RU2493465C1 - Constant low-pressure shutoff electropneumatic valve - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: constant low-pressure shutoff electropneumatic valve includes an adjustment element to the specified low pressure, a high-pressure cavity with a gas supply channel, and a cylindrical chamber. Control electromagnetic valve includes an inlet seat interconnected with the gas supply channel, a control element and an outlet seat. Moving element with two stocks is equipped with a limit stop and forms an auxiliary cavity with a mechanical spring in the chamber and a low-pressure cavity on the opposite side. Low-pressure cavity is separated from the high-pressure cavity with a control gate valve and moving seat made in the end face of the first stock and interconnected through a channel in the moving element and stocks to the low-pressure cavity. The channel in the moving element and stocks is straight-flow. The auxiliary cavity is connected to atmosphere. In the cylindrical chamber there is an additional working cavity located between the moving element and the low-pressure cavity and interconnected with that cavity through a feedback channel. Control electromagnetic valve is built into the above feedback channel so that its cavity is interconnected with the working cavity and the outlet seat is interconnected with the low-pressure cavity.

EFFECT: improving quick action of a shutoff electropneumatic valve.

1 cl, 1 dwg

Description

The invention relates to the field of gas supply systems and industrial pneumatic automation, and more particularly to direct-flow devices of gas automation, providing flow, cut-off and regulation of gas pressure.

A known gas supply system for a block of gas-actuating actuators, comprising a cylinder with compressed gas, a filling and drain valve, a start-off electric pneumatic valve, a pressure regulator and a safety valve [Reactive control systems for spacecraft. / N.M. Belyaev, N.P. Great, E.I. Uvarov. - M.: Mechanical Engineering, 1979. - S. 45, Fig. 2.5].

The use of a pressure regulator increases the size and weight of the gas supply system, while two-stage electro-pneumatic valves contain elements that can be used to provide a constant low pressure in the mode of operation of the pressure regulator.

A direct-flow pressure regulator is known that contains a setting element for a given low pressure, a high-pressure cavity with a gas supply channel, a cylindrical chamber and a movable element with a rod, equipped with a stop and forming an auxiliary cavity in the chamber from the side of the rod high pressure cavity with a mechanical spring located therein and, on the opposite side, a low-pressure cavity with a tap channel, separated from the high-pressure cavity by a non-flow shutter and a movable flow seat, flanged at the end of the rod and the communicated channel in the movable element and the rod with a low-pressure cavity. The channel in the movable element and the rod is straight-through, and the auxiliary cavity of the regulator is in communication with the atmosphere [Gas pressure reducers. / A.I. Edelman. - M.: Mechanical Engineering, 1980. - P.58, Fig.3.40, b].

The advantage of this regulator is the direct flow of the axial channel of the gas path, reducing its hydraulic resistance and pressure loss caused by the action of friction. The disadvantage is that the supply of control pressure to the auxiliary control cavity does not cut off the gas flow.

Known two-stage shut-off electro-pneumatic valve of constant low pressure, which is selected as a prototype and is a two-functional unit that performs the functions of a shut-off electro-pneumatic valve and pressure regulator. It contains a setting element for a given low pressure, a high pressure cavity with a gas supply channel, a control solenoid valve with an inlet seat in communication with a gas supply channel, a regulating body driven by an electromagnet, and an exhaust seat, a cylindrical chamber and a movable element with two rods, equipped with focusing and forming in the chamber from the side of the auxiliary rod protruding into the high pressure cavity of the first rod with a mechanical spring located in it, and with the opposite side, a low-pressure cavity with a second rod protruding into it and a tap channel, separated from the high-pressure cavity by a control valve connected to the tuning element, and a movable seat made at the end of the first rod and communicated with the channel in the movable element and rods with a low-pressure cavity. The auxiliary cavity is in communication with the cavity of the electromagnetic valve, and the exhaust channel is separated from the low-pressure cavity by a shut-off valve, made at the end of the second rod, and an exhaust saddle, which is simultaneously the stop of the movable element [RF Patent No. 2339991, IPC G05D 16/00].

