KR102165550B1 - Pressure reduction shaft device for high pressure electronic regulator - Google Patents

Abstract

The present invention relates to a high pressure regulator. The present invention has a body having a hollow in the axial direction, a piston accommodated in the hollow of the body so as to move up and down with a protrusion at the bottom, and a conical inner surface that becomes narrower downward and is accommodated under the piston to form an orifice in the body A guide that is installed under the guide, a sheet having a hole corresponding to the orifice of the body, an upper portion having a fitting protrusion, a slide portion in the middle, and a shaft that slides the hollow to the slide portion to move up and down, the A fitting groove is formed in the protrusion to provide a pressure reducing shaft mechanism of a high pressure regulator in which the fitting protrusion engages with the fitting groove when the shaft contacts the piston.

Description

Pressure reduction shaft device for high pressure electronic regulator

The present invention relates to a high pressure regulator.

The hydrogen vehicle uses a fuel cell system composed of a fuel cell stack body, a fuel supply unit, and a cooling unit. Hydrogen is supplied from the high-pressure tank to the fuel cell through the decompression of the regulator. The high pressure regulator decompresses high pressure hydrogen of up to 875 bar to the set pressure. The regulator discharges the reduced pressure hydrogen at a set flow rate.

Regulators that use hydrogen as fuel require even performance in the high and low pressure regions. Since hydrogen is used as fuel, the regulator must be airtight inside and out.

As a prior art document that can be referred to in relation to the hydrogen regulator, there is Patent No. 10-1759492 "Seal structure of a regulator for a hydrogen fuel cell vehicle".

Prior literature is a body for forming a low pressure at the bottom of the spool through the balance groove in communication with the outlet port; And a sealing member accommodated on the body so as to maintain a low pressure of the spool, and having an auxiliary portion for enhancing airtightness to the spring energized seal. Accordingly, the effect of enhancing operational reliability is expected by minimizing the change in the outlet pressure according to the change in the inlet pressure with the energetic seal during the hydrogen decompression process.

The regulator disclosed in the prior literature can perform stable decompression. However, there is a problem in that a leak may be caused in a decompression shaft that contacts a piston configured inside the regulator.

In addition, there is a problem in that the airtight state is unstable because the pressure reducing shaft does not come into close contact with the sheet in the process of reducing the pressure of hydrogen.

Registered Patent No. 10-1759492 "Hydrogen Fuel Cell Vehicle Regulator Sealing Structure" (Announcement 2017.07.31.)

An object of the present invention is to provide a decompression shaft mechanism of a high pressure regulator for closely maintaining a touch-type connection between a piston and a decompression shaft in a process of supplying fuel while being mounted on a hydrogen fuel cell vehicle.

It is an object of the present invention to provide a decompression shaft mechanism of a high pressure regulator capable of preventing irregular rotation of a shaft in contact with a piston while a fuel is depressurized in the regulator.

It is an object of the present invention to provide a pressure reducing shaft mechanism of a high pressure regulator capable of preventing fuel from leaking inside the regulator by closely maintaining a connection state between a piston and a shaft while fuel is depressurized in a regulator.

In order to solve the above problems, the present invention has a body having a hollow in the axial direction, a piston accommodated in the hollow of the body so as to move up and down with a protrusion at the bottom, and a conical inner surface that becomes narrower downward. A guide accommodated under the piston to form an orifice, a sheet installed under the guide and having a hole corresponding to the orifice of the body, and a seat having a fitting protrusion at an upper portion and a slide portion in the middle, and sliding the hollow to the slide portion It includes a shaft that moves up and down, and a fitting groove is formed in the protrusion to provide a pressure reducing shaft mechanism of a high pressure regulator in which the fitting protrusion engages with the fitting groove when the shaft contacts the piston.

A decompression shaft mechanism of a high pressure regulator in which a locking piece for restricting rotation of the shaft protrudes from the fitting groove while the fitting protrusion is engaged with the fitting groove.

The locking piece is formed symmetrically so as to face left and right, so that the fitting groove has a groove shape.

The locking piece is formed symmetrically up, down, left and right, and the fitting groove has a cross shape.

The decompression shaft mechanism of the high-pressure regulator of the present invention is mounted on a hydrogen fuel cell vehicle to secure a stable airtight performance by closely maintaining a touch-type connection between the piston and the decompression shaft during the supply of fuel.

The present invention has the effect of maintaining stable depressurization performance by preventing the shaft in contact with the piston from rotating irregularly while the fuel is depressurized in the regulator.

The present invention has the effect of preventing fuel from leaking inside the regulator by maintaining a long connection between the piston and the shaft.

1 is a block diagram showing a high pressure regulator according to an embodiment of the present invention in partial cross-section.
2 is a cross-sectional view and a partial enlarged view of AA′ in FIG. 1.
3 is an example of a contact portion between a piston and a shaft in the partially enlarged view of FIG. 2.
4 is another embodiment of a contact portion between a piston and a shaft in the partially enlarged view of FIG. 2.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This embodiment is provided to more completely describe the present invention to those with average knowledge in the art. Accordingly, the shape of the element in the drawings may be exaggerated to emphasize a clearer description. It should be noted that in each drawing, the same member may be indicated by the same reference numeral. In addition, detailed descriptions of known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention will be omitted.

