SU736205A1 - Threshold switch - Google Patents

Description

The invention relates to electromagnetic elements of automation, designed to turn on the circuit during overload.

Known threshold automation devices 5 containing an inertial magnetically conductive mass in the form of a ball, which, under the action of an overload exceeding the specified value from the amplitude and duration, breaks 10 from the support element and acts on the contacts, closing or opening them. The return of the inertial mass to its original position is carried out using the magnetic field of a permanent 15 magnet, an electromagnet or due to the strength of an elastic element, such as a spring, and contacts. as a rule, they also switch, returning to the initial state [1].

However, the device switches only one circuit, which for many automation schemes is insufficient. Other disadvantages are that the resetting of the movable contact 25 to its original state is carried out only by means of a push button.

Is also an insulating device known? a base on which a rectangular permanent magnet is installed, located with a gap between the V-shaped branches of the armature, which can oscillate around its axis of rotation within the gap between the magnet and the V-shaped branches. In addition to the indicated branches, the anchor has springy ends of the branches, which give it a ^ -shaped shape. The axis of rotation of the armature is located at the intersection of the branches. Relative to the axis of rotation, the anchor is balanced. A contact is established on one of the V-branches, and a contact is established opposite to it. On a flat spring. A conductor is mounted on another V-shaped branch. The electrical connection between the conductor and the contact is due to the V-shaped 20 branches.

In the springy ends of the arm branches there are coaxial holes through which the rod passes with a gap. Insulating caps and cylindrical compression springs (2] are mounted symmetrically from the ends of the branches on the rod.

However, in order to control the device with forces less than 30, the anchor holding force by a permanent magnet, it is necessary to increase the distance from the axis of rotation of the armature to the axis of the rod, which increases the dimensions of the device, and the V-shaped shape of the armature does not allow rational use of the constant flow magnet and apply the control winding, • in addition, the magnetic flux of a permanent magnet and a switched current simultaneously flow through the armature, which reduces the stability of the parameters.

The closest in technical essence and the achieved result to the proposed one is a threshold switch containing a housing and a guide sleeve in which a magnetically conducting ball is mounted with free movement, a permanent magnet is located on one end of the sleeve, and a contact control mechanism is located on the other end of the sleeve node and contact node (3].

In some on-board automation schemes, it is required to ensure that the fact of reaching the threshold value of the overload for a long time is memorized, regardless of the further change in the overload and without generating additional energy consumption. In the known device, in order to maintain the on state of the contacts, regardless of the further change in overload, it is necessary that current flows through the winding. The disadvantage is the limited stability of the circuit breaker to vibration, shock, linear influences, especially directed perpendicular to the longitudinal axis of the magnetically controlled contact bulb / The switching capabilities of loads, especially inductive ones, are also limited. • Magnetically controlled contacts specially designed for switching high current loads have significant dimensions and weight.

The purpose of the invention is the expansion. functionality of the threshold switch.

This goal is achieved by the fact that in the threshold switch containing the housing and the guide sleeve, in which a magnetically conducting ball is installed with the possibility of free movement, a permanent magnet is located at one end of the sleeve, and a contact assembly control mechanism and a contact assembly are located at its other end, the control mechanism of the contact node is made in the form of a disk with a membrane spring fixed on it with two pairs of arcuate plates bent at an acute angle, the ends of which are turned towards the contact node, as a contact node, as a contact node, a polarized relay is used. with a rotary arm equipped with protrusions and a bar having windows and fixed stops, one pair of diametrically opposite ends of the arcuate plates made .. abutting the protrusions of the armature, and the other pair of arcuate plates rests against motionless emphasis.

Figure 1 shows a threshold switch, a longitudinal section; figure 2 is a view of the membrane spring and the disk from the contact node. In Fig.Z is a view of the polarized electromagnetic relay from the location of the fixed stops and protrusions of the armature.

The threshold switch contains a ball L of magnetically conductive steel, a permanent magnet 2 in the form of a ring, the direction of magnetization of which coincides with the longitudinal axis of the switch. The magnetic core 3 is attached to the end face of the permanent magnet using a non-magnetic stop 4, made in the form of a rivet with a cylindrical head.Non-magnetic washers 5 are installed under the head of the non-magnetic stop, which serve to adjust the pressure of the ball against the end of the non-magnetic stop. A magnetic circuit 6 is made to the pole of the permanent magnet from the side of the ball, made in the form of a ring with a conical hole and facing one end of the sleeve 7, The sleeve 7 of non-magnetic conductive material is a guide for the free movement of the ball 1 and the disk 8 mounted on its other end. A stop 9 is installed in the center of the disk with a gap from the ball. A membrane spring 11 is mounted on the disk with rivets 10 and has two pairs of arcuate plates symmetrically bent at an acute angle in the direction of the contact assembly. There are gaps between the opposite ends of the arcuate plate and the disk opposite of these gaps there are windows exceeding the width of the specified gaps.

