RU2444079C2 - Mechanism with two fixed positions and electric control device comprising this mechanism - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: mechanism with two fixed positions comprises a driving unit (4), made as capable of sliding displacement between rear and front positions, and capable to retain the unit (4) in one of its positions after effecting the force for sliding displacement. The mechanism comprises facilities of the unit (4) return, a traction rod (21), comprising a sliding contact (35), and a cam surface (37), along which the sliding contact moves (35) and from which the central section (40) protrudes, a cam track comprising the first path and the second path for the sliding contact (35) and arranged around the section (40). The mechanism also comprises locking facilities that cover access to the second path for the sliding contact. The track is made as flat, and locking facilities comprise a branch (67) of a spring, which, when unloaded, is arranged crosswise to the track at the connection between the first path and the specified second path. The invention also relates to the electric control device, comprising the specified mechanism.

EFFECT: simplified manufacturing of the mechanism and its increased service life.

28 cl, 7 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to a mechanism with two fixed positions.

In particular, the present invention relates to a mechanism that comprises a drive unit configured to slide in sliding between the rear position and the front position and to hold the unit in the front position after being subjected to an effort to move the slide in the direction from the rear position to the front position produced by the unit when he is in the back position, and holding him in the back position after a similar action to move the slip produced on the site when he tries ditsya in its forward position.

BACKGROUND OF THE INVENTION

The specified mechanism can be used for various purposes, for example, in locking doors or covers, or in electrical switching devices, which are controlled by successive pressing the drive unit. This type of mechanism, when used in an electrical control device containing terminals, allows you to connect or disconnect the terminals by controlling the movement of the drive unit to the rear position or to the front position.

In particular, a mechanism is known whose assembly is moved by a magnetic circuit made in the form of a coil, one plate of which is movable and connected to the assembly. This mechanism comprises a thrust mounted rotatably on the assembly. The rod contains a curved free end, forming a sliding contact. The mechanism also comprises a heart-shaped cam comprising a portion around which a cam path is made in which the sliding contact moves from the rear position to the front position and vice versa.

The passage of the sliding contact around the section is divided into a first path between the rear position and the front position and a second path different from the first path between the front position and the rear position.

The sliding contact is subjected to a force causing it to move in the necessary direction.

In order to prevent the sliding contact from moving in the wrong direction in the rear position, locking means are provided comprising a spring that presses the sliding contact against the cam surface, while the cam surface comprises a locking cutout made by connecting the two paths.

At the end of the second path, the sliding contact rises along the inclined side of the cutout, reaching the top, after which the sliding contact is on the first path in the rear position pressed against the straight side of the cutout, which does not allow the sliding contact to go on the second path. This solution, which allows you to direct the sliding contact along the correct path by acting on it in the transverse direction and towards the surface of the cam, is quite satisfactory. But since the thrust is a thin metal rod, and the cam is made of plastic, the cam wears out as the thrust is pressed against it. As a result, frictions arise that the magnetic circuit must overcome for the normal movement of the sliding contact.

The implementation of the free end of the sliding contact of the appropriate geometric shape will allow you to find a compromise between the action of significant friction during blocking and the negative impact of friction when moving the sliding contact along the cam path, however, this requires complex machining of the end of the thin rod.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a mechanism of a similar type, which is easy to manufacture and / or has improved characteristics.

The problem according to the present invention is solved by creating a mechanism with two fixed positions, containing a drive unit configured to move in the sliding direction by sliding between the rear position and the front position, while the mechanism is configured to hold the drive unit in the front position after acting in the direction from rear position to the front position produced on the drive unit when it is in the rear position, and with the possibility of holding the drive unit in the rear position after acting in the direction from the rear position to the front position produced by the drive unit when it is in the forward position, the mechanism comprising means for returning the specified unit configured to impact the said unit in the direction from the forward position to a rear position, a rod containing a proximal end associated with the drive unit, and a distal end containing a sliding contact, and a cam surface along which the sliding nth contact and from which the central portion and the recess protruding opposite the temple formed by said region protrude, the sliding contact being in the temple in the front position when the drive unit is in its front position and closer to the tip of the section opposite the temple in the rear position, when the drive unit is in its rear position, while around the plot made cam path for sliding contact, which contains the first path on the first side of the plot and the second path to W on the other side of the section, while the sliding contact is exerted by force, at least when it is opposite the recess, transversely to the direction of movement by sliding from the first side of the section to the second side of the section, while the mechanism further comprises locking means blocking access to the second path for sliding contact in its rear position so that during exposure to move from the rear position, the sliding contact enters the first path, the mechanism is characterized in that the cam the path is made flat, the locking means comprise a spring branch, which in the absence of load is located transversely to the cam path at the connection between the first path and the second path.

Thus, constant contact between the cam surface and the sliding contact is not necessary, therefore, the geometric requirements for the end of the sliding contact are not strict. On the other hand, the absence of strong pressure on the cam surface provides a longer service life of the mechanism.

