Patents

Abstract

FIELD: blasting operations.

SUBSTANCE: invention is intended for use in automation systems of explosive objects. Electromagnetic polarized switch contains a case inside of which there are interacting magnetic and contact systems. Magnetic system consists of magnetic conductors with control windings, between which there is a clapper. Contact system consists of a contactor with ledges interacting with elastic contacts, arranged on the terminals arranged in the base of the case. Between the contact system and magnetic system two toothed sectors with ledges are installed. On the axis of the clapper there is a torsion spring with hook turn limiters. On the axis of contactor there is a gear wheel engaged with toothed sectors, interacting with one of its ledges when rotation of clapper with corresponding hook of a torsion spring. Initial moment provided by a torsion spring, exceeds the moment, required to turn the contactor when switching contacts.

EFFECT: technical result is increased resistance of the electromagnetic polarized switch to impact and vibration external effects and expansion of current ranges of switched electric circuits, which allows enlarging the application of the switch.

1 cl, 7 dwg

Description

The invention is intended for automation systems of explosive objects subjected to shock and vibration external influences.

Known electromagnetic polarized switch [and.with. USSR No. 452874, publ. 12/05/1974, IPC ¹ H01H 51/22], comprising a housing, in the inner cavity of which interacting magnetic and contact systems are installed, the magnetic system consists of magnetic circuits with control windings made on them, between which a rotary armature is installed, the contact system consists of a jumper with protrusions interacting with elastic contacts located on the current leads installed in the base of the housing.

The rotary armature of the known electromagnetic polarized switch located inside the magnetic system provides a small angle of rotation, which imposes restrictions on the contacts used, which must also have small contact gaps. This circumstance does not allow the use of such an electromagnetic switch, for example, for explosive objects subjected to shock, for objects that require switching electrical circuits with significant currents, that is, the scope of the known electromagnetic polarized switch is limited.

Known electromagnetic polarized switch [and.with. USSR No. 1024994, publ. 06/23/1983, IPC ³ H01H 51/22], comprising a housing in the inner cavity of which interacting magnetic and contact systems are installed, the magnetic system consists of magnetic circuits with control windings made on them, between which a rotary armature is installed, the contact system consists of a jumper with protrusions interacting with elastic contacts located on the current leads installed in the base of the housing.

The rotary armature of this electromagnetic polarized switch is located inside the magnetic system, provides a small angle of rotation, which imposes restrictions on the contacts used, which should have small contact gaps. The scope of the known electromagnetic polarized switch due to this circumstance is significantly limited.

Known electromagnetic polarized switch [RF patent No. 2529642, publ. 09/27/2014, IPC H01H 51/00], comprising a housing, in the inner cavity of which interacting magnetic and contact systems are installed, the magnetic system consists of magnetic circuits with control windings made on them, between which a rotary armature is installed, the contact system consists of a jumper with protrusions interacting with elastic contacts located on the current leads installed in the base of the housing.

The known technical solution allows to reduce losses in the magnetic system of an electromagnetic polarized switch and, as a result, slightly increase the angle of rotation and the created moment of rotation of the armature. However, in some cases this increase in the angle and moment is still not enough to implement a reliable contact system, for example with “cut-in” contacts, that is, the use of an electromagnetic polarized switch is also limited.

This electromagnetic polarized switch is considered as a prototype.

Currently, there are a wide variety of designs of electromagnetic polarized switches, but all of them, having certain disadvantages, do not fully fulfill the tasks set by the invention.

The problem to which the invention is directed is the creation of an electromagnetic polarized switch that provides increased angles and angles of rotation of the armature.

The technical result, the achievement of which the present invention is directed, is to increase the resistance of the electromagnetic polarized switch to shock and vibration effects and to expand the current ranges of switched electrical circuits, which allows to expand the scope.

The specified technical result is achieved by the fact that in the electromagnetic polarized switch containing the housing, in the inner cavity of which interacting magnetic and contact systems are installed, the magnetic system consists of magnetic circuits with control windings made on them, between which a rotary armature is installed, the contact system consists of a jumper with protrusions interacting with elastic contacts placed on the current leads installed in the base of the housing, according to the invention two gear sectors with protrusions are installed on the contact and magnetic systems, a torsion spring with limiters to turn its hooks is placed on the axis of the rotary armature, a gear wheel is installed on the bridge axis, which is engaged with gear sectors interacting with one of its protrusions when the armature is rotated with the corresponding hook torsion springs, while the initial moment provided by the torsion spring exceeds the moment required to rotate the switch when switching contacts.

