KR20130105979A - Regulator - Google Patents

Abstract

PURPOSE: A regulator is provided to obtain the decompression rate with a large width and to precisely control pressure. CONSTITUTION: A regulator comprises a body (100), a valve body (200), a piston (300), a cover (400), a spring (500), an auxiliary spring (600), and a solenoid valve (700). The body is formed to have an inlet port and an outlet port. The valve body controls the opening rate of a first valve seat (130) which is formed on the valve body. The piston is installed on the body, and fixedly combined with the valve body. The cover is combined with the body. The spring is interposed between the piston and the cover. The auxiliary spring is interposed between the body and the valve body. The solenoid valve controls the opening rate of a second valve seat (140) which is formed on the body.

Description

Regulator {REGULATOR}

TECHNICAL FIELD The present invention relates to a regulator, and more particularly, to a regulator for reducing pressure in two stages at a constant pressure required by an engine or a system.

In general, the regulator is a device for supplying to the outlet side by reducing the high pressure gas pressure formed on the inlet side to a predetermined pressure.

Such a gas pressure reducing regulator performs only one-stage pressure reduction, and a representative structure thereof is disclosed in Document 1 below. Hereinafter, a configuration thereof will be described with reference to FIG. 1.

As shown in FIG. 1, the conventional regulator 10 includes a gas supply port 6 through which gas is supplied from a control valve, a diaphragm 7 that expands and contracts with the inflow and outflow of gas, and A pressure regulating screw 8a for adjusting the flow rate, a balance spring 8 for pressing the diaphragm 7, and a valve 6a installed at the gas supply port 6 when the diaphragm 7 is lowered are opened and closed. The lever 9 is comprised.

First, when the high-pressure fuel is introduced into the interior through the valve 6a provided at the end of the gas supply port 6, the pressure in the decompression chamber is increased, and the diaphragm 7 is raised upward.

In this case, the balance spring 8 provided on the upper surface of the diaphragm 7 is retracted, and the main spring 9a mounted at the lower part of the lever 9 is expanded while the valve 6a formed at the top of the gas supply port 6. ) To close the gas supply.

The gas thus decompressed is discharged through the gas discharge port 10a formed at one side, and the diaphragm 7 is lowered by the elasticity of the balance spring 8 to operate the lever 9 downward to operate the gas supply port 6. The gas starts to be supplied again by opening the valve 6a.

As such, the high pressure fuel is moved to the next step in a state in which the high pressure fuel is decompressed through repeated opening and closing of the valve 6a.

However, in the conventional regulator 10, the cross-sectional area of the decompression chamber had to be large and the spring constant of the spring had to be adopted to reduce the pressure of a considerable magnitude. In this case, there is a problem that the total volume is increased and the installation cost increases.

In addition, since the pressure is reduced only by the expansion and contraction of the spring and the diaphragm, there is a limit to controlling the fluctuation range of the outlet pressure small according to the large fluctuation of the inlet pressure.

[Reference 1] Korea Utility Model Registration No. 0289663 (2002.09.04)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a large pressure reduction ratio by adjusting a reduced pressure to secondary pressure at a constant pressure required by an engine or a system. In addition, the present invention provides a regulator capable of precisely controlling pressure.

In addition, another object of the present invention to provide a regulator capable of automatically controlling the pressure and flow rate of the desired gas by measuring the outlet pressure of the reduced pressure gas.

Further, another object of the present invention is to provide a regulator that protects the driving part by maintaining a constant pressure even when the pressure exceeds the set pressure during the reduced pressure over the secondary.

Regulator of the present invention for achieving the above object, the inlet port and the outlet port body is formed; A valve body for adjusting the opening amount of the first valve seat formed in the body; A piston installed in the body and fixedly coupled to the valve body so that the pressure of the gas introduced through the inlet port acts; A cover coupled to the body to close the open end of the body on which the piston is installed; A spring interposed between the piston and the cover; An auxiliary spring interposed between the body and the valve body; And a solenoid valve controlling an opening amount of the second valve seat formed on the body.

The body is further provided with a pressure sensor for measuring an outlet pressure of the gas.

In addition, the feedback pressure measured by the pressure sensor to the solenoid valve (FEEDBACK) is characterized in that for automatically controlling the opening amount of the second valve seat.

The body may further include a cutoff valve for opening and closing the inflow of the high pressure gas introduced into the inlet port.

The body may include a first flow path connecting the first valve seat and the second valve seat and a bypass flow path connecting the first connection flow path and the pressure reducing chamber in which the piston is installed.

The body may further include a relief valve for discharging the gas to the outside of the body to maintain a constant pressure when the pressure of the gas passing through the first valve seat is higher than the set pressure.

The relief valve may further include a relief valve seat formed in the body, a relief valve body for opening and closing the reel pipe valve seat, a relief body coupled with the body to surround the relief valve body, and the relief valve body; And a relief spring interposed between the relief bodies to apply an elastic force to move the relief valve body in the relief valve seat direction.

Further, the cover is screwed to the body to adjust an elastic force of the spring.

In addition, the body is characterized in that the hot water nipple is installed.

According to the regulator according to the present invention, the gas compressed to high pressure by the first pressure reduction by the valve body and the piston and the second pressure reduction by the solenoid valve is adjusted to reduce the pressure to the pressure required by the engine or the system. At the same time, it is possible to obtain a pressure reduction ratio of the width and to control the pressure precisely.

In addition, the outlet pressure of the decompressed gas measured by the pressure sensor is fed back to the solenoid valve to automatically control the opening and closing amount of the second valve seat.

That is, by measuring the outlet pressure of the reduced pressure gas automatically controls the pressure and flow rate of the desired gas.

In addition, by adjusting the cover screwed with the body, it is possible to freely adjust the set pressure of the valve body and the piston by adjusting the elastic force of the spring.

In addition, the hot water nipple is provided to prevent the risk of operation deterioration and damage caused by the temperature decrease generated during the decompression.

In addition, the relief valve maintains a constant pressure even when the pressure exceeds the set pressure during the second pressure reduction by the relief valve to protect the driving part.

1 is a cross-sectional view showing an example of a conventional gas pressure reducing regulator.
2 is a perspective view showing a regulator according to the present invention.
3 is a cross-sectional view of Fig.
4 is a cross-sectional view of the pressure sensor of FIG. 2.
5 is a cross-sectional view illustrating the relief valve of FIG. 2.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view illustrating a regulator according to the present invention, FIG. 3 is a sectional view of FIG. 2, FIG. 4 is a sectional view of the pressure sensor of FIG. 2, and FIG. 5 is a sectional view of the relief valve of FIG. 2. .

2 to 5, the regulator A according to the present invention includes a body 100 having an inlet port 110 and an outlet port 120, and a first body formed on the body 100. The valve body 200 for adjusting the opening amount of the valve seat 130, and is installed in the body 100 so that the pressure of the gas introduced through the inlet port 110 acts and is fixed to the valve body 200 Piston 300 to be coupled, the cover 400 is coupled to the body 100 to close the open end of the body 100, the piston 300 is installed, the piston 300 and the cover 400 ) The opening amount of the spring 500 interposed between the auxiliary spring 600 interposed between the body 100 and the valve body 200, and the second valve seat 140 formed on the body 100. It consists of a solenoid valve 700 to adjust.

First, the body 100 is engaged with the cover 400 to play a role of a housing (Housing) to allow the parts to perform the pressure-sensitive adjustment function to take place.

In addition, the valve body 200 forms a gap between the first valve seat 130 and the valve body 200 by raising and lowering the piston 300 by the gas pressure and the spring 500. Decompression is achieved.

In addition, the piston 300 plays a role of diaphragm similar to the function of a known diaphragm (Diaphragm) to act as a pressure of the gas acts to move the valve body 200. That is, the pressure of the gas acts to adjust the gap between the valve body 200 and the first valve seat 130.

On the other hand, the cover 400 is to support the piston 300 and the spring 500.

In addition, the spring 500 supports the force transmitted by the piston 300 by the gas to maintain the parallel of the force, through which the primary pressure setting is possible.

Specifically, the cover 400 is screwed with the body 100 because it is possible to adjust the elastic force of the spring (500).

In addition, the auxiliary spring 600 serves to support the valve body 200.

On the other hand, the solenoid valve 700 precisely adjusts the opening degree of the second valve seat 140 for the gas primarily depressurized by the first valve seat 130, the valve body 200, the piston 300. As a result, the second pressure reduction is performed.

In addition, the body 100 is further provided with a pressure sensor 710 for measuring the outlet pressure of the gas, by feeding back the outlet pressure measured by the pressure sensor 710 to the solenoid valve 700 (FEEDBACK) The opening amount of the second valve seat 140 is automatically controlled.

Specifically, the value measured by the pressure sensor 710 is transmitted to an ECU (not shown) of a known vehicle, and the ECU (not shown) calculates whether the signal is an appropriate pressure and returns the calculated value to the solenoid valve. Feedback to 700 to maintain a constant pressure.

That is, the solenoid valve 700 controlled by the duty value of the pressure sensor 710 has a wide pressure control displacement through automatic pressure control, and receives the signal of the pressure sensor 710 through the ECU. 700 can immediately control the displacement of the second valve seat 140, so that there is no pressure drop to maintain a constant outlet pressure.

In addition, the pressure sensor 710 is installed at a position capable of measuring the pressure of the gas discharged to the outlet port 120 by secondary pressure reduction as shown in FIG. 4.

The body 100 further includes a cutoff valve 800 that opens and closes the inflow of the high pressure gas introduced into the inlet port 110. At this time, the cutoff valve 800 is installed on the flow path connecting the first valve seat 130 in the inlet port 110 to open and close the flow path by an electrical signal.

On the other hand, the solenoid valve 700 and the cut-off valve 800 is a known solenoid valve is applied to the detailed description of the structure and operation will be omitted.

In addition, the body 100 is provided with a first connection flow path 150 and the first connection flow path 150 and the piston 300 connecting the first valve seat 130 and the second valve seat 140. The bypass flow path 170 connecting the decompression chamber 160 is formed.

And, in the body 100, as shown in Figure 5 when the pressure of the gas passing through the first valve seat 130 is higher than the set pressure relief gas for discharging the gas to the outside of the body 100 to maintain a constant pressure 900 is further provided.

In detail, the relief valve 900 includes a relief valve seat 910 formed in the body 100, a relief valve body 920 that opens and closes the relief pipe seat 910, and the relief valve body. A relief body 930 coupled to the body 100 to surround 920 and having a discharge hole 931 formed therebetween and interposed between the relief valve body 920 and the relief body 930 so as to surround the relief valve body ( Relief spring 940 is applied to the elastic force to move the 920 in the direction of the relief valve seat (910).

Accordingly, when the pressure of the gas is higher than the set pressure, the relief valve body 920 compresses the relief spring 940 and opens the relief valve seat 910 so that the gas is discharged to maintain the positive pressure. 910 is closed.

On the other hand, the hot water nipple 180 is installed on the body 100. Accordingly, the hot water is circulated through the hot water nipple 180 to the hot water flow passage (not shown) of the body 100 to prevent the risk of operation deterioration and damage caused by the temperature decrease generated when the gas is decompressed.

According to the present invention, the gas compressed to high pressure by the primary pressure reduction by the valve body 200 and the piston 300 and the secondary pressure reduction by the solenoid valve 700 to the secondary at a pressure required by the engine or the system. By adjusting the pressure reduction overly, a large pressure reduction ratio can be obtained and the pressure can be precisely controlled.

In addition, the outlet pressure of the reduced pressure gas measured by the pressure sensor 710 is fed back to the solenoid valve 700 to automatically control the opening and closing amount of the second valve seat 140.