According to the distinguishing features, it is extremely simple and preferable both in manufacturing and in use:

said branch in the absence of load is in contact with the first part of the section bounding part of the second path and forms a stop for sliding contact in its rear position opposite the second part of the section bounding part of the first path and forming together with the first part said sharp end,

the mechanism comprises a spring for acting on the sliding contact, at least when it is opposite the recess, transverse to the direction of movement by sliding from the first side of the section to the second side of the section,

the rod is mounted to rotate on the drive unit with its proximal end, while the spring is made with the possibility of impact on the rotary rod,

the spring contains a branch, which is part of the locking means, and another branch, designed to act on the traction, while both branches are arranged in the form of a compass and are connected to each other by a wound core,

the spring is held by means of fasteners located outside the cam path, with the free end of each branch opposite the core and the fasteners located on both sides of the cam path,

fastening means comprise a cylindrical stand around which a core is wound;

the other branch has a fixed end located close to the place on the cam path corresponding to the rear position of the sliding contact, so that it has an inoperative position in which it is transverse to the cam path and to the section, while the other branch is between the sliding contact in the rear position and the recess , and the working position in which it is located at a distance from the site, while the other branch is made with the possibility of movement by rotation around the fixed end from the idle position in e rs position and to act on a sliding contact force transverse to the direction of sliding movement, in a direction from the first portion side to the second side portion, at least when it is opposite the notch,

in the rear position of the sliding contact, both branches are located on both sides of the pin made in the specified area, while the other branch abuts the pin, and the sliding contact is in contact with the branch and at the same time is at a distance from the other branch,

the recess comprises a first inclined section and a second inclined section, which are generally inclined with respect to the direction of movement by sliding and into which the sliding contact abuts, respectively, in the first intermediate position and in the second intermediate position, while the sliding contact passes the first path from its rear position to its front position, passing through its first intermediate position, and the sliding contact passes the second path from its front position to its rear position passing through its second intermediate position, while the sliding contact passes from its rear position to its second intermediate position after exposure to sliding movement applied to the drive unit, while the sliding contact passes from its first intermediate position to its forward position and from its the second intermediate position to its rear position with the help of another branch and with the help of returnable funds,

being in its rear position, during exposure to slide along the first path, the sliding contact moves to its first intermediate position, overcoming the force of the other branch, and when the drive unit is moved by sliding using return means in the direction from the front position to the rear position, the sliding contact moves from the first intermediate position to its forward position,

during the action of sliding movement, starting from its front position, the sliding contact moves to its second intermediate position, overcoming the force of the other branch, and when the drive unit is sliding-shifted by means of returning means from the front position to the rear position, the sliding contact is subjected to force transverse to the direction of movement by sliding, from another branch on one part of the second path, after which it moves, overcoming the force of the branch, locking means lying to its rear position on the other side of the second path,

the mechanism further comprises a first side wall and a second side wall, respectively restricting the first path and the second path, the second side wall comprising a step opposite the recess, the thickness of which essentially corresponds to the distance between the two branches transversely to the cam surface,

transverse to the cam surface, the distance separating the cam path and the branch belonging to the locking means is less than the distance between the cam path and the other branch,

both branches are connected to each other by means of a wound core that is outside the cam path outside the wall restricting the first path, while the free ends of the branches are outside the cam path outside the wall limiting the second path in the rear position of the sliding contact,

the rod is a rod, the distal end of which is made curved, forming a sliding contact.

The object of the present invention is also an electrical control device, characterized in that it contains two terminals in the box, a magnetic circuit and a mechanism according to any one of the preceding paragraphs, the mechanism being located between the terminals, connecting or disconnecting them electrically, and controlling the movement of the drive unit between its rear position and its forward position is carried out by a magnetic circuit in response to an electrical impulse supplied to the terminals of the magnetic circuit, while the drive unit contains electrically conductive contacts made with the possibility of coming into contact with the terminals in the forward position of the drive unit and interrupting contact with the terminals in the rear position of the drive unit.

According to distinguishing features, extremely simple and preferred both in manufacture and in use

the magnetic circuit comprises a coil containing a hollow central block around which an electric wire is wound, a fixed plate located at one end of the block, and a movable plate located at the other end of the block,

each plate has an E-shape and contains a base, from which three branches extend parallel to each other: one central branch and two branches located each at the corresponding end of the base, with the plates located opposite each other, the free ends of each branch of one plate are opposite the ends of each corresponding branch of another plate,

the central branch of the fixed plate is located in the hollow space bounded by the block, while its two other branches are located on both sides of the block,

the movable plate is made to move along the direction of movement by sliding between the inoperative position in which the free end of its central branch is in the hollow space, and the rest of the central branch is outside the unit, and the working position in which its central part is in the hollow space and in wherein the movable plate is in contact with the fixed plate;

on both sides of the toe there is a first bottom section and a second bottom section, wherein the toe contains a first inclined section and a second inclined section, which generally have a slope relative to the sliding direction and which slide contact abuts, respectively, at a distance from the first bottom section in the first intermediate position and at a distance from the second bottom section in the second intermediate position, wherein the plate is in the working position when the sliding contact is in its first intermediate position or in its second intermediate position,

the box contains a housing having a hole on the outer wall, and the device contains a handle covering part of the movable plate and containing a button for the manual drive of the device protruding from this wall through the hole,

the handle comprises at one end a U-shaped cutout configured to engage a finger therein, means for connecting the handle to the movable plate at its opposite end, and a rotary shaft located between the cutout and the means of connection,