Placement on the axis of the rotary anchor of the torsion spring with rotation limiters of its hooks, each of which interacts when the armature is rotated with the corresponding protrusion of one of the two gear sectors engaged with the gear wheel fixed on the axis of the bridge, providing the torsion spring with an initial moment exceeding the moment required to rotate the jumper when switching contacts, allows using the magnetic system with a small angle of rotation of the armature to provide an increased angle of rotation from the contact system’s switch, while eliminating the influence of the contact system switching time on the switching time of the magnetic system (arm rotation) and, as a result, eliminating the “hanging” of the swivel arm in an intermediate angular position between the poles of the magnetic system when switching (changing the state) of an electromagnetic polarized switch . The initial moment of the torsion spring provides a guaranteed turn of the switch and, as a result, reliable switching of the contact system in wide operating conditions. Providing an increased angle of rotation of the armature allows you to use a contact system with increased contact gaps, which increases the resistance of the electromagnetic polarized switch to shock and vibration and, accordingly, expands its scope. The increased angle of rotation of the armature allows the use of contacts with extended current ranges of switched electrical circuits, which also expands the field of application of the inventive electromagnetic polarized switch.

The presence in the claimed invention features that distinguish it from the prototype, allows us to consider it appropriate to the condition of "novelty."

New features that contain a distinctive part of the claims are not identified in technical solutions for a similar purpose. On this basis, we can conclude that the claimed invention meets the condition of "inventive step".

The invention is illustrated by drawings:

in FIG. 1 shows a longitudinal section through an electromagnetic polarized switch;

in FIG. 2 is a cross-sectional view Α-A in FIG. 1, the design of the electromagnetic system;

in FIG. 3 is a transverse section bB in FIG. 1, the design of the auxiliary contact system;

in FIG. 4 is a transverse section bb of FIG. 1, the design of the main contact system;

in FIG. 5 is a transverse section GG in FIG. 1, the initial state;

in FIG. 6 is a transverse section GG in FIG. 1, the intermediate state when switching;

in FIG. 7 is a transverse section GG in FIG. 1, switched state.

An electromagnetic polarized switch contains a housing made in the form of a casing 1 of non-magnetic material and a base 2. Interactive magnetic and contact systems are installed in the housing (Fig. 1).

The magnetic system consists of two symmetrically located magnetic cores 3, on which two control windings are made - working 4 and fender 5. Magnetic cores 3 are made of soft magnetic steel. Parts of the working 4 and fender 5 windings located on different magnetic cores 3 are connected in pairs in series, while the end of the part of the winding on the first magnetic circuit 3 is connected to the end of the part of the winding on the second. Permanent magnets 6 are fixed at each end of the magnetic circuits 3 (Fig. 1, 2).

Boards 7 and 8 of non-magnetic metal are attached to the magnetic cores 3, in the central holes of which a symmetrical rotary armature 9 is installed, made of magnetically soft steel in the form of a plate with pressed axes 10 and 11.

On the axis 10 of the anchor 9, a torsion spring 12 with hooks 13 and a limiter 14 with stops 15 are installed, preventing the turn of the hooks 13 of the torsion spring 12.

The contact system consists of a switch 16 with projections 17 and plates 18, which switch auxiliary 19 and main 20 contacts, respectively. The switch 16 is mounted on an axis 21 installed in the Central holes of the base 2 and the bracket 22, fixed in the internal cavity of the housing on the base 2. Contacts 19 and 20 are placed on the current leads 23 and 24 installed through insulators 25 in the base 2 (Fig. 3, 4 )

A gear wheel 26 is fixed on the axis 21, which is meshed with the gear sectors 27 with the protrusions 28 interacting with the hooks 13 of the torsion spring 12. The gear sectors 27 are fixed on the axes 29 installed in the holes of the board 7 and the bracket 22.

To reduce friction losses, all axes of the rotating elements of the switch construction are mounted on ball bearings.

An electromagnetic polarized switch operates as follows.

In the absence of voltage on the windings 4 and 5, the rotary armature 9 is drawn to the poles of the permanent magnets 6 through the magnetic cores 3, providing the initial or activated state of the polarized electromagnetic switch (Fig. 5).

When voltage is applied to the serially connected working windings 4, magnetic fluxes are created in them, causing suppression of the holding and amplification of the rotating magnetic fluxes of the permanent magnets 6 and, as a result, rotation of the armature 9 on the axes 10, 11 to the other poles of the permanent magnets 6. The limiter is rotated. 14, twisting a torsion spring 12 with an appropriate stop 15, which, with one of the hooks 13, rotates the corresponding gear sector 27 by the protrusion 28. The gear sector 27 rotates the gear wheel 26 together with the jumper Lemma 16. The protrusions 17, 16 Peremykatel auxiliary switches 19 and plates 18 - 20 main contacts. The electromagnetic polarized switch switches to the triggered state (Fig. 6, 7).