; A polarized electromagnetic relay is connected to the contact node control mechanism by a rotary armature 12 mounted between four magnets 13, which are connected by ends to poles 14 and magnetic circuits 15, The poles are connected in pairs by cores 16 to control windings 17, which are electrically connected to each other. The magnetic system of a polarized electromagnetic relay is connected in a single unit by means of a bracket 18 and a rack 19. This relay is used as a contact node. The pivots of the swivel armature enter the holes available in the bar and rack. The axial play of the swivel armature is adjusted using washers 20 ,.

There are two windows on the bar, into which protrusions 21 are made integrally with the anchor. On the diametrically opposite sides of the windows, two fixed stops 22 are installed in the bar.

Two diametrically located annular spring plates with their Ends abut against the fixed stops, and the other two - into the protrusions of the rotary armature.

On the rack side, a ring 23 is attached to the rotary anchor, in which the pushers 24 are fixed.

• The stand is connected to the panel 25, in the openings of which the terminals 27 are installed using sealed glass insulators 26. Fixed contacts 28 and movable contacts are connected to the terminals

29. The solutions and contact dips are adjusted by means of flexible pushers.

The structural elements are placed inside a non-magnetic casing

30, which compresses them in the direction of the longitudinal axis and hermetically welded flanging with the panel.

The threshold switch operates as follows.

With a directed overload threshold and a certain duration, the force holding the ball 1 at the end of the non-magnetic stop 4 becomes less than the force determined by the expression Fuj where is the force acting on the ball;

- mass of the ball;

and - acceleration.

The ball rolls with acceleration along the sleeve 7, selects kinematic energy and, by hitting the stop 9, moves the disk 8, bending the annular plates of the spring 11 until it is incompletely straightened between the ends of the disk and the bar 18.

The protrusions 21 and the fixed stops 22 do not interfere with the movement of the disk 8, as they pass through the windows of the disk without touching it. When straightening symmetrically bent from the end of the disk ring of the output plates of the spring 11 there is a decrease in the gap between the opposite ends of the plates,

In the process of moving from the initial state to compression of the annular plates of the spring 11 between the ends of the disk 8 and the strap 18, the ball 1 performs the work of overcoming the forces of attraction of the ball to the non-magnetic stop 4 created by the magnetic flux of the magnet 2, the forces necessary for the deflection of the annular plates of the springs 11; forces holding the rotary anchor 12 at the poles 14 created by the magnetic fluxes of the magnets 13; and friction forces.

Since the two diametrically opposite ends of the annular plates of the spring 11 abut against the fixed stops 22, and the other two against the protrusions 21 of the rotary armature 12 of the polarized electromagnetic relay, reducing the gap between these ends leads to the rotation of the disk 8 together with the spring 11 and the rotary armature 12.

For reliable operation of the device, the amount by which the gap between the ends of the spring plates _ 11 decreases is consistent with the dependence of the force ⁵ attracting the rotary armature 12 to the poles 14 so that the force acting on the ball 1 is transmitted to the rotary armature 12 through the disk. 8 with a spring 11 until the rotation of the armature 12 to another pair of poles 14 starts due to the forces created by the magnetic fluxes of the magnets 13. Together with the armature 12, the pushers 24 are rotated, which switch contacts.

Regardless of the further action of the overload, the rotary armature and contacts remain in the on position due to the forces created by the magnetic fluxes of the magnets 13.

After reducing the overload to a certain value, the ball 1 returns to its original state both due to the forces created by the magnetic flux of the permanent magnet 2, and due to the elastic forces of the annular plates of the spring 11.

To return the contacts of the 3Q device to its initial state, one of the windings 17 must be supplied with a direct current pulse of the corresponding polarity and (Duration.

The control windings 17 can be used to turn on and off the device contacts, both under the influence of various overloads and in normal, normal conditions.

The protrusions can be performed separately .. from the rotary armature 12 with their subsequent attachment, but this complicates the assembly of the structure, especially with small dimensions.

In addition to the indicated .. magnetic system of a polarized electromagnetic relay, others can also be used with a rotary armature, the axis of rotation of which can be parallel to the axis of rotation of the guide sleeve (or to align the axis). The most optimal of the known ones is the chosen magnetic system, since in it the direction of magnetization of the permanent magnets and their location in the structure protect 55 of them from the influence of external magnetic fields and ferromagnetic masses, which increases the stability of the characteristics of the device as a whole.