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

1 is a block diagram showing a high pressure regulator according to an embodiment of the present invention in partial cross-section. 2 is a cross-sectional view and a partially enlarged view of a portion A-A' in FIG. 1. 3 is an embodiment of a contact portion between the piston 20 and the shaft 50 in the partially enlarged view of FIG. 2. 4 is another embodiment of the contact portion of the piston 20 and the shaft 50 in the partially enlarged view of FIG.

1 and 2, the high pressure regulator according to an embodiment of the present invention includes a body 10, a piston 20, a guide 30, a seat 40, and a shaft 50. .

In the high pressure regulator, the body 10 forms the exterior. The body 10 has a hollow 11 in the axial direction. The body 10 has a number of ports in the axial and radial directions. The body 10 has an inlet port 12, an outlet port 15, and a sensor port 17 in the radial direction on the side while having a hollow 11 in the upper and lower axial directions at the center. A hole is formed on the side of the body 10 in addition to the above port. A valve port 19 is formed at the lower end of the body 10. The inlet port 12, the sensor port 17, and the valve port 19 are connected to be in direct communication with the hollow 11. The outlet port 15 is not directly connected to the hollow 11 but is connected to the hollow 11 through an outlet hole.

The piston 20 is accommodated in the hollow 11 of the body 10 so as to move up and down. The piston 20 has a protrusion 21 at the bottom. The piston 20 is disposed above the hollow 11. The piston 20 receives an elastic force from the top by a spring. The elastic force acting on the piston 20 can be varied by adjusting bolts to change the outlet pressure. The adjustment bolt 14 and the spring are installed on the cover 12 coupled to the upper side of the body 10.

The guide 30 is accommodated under the piston 20 having a conical inner surface that becomes narrower downward. The guide 30 accommodated in the piston 20 forms an orifice 13 in the body 10. The sheet 40 is installed under the guide 30. The sheet 40 has a hole 41 corresponding to the orifice 13 formed in the body 10. The guide 30 and the sheet 40 are structured to be accommodated to form an orifice 13 in the hollow 11 of the body 10. The seat 40 is fixed to the middle portion of the hollow 11 of the body 10. The sheet 40 has a hole 41 for forming an orifice 13 in the center of the body 10. The guide 30 is installed on the upper side of the seat 40 in order to restrain the vertical movement of the seat 40. An orifice 13 is formed by the guide 30 and the sheet 40 in the hollow 11 of the body 10 by fixing the guide 30 on the upper side while the sheet 40 is installed. The conical inner surface of the guide 30 is for uniform diffusion of high-pressure hydrogen flowing into the guide 30 through the orifice 13.

The shaft 50 is formed elongated along the vertical direction of the hollow (11). The shaft 50 is divided into upper, middle and lower parts. It has a fitting protrusion 51 in the upper part and a slide part 53 in the middle. The shaft 50 slides the hollow 11 of the body 10 with the slide 53 and moves up and down. The shaft 50 is installed to pass through the piston 20 and the seat 40. The shaft 50 performs pressure control while moving the hollow 11 up and down. Pressure regulation is performed by elastic force in the axial direction by a spring installed at the bottom. The upper part of the shaft 50 changes the cross-sectional area of the flow path flowing through the orifice 13 while passing through the seat 40 and the guide 30. The slide portion 53 of the shaft 50 has a cross-sectional area larger than that of the orifice 13. When the shaft 50 moves upward, the slide part 53 blocks the hole 41 of the seat 40 to block the flow path formed by the orifice 13.

Referring to the partially enlarged view of FIG. 2, a fitting groove 23 is formed in the protrusion 21 of the piston 20.

When the shaft 50 contacts the piston 20, the fitting groove 23 engages the fitting protrusion 51 of the shaft 50. The fitting groove 23 has a concave shape and the fitting protrusion 51 has a convex shape. The fitting groove 23 and the fitting protrusion 51 have a shape corresponding to each other so that the angler fits. The fitting protrusion 51 may be chamfered so that the surface engaging the fitting groove 23 is inclined. In the fitting groove 23, a locking piece 25 is formed to protrude. The locking piece 25 determines the concave shape of the fitting groove 23. The fitting protrusion 51 is engaged with the fitting groove 23 in which the locking piece 25 is formed, and rotation of the shaft 50 is restricted by the locking piece 25.

3 and 4, as an embodiment of the fitting groove 23 of the piston 20 and the fitting protrusion 51 of the shaft 50, the locking piece 25 is formed symmetrically so as to face left and right to be fitted. The groove 23 has a groove shape. In addition, as another embodiment, the locking piece 25 is formed symmetrically vertically and horizontally, and the fitting groove 23 has a cross shape.