It should be noted that the low-pressure cavity of the open unit can, as in the last analogue, be considered the result of combining two cavities located next to each other and connected to each other by the feedback channel: the working cavity of the piston gas engine and the outlet cavity of the control valve valve, which, in essence, in regulators, it is directly a low-pressure cavity that enters the working cavity of a gas engine through a feedback channel.

The advantage of this constant-pressure low-pressure start-up electropneumatic valve is its very simple, including remote, adjustment to a given low pressure by moving the control shutter, in particular, by an electric actuator.

The disadvantage is the low speed due to the large stroke of the movable element in transitional opening and closing modes, equal to the initial stroke of this element in the process of setting the unit and compressing the mechanical spring, unloaded in the initial state. In addition, due to the presence of a shut-off valve, the channel in the movable element and the rods cannot be straight-through, which increases the hydraulic resistance of the unit.

An object of the present invention is to increase the speed of a two-stage constant-pressure low-pressure shut-off electro-pneumatic valve due to the use of a control shutter as a shut-off valve and a corresponding reduction in its stroke in the opening and closing processes while ensuring the direct flow of the gas path.

The solution to this problem is achieved by the fact that the constant-pressure start-off electro-pneumatic valve contains a setting element for a given low pressure, a high-pressure cavity with a gas supply channel, a control solenoid valve with an inlet seat in communication with the gas supply channel, a regulating body driven by an electromagnet, and an exhaust seat , a cylindrical chamber and a movable element with two rods, provided with a stop and forming in the chamber from the side protruding into the high-pressure cavity I have an auxiliary cavity of the first rod with a mechanical spring located in it, and on the opposite side, a low-pressure cavity with a second rod protruding into it and an outlet channel, separated from the high-pressure cavity by a control valve connected to the tuning element, and a movable saddle made in the end of the first rod and the communicated channel in the movable element and rods with a low-pressure cavity, while the channel in the movable element and rods is straight-through, the auxiliary cavity is in communication with the atmosphere, and in of cylindrical chamber is formed additional working chamber located between the movable element and the low-pressure cavity and communicated with the cavity of the feedback channel, into which a control solenoid valve so that its cavity communicates with the working chamber, and a discharge saddle with a low pressure cavity.

The invention is illustrated in the drawing.

The drawing shows a diagram of a constant pressure low pressure start-up electro-pneumatic valve.

The constant low pressure start-up electro-pneumatic valve contains a setting element for a predetermined low pressure 1, a high-pressure cavity 2 with a gas supply channel 3, a control solenoid valve 4 with an inlet seat 5 in communication with a gas supply channel 3, a regulating body 6 driven by an electromagnet 7, and an exhaust a saddle 8, a cylindrical chamber 9 and a movable element 10 with two rods 11, 12, provided with a stop 13 and forming in the chamber 9 from the side of the first rod 11 which protrudes into the high pressure cavity 2 a burning cavity 14 with a mechanical spring 15 located therein, and on the opposite side a low pressure cavity 16 with a second rod 12 protruding into it and an outlet channel 17, separated from the high pressure cavity 2 by a control valve 18 connected to the setting element 1, and a movable saddle 19, made in the end face of the first rod 11 and communicated channel 20 in the movable element 10 and rods 11, 12 with a low-pressure cavity 16, the channel 20 in the movable element and rods 11, 12 is made straight-through, the auxiliary cavity 14 is in communication with the atmosphere, and in The cylindrical chamber 9 has an additional working cavity 21 located between the movable element 10 and the low-pressure cavity 16 and connected to this cavity by a feedback channel 22, into which the control electromagnetic valve 4 is integrated so that its cavity communicates with the working cavity 21, and the outlet seat 8 with a low-pressure cavity 16.

The device described above operates as follows.

