RU167615U1 - Electromagnetic gas valve - Google Patents

Abstract

The invention relates to devices of automatic pipe fittings with remote control. A gas electromagnetic valve, which includes: a body (1) of non-magnetic metal, made in the form of a hollow cylinder, located coaxially with the controlled line; a nut (2) in the form of a sleeve of magnetic metal fixed by a thread on one of the ends of the housing (1) coaxially with its longitudinal axis; a fitting (3) in the form of a sleeve of magnetic metal, fixed by a thread on the other end of the housing (1) coaxially with its longitudinal axis; the spool (4), made in the form of a glass made of a polymeric material with external guide ribs, facing the bottom towards the nozzle (3), a sealing gasket (5), fixed coaxially to the longitudinal axis of the housing (1) on the end of the spool (4) facing to the side fitting (3); an anchor (6), made in the form of a thin-walled cup of magnetic metal, facing the bottom towards the fitting (3) and placed inside the spool (4) coaxially to the longitudinal axis of the valve until the outer wall of its bottom abuts against the inner wall of the bottom of the spool (4); a magnetic element (7) made in the form of a sleeve located concentrically around the housing (1); a bobbin (8) of non-magnetic insulating material with a removable end wall (9), mounted on the housing (1) concentrically around the magnetic element (7) without the possibility of both moving along the housing (1) and rotating around it; control winding (10) wound on a bobbin (8). The technical result is expressed in increased wear resistance and reliability of the moving parts of the valve. 3 ill.

Description

The utility model relates to devices for automatic pipe fittings with remote control. The proposed valve is a high-speed electromagnetic coaxial shutoff normally open valve and is designed to automatically shut off gaseous working fluid flows on gas pipelines of gas distribution, gas supply and gas consumption systems.

A known direct-flow electromagnetic valve (RU patent No. 2371625), which comprises a housing with an inlet pipe, a housing cover with a discharge pipe, an electromagnetic actuator with a winding and a protective element, a disk armature and a yoke with conical surfaces of the magnetic gap between them and the armature spring return. The disk anchor contains a sealing element. The anchor is equipped with drainage holes. The actuator is located in the valve body. The inner and outer coaxially placed hollow cylinders are rigidly connected by an annular bridge with drainage holes. The sealing element of the armature overlaps the seat of the outlet pipe. The latter is located on the end wall of the valve body cover.

A known electromagnetic valve (SU certificate of invention No. 1687988), comprising a housing in which are located: a seat, a locking member, an electromagnet armature, a permanent magnet mounted along the axis of an electromagnet armature, and conical bores are made in the housing, with their vertices directed towards each other, while the height of the bore along the axis of the valve is equal to the stroke of the locking body.

The disadvantages of the above technical solutions include:

- design complexity;

- low wear resistance of the moving elements of the valve structure;

- low reliability due to the presence of spring elements subject to the aging effect;

- short service life.

The closest analogue is a device for the same purpose as the claimed utility model: “Electromagnetic valve” (RU patent for invention No. 2243441), consisting of a cylindrical body, input and output bushings made of ferromagnetic material, on which two sections of the control winding are placed, a spool located between the input and output bushings, which is a locking member, and the valve status indicator in the form of a magnetically controlled contact, characterized in that both bushings and a cylindrical housing are laid coaxially with the controlled line, the control windings located on the bushes are connected in series, forming two sections of a single control winding, and at the ends of the spool made of non-magnetic material, two radially magnetized permanent magnets are rigidly fixed, and the sections of the control winding are interconnected so that at a certain polarity of the control current, the magnetic flux of one section was directed according to the magnetic flux of a permanent magnet adjacent to this section, while as the magnetic flux of the second section is directed against the adjacent magnetic flux of the permanent magnet thereto.

The disadvantages of the closest analogue include:

- design complexity;

- low wear resistance and reliability of the moving elements of the valve structure and their short service life.

The task to which the utility model is directed is to increase the service life of stop valves and increase the efficiency of its operation.

The technical result that meets the task formulated above is expressed in increasing the wear resistance and reliability of the moving parts of the valve.