the device comprises a shaft support, fixed relative to the block and configured to install a rotary shaft, wherein the drive unit includes a finger configured to go into the cutout so that the rotary movements of the handle, movement movements along the direction of movement by sliding the movable plate or drive unit were interconnected with each other,

at the end opposite the finger, the drive unit contains a protruding hollow section, open on its two sides and containing the spring of the section installed, starting from the bottom of this section, in the direction from the rear position to the front position towards the upper wall of the section, as well as a platform that is located transversely to the site and only the ends of which are outside the site and each of the two ends of which contains contact, while the spring acts in the direction of the upper wall,

in the rear position of the drive unit, both terminals are opposite and at a distance from two contacts, while the distance between the contacts and terminals is less than the stroke of the drive unit, and in the front position of the drive unit, the platform is at a distance from the bottom and from the upper wall of the section, and the spring of the section is compressed more than in the rear position of the drive unit,

the spring is held by means of fasteners located outside the cam path, while the fasteners comprise a cylindrical strut, the extreme part of which is adapted to be connected to the groove with the cylinder, which is part of the lid designed to close the box.

BRIEF DESCRIPTION OF THE DRAWINGS

Distinctive features and advantages of the present invention will be more apparent from the following description of a preferred, but not restrictive exemplary embodiment, with reference to the accompanying drawings, in which:

Figure 1 depicts a front view of the interior of an electrical control device according to the invention;

Figure 2 - General view of the control device with the allocation of the mechanism according to the invention;

Figure 3 is a front view of the mechanism shown in figure 2, while the sliding contact is in its rear position, according to the invention;

4 is a front view of a mechanism where the sliding contact is in its first intermediate position, according to the invention;

5 is a front view of a mechanism where the sliding contact is in its front position, according to the invention;

6 is a front view of the mechanism where the sliding contact is in its second intermediate position, according to the invention;

7 is a front view of the mechanism where the sliding contact is in its position along the second path according to the invention;

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

Figure 1 shows an electrical control device configured to remotely control using electrical pulses. In this example, we are talking about the switch 1 with a remote control, which is modular, that is, has a common flat shape, and its thickness is a multiple of the thickness of one specific module. This allows you to place the switch 1 on the same support next to other modular electrical appliances of the same format.

The remote-controlled switch 1 comprises a box having a box body 2 and a lid (not shown) connected to each other accordingly.

As you know, the remote control switch 1 contains in the box a magnetic control circuit comprising a coil 3 configured to receive electrical pulses and a drive unit 4 controlled by a magnetic circuit, which will be described in detail below.

The coil 3 comprises a fixed central unit 5 of a generally rectangular shape, containing a hollow part in the center. At the periphery, block 5 comprises a winding of an electrical wire (not shown). In addition, the coil 3 includes a fixed plate 6 and a movable plate 7 located on each side of the block 5, containing a hole in the hollow part. Two plates 6, 7 have the same shape in the form of a lying E with three parallel branches 8. Each branch 8 of one plate 6, 7 is located opposite the corresponding branch 8 of the other plate 7, 6.

The central branch 8 of the fixed plate 6 completely enters the hollow part of the block 5. The central branch 8 of the movable plate 7 partially enters the hollow part of the block 5.

The plate 7 is movable with the possibility of translational movement along the direction of movement by sliding parallel to the main direction of the branches 8.

The coil 3 further comprises a shaft support 9, made at the level of one side of the block 5, containing a hole in the hollow part. The support 9 is fixedly connected to the wall 10, mounted on the block 5.

The support 9 is designed to install the shaft 11 in it, which is part of the handle 12 formed by the casing 13, partially located around the part of the movable plate 7. From the side opposite to the shaft support 9, the handle 12 comprises a button 14 protruding above the housing 2 through a case made for this purpose rectangular hole. Button 14 is intended for manual actuation of the switch 1 with remote control.

Opposite to the button 14, the handle 12 contains a protruding wall containing a cutout 15 of a U-shape with a rounded bottom of the cutout 15. This cutout 15 is designed to fit a cylindrical finger 20, which will be described below.

The handle 12 also contains a rod (not shown) made between the two walls of the casing 13. The rod is located under the button 14. The handle 12 and the movable plate 7 are not connected to each other rigidly, that is, with a gap due to the rod being installed in the sectional opening basically elongated, made at the base of the movable plate 7 so that the movements of the handle 12 are interconnected with the movements of the movable plate 7. The shaft 11 is half the distance between the rod and the cutout 15.

The following is a description of the movements of the movable plate 7 and the handle 12. According to this configuration, the movable plate 7 and the handle 12 are each in a position, hereinafter referred to as the inoperative position.

Upon receipt of an electric impulse to the coil 3, the plate 7, made with the possibility of translational movement, is attracted in the direction of movement by sliding to the fixed plate 6. Since the handle rod 12 is located in the hole 16, it is attracted to the plate 6 together with the plate 7. Since the shaft 11 is installed in the support 9, the part of the handle 12, not containing the rod, rotates outward of the housing 2 together with a cutout 15, which moves in the direction of sliding movement towards the upper part of the housing 2, that is, towards the part case 2, containing a hole intended for the passage of the button 14. In this case, the top and bottom are considered the top and bottom of the remote control switch 1, as shown in figure 1.

