RU71399U1 - SOLENOID VALVE - Google Patents

Abstract

The utility model relates to the field of valve engineering and is intended for use in gas pipelines. The objective of this solution is to develop a safety solenoid valve having a simple and reliable design, compact size, low power consumption, the possibility of using various flow cross-sections in gas pipelines, and a high degree of unification with pulse valves. The technical result is to simplify the design, improve efficiency, increase reliability. The electromagnetic valve comprises a housing 1, inside which a seat 2 and a locking member 3 are located. On the housing 1, an electromagnet 4 is located on the side of the locking member 3. Electromagnet 4 consists of a casing 5, a winding 6 and a core 7. The core 7 is made of soft magnetic material and has the ability displacement along the axis. On the electromagnet 4 from the side opposite to the housing 1, there is a manual control device 9 consisting of a button 10, a drive 11 and a return spring 12. Between the winding of the electromagnet 6 and the return spring 12 there is a flat washer 8 with a hole in the center. The core 7 is simultaneously the drive 11 of the manual control device 9. At one end, the core 7 is rigidly connected to the locking member, and the other end passes through the hole in the washer 8 and is rigidly connected to the button 10. The electromagnet is powered through the connecting electromagnet 13. 1 pf , 1 FIG.

Description

The utility model relates to the field of valve engineering and is intended for use in gas pipelines.

A direct-acting electromagnetic valve is known, in the body of which an anchor is installed - a locking member controlled by an electromagnet and interacting with a spring-loaded non-magnetic push rod located between the ends of the foot and the armature. A through hole is made in the foot and an adjusting screw is installed between the end of the pusher and the housing cover with the possibility of affecting the end of the armature from the side of the adjusting screw. The anchor together with the locking body moves to the foot, thereby opening the passage for the working fluid. When removing stress, the anchor with the locking element under the influence of a return spring returns to its original position, closing the passage (see USSR author's certificate No. 1000654, IPC F16K 31/02, published on 02.28.1983 Bull. No. 8).

The disadvantage of the valve is the need to use an electromagnet of high power, and, with an increase in the orifice of the valve, the stroke of the shut-off element increases and, as a result, the power of the electromagnet must increase, which either leads to an increase in size, if the current consumption is preserved, or to an increase in the current consumption leads to an increase in heating of the electromagnet and a decrease in its reliability.

A known electromagnetic valve with a manual control mechanism for installing it in an open state. The valve comprises an electromagnet, a valve seat, an anchor with a locking element, made with the possibility of movement between the valve seat and the electromagnet, two washers, one of them is made of magnetic, the other of magnetically conductive material. Both washers are installed on one side relative to the locking element with an anchor, and the electromagnet on the other. One of the washers is rigidly connected, for example, by means of a rod with a locking element and an anchor, the other is mounted motionless. When the valve is installed in the closed state, both washers are in close proximity to each other, and one of the washers is configured to adjust the final distance between them (see RF patent for invention No. 2282090, IPC F16K 31/06, published on 08.20.2006) .

The disadvantage of this device is the need to mount strictly in an upright position, which limits its scope. Due to the increasing friction between the stem and the rubber seal over time, there is a chance that the valve’s dead weight will not be enough to securely seat when shutting down

electromagnet. Continuous maintenance of the device is also necessary so that the gap between the movable and stationary washers remains minimal. However, when a seal is formed between the valve and the seat, these washers may touch and the valve will not be pressed against the seat. The design is complex and bulky. It does not allow the use of standardized parts, for example, housing according to GOST. It is necessary to refine the case and attach to it an additional part with the part of the locking device located in it. The cost of manufacturing the design does not pay off due to savings in operation.

Closest to the proposed invention is an electromagnetic valve (see patent RU No. 2092738, IPC F16K 31/08, publ. 1997.10.10), containing an electromagnet in the cavity of which there is a fixed pole and an armature connected to a locking member, a return spring, a permanent magnet connected to a movable manual control device. When voltage is applied to the winding of an electromagnet, the magnetic flux generated by it, having the same polarity with a permanent magnet, closing through the casing, anchor, pusher, permanent magnet, winding body, the armature creates a pulling force on the latter, which, overcoming the force of the return spring and permanent magnet, pulls the anchor to the pole and thereby draws the closure to the body seat, blocking the passage of the working fluid. When removing the voltage from the winding of the electromagnet, the anchor remains pressed to the pole under the influence of a magnetic flux created by a permanent magnet. The valve is opened by a hand-held device, which tears off the permanent magnet from the end of the electromagnet housing, thereby weakening the magnetic flux and the locking device, together with the armature, under the influence of the return spring, departs from the saddle, opening the passage of the working fluid.