In addition to the indicated magnetic system for holding the ball in its initial state, it is possible to apply others containing a guide sleeve.

The threshold switch is operable for any acute bending angle 65 of the arcuate plates of the spring 11.

Ί

However, when the bending angle is less than 53 ^{e, the} linear displacement of the disk is always greater than the amount of reduction in the gap between the ends of the annular plates of the spring 11.

The disk 8 with the spring 11 acts as a transmitter! Of the kinetic energy of the ball 1 to the rotary armature 12, therefore, when the angle of bending of the ring plates of the spring 11 is less than 53 ^{, the} force transmitted by the rotary armature is more than the force acting in the direction of linear movement of the disk by so many times , how much the linear displacement of the disk is greater than the value, reducing the gap between the ends of the annular plates of the spring 11, provided that the friction losses and deflection of these annular plates are neglected.

Since the force linearly moving the disk 8; proportional to the mass of the ball 1, then, in order to reduce its mass, and, consequently, the mass and dimensions of the device as a whole, ceteris paribus, the bending angle of the ring 'plates of the spring 11 should be no more than 53 ° from the end face of the disk 8.

Due to the fact that after the threshold switch is activated, the armature of the polarized electromagnetic relay is kept on due to the forces created by the magnetic fluxes of permanent magnets of the Relay, the fact that the threshold value of acceleration is reached is remembered by the device at any time without the consumption of electricity. At the same time, turning on and off the contacts of the device can be performed at the required time; by applying a pulse of DC voltage of a certain polarity, duration and amplitude to the control windings of a polarized electromagnetic relay at the required time.

The proposed device provides a wider range of switching loads; increasing immunity to interference in the form of accelerations, vibrations, shocks directed perpendicularly to the longitudinal axis of the device; improving the conditions for switching current loads by contacts in connection with their relay operation; weight reduction.

The conclusions are confirmed by the test results of the prototype device.

Claims (3)