When the movable plate 7 is at the end of its stroke, the branches 8 of the plate 7 and the branches of the plate 6 are in contact in pairs. The plate 7 and the handle 12 are each in a position called hereinafter the working position.

After the cessation of the pulse, the plate 7 performs a reverse movement and, like the handle 12, moves from the working position to the inoperative position.

The following is a description of the drive unit 4. This unit is located at most of the height of the box body 2 and mainly opposite the inside of the box body 2. The node 4 is mainly located and can be moved by sliding along the direction of movement.

At its end, which is closer to the upper part of the housing 2, the node 4 contains a cylindrical finger 20, made with the possibility of engagement in the cutout 15. At a distance from the finger 20, the node 4 contains a cylindrical hole of small diameter, made with the possibility of getting into it rods 21 of circular cross section .

At its opposite end, located at the bottom of the box body 2, that is, from the side opposite to the button 14, the node 4 is fixedly connected to the tubular link 22. This link 22 contains four rectangular walls, generally located at right angles and restricting the space in the form of a parallelepiped. Link 22 is connected to the rest of the node 4 using a bridge (not shown). Between the portion 22 and the rest of the node 4 is a wall 26 of the housing 2 of the box. The wall 26 contains a cutout 27, made with the possibility of passage of the bridge. This allows the bridge and, therefore, the link 22 to move along the direction of movement by sliding along with the rest of the node 4.

Link 22 forms for the platform 25 a guide for translational movement along the direction of movement by sliding. The platform 25 is transverse to the direction of movement by sliding. Area 25 is generally rectangular. On its part, located in the link 22, it has a width equivalent to the inner width between two opposite longitudinal walls. On adjacent parts, it has a slightly larger width, so the translational movement of the platform 25 can be blocked in a direction parallel to its length.

Between the bottom of the link 22 and the platform 25, a spring (not shown) is installed, which acts on the platform with a force, in particular, directed towards the upper part of the link 22.

Electrically conductive contacts 30 are fixed at each end of the pad 25, and the box body 2 contains terminals 31 with which the contacts 30 interact. The terminals 31 are on the fixed walls of the box body 2. Each terminal 31 is configured to interact with one of the contacts 30 so that when each contact 30 is pressed against the corresponding terminal 31, an electrical connection is established between both terminals 31. This position of the contacts 30 corresponds to the front position of the assembly 4. When each contact 30 moves away from the corresponding terminal 31, the terminals 31 are electrically isolated from each other. This position of the contacts 30 corresponds to the rear position of the node 4.

The rod 21 is made in the form of a metal rod, both ends of which are bent in the transverse direction. The first end is inserted into the hole of the node 4, while the other end is free. The free end forms a sliding contact 35 (figure 2), made with the possibility of movement along the cam path of the device, usually called the heart-shaped cam 36. The heart-shaped cam 36 is made in the fixed wall of the box body 2. It comprises a flat and substantially rectangular cam surface 37.

Two bulges forming the side wall 38 and the side wall 39 are made at a distance from each other along the entire height of the cam surface 37. These walls 38, 39 are located on both sides of the central portion 40 and protrude perpendicular to the cam surface 37.

Each wall 38, 39 contains two parts separated by a ledge.

At its upper extreme part, the side wall 38 has a thickness equivalent to the thickness of the portion 40. The rest of the wall 38 has a smaller thickness, and these two parts of the wall 38 are separated by a ledge 42 (Fig. 4).

The side walls 38, 39 form guide walls that allow the sliding contact 35 to move along the cam path without leaving it in the lateral direction.

The thickness values are measured starting from the cam surface 37 and perpendicular to this surface.

The central portion 40 extends perpendicularly to the cam surface 37 between the side walls 38, 39 and substantially in the center of the cam surface 37. Its cross section is in the shape of a triangle, one of whose sides is replaced by a curved line, the convexity of which is turned inside the triangle.

Section 40 contains three side sections 49, 50, 51 (Fig.7). The two sections 49, 50 are inclined sections containing a common peak 48 in their connection. They form a V shape, the tip of which is the peak 48. The sections 49, 50 are directed upward and respectively to the side wall 38 and the side wall 39.

The last portion 51 or recess defines a recess into which the sliding contact 35 enters, as will be described below.

The central portion 40 further comprises a pin 56 protruding above the rest of the central portion 40. The pin 56 has an elongated cross section and is made along the portion 49 so that one of its two straight sides is in the continuation of the portion 49.

A protruding toe 45 is formed opposite the central portion 40 protruding from the cam surface 37, and its thickness corresponds to the thickness of the portion 40, except for the pin 56.

As for the toe 45, it is located on one of the edges of the cam surface 37 (Fig.6). It contains an end directed towards the recess 51. The toe 45 (FIG. 3) contains a first inclined portion 52 directed substantially parallel to the portion 50 of the portion 40. The second portion 53 of the toe 45 forms the aforementioned end together with the portion 52. Section 53 is connected to the end of section 52 and tilts in a direction substantially parallel to section 49 on the first part. Section 53 is continued by a portion located in the sliding direction of travel.

On either side of the end formed by sections 52, 53, the toe 45 further comprises two bottom sections 54, 56 located transversely to the direction of movement by sliding.

