RU2705129C1 - Double electromagnetic valve - Google Patents

Abstract

FIELD: transportation.

SUBSTANCE: invention relates to the field of transportation of low-pressure gaseous media, namely to the area of shutoff valves, and can be used in heat power systems at thermal stations, in vacuum systems, in petrochemical and gas equipment. Double electromagnetic valve comprises a housing accommodating the first seat, the first membrane gate with unloading opening, the first membrane with bypass holes. Between the case flange and its cover the first slide valve is installed with possibility of overlapping / opening of unloading hole of the first membrane shutter, connected to anchor of the first electromagnet and to the first membrane gate. On the housing gas supply means and gas outlet means are fixed, wherein gas outlet means is made in form of pipeline rigidly fixed in housing wall by first end extending beyond housing limits. Inside the housing there is a second seat, a second membrane gate with a discharge opening, a second membrane with bypass openings and a second slide installed to shut off / open the discharge opening of the second membrane gate connected to the armature of the second electromagnet and to the second membrane gate. First gas duct is located between gas supply means and second membrane gate, wherein first shutter membrane is configured to shut off gas duct, body volume is divided by a partition into two parts, the first of which is located under the membrane of the first gate, and the second part is located under the membrane of the second gate, note here that said second gate is arranged to discharge gas into gas outlet. Note here that gas outlet means adjoins second diaphragm shutter.

EFFECT: technical result achieved during implementation of the developed device consists in simplification of shutoff valves of the gas line.

6 cl, 2 dwg

Description

The invention relates to the field of equipment for transporting low-pressure gas environments, namely, to the field of valves, and can be used in heat and power systems at thermal stations, in vacuum systems, in petrochemical and gas equipment.

Known (RU, patent No. 215858, published on 08.27.1999) is a shut-off valve comprising a housing with an inlet and outlet nozzles and a seat, a locking member with a return spring and a pusher, an actuator enclosed in a casing, an intermediate assembly is placed between the rod and the pusher, which provides valve actuation and equipped with an electromagnet with a flat armature. The stem and pusher are aligned. The valve body has a cover with a gland assembly that seals the pusher, which, together with a return spring, are located on different sides of the locking element. The intermediate node is made in the form of a lever, one end of which is pivotally mounted on the base - the base of the drive, and the second is connected to a flat armature of the electromagnet, and two earrings having a common axis. One, the earring is pivotally connected to the pusher of the locking member, and the other is pivotally connected to the actuator stem, and in the lever, the groove is inclined to the push rod and the stem, and the indicated common axis of the earrings is inserted into it.

The disadvantages of the known technical solutions can be recognized as the difficulty of providing this solution with large loads on the rod (from 1-2 tons and above) due to the small efforts in the applied electromagnets and the instability of the work due to the inconsistency of the friction coefficients (lubrication, lack of lubrication), as well as the need for duplication even on a low pressure gas line.

It is known (RU, patent 2362900, publ. 07.27.2009) a valve device for supplying gaseous fuel to an internal combustion engine comprising a housing with a base and an electromagnetic valve, the device having a second electromagnetic valve, the electromagnetic valves are located on the sides of the base, the axis of which is located a stepper motor driving a hollow cylinder with a side slit and regulating the gas flow through the opening of the base during rotation of the hollow cylinder, the solenoid valves being connected to the cavity base holes perpendicular to its axis.

The valve device operates as follows. When starting the engine: in the pre-start mode, after power is supplied according to the program set by the electronic block of the gas engine control system, the stepper motor opens the slotted dosing device in such a way that the gaseous fuel consumption necessary for starting the engine is ensured. The solenoid valves are closed. With a slow change in engine speed and load, the slotted batcher opens (closes) according to a predetermined program, ensuring the supply of the amount of gas necessary for the engine to work. With a rapid change in the load or engine speed, within the tolerance of maintaining the rotational speed, a change in the flow area of the gas supply channel is carried out by turning on the electromagnetic valves for the time specified by the program of the electronic unit. When the load is removed and the engine speed is reduced by the command of the electronic unit of the gas engine control system, the electromagnetic valves are turned off and the slotted doser is closed so that the gas flow necessary to stop the engine is provided.

A disadvantage of the known device should be recognized as a narrow scope - only the gas supply to the internal combustion engine.