The disadvantages of this invention include the following: the complexity of the design, and therefore the high cost; impossibility of closing the valve manually; voltage supply to the electromagnet winding is required; the impossibility of using the same electromagnet on valves having different flow sections, since with increasing cross-section, the amount of lifting of the locking member and the amount of clamping force to the seat increase, which necessitates the use of an electromagnet of greater power.

The objective of this solution is to develop a safety solenoid valve having a simple and reliable design, compact dimensions, low power consumption, the possibility of use in gas pipelines

various through section, high degree of unification with pulse valves.

The technical result is to simplify the design, improve efficiency, increase reliability.

The problem is solved in that the electromagnetic valve comprises a housing with a seat and a locking member located therein, an electromagnet with a core, a manual control device for setting the valve in the open state, according to the solution, the core of the electromagnet made of soft magnetic material is simultaneously a manual control device and is rigidly connected to the locking body, and between the electromagnet and the manual control device there is a washer with a central hole to accommodate the core .

The device is illustrated in the drawing, where the following items are indicated:

1. housing;

2. saddle;

3. a locking organ;

4. electromagnet;

5. casing;

6. winding;

7. core;

8. washer;

9. manual control device;

10. button;

11. drive;

12. return spring;

13. connecting electric pad;

The electromagnetic valve comprises a housing 1, inside which a seat 2 and a locking member 3 are located. On the housing 1, an electromagnet 4 is located on the side of the locking member 3. Electromagnet 4 consists of a casing 5, a winding 6 and a core 7. The core 7 is made of soft magnetic material and has the ability displacement along the axis. On the electromagnet 4 from the side opposite to the housing 1, there is a manual control device 9 consisting of a button 10, a drive 11 and a return spring 12. Between the winding of the electromagnet 6 and the return spring 12 there is a flat washer 8 with a hole in the center. The core 7 is simultaneously the drive 11 of the manual control device 9. At one end, the core 7 is rigidly connected to the locking member, and the other end passes through the hole in the washer 8 and is rigidly

connected to the button 10. The power of the electromagnet is carried out through a connecting electroplate 13.

The solenoid valve operates as follows. In the initial state, the supply voltage on the winding 6 of the electromagnet 4 is absent. The locking element 3 is pressed by the return spring 12 to the seat 2 of the housing 1. The passage of the working fluid is closed. When the power is turned on, the magnet 6 generates a magnetic flux passing through the casing 5, the washer 8 and the core 7. However, the action of the magnet 4 on the locking element 3 is minimal and much less effort return spring 12 due to the large distance between the end of the locking element 3 and the end of the electromagnet 4. In the open state, the electrovalve is driven by a manual control device 9 by moving the actuator 11. When moving at od 11 compresses the spring 12 and separates the closure member 3 from the seat 2. With further movement of the actuator end 11 of the locking body 3 is pressed against the end face of the electromagnet 4, minimizing the air gap between them. Due to this, the magnetic flux generated by the electromagnet 4 is closed through the casing 5, the washer 8, the core 7, the locking member 3 and creates a force sufficient to hold the locking member 3 in the open position. The passage of the working fluid is open. When you turn off the voltage on the winding 6 of the electromagnet 4, the magnetic flux weakens, and the shut-off element 3 under the influence of the return spring 12 is torn off from the end of the electromagnet 4 and pressed against the seat 2. The passage of the working fluid is closed.

Claims (1)

An electromagnetic valve comprising a housing with a seat and a locking member located therein, an electromagnet with a core, a manual control device for setting the valve in the open state, characterized in that the core of the electromagnet made of soft magnetic material is simultaneously a manual control actuator and is rigidly connected to the locking body, and between the electromagnet and the manual control device there is a washer with a central hole to accommodate the core.