The specified technical result in the implementation of the utility model is achieved by the fact that in the gas electromagnetic valve, which includes: a body in the form of a hollow cylinder located coaxially with the controlled line; a nut in the form of a sleeve fixed by a thread on one of the ends of the housing coaxially to its longitudinal axis, a fitting in the form of a sleeve fixed by a thread on the other end of the body coaxially with its longitudinal axis; a spool located inside the housing coaxially with its longitudinal axis; a sealing gasket mounted on the end of the spool coaxially with the longitudinal axis of the housing; the magnetic element and the control winding, placed coaxially with the longitudinal axis of the housing between the nut and the fitting, according to the utility model, the housing is made of non-magnetic metal, the nut and the fitting are made of magnetic metal, the magnetic element is made in the form of a sleeve located concentrically around the housing, the control winding is wound on a bobbin of non-magnetic insulating material with a removable end wall, and the bobbin is concentrically mounted on the housing around the magnetic element without the possibility of movement along the cor pusa, and rotation around it, the spool is made in the form of a cup of polymer material with external guide ribs facing the bottom towards the nozzle, and an anchor is inserted into the valve, made in the form of a thin-walled cup of magnetic metal facing the bottom towards the nozzle and placed inside the spool, coaxial to the longitudinal axis of the valve, against the stop by the outer wall of its bottom into the inner wall of the bottom of the spool, while the material from which the spool cup is made has a low friction coefficient and high resistance to m mechanical, thermal and chemical influences.

The causal relationship between the technical result and the essential features introduced into the gas electromagnetic valve is that the shape and relative position of the valve components, including: a magnetic element; bobbins with a control winding placed on it; spool; sealing gaskets; Anchors as well as the materials from which the valve structural elements are made, significantly increase its wear resistance, as well as resistance to harmful factors of the transported medium. In addition, the manufacture of a spool from a polymeric material with a low coefficient of friction, as well as its manufacture in the form of a cup with external guide ribs facing the bottom towards the nozzle, inside of which an anchor is placed in the form of a thin-walled cup of magnetic material, requires less control magnetic field energy coils for its movement and dramatically reduces the possibility of jamming the spool during valve operation, which increases the reliability of the valve. From this it follows that the introduction of the essential features indicated in the formula of the claimed utility model is directly related to the technical result, which is expressed in increasing the wear resistance of the moving elements of the valve structure and increasing the reliability of the valve.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information, did not allow to find at the filing date of the application funds of the same purpose, the set of essential features of which is completely identical to the set of essential features of the claimed utility model. From this a conclusion has been drawn on the conformity of the claimed utility model with the NEW test.

The list of figures of the claimed utility model.

In FIG. 1 is a drawing of a valve in the “Open” state, which corresponds to the initial state, FIG. 2 is a drawing of a valve in the “Closed” state; FIG. 3 shows a drawing of a spool, with an anchor and a sealing washer mounted on it.

The positions in the drawing indicate:

1 - housing;

2 - a nut;

3 - fitting;

4 - spool;

5 - a sealing washer;

6 - anchor;

7 - a magnetic element;

8 - bobbin;

9 - removable end wall;

10 - control winding.

The composition of the gas electromagnetic valve includes: a body (1) of non-magnetic metal, made in the form of a hollow cylinder, located coaxially with the controlled line; a nut (2) in the form of a sleeve of magnetic metal fixed by a thread on one of the ends of the housing (1) coaxially with its longitudinal axis; a fitting (3) in the form of a sleeve of magnetic metal, fixed by a thread on the other end of the housing (1) coaxially with its longitudinal axis; the spool (4), made in the form of a glass made of a polymeric material with external guide ribs, facing the bottom towards the nozzle (3), a sealing gasket (5), fixed coaxially to the longitudinal axis of the housing (1) on the end of the spool (4) facing to the side fitting (3); an anchor (6), made in the form of a thin-walled cup of magnetic metal, facing the bottom towards the fitting (3) and placed inside the spool (4) coaxially to the longitudinal axis of the valve until the outer wall of its bottom abuts against the inner wall of the bottom of the spool (4); a magnetic element (7) made in the form of a sleeve located concentrically around the housing (1); a bobbin (8) of non-magnetic insulating material with a removable end wall (9), mounted on the housing (1) concentrically around the magnetic element (7) without the possibility of both moving along the housing (1) and rotating around it; control winding (10) wound on a bobbin (8). Structural elements, mandatory for any valve, but not reflecting the essence of the proposed technical solution (for example, fasteners, gaskets, protective nets, etc.), are not shown in the drawings.