Section 54 is adjacent to section 52 of the toe 45 and adjacent to the side wall 39, while section 55 is adjacent to the section 53 of the toe 46 and to the side wall 38.

The area opposite the ledge 43 (Fig.6) and on the edge of the cam path, contains essentially a cylindrical finger 60 (Fig.2) of the winding. The finger 60 contains a cutout 61 made in a plane parallel to the axis of the finger 60 and at a distance from this axis. Cutout 61 is made in the upper part of the finger 60.

The finger 60 is configured to install springs 65 (FIG. 3) on it in the form of a compass or in the form of a stud containing the first straight branch 66 and the second straight branch 67. The finger 60 and, in particular, the cutout 61 are also intended to act as connecting means in groove of the lid of the box covering the housing 2.

The spring 65 is made integral with two branches 66, 67 connected to each other by a wound core 68. This core is wound around the finger 60 and is worn on the finger 60 so that the spring 65 is worn on this finger 60.

The second branch 67 is located at a distance from the cam surface 37, less than the distance separating the first branch 66 from the cam surface 37, while the distance difference corresponds to the height of the core 68.

In the absence of load, the spring 65 is in its idle position and is positioned so that its first branch 66 is pressed against the pin 56 from the side of the recess 51. The first branch 66 is located transversely to the cam path, and its end extends beyond the cam path, passing above the step 42. Its free end is outside the side wall 38.

In the idle position, the second branch 67 (Fig. 7) is pressed against the portion 49 of the portion 40. It is located transversely to the cam path and is directed toward the end of the first branch 66. The free end of the second branch 67 is located near the step 42.

The following is a description of the circuit according to which the sliding contact 35 moves in the cam path. The sliding contact 35 is moved between four main positions: the rear position (figure 3), the first intermediate position (figure 4), the front position (figure 5) and the second intermediate position (figure 6). After this last position, the sliding contact 35 returns to its original rear position.

In the rear position, the sliding contact 35 is pressed against the wall 39 and is located at a small distance from the top 48 of the portion 40. In the first intermediate position, the sliding contact 35 is pressed to the portion 52 at a distance from the portion 54. In its forward position, the sliding contact is in the recess 51. And finally, in the second intermediate position, the sliding contact 35 is pressed against the wall 38 at a distance from the portion 55.

The following is a description of the full cycle of movement of the sliding contact 35.

Initially, the movable plate 7 and the handle 12 are in an inoperative position, and the assembly 4 and the sliding contact 35 are each in the rear position so that the contacts 30 are at a distance from the corresponding terminals 31.

Under the action of an electric pulse supplied to the terminals of the coil 3, the plate 7 goes into working position, as well as the handle 12, which rotates. Due to the presence of the cutout 15 and the finger 20, the node 4 is moved in the direction of movement by sliding (direction from the rear position to the front position) to its front position.

At cam level 36, this is expressed by moving the sliding contact 35 along the first path. The spring configuration on the cam 36 is such that in its inoperative position, the branch 67 abuts against the portion 49 of the portion 40. The sliding contact is pressed against the opposite wall 39 along the sliding direction of the portion 50 of the portion 40. The branch 67 thus blocks the passage between the portion 49 and wall 38. Thus, the sliding contact 35 can only enter the passage bounded by section 50 and wall 39. In this case, it extends obliquely towards section 54, pressing against section 50, between this section 50 of section 40 and wall 39. and at half the length of the section 50, the sliding contact 35 meets the branch 66 of the spring 65. In this case, the sliding contact 35 acts on the branch 66 in the direction of unwinding so that the angle formed by the two branches 66, 67 gradually opens as the sliding contact 35 moves. When the sliding contact reaches the end of section 50, the branch 66 is located in the direction of section 54, which corresponds to its maximum unwound state. Since after this, the section no longer acts on the sliding contact 35, the branch 66 acts on it by the force directed to the section 52, along which it rises to a stop at a small distance from the section 54. In this first intermediate position of the sliding contact 35, the node 4 is higher. than in its back position and than in its forward position.

Simultaneously with this advancement of the sliding contact 35 on this part of the first path, the link 22 will move up in the direction of sliding movement under the action of the spring installed in it, the platform 25 also moves slightly in the same direction. Since the stroke of the node 4 and, therefore, the link 22 is greater than the distance separating the platform 25 in the rear position of the node 4 from the terminals 31, the contacts 30 are pressed to the terminals 31 even before the end of the stroke of the node 4. Between the contacts of the contacts 30 and the terminals 31 and at the end link 22, the spring gradually compresses, choosing this distance difference, and acts by the force providing continuous contact between contacts 30 and terminals 31.

As long as the pulse is active, the sliding contact 35 remains pressed against the portion 52 in its first intermediate position (FIG. 4) with a small gap with respect to the bottom portion 54. This gap avoids the abutment of the sliding contact 35 against the bottom wall 54 before the plates 6, 7 come into contact with each other. As soon as the pulse stops, the plate 7 and the handle 12, forming the return means, return to their idle position, and the node 4 moves to its rear position, but does not reach this position. After that, the sliding contact 35 moves down. In this part of the first path, a force is applied to the sliding contact 35, causing it to rotate counterclockwise (a clockwise force is applied to the rod 21) so that the sliding contact 35 moves to the portion 40 along the portion 52 of the toe 45 until it stops in the recess 51. It enters the recess 51 in its forward position, which is a fixed position (figure 5). At the same time, branch 66 does not come into its inactive position. She is in line with the inclined part of the plot 53 of the toe 45.

Simultaneously with this passage of the sliding contact 35 along this part of the first path, the link 22 has moved sliding downward in the longitudinal direction. Since the sliding contact passed only half of the previous move, link 22 also did not come into its rear position. The spring of the link 22 holds the contact between the contacts 31 and the terminals 31. The mechanism comprising the cam 36 is thus in a fixed position in which the terminals 31 are electrically connected.

Under the action of a new pulse, the plate 7 again goes into working position, as does the handle 12, which in this case produces a pivoting movement. The node 4 moves up along the direction of movement by sliding.

In this case, the sliding contact 35 moves up the second path. Since the position of the branch 66 coincides with the direction of the inclined part of the section 53, the branch 66 blocks the passage for the sliding contact 35 in the direction of the first intermediate position so that it enters a part of the second path bounded between the recess 51 and the section 53, overcoming the resistance of the branch 66. When the sliding contact 35 reaches the end of the recess 51, the section 40 is no longer affected by it, and it is pressed by the branch 66 to the wall 38, along which it rises to a stop at a small distance from the section 55. In this second KSR position of the sliding contact 35 unit 4 is higher than in its rear position and its forward than position.

Simultaneously with the passage of the sliding contact 35 along this part of the second path, the link 22 will again move upward along the direction of movement by sliding, and the spring installed on it will again be compressed to compensate for the preserved position of the contacts 30 pressed against the terminals 31.

As long as the pulse is active, the sliding contact 35 remains pressed against the wall 38 in its second intermediate position (Fig.6). At the same time, a gap is provided that is identical to the gap that existed in the first intermediate position, for the same reasons. As soon as the pulse stops, the plate 7 and the handle 12 return to the inoperative position, and the node 4 moves to its rear position. In this case, the sliding contact 35 moves down. On this part of its second path, the thrust 21 and therefore the sliding contact 35 are acted upon by a rotational force in a counterclockwise direction so that the sliding contact 35 moves to the portion 40 along the wall 38 until the branch 67 reaches the stop position in the pin 56 and until the sliding contact 35 meets the second branch 67. In this case, the branch 66 is in its idle position, while the branch 67 experiences unwinding force from the sliding contact 35. The angle that it forms with the branch 66 at rest, gradually open breaks as the sliding contact 35 advances. This rotation of the branch 67 becomes possible due to the difference in the wall thickness 38. The sliding contact moves along the section 49 of the section 40, overcoming the resistance of the branch 67. When the sliding contact 35 reaches the top 48 of the section 40, the branch 67 is in its maximally unwound condition. The sliding contact 35 passes through the peak 48 and moves to its original rear position, while the branch 67 acts on it immediately after the passage of the peak 48. The sliding contact is pressed against the branch 67 and the wall 39 in its fixed position. The force of action of the branch 67 on the sliding contact 35 in this case exceeds the return force by which the handle 12 and the plate 7 act on the node 4.

Simultaneously with this passage of the sliding contact 35 along this part of the second path between the second intermediate position and the rear position, the node 4 completely made its move along the direction of movement by sliding. Link 22 will move down. At the first stage, the spring is opened, and the contacts 30 are held pressed to the terminals 31. Then, when the upper part of the link 22 comes into contact with the platform 25, the section forces the platform 25 to move down with it so that the contact between contacts 30 and terminals 31 is interrupted , and the terminals are no longer electrically connected. Thus, the mechanism containing the cam 36 is in a fixed position in which the terminals 31 are isolated from each other.

During the cycle, the electrical pulses supplied to the terminals of the coil 3 can be replaced by a manual drive from the handle 12 using the button 14.

According to an embodiment, branch 66 and branch 67 are made independently of each other.

According to another embodiment, the various elements limiting the cam path have slightly different shapes. For example, the portion 53 remains inclined to the bottom portion 55. The sections 54, 55 of the bottom are rounded.

According to another embodiment, the branch 66 does not extend beyond the cam path and, therefore, does not exert force on the sliding contact 35 as it moves from the second intermediate position, and the shapes of the toe 45, side wall 38, and portion 40 are provided so as to prevent the return of said sliding Pin 35 to the front position.

According to another embodiment, the spring contains only one branch, and the thrust is made elastic so that a force is applied to its free end transverse to the direction of movement by sliding.

According to an embodiment, the thrust is rigid, and a force is applied to it, transverse to the direction of movement by sliding, created by an independent spring.

According to another embodiment, the mechanism is used in another electrical device.

According to another embodiment, the device is used in a mechanical device, where sliding movements are provided manually by pressing in the same direction and in the same direction.

It should be noted that in an embodiment not falling within the scope of the present invention, the rod 21 and spring 65 are absent, and the device is not a remote control switch, but a switch.