This invention relates to electromagnetic automation elements intended for switching circuits in case of overload. Threshold automatic devices are known that contain an inertial magnetically conductive mass in the form of a ball that, under the action of an overload exceeding a predetermined value from amplitude and duration, is detached from the supporting element and acts on the contacts, closure or opening them. The inertial mass is returned to its original position by means of a magnetic field of a permanent magnet, an electromagnet, or due to the force of an elastic element, for example, a spring, and the contacts also return to their original state 1. However, the device switches only one circuit that for many automation schemes is insufficient. Another disadvantage is that the 41-0 return of the movable contact to the initial state is carried out only by means of a push button. It is also known a device containing an insulating core on which a permanent rectangular magnet is mounted, disposed with a gap between the V-shaped branches of the core, which can oscillate around its axis of rotation within the gap between the magnet and the V-shaped branches. In addition to these branches, measles has spring ends of branches that give it an h-shape. The axis of rotation of the core is located at the intersection of the branches. Relative to the axis of rotation, measles is balanced. A contact is made on one of the V-branches, and the opposite is a contact spring installed on a flat spring. A conductor is installed on the V-shaped branch. The electrical connection between the conductor and the contact is made by the V-shaped branches. In the spring ends of the branches of the bark there are coaxial holes through which the rod passes with a gap. Insulating caps and compression cylindrical springs 2 are installed symmetrically from the ends of the branches. However, in order to control the device with forces smaller than the force holding the core by a permanent magnet, it is necessary to increase the distance from the axis of rotation of the core to the axis of the rod , which increases the gab of the device, and the V-shaped form of the core does not allow rational use of the flow of a permanent magnet and apply a control winding, moreover, the magnetic flux of a constant magnet simultaneously flows through the core. switching current, which reduces the stability of the parameters. The closest to the technical essence and the achieved result is the noporoBiiffi. switch, comprising a housing and a guide sleeve, in which a magnetically conducting ball is mounted with the possibility of free movement, with a single end of the sleeve the magnet and, on the other end of it, the control unit of the contact unit and the contact unit 3 are located. In some onboard circuits of the automatics, it is necessary to ensure that the fact that the threshold is reached the load over time will be irrespective of the further change of the overload and the non-production of Additional Electricity consumption. In the known device, in order to maintain the on state of the contacts regardless of the further change of the overload. It is necessary that a current flow through the winding. The disadvantage is that the limited resistance of the switches to vibration, shock, linear effects, especially directionally perpendicular to the longitudinal axis of the flask of the magnetically controlled contact; The switching capacities of loads, especially inductive ones, are also limited. Magnetically controlled contacts specially designed for switching overcurrent loads have considerable dimensions and weight. The purpose of the invention is the expansion of the functionality of a threshold switch. This goal is achieved by the fact that in a threshold switch containing and a guide sleeve in which a magnetically conducting ball is installed with free movement, a permanent magnet is located at one end of the sleeve, and a contact control mechanism is located at its other end. knot and contact knot, the control knot of the contact knot is made in a de disk with a two-pair diaphragm spring fixed on it, bent at an acute angle of the arcuate layer whose ends are turned to the side of the contact knot, as The contact node, as a contact node, is used a polarized relay. With a rotary bark, equipped with projections and a bar having windows and fixed stops, one pair of diametrically opposite condies of the arcuate plates are made abutting the protrusions of the core, and the other pair of arcuate plates abut in fixed stops. 1 shows a threshold switch, a longitudinal section; figure 2 is a view of the membrane spring and the disk from the side of the contact node. Fig. 3 is a view of the polarized electromagnetic relay from the side of the stationary stops and the protrusions of the core. The threshold switch contains a ball 1 of magnetically conductive steel, a permanent magnet 2 in the form of a ring, the direction of magnetization of which coincides with the longitudinal axis of the switch. The magnetic core 3 is attached to the end of the permanent magnet using a non-magnetic stop 4, made in the form of a rivet with a cylinder head. Under the head of the non-magnetic stop are non-magnetic washers 5, which serve to adjust the force of pressing the ball to the end of the non-magnetic stop. Magnetic circuit 6, made in the form of a ring with a tapered bore and facing the same end of the sleeve 7, is attached to the pole of the permanent magnet. non-conductive material is a guide for. free movement of the ball 1 and the disk 8 installed from the other end. An emphasis 9 is installed in the center of the disk with a clearance from the ball. On the disk, a membrane spring 11 is fastened with rivets 10, having two pairs of arcuate plates bent at an acute angle in the direction of the contact node. Between the opposite ends of the arcuate spring plates there are gaps, and in the disk opposite these gaps there are windows exceeding in width the specified gaps,; A polarized electromagnetic relay 12 mounted between four magnets 13, which are connected to poles by ends, is connected to the control mechanism of the contact node. 14 and magnetically: y) gadfly 15, the poles are connected in pairs by cores 16 with control windings i7, which are electrically connected - between each other. The magnetic system of a polarized electromagnetic relay is connected to a single unit by means of a strip 18 and a rack 19. This relay is used as a contact node. The trunnion trunnions enter the holes in the bar and the stand. The axial play of the rotary core is adjusted with the help of washers 20 ,. On. There are two windows in the plank, in which the protrusions 21 are made, which are made in one piece with the rim. On the diametrically opposite sides of the windows, there are two movable stops 22 in the plank. Two diametrically arranged annular spring plates abut their fixed ends with the ends, and the other two in the projections of the rotary box. A ring 23 is attached to the pivot bark from which the pushers 24 are fixed. The rack is attached to the panel 25, in the holes of which pins 27 are fixed by means of sealed glass insulators 26. The pins contain fixed contacts 28 and movable 29. Adjustment solutions