The operation and operation of the decompression shaft mechanism of the high-pressure regulator according to the present invention configured as described above will be described as follows.

The present invention relates to a high pressure regulator for regulating a supply pressure of fuel supplied to a vehicle. The fuel supplied is mainly hydrogen. Hydrogen is stored in high pressure fuel tanks for stability reasons. And when supplied, the hydrogen fuel is depressurized to a low pressure. Depressurization takes place in a high pressure regulator.

In the high pressure regulator, the pressure of hydrogen (gas) formed at the inlet port is reduced to a constant pressure at the outlet port. Decompression is performed in a decompression chamber inside the high pressure regulator. Hydrogen fuel is decompressed while passing through the orifice 13 by the operation of the piston 20 and the shaft 50 in the decompression chamber.

The upper part of the shaft 50 passes through the orifice 13 formed by the guide 30 and the seat 40 and is installed to contact the protrusion 21 of the piston 20. The protrusion 21 of the piston 20 moves up and down according to the pressure change of the depressurized fuel. In conjunction with the lifting operation of the piston 20, the shaft 50 moves up and down to open or close the orifice 13.

The shaft 50 operates at a high frequency in the process of decompressing the fuel by contacting the piston 20. The shaft 50 operating at a high frequency makes unspecified rotation while in contact with the piston 20. This rotation of the shaft 50 prevents the tight fit of the shaft 50 and the seat 40.

The fitting groove 23 is formed in the protrusion 21 of the piston 20, and the fitting protrusion 51 of the shaft 50 is formed so that the fitting groove 23 and the fitting protrusion 51 are engaged with each other. 50) can be prevented from rotating.

3, the fitting groove 23 of the piston 20 is symmetrically formed so that the two locking pieces 25 face left and right. The fitting groove 23 formed at the end of the protrusion 21 has a locking piece 25 protruding symmetrically so as to face each other on the outer circumferential surface. The fitting groove 23 by the locking piece 25 may have a U-shaped groove shape.

When the fitting protrusion 51 is engaged with the fitting groove 23, the locking piece 25 protruding symmetrically may limit the rotation of the shaft 50. By the contact pressure between the piston 20 and the shaft 50, the fitting protrusion 51 and the fitting groove 23 are strongly engaged. The strong engagement can prevent rotation of the shaft 50 just by restricting the movement of the fitting protrusion 51 by the locking piece 25.

Looking at another embodiment shown in FIG. 4, the fitting groove 23 of the piston 20 has four locking pieces 25 formed symmetrically vertically. The fitting groove 23 formed at the end of the protrusion 21 has four locking pieces 25 protruding symmetrically up, down, left and right so as to face each other on the outer circumferential surface. The fitting groove 23 by the locking piece 25 may have a cross shape.

When the fitting protrusion 51 is engaged with the fitting groove 23, the protruding locking piece 25 may limit the rotation of the shaft 50. By the contact pressure between the piston 20 and the shaft 50, the fitting protrusion 51 and the fitting groove 23 are strongly engaged. The strong engagement can prevent rotation of the shaft 50 just by restricting the movement of the fitting protrusion 51 by the locking piece 25. Since the fitting groove 23 has a cross shape, it is not limited to the direction in which the fitting protrusion 51 is inserted into the fitting groove 23.

The embodiments of the decompression shaft mechanism of the high-pressure regulator of the present invention described above are merely exemplary, and various modifications and other equivalent embodiments are possible from those of ordinary skill in the art to which the present invention belongs. You will know well. Therefore, it will be appreciated that the present invention is not limited to the form mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. In addition, the present invention is to be understood as including the spirit of the present invention as defined by the appended claims and all modifications, equivalents and substitutes within the scope thereof.

10: body
11: hollow
13: Orifice
20: piston
21: protrusion
23: fitting groove
25: jamming piece
30: guide
40: sheet
41: hole
50: shaft
51: fitting protrusion
53: slide part

Claims (4)

A body having a hollow in the axial direction;
A piston having a protrusion at a lower portion thereof and accommodated in a hollow of the body to be vertically moved;
A guide accommodated under the piston to form an orifice in the body with a conical inner surface that becomes narrower downward;
A sheet installed under the guide and having a hole corresponding to the orifice of the body; And
A shaft having a fitting protrusion in the upper portion and a slide portion in the middle, and a shaft that slides the hollow through the slide portion and moves up and down;
Including,
A fitting groove is formed in the protrusion, and when the shaft contacts the piston, the fitting protrusion is engaged with the fitting groove,
A decompression shaft mechanism of a high pressure regulator in which a locking piece for restricting rotation of the shaft protrudes from the fitting groove while the fitting protrusion is engaged with the fitting groove. delete In claim 1,
The locking piece is formed symmetrically so as to face left and right, so that the fitting groove has a groove shape. In claim 1,
The locking piece is formed symmetrically up, down, left and right, and the fitting groove has a cross shape.

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