The closest technical analogue of the developed device can be recognized (RU, patent 161932, publ. 05.20.2016) a valve with an electromagnetic actuator, containing a cylindrical, bottom-closed housing with a cover, inside which a seat, a membrane shutter with a discharge hole, with a bypass hole and a disk are placed located between the flange of the housing and its cover, a spool with the ability to overlap / open the discharge opening of the membrane shutter, rigidly connected to the armature of the electromagnet and telescopically with a membrane shutter rum, a gas supply means and a gas outlet means are fixed on the cylindrical surface of the body, the gas outlet means being made in the form of a pipeline rigidly fixed in the cylindrical wall of the body and one end adjacent to the membrane shutter, and the other end extending outside the body, with the valve additionally contains an induction sensor mounted on the sleeve of the electromagnet.

The valve operates as follows. The valve opens in the following order. When voltage is applied, the armature of the electromagnet rises, compressing the spring and dragging the spool along, opening the discharge opening. Due to the difference in the area of the bypass and discharge openings, the pressure of the working medium in the submembrane chamber drops and due to the pressure of the working medium in the submembrane chamber, the membrane shutter rises and the valve opens. At zero pressure of the working medium, the valve opens due to the lifting of the membrane shutter by an electromagnet armature through a telescopic connection between the armature and the membrane. When removing the voltage from the electromagnet, the spool, due to the force of the spring, blocks the discharge opening and the working medium fills the supmembrane space through the bypass hole. The pressure under and above the membrane is equalized, and due to the larger working area of the membrane top (by the size of the seat area), the force on the membrane shutter from above exceeds the force on the membrane shutter from below, the membrane shutter is pressed against the seat and the valve closes. At zero or close to zero pressure of the working medium, the valve closes due to the spring force on the membrane valve through the disk and the elasticity of the membrane valve due to the shape of the membrane. An induction sensor detects the position of the armature of an electromagnet mechanically connected to the membrane shutter and shows the valve status (open - closed). The valve is controlled automatically or remotely.

A disadvantage of the known valve should be recognized as the need for duplication, even on a low-pressure gas line.

The technical problem solved using the developed device is to ensure the tightness of the gas supply to the place of consumption.

The technical result achieved by the implementation of the developed device is to simplify the shutoff valves of the gas main.

To achieve the specified technical result, it is proposed to use a solenoid valve double developed design. The electromagnetic double valve contains a housing, inside of which there is a first seat, a first membrane shutter with a discharge hole, a first membrane with bypass holes located between the first flange of the body and its cover, the first spool installed with the possibility of overlapping / opening the discharge opening of the membrane shutter, connected ( rigidly, telescopically or by a spring) with an electromagnet anchor and with a membrane shutter, a gas supply means and a gas exit means are fixed to the housing, moreover, the gas outlet is designed as a pipe rigidly fixed in the housing wall facing the first end outside the housing. In addition, it additionally contains a second seat located inside the housing, a second membrane shutter with a discharge hole, a second membrane with bypass holes located between the second housing flange and its cover, a second spool installed to overlap / open the discharge gate of the membrane shutter, connected ( rigidly, telescopically or spring) with an electromagnet anchor and with a membrane shutter, the first gas duct located between the gas supply means and the second membrane shutter, The membrane of the first shutter is installed with the possibility of overlapping the first gas duct, the body volume is divided by a partition into two parts, the first of which is located under the membrane of the first shutter, and the second part is located under the membrane of the second shutter, while the second shutter is located with the possibility of gas outlet to the gas outlet while the gas outlet means with the second end abuts against the second membrane shutter.

In some embodiments, the gates are mounted at the ends of the housing, and the gas supply means and the gas outlet means are located on opposite sides of the housing.

In other embodiments, a first shutter is mounted on an end of the housing, a gas outlet means is installed at a second end of the housing, a gas supply means and a second shutter are located on opposite sides of the housing.

Valves can be mounted on the housing using flange connections. Although other options for mounting the valves on the body are not ruled out.

Preferably, the housing is cylindrical.

In FIG. 1 shows an embodiment of the developed device, in which both shutters are located at the ends of the housing, and in FIG. 2 - an option when the first shutter is installed on the end of the housing, a gas outlet means is installed on the second end of the housing, the gas supply means and the second shutter are located on opposite sides of the housing. The following notation is used on the graphic material: body 1, first seat 2, first membrane shutter 3 with discharge hole 4, first membrane 5 with bypass holes 6, first flange 7 of body 1 with cover 8, first spool 9, anchor 10 and coil 11 of the first electromagnet, gas supply means 12, gas outlet means 13, second seat 14, second membrane shutter 15 with discharge opening 16, second membrane 17 with bypass openings 18, second spool 19, armature 20 and coil 21 of the second electromagnet, second flange 22 of housing 1 with cr knob 23, gas duct 24, partition 25.