In the initial state, the control shutter 18 and the movable element 10 are in the extreme lower positions defined by the stop 13, and the mechanical spring 15 can be completely unloaded. The electrical signal Uin is applied successively to the input of the normally open solenoid valve 4 shown in the drawing and the high pressure Pb to the gas supply channel 3 and the high pressure cavity 2. The regulating member 6 is pressed against the inlet seat 5, providing communication through the feedback channel 22 of the working cavity 21 with the cavity low pressure 16 of the device, which in this state is configured for a given low pressure PH.

When moving the control shutter 18 with the help of the setting element 1 up to the adjustment position, the low pressure Рн in the cavity 16 and in the working cavity 21 connected with it increases. Under the influence of this pressure, the movable element 10, compressing the initially unloaded spring 15, moves after the control shutter 18 at a considerable distance to its tuning position, in which the spring force and the gas-dynamic force on the movable element 10 and its rods 11, 12 are balanced. In this state, the device, as well as The prototype described above works in the mode of a pressure regulator, maintaining with a certain accuracy the adjusted level of low-pressure discharge due to negative feedback on this pressure. In this mode, the distance between the control valve 18 and the movable seat 19 is small and is usually a fraction of a millimeter in pressure regulators.

When the input signal Uvc is removed, the regulating body 6, under the action of the pressure Рв in the gas supply channel, moves to the outlet seat 8, blocking the feedback channel 22 and causing an increase in pressure in the working cavity 21. Under the action of the force of this pressure, the movable element 10 moves to its highest position, providing closing the device and cutting off the low-pressure cavity 16 from the high-pressure cavity 2.

Upon subsequent supply of the input signal Uin, the electromagnet 7 moves the regulator 6 from the outlet seat 8 to the inlet seat 5, which leads to the opening of the feedback channel 22 and the device returns to the tuning open state.

In the considered transitional modes of closing and opening, the stroke of the movable element 10, as noted above, is a fraction of a millimeter, in contrast to the large stroke in the prototype, which is equal to the movement of this element in the process of setting and compressing the spring 15 by several millimeters. This circumstance leads to a significant increase in the speed of the claimed device, which, in contrast to similar devices using a control shutter as a shut-off valve, has a direct-flow gas path close to the second analogue, which reduces pressure losses due to the action of friction forces. Due to this, in particular, when using a supersonic nozzle as a consumer, the resulting gas-reactive actuator will, without the use of the first shut-off electro-pneumatic valve and pressure regulator in the first analogue, create a predetermined constant reactive force at lower gas costs.

In addition, it should be noted that a decrease in the stroke of the movable element 10 in the transitional opening mode and a certain throttling of the gas flowing in this mode from the cavity 21 to the cavity 16 through the throttling hole between the regulating body 6 and the outlet seat 8, contribute to the reduction of overshoot and increase the stability of the steady state open device state when operating in pressure control mode. On the other hand, the possible flow of part of the gas from the cavity 16 to the cavity 21 in the transitional opening process is accompanied by a dynamic cleaning of this part due to its rotation when it flows from the channel 20 into the cavity 16 by an angle close to 90 °, which increases the reliability of the device’s gas engine .

Claims (1)

A low-pressure constant pressure start-up electropneumatic valve containing a setting element for a given low pressure, a high-pressure cavity with a gas supply channel, a control solenoid valve with an inlet seat in communication with a gas supply channel, a regulating body driven by an electromagnet, and an exhaust seat, a cylindrical chamber and a movable element with two rods, equipped with a stop and forming in the chamber from the side of the auxiliary cavity protruding into the high pressure cavity of the first rod with a mechanical spring located in it, and on the opposite side, a low-pressure cavity with a second rod protruding into it and an outlet channel, separated from the high-pressure cavity by a control valve connected to the tuning element, and a movable saddle made in the end face of the first rod and communicated in a movable element and rods with a low-pressure cavity, characterized in that the channel in the movable element and rods is straight-through, the auxiliary cavity is in communication with the atmosphere, and in the cylindrical chamber ene additional working chamber located between the movable element and the low-pressure cavity and communicated with the cavity of the feedback channel, into which a control solenoid valve so that its cavity communicates with the working chamber, and a discharge saddle with a low pressure cavity.