Claims (28)

1. The mechanism with two fixed positions, containing the drive unit (4), made with the possibility of movement in the direction of movement by sliding between the rear position and the front position, while the mechanism is configured to hold the drive unit (4) in the front position after exposure to the force to move in the direction from the rear position to the front position, acting on the drive unit (4) when it is in the rear position, and with the possibility of holding the drive unit (4) in the rear position after air the action of the force to move in the direction from the rear position to the front position acting on the drive unit (4) when it is in the front position, while the mechanism comprises means for returning the unit (4), configured to act on the unit (4) in the direction from the front to the rear position, a rod (21) containing a proximal end connected to the drive unit (4) and a distal end containing a sliding contact (35) and a cam surface (37) along which the sliding contact (35) moves and from which the central portion (40) as well as the toe (45) opposite the recess (51) formed by the portion (40) fall, and this sliding contact (35) is in the recess (51) in the forward position when the assembly (4) is in its forward position, and is closer to the end of the section (40), opposite the recess (51), in the rear position, when the node (4) is in its rear position, while a cam path for sliding contact is made around the section (40) ( 35), which contains the first path on the first side of the section (40) and the second path on the second side of the section (40), moreover, the force acting on the sliding contact (35), at least when it is opposite the toe, is transverse to the direction of movement by sliding from the first side of the section (40) to the second side of the section (40), while the mechanism further comprises locking means blocking access to the second path for the sliding contact (35) in its rear position so that during exposure to move from its rear position, the sliding contact (35) enters the first path, characterized in that the cam The marketing path is made flat, the locking means comprise a spring branch (67), which in the absence of load is transverse to the cam path at the connection between the first path and the second path. 2. The mechanism according to claim 1, characterized in that the branch (67) in the absence of load is in contact with the first section (49) of the section (40), limiting part of the second path and forming a stop for the sliding contact (35) in its rear position opposite the second section (50) of the section (40), bounding part of the first path and forming a tip together with the first section (49). 3. The mechanism according to any one of claims 1 or 2, characterized in that it comprises a spring (65) for exerting force on the sliding contact (35), at least when it is opposite the toe, transverse to the direction of movement by sliding from the first side of the section (40) to the second side of section (40). 4. The mechanism according to claim 3, characterized in that the rod (21) is mounted rotatably on the drive unit (4) with its proximal end, while the spring (65) is configured to exert a force on the rotary rod (21). 5. The mechanism according to claim 4, characterized in that the spring (65) contains a branch (67), which is part of the locking means, and another branch (66), designed to act on the traction (21), while both branches (66 , 67) are arranged in the form of a compass and are connected to each other by a wound core (68). 6. The mechanism according to claim 5, characterized in that the spring (65) is held by means of fasteners (60) located outside the cam path, with the free end of each branch (66, 67) opposite the core (68), and means (60) mounts are located on either side of the cam path. 7. The mechanism according to claim 6, characterized in that the fastening means comprise a cylindrical column (60) around which a core (68) is wound. 8. The mechanism according to any one of paragraphs.5-7, characterized in that the branch (66) contains a fixed end located near a place on the cam path corresponding to the rear position of the sliding contact (35), the branch (66) has an inoperative position in which it is located transverse to the cam path and to the section (40), with the branch (66) between the sliding contact (35) in its rear position and the toe (45), and the working position in which the branch (66) is located at a distance from the section (40), while the branch (66) is arranged to move by turning in the circle of its fixed end from the idle position to the working position and with the possibility of acting on the sliding contact (35) with a force transverse to the direction of movement by sliding in the direction from the first side of the section (40) to the second side of the section (40), at least when the sliding contact is opposite the toe. 9. The mechanism according to claim 8, characterized in that in the rear position of the sliding contact (35), both branches (66, 67) are located on both sides of the pin (56) in the area (40), while the branch (66) abuts against the pin (56), and the sliding contact (35) is in contact with the branch (67) and at the same time is at a distance from the branch (66). 10. The mechanism according to any one of claims 5 to 7, characterized in that the toe (45) comprises a first inclined section (52) and a second inclined section (53), which are made with an inclination relative to the direction of movement by sliding and into which the sliding contact abuts ( 35) respectively, in the first intermediate position and in the second intermediate position, while the sliding contact (35) passes the first path from its rear position to its front position, passing through the first intermediate position, and passes the second path from the front position to the rear position, passing through the second intermediate position, while the sliding contact (35) passes from the rear position to the second intermediate position after exposure to sliding movement applied to the drive unit (4), while the sliding contact (35) passes from its first intermediate position to its forward position and from its second intermediate position to its rear position under the action of the branch (66) and under the action of returnable funds (7, 12). 11. The mechanism according to claim 10, characterized in that in its rear position during exposure to slide on the first path, the sliding contact (35) moves to its first intermediate position, overcoming the resistance of the branch (66), and when the node (4) moves by sliding under the action of the return means (7, 12) in the direction from the front position to the rear position, the sliding contact (35) moves from the first intermediate position to the front position. 