Description of the valve.

The starting position is the open state of the valve shown in FIG. 1. At the same time, the spool (4) is in the extreme right position. The gap between the magnetic element (7) and the nut (2) is minimal and is determined by the thickness of the removable end wall (9), which ensures that in the absence of current in the control winding (10), the magnetic element (7), the armature (6) and the spool (4) are fixed in the far right position. In this position, the spool (4) the inner cavity of the nut (2) is in communication with the inner cavity of the fitting (3) and the gas (or other medium) freely passes along the working cavity of the valve from right to left. To switch the valve to the closed state, a positive polarity pulse is supplied to the control winding (10), which causes a magnetic field around the control winding (10) to emerge, pushing the magnetic element (7) in the direction of the fitting (3). Moving the magnetic element (7) to the leftmost position causes the armature (6) and the spool (4) to move in the same direction, blocking the outlet of the fitting (3). In the extreme left position of the magnetic element (7), its magnetic field is closed through the material of the fitting (3) and the material of the armature (6), which ensures the fixation of the magnetic element (7), the fixation of the armature (6), and the fixation of the spool (4) in this position after the termination of the control pulse. This position of the spool (4) is shown in FIG. 2. To return the valve to its initial open position, a negative polarity pulse is supplied to the control winding (10), which causes a magnetic field around the control winding (10), which moves the magnetic element (7) in the direction of the nut (2), and then the movement in the same direction are anchors (6) and spool (4). After the magnetic element (7) has taken its extreme right position, the attractive force created by its magnetic field ensures its retention after the termination of the control pulse, as well as the retention of the armature (6) and spool (4) in the extreme right position.

The introduction of changes in its design into the inventive valve, as reflected in the utility model formula, significantly increased the wear resistance of the movable elements of the valve structure and reduced the risk of jamming the spool (4) during its movement inside the body (1), which increases its reliability and valve service life. As a result of using the technical solution set forth in the claimed utility model, the durability and reliability of the valve operation are significantly increased.

The above information shows that when using the claimed utility model, the following set of conditions is fulfilled:

- a tool embodying the claimed utility model in its implementation, is intended for use in devices of automatic pipe fittings with remote control.

- a tool that embodies the claimed utility model in its implementation, is able to ensure the achievement of a technical result, namely increasing the durability and reliability of the moving parts of the valve.

For the claimed device, in the form in which it is described in the claims, the possibility of its implementation using the means described in the application is confirmed, therefore, the claimed utility model meets the criterion of INDUSTRIAL APPLICABILITY.

Claims (1)

Electromagnetic gas valve, which includes: a body in the form of a hollow cylinder located coaxially with the controlled line; a nut in the form of a sleeve fixed by a thread on one of the ends of the housing coaxially to its longitudinal axis, a fitting in the form of a sleeve fixed by a thread on the other end of the body coaxially with its longitudinal axis; a spool located inside the housing coaxially with its longitudinal axis; a sealing gasket mounted on the end of the spool coaxially with the longitudinal axis of the housing; a magnetic element and a control winding placed coaxially with the longitudinal axis of the housing between the nut and the fitting, characterized in that the housing is made of non-magnetic metal, the nut and the fitting are made of magnetic metal, the magnetic element is made in the form of a sleeve located concentrically around the housing, the control winding is wound on a bobbin of non-magnetic insulating material with a removable end wall, and the bobbin is concentrically mounted on the housing around the magnetic element without the possibility of movement along the housing as well as rotation around it, the spool is made in the form of a cup of polymer material with external guide ribs facing the bottom towards the nozzle, and an armature is introduced into the valve, made in the form of a thin-walled cup of magnetic metal facing the bottom towards the nozzle and placed inside the spool coaxially with the longitudinal axis of the valve against the stop by the outer wall of its bottom into the inner wall of the bottom of the spool, while the material from which the spool glass is made has a low coefficient of friction and high resistance to mechanical thermal, chemical and chemical influences.

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