and contact dips are produced by flexible pushers. The structural elements are placed inside the non-conductive casing 30, which compresses them in the direction of the longitudinal axis and is hermetically welded and flared to the panel. The threshold switch operates as follows. With a directed threshold value not overload and a certain duration, the force holding the ball 1 to the end of the nonmagnetic stop 4 becomes less than the force determined by the expression. where is the force acting on the ball; - the mass of the ball; and - acceleration. The ball with acceleration rolls along the sleeve 7, chooses kinematic energy and striking the stop 9 moves the disk 8, deflecting the ring plates of the spring 11 to incomplete straightening between the ends of the disk and the bar 18. The projections 21 and the fixed stops 22 do not prevent the movement of the disk 8, such as pass through the windows of the disk without being in contact with it. When the annular plates of the spring 11, which are bent from the disk end face symmetrically bent from the disk, the gap between the opposite ends of the plates decreases. In the process of moving from the initial state to the compression of the ring plates of the spring 11 between the ends of the disk 8 and the bar 18, the ball 1 performs work to overcome the forces of attraction of the ball to the non-magnetic stop 4 created by the magnetic flux of the magnet 2, the forces required to deflect the ring plates of springs eleven; the forces holding the rotating bark 12 at the poles 14 created by the magnetic flux of the magnets 13; and friction forces. Since the two diametrically opposite ends of the annular plates of the rod 11 rest against the fixed stops 22 and the other two against the protrusions 21 of the rotary box 12 of the polarized electromagnetic relay, the gap between these ends decreases the disk 8 with the spring 11 and the rotary korem 12. For reliable operation of the device of sizes a, by which the gap between the ends of the plates of the spring 11 is reduced, is matched with the force dependence, attracting the rotating bar 12 to the poles 14 in such a way that the force acting on the ball 1 are rotary armature 12 by the disk 8 with the spring 11 as long as the rotation of the armature 12 to the other pair of the poles 14 will begin to occur due to the forces produced by the magnet's magnetic flow 13. Together with the armature 12 are rotated pushers 24, which switch contacts. Regardless of the further action of the overload, the rotary measles and contacts remain in the switched on position due to the forces created by the BaetNttJx magnetic flux of the magnets 13. After reducing the overload to a certain value, the ball 1 returns to its initial state as due to the forces created by the magnetic flux constant magnet 2, and due to the elastic forces of the ring plates of the spring 11. To return the contacts of the device to the initial state, one of the windings 17 must be fed a DC pulse of the corresponding polarity and Call duration. The control windings 17 can be used to turn the device contacts on and off, both under different overload conditions and under normal conditions. The projections can be made separately from the pivot core 12 and then connected, but this complicates the assembly of the structure, especially with small dimensions. In addition to the indicated .. magnetic system of a polarized electromagnetic relay, 1 "yugut is applied and yes). Pivoting measles, the axis of rotation of which can be positioned parallel to the axis of rotation of the guide sleeve (or aligned axes). The best known one is the chosen magnetic system, since in it the direction of magnetization of the permanent magnets and their arrangement in the structure maximally protect them from the influence of external magnetic fields and ferromagnetic masses, which increases the stability of the characteristics of the device as a whole. In addition to the above-mentioned magnetic system of holding the ball in the initial state, others can be used that contain a guide sleeve. The threshold switch is operational at any acute bending angle of the arcuate plates of the spring 11. However, when the bending angle is less than 53, the linear movement of the disk is always greater than the amount of reduction of the gap between the ends of the ring plates of the spring 11. The disk 8 with spring 11 acts as a transmitter: the kinetic energy of the ball 1 pivot bore 12, therefore, when the angle of the bend of the annular plates of the spring 11 is less than 53, the force transmitted to the pivot bark is greater than the force acting in the direction of the linear movement of the disk by as many times as linear emeschenie, the disc greater than the reduction of the gap between the ends of the annular spring plate 11, with the proviso that lossy friction and deflection of the annular plates lrenebregayut Since force is linearly traveling disk 8; proportional to the mass of the ball 1, in order to reduce its mass, and, consequently, the mass and dimensions of the device as a whole, ceteris paribus conditions, the angle of the bend ring. spring plates 11 should be no more than 53 ° from the end of the disk 8. Since the threshold switch is triggered, the polarized electromagnetic relay is held in the on state due to the forces generated by the magnetic flux of the permanent magnets of the specified relay, the fact when the acceleration threshold value is reached, it is memorized by the device at any time without the cost of electricity. At the same time, switching on and off device contacts can be made at the required moment; time by applying a DC voltage pulse of a certain polarity, duration, and amplitude. to the control windings of a polarized electromagnetic relay at a desired point in time. The proposed device provides a wider range of switching loads; increasing the resistance to interference in the form of perpendicularly directed to the longitudinal axis of the device accelerations, vibrations, impacts; the improvement of the conditions for switching current loads by contacts in connection with their ruler actuation; decrease in weight and dimensions. confirmed by the test results of the prototype device. The invention includes a threshold switch comprising a housing and a guide sleeve in which a magnetically conductive ball is mounted for free movement, a permanent magnet is mounted at one end of the sleeve in: the housing, and a contact node at its other end , characterized in that, in order to expand the functionality, the control mechanism of the contact unit is made in the form of a disk with a membrane spring fixed on it with two pairs bent under a sharp, angle arcuate plate n, the ends of which are turned towards the contact node, a polarized relay with a rotary bark, fitted with projections and a bar, having windows and fixed stops, one pair of diametrically opposite ends of the arcuate plates abutting the bores of the core and another arcuate plates rests on fixed stops. Sources of information taken into account in examination 1, Japan Patent according to application 50-14345, H 01 H 35/02, 1975. 2. The patent of France No. 1550954, H 01H, 1973. 3. Patent SDPA 3737599, 200-61. .45, 1973 (prototype).