The device operates as follows.

Gas is supplied to the housing and it moves through the gas duct. On the gas path is the first (upper) membrane, which simultaneously plays the role of a shutter. The membrane, in the case when there is no pressure at the inlet, is pressed against the saddle by a spring and due to its shape (the saddle is the edge of the pipe welded into the oblique partition) blocks the gas flow. The membrane has openings located in a circle opposite the annular gap between the seat and the body. If there is pressure at the inlet, gas from below presses on the membrane, passes through these openings into the supmembrane space and presses the membrane to the seat, ensuring the shutter is tight. Since the area of the membrane on which the gas presses from above is larger, the membrane is tightly pressed by gas pressure. In the center of the membrane there is an additional discharge opening, which is tightly blocked by an electromagnet anchor. When voltage is applied to the coil of the first electromagnet, its anchor retracts, opening the discharge opening. Through it, the pressure from the supmembrane space is sharply discharged, and the pressure from below pressing on the membrane opens the valve. Practice has shown that at low pressure (5 kPa or less), the connection of the armature and the membrane is necessary so that the valve opens not only due to the pressure from below, but also due to the movement of the armature lifting the membrane. This circuit works at any position of the electromagnet (up, side, down). After that, the gas with the first upper valve open (raised membrane) enters the space under the oblique insert, pressing on the lower (second) membrane, which is the same as the upper one. The lower (second) membrane works similarly to the upper one, and after opening the second valve, the gas exits the valve and goes further through the gas pipeline (for example, to the burner). The valve (each) closes as follows: when removing the power supply from the magnet, the spring lowers the anchor, which closes the discharge opening, and pushes the membrane. The membrane, due to its shape and elasticity, also seeks to close the valve. Also, the pressure above the membrane is greater than under the membrane, and the membrane lowers, closing the valve and ensuring complete tightness in the valve. This operating procedure is the same for both membranes (valves).

Achieving the specified technical result is ensured by the entire design of the developed device.

Claims (6)

1. Double electromagnetic valve, comprising a housing, inside of which a first seat is placed, a first membrane shutter with a discharge opening, a first membrane with bypass holes located between the housing flange and its cover, the first spool installed with the possibility of overlapping / opening the discharge opening of the first membrane shutter connected to the armature of the first electromagnet and to the first membrane shutter, gas supply means and a gas outlet means are secured to the housing, and the gas outlet means flaxen in the form of a pipeline rigidly fixed in the wall of the housing, the first end extending outside the housing, characterized in that it further comprises a second seat located inside the housing, a second membrane valve with a discharge opening, a second membrane with bypass openings located between the housing flange and a lid, a second spool installed with the possibility of overlapping / opening the discharge opening of the second membrane shutter, connected to the armature of the second electromagnet and to the second membrane the valve, the first gas duct located between the gas supply means and the second membrane shutter, the membrane of the first shutter being installed with the possibility of overlapping the gas duct, the body volume is divided by a partition into two parts, the first of which is located under the membrane of the first shutter, and the second part is located under the membrane of the second shutter while the second shutter is arranged with the possibility of gas outlet to the gas outlet means, while the gas outlet means with the second end abuts against the second membrane shutter. 2. The electromagnetic double valve according to claim 1, characterized in that the gates are installed on the ends of the housing, and the gas supply means and the gas outlet means are located on opposite sides of the housing. 3. The double electromagnetic valve according to claim 1, characterized in that the first shutter is installed on the end of the housing, a gas outlet means is installed on the second end of the housing, the gas supply means and the second shutter are located on opposite sides of the housing. 4. Double electromagnetic valve according to claim 1, characterized in that the valves are mounted on the housing using flange connections. 5. The electromagnetic double valve according to claim 1, characterized in that the body is cylindrical. 6. The double electromagnetic valve according to claim 1, characterized in that the spool installed with the possibility of overlapping / opening the discharge opening of the membrane shutter is connected to the armature of the electromagnet and to the membrane shutter rigidly, telescopically or by a spring.

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