BG4093U1 - Hydrogen pressure reducing valve - Google Patents

Abstract

Hydrogen pressure reducing valve, which finds application in reduction (regulation) of pressure from a stand-alone high-pressure hydrogen tank to a certain value, as well as for regulation of the said value within certain limits. It consists of cylinder-piston groups, springs, valves and adjustment screw, as in the piston (4) of the first cylinder-piston group with a spring (3) is formed a cylinder in which are located a valve (5) and a nozzle (1) for supply of the inlet pressure, and the cylinder is connected to a chamber (B) for the primary reduced pressure. The piston (8) of another cylinder-piston group with a spring (9) has an opening connecting the chamber (B) for primary reduced pressure with a chamber (C) for outlet pressure, as the stem of this piston is a smooth cylinder and acts as a saddle of the second valve (6). On the other end of the piston (8) there is a spring regulating the outlet pressure (11) with an adjustment screw (12), counteracting the spring (9) of the cylinder-piston group.

Description

Hydrogen pressure reducer, which is used to reduce (reduce) pressure from a stand-alone high-pressure hydrogen vessel to a certain value, as well as to regulate this value within certain limits when feeding fuel cells and devices using hydrogen.

A hydrogen pressure reducer [1] is known, consisting of a piston-cylinder group, a spring and a valve, in which to reduce the effect of the change in inlet pressure on the outlet pressure, the outlet pressure is supplied under the valve stem via a balancing channel, and a radial sealing element comprising an auxiliary part is used to separate the inlet and outlet pressures.

The disadvantage of such a pressure reducer is the need for a high-pressure separating radial seal between the moving parts, as well as the potential possibility of mixing the inlet and outlet pressure.

A hydrogen pressure reducer [2] is known, containing one or more cylinder-piston groups, using one or more radial seals in the form of a corrugated cuff and static seals to the piston and cylinder.

The disadvantage of such a pressure reducer is the effect that the change in inlet pressure has on the outlet pressure.

The task of the utility model is to create a pressure reducer for hydrogen, which does not require radial sealing between the moving parts of the inlet (high) pressure, as well as reducing the impact of highly variable inlet pressure on the outlet pressure, provided adjustable of the outlet pressure.

The problem is solved with a pressure reducer for hydrogen, which consists of cylinder-piston groups, springs, valves and adjusting screw, and in the piston of the first cylinder-piston group with spring there is a cylinder in which a valve and a nozzle are located. of the inlet pressure, acting as a piston and a valve seat, and the cylinder is connected to a primary reduced pressure chamber in which there is a second valve. The piston of another spring-loaded cylinder-piston group has an opening connecting the primary reduced pressure chamber to the outlet pressure chamber, the stem of this piston being a smooth cylinder and acting as a seat on the second valve, and on the other piston face a regulating the output pressure spring with adjusting screw, counteracting the spring of the cylinder-piston group.

The advantages of such a hydrogen pressure reducer are the absence of the need for radial sealing between the moving parts of the inlet (high) pressure, with reduced influence of changing inlet pressure on the outlet pressure and the ability to adjust the outlet pressure.

An exemplary embodiment of such a hydrogen pressure reducer is shown in FIG. 1. It consists of series-connected housings 2, 7 and cap 10. In housings 2 and 7, cylinders of cylinder-piston groups are formed. Pistons 4 and 8 and springs 3 and 9 are mounted in the cylinders. A cylinder is formed in the piston 4, in which a valve 5 and a nozzle 1 are located, acting as a piston and a valve seat.

BG 4093 UI

Thus, chamber A for inlet (high) pressure is formed in the nozzle 1. The cylinder in the piston 4 and part of the housing 7 form a chamber B for primary reduced pressure. The front of the smooth stem of the piston 8 of another cylinder-piston group is used for the valve seat 6, and an opening in the piston connected to a cavity in the cap 10 forms a chamber C for secondary reduced outlet pressure. On the other end of the piston 8 is located a spring 11, counteracting the spring 9 and connected to the screw regulating the outlet pressure 12.

The action of the hydrogen pressure reducer is as follows.

The inlet pressure is supplied to chamber A via a nozzle 1. Part of this pressure, through valve 5 and holes in piston 4 and valve 6, enters chamber B and when this pressure causes axial force on piston 4, greater than spring force 3, the piston is moved and through chamber 5 closes chamber A (the connection between chambers A and B is interrupted). Thus, a certain (primary reduced) pressure is maintained in chamber B, depending on the force created by spring 3 and the force with which the inlet pressure acts on valve 5. Part of the pressure in chamber B enters chamber C through a hole in piston 8. When the secondary reduced pressure in chamber C creates an axial force on the piston 8 greater than the resulting force of the opposing springs 9 and 11, the piston 8 moves and closes chamber B through valve 6 (the connection between chambers B and C is interrupted). As the pressure in chamber C decreases, the connection between chambers B and C is renewed. The change in inlet pressure causes a variable axial force on the valve 5 or piston 4. and affects the primary reduced pressure in chamber B, which does not cause axial forces on the piston rod 8. Thus the outlet pressure in chamber C does not depend on changes in inlet pressure . Adjustment of the outlet pressure is carried out by means of an adjusting screw 12 acting on a spring 11.

Claims (1)

Hydrogen pressure reducer consisting of cylinder-piston groups, springs, valves and adjusting screw, characterized in that in the piston (4) of the first cylinder-piston group with spring (3) is formed a cylinder in which located valve (5) and nozzle (1) for supplying the inlet pressure, acting as a piston and a valve seat, the cylinder is connected to a chamber (B) for primary reduced pressure, in which there is a second valve (6), for the seat on which the stem of a piston (8) from another cylinder-piston group with a spring (9) is used, in the piston (8) of which there is an opening connecting the chamber (B) for primary reduced pressure with a chamber (C) for outlet pressure, and on the other end of the piston (8) there is a spring regulating the outlet pressure (11) with a regulating screw (12), counteracting the spring (9) of the cylinder-piston group