The presence of the protrusions 28 allows their rotation to make the necessary adjustments to the interface "gear sectors 27 - gear 26" and to provide the required interaction with the hooks 13 of the torsion spring 12 when assembling "in place".

The stops 15 of the limiter 14 during assembly allow them to be bent also to ensure adjustments "in place".

To avoid overheating of the working winding 4, the voltage is supplied through the opening auxiliary contact 19.

When voltage is applied to the series-connected breakaway windings 5, magnetic fluxes are created in them, causing suppression of the holding and amplification of the rotating magnetic fluxes of the permanent magnets 6 and, as a result, rotation of the armature 9 on the axes 10, 11 (already in the opposite direction) to the poles of the permanent magnets 6 . In this case, the stopper 14 is rotated, twisting the spring 12 with the corresponding stop 15, which with the other hook 13 rotates the corresponding gear sector 27 by its protrusion 28. The gear sector 27 rotates the gear wheel 26 ohms (in the opposite direction) along with 16 peremykatelem 16. Peremykatel protrusions 17 switches to the initial state auxiliary 19 and the plates 18 - 20 main contacts.

To avoid overheating of the fender winding 5, the voltage is also supplied through the corresponding opening auxiliary contact 19.

The angle of rotation of the jumper 16, compared with the angle of rotation of the armature 9, increases due to the difference in the radii (distances from the point of interaction to the axis of rotation) of the hooks 13 and protrusions 28, as well as the gear ratio in the meshing of the gear sectors 27 and the gear 26.

Torsion spring 12, which acts as a power (moment) limiter, eliminates the possibility of tooth decay in the gearing “the gear sector 27 - the gear wheel 26” with accelerated rotation of the armature 9 from the supply to the winding 4 or 5 of the maximum allowable voltage with an increased number of main contacts 20, and also eliminates the influence of the switching time of the contact system (rotation of the gear sector 27, the gear 26 and the jumper 16) on the switching time of the magnetic system (rotation of the armature 9) and, as a result, becomes active "freeze" the rotary armature 9 in an intermediate angular position between the poles of the magnetic system when switching (changing condition) polarized electromagnetic switch.

Due to the presence of a torsion spring 12, the contact system in some cases can switch already after the armature 9 is rotated. Moreover, in the process of switching between the stop 15 of the limiter 14 and the corresponding hook 13 of the torsion spring 12, an angular clearance “a” is realized (Fig. 6), which selected after completion of the switch (Fig. 7).

Thus, the use of the inventive electromagnetic polarized switch will provide an increased angle and the moment of rotation of the armature, at which the contacts can be spaced relative to each other at sufficient distances, which will increase resistance to shock and vibration, that is, significantly expand the possible areas of its application.

In addition, the increased angle of rotation of the bridge 16 allows you to open auxiliary elastic contacts 19, through which voltage is applied to the working 4 or fender 5 windings, in the final section of the angle of rotation of the bridge 16 (respectively, and the armature 9), that is, the generated torque at the armature 9 from voltage supply to the corresponding winding is provided on most of its rotation angle.

In the inventive electromagnetic polarized switch can be used "cut-in" contacts with two-way contact, providing switching and transmission of both small and high currents, which will also expand its field of application.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed invention:

- a tool embodying the claimed invention in its implementation, is intended for use in automation systems of explosive objects subjected to shock and vibration external influences;

- for the claimed device in the form as it is described in the independent claim, the possibility of its implementation is confirmed;

- a tool embodying the claimed invention in the implementation, is able to provide increased resistance of the electromagnetic polarized switch to shock and vibration and expansion of the current ranges of switched electrical circuits, which allows to expand the scope.

Therefore, the claimed invention meets the condition of "industrial applicability".

Claims (1)

An electromagnetic polarized switch containing a housing, in the inner cavity of which interacting magnetic and contact systems are installed, the magnetic system consists of magnetic circuits with control windings made on them, between which a rotary armature is installed, the contact system consists of a jumper with protrusions interacting with elastic contacts placed on current leads installed in the base of the housing, characterized in that between the contact and magnetic systems two teeth are installed of these sectors with protrusions, a torsion spring with rotation limiters of its hooks is placed on the axis of the rotary armature, a gear wheel is installed on the jumper axis, which is engaged with gear sectors interacting with one of its protrusions when the armature is rotated with the corresponding hook of the torsion spring, while the initial moment provided by the torsion spring exceeds the moment required to rotate the switch when switching contacts.

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