That is, by measuring the outlet pressure of the reduced pressure gas automatically controls the pressure and flow rate of the desired gas.

In addition, by adjusting the cover 400 coupled to the body 100 and the screw 400 can adjust the elastic force of the spring 500 to freely adjust the set pressure of the valve body 200 and the piston 300.

In addition, the relief valve 900 protects the driving part by maintaining a constant pressure even when the pressure exceeds the set pressure during the second pressure reduction.

Hereinafter, the operation of the regulator according to the present invention will be described.

First, the high pressure gas introduced from the inlet port 110 is introduced through the first valve seat 130, and at this time, the force of the spring 500 and the pressure of the gas opposite thereto are transmitted to the piston 300 d so that Constant pressure can be maintained in parallel.

When the set inlet pressure rises, the piston 300 rises and the valve body 200 also rises to move in the direction of closing the first valve seat 130, thereby lowering the pressure of the gas.

On the other hand, when the inlet pressure is lower than the set pressure, the valve body 200 moves in the direction of opening the first valve seat 130 in the opposite direction to the above principle, thereby increasing the outlet pressure.

The first pressure-reduced gas is introduced into the second valve seat 140 through the first connection passage 150.

Thereafter, secondary pressure reduction is achieved by adjusting the opening amount of the second valve seat 140 by the pressure sensor 710 and the solenoid valve 700.

That is, a gap is generated between the second valve seat 140 and the solenoid valve 700, and finally, the pressure is reduced. The decompressed gas is discharged out of the regulator A through the outlet port 120.

Although the preferred embodiments of the present invention have been described in detail, the technical scope of the present invention is not limited to the above-described embodiments, but should be construed according to the claims. It will be understood by those skilled in the art that many modifications and variations are possible without departing from the scope of the present invention.

A-Regulator 100-Body
110-Inlet Port 120-Outlet Port
130-1st valve seat 140-2nd valve seat
150-Connection 1 160-Pressure Reducing Room
170-Bypass Euro 180-Hot Water Nipples
200-valve body 300-piston
400-Cover 500-Spring
600-Auxiliary Spring 700-Solenoid Valve
710-Pressure Sensor 800-Cutoff Valve
900-relief valve

Claims (9)

A body formed with an inlet port and an outlet port;
A valve body for adjusting the opening amount of the first valve seat formed in the body;
A piston installed in the body and fixedly coupled to the valve body so that the pressure of the gas introduced through the inlet port acts;
A cover coupled to the body to close the open end of the body on which the piston is installed;
A spring interposed between the piston and the cover;
An auxiliary spring interposed between the body and the valve body; And
And a solenoid valve configured to adjust an opening amount of a second valve seat formed on the body.
The method of claim 1,
Wherein the body is further provided with a pressure sensor for measuring an outlet pressure of the gas.
The method of claim 2,
And the outlet pressure measured by the pressure sensor is fed back to the solenoid valve to automatically control the opening amount of the second valve seat.
The method of claim 1,
The body regulator further comprises a cutoff valve for opening and closing the inflow of the high pressure gas introduced into the inlet port.
The method of claim 1,
And a bypass flow passage formed in the body to connect a first connection passage connecting the first valve seat and the second valve seat and a pressure reducing chamber in which the first connection passage and the piston are installed.
The method of claim 1,
And a relief valve for discharging the gas to the outside of the body to maintain a constant pressure when the pressure of the gas passing through the first valve seat is higher than the set pressure.
The method according to claim 6,
The relief valve,
A relief valve seat formed on the body, a relief valve body for opening and closing the reef valve seat, a relief body coupled to the body to surround the relief valve body, and a relief valve body interposed between the relief valve body and the relief body, And a relief spring for applying an elastic force to move the relief valve body in the direction of the relief valve seat.
The method of claim 1,
And the cover is screwed with the body to adjust the elastic force of the spring.
The method of claim 1,
The body regulator is characterized in that the hot water nipple is installed.

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