12. The mechanism according to claim 10, characterized in that during the action for sliding movement, starting from its front position, the sliding contact (35) moves to its second intermediate position, overcoming the resistance of the branch (66), and when the node (4) moves by sliding under the action of return means (7, 12) in the direction from the forward position to the rear position, the sliding contact (35) is subjected to a force transverse to the direction of movement by sliding from the branch (66) on one part of the second path, after which moves, overcoming the resistance branch (67) belonging to the locking means, to its rear position on the other portion of the second path. 13. The mechanism according to claim 10, characterized in that it further comprises a first side wall (39) and a second side wall (38), limiting respectively the first path and the second path, while the second side wall (38) contains a ledge (42) opposite a toe (45), the thickness of which essentially corresponds to the distance between two branches (66, 67) transversely to the cam surface. 14. The mechanism according to item 13, wherein the distance separating the cam path and the branch (67) belonging to the locking means transverse to the cam surface is less than the distance between the cam path and the branch (66). 15. The mechanism according to any one of paragraphs.13 or 14, characterized in that both branches (66, 67) are connected to each other by a wound core (68), which is located outside the cam path outside the wall (39) that limits the first path, then how the free ends of the branches (66, 67) are located outside the cam path outside the wall (38) that limits the second path in the rear position of the sliding contact (35). 16. The mechanism according to claim 1, characterized in that the rod (21) is a rod, the distal end of which is made curved, forming a sliding contact (35). 17. An electrical control device, characterized in that it contains two terminals (31) installed in the box, a magnetic circuit and a mechanism according to any one of the preceding paragraphs, the mechanism being located between the terminals (31), connecting or disconnecting them electrically, while moving by sliding the drive unit (4) between its rear position and its forward position is controlled by a magnetic circuit in response to an electrical impulse supplied to the terminals of the magnetic circuit, and the node (4) contains electrically conductive contacts (30) configured to occur during the contact with the terminals (31) in a forward position of the node (4) and interrupts the contact with the terminals (31) in the aft position (4). 18. The device according to 17, characterized in that the magnetic circuit comprises a coil (3) containing a hollow central block (5), around which an electrical conductor is wound, a fixed plate (6) located at one end of the block (5), and a movable plate (7) located on the other end of the block (5). 19. The device according to p. 18, characterized in that each plate (6, 7) has an E-shape and contains a base from which three branches (8) extend parallel to each other - one central branch (8) and two branches ( 8) located each at the corresponding end of the base, and the plates (6, 7) are located opposite each other, and the free ends of each branch (8) of one plate (6, 7) are opposite the ends of each corresponding branch (8) of the other plate (7 , 6). 20. The device according to claim 19, characterized in that the central branch (8) of the fixed plate (6) is located in the hollow space bounded by the block (5), and two other branches (8) are located on both sides of the block (5). 21. The device according to claim 20, characterized in that the movable plate (7) is arranged to move along the direction of movement by sliding between the idle position, in which the free end of its central branch (8) is in the hollow space, while the rest of the central branch (8) is located outside the unit (5), and in the working position, in which its central branch (8) is in the hollow space, and the movable plate (7) is in contact with the fixed plate (6). 22. The device according to item 21, characterized in that on both sides of the toe (45) are the first section (54) of the bottom and the second section (55) of the bottom, and the toe (45) contains the first inclined section (52) and the second inclined a section (53) that have an inclination with respect to the sliding direction and against which the sliding contact (35) abuts, respectively, at a distance from the first bottom section (54) in the first intermediate position and at a distance from the second bottom section (55) in the second intermediate position, this plate (7) is in working position when sliding contact (35) is in its first intermediate position or in its second intermediate position. 23. The device according to any one of paragraphs.21 or 22, characterized in that the box contains a housing (2) containing a hole on the outer wall, a handle (12) covering the part of the movable plate (7) and containing a button (14) for the manual drive of the device protruding from this wall through the hole. 24. The device according to p. 23, characterized in that the handle (12) contains at one end a cut-out (15) of a U-shape configured to engage a finger (20), means for connecting the handle (12) with a movable plate ( 7) at its opposite end, and a rotary shaft (11) located between the cutout (15) and the means of connection. 25. The device according to paragraph 24, characterized in that it contains a support (9) of the shaft, fixed relative to the block (5) and configured to install a rotary shaft (11), while the drive unit (4) contains a finger (20) made with the possibility of entering into the cutout (15), so that the rotary movements of the handle (12), the movement movements along the direction of movement by sliding the sliding plate (7) or unit (4) are interconnected with each other. 26. The device according A.25, characterized in that at its end, opposite the finger (20), the node (4) contains a protruding hollow section (22), open from its two sides and containing the spring section installed from the bottom of this section, in the direction from the rear position to the front position towards the upper wall of the section, as well as the platform (25), which is transverse to the section and only the ends of which are outside the link (22), each of which two ends contains a contact (30 ), while acting on the platform (25) by the force Jin toward the top wall. 27. The device according to p. 26, characterized in that in the rear position of the node (4) both terminals (31) are opposite and at a distance from two contacts (30), while the distance between the contacts (30) and the terminals (31) is less the path of the assembly (4), and in the front position of the assembly (4), the platform (25) is located at a distance from the bottom and from the upper wall of the section, and the spring of the section is compressed to a greater extent than in the rear position of the assembly (4). 28. The device according to 17, characterized in that the spring (65) is held by means of fasteners located outside the cam path, while the fastening means comprise a cylindrical stand (60), the extreme part of which is made with the possibility of connection in the groove with the cylinder, which is part of the lid designed to close the box.

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