JP6968275B2 - A metering valve for controlling a gaseous medium - Google Patents

Description

The present invention relates to a metering valve for controlling a gaseous medium, especially hydrogen, for application, for example, in a vehicle having a fuel cell drive.

Patent Document 1 describes a metering valve configured as a proportional valve for controlling a gaseous medium, particularly hydrogen, and the proportional valve has a nozzle body, a closing member, and an elastic seal. Includes members. The nozzle body is configured with at least one passage opening that can be opened or closed at the valve seat by a closing member. The elastic sealing member is sealed with a valve seat.

The normal operation of a proportional valve, especially when applied as a proportional valve in the anode region of a fuel cell system, results in frequent opening and closing processes. Additional switching processes may also be desired to optimize the cleaning process at the fuel cell anode path, or for the best operation of the suction jet pump in the fuel cell structure. However, frequent opening and closing of the proportional valve results in wear on the valve seat and tilting of the closing member with respect to the valve seat. This is because an angle tolerance can occur between the closing member and the valve seat. This, in turn, has a negative effect on the tightness of the entire proportional valve.

German Patent Application Publication No. 1020122045665

In contrast, the metering valve according to the invention for controlling gaseous media, especially hydrogen, is guaranteed to be hermetically sealed at the valve seat despite the frequent opening and closing processes of the metering valve. Has the advantage of

To that end, the metering valve for controlling gaseous media, especially hydrogen, is longitudinally movable in cooperation with the valve seat to open and close the opening cross section from the inflow region to the passage opening. It has a valve housing with a flat closure member placed inside. The valve seat is configured as an orbiting seal edge on the seating surface of the nozzle housed in the valve housing and fixedly coupled to it facing towards the closure member. In addition to this, the seating surface of the nozzle is configured to be tapered, and the closing member has a radial protrusion in contact with the seal edge that orbits when the metering valve is in the closed position. The radial protrusion limits the maximum tilt position of the closure member on the nozzle seating surface when the closure is in the maximally formed tilted position, with the tapered seating surface opening angle β of 172 °. It is in the value range between 178 ° and.

With the metering valve according to the present invention, the descending seating surface produces an even force distribution in the closing member despite the angular error between the valve seat and the closing member, which in turn results in a higher sealing. It leads to sex.

In a first preferred development example, the radial overhang extends from the center of the orbiting seal edge to the outer orbiting edge of the closure member and has a width X of 0.2 mm to 2 mm, preferably 0.5 mm to 1 mm. Is intended. The orbiting seal edge of the nozzle preferably has a height R of between 0.04 mm and 0.2 mm, preferably 0.1 mm. In this way, the seal edge has the advantage of being able to enter the elastic sealing member arranged between the valve seat and the closing member with a low force, whereby the closing member and the seating surface of the nozzle are seated. High airtightness at the valve seat and thereby the best functional form of the metering valve is guaranteed when an additional tilt position occurs with the mounting surface of the radial protrusion to.

In another embodiment of the invention, it is preferred that the closure member is intended to be longitudinally movable by an electromagnet and by a magnetic armature acting and connected to the closure member. In this way, the gaseous medium can be controlled by the metering valve.

In a preferred development, it is intended that an inflow passage is configured in the valve housing radially with respect to the major axis of the metering valve, which allows the inflow region of the metering valve to be filled with a gaseous medium. NS.

The metering valve described is preferably configured as a proportional valve and is particularly suitable for controlling the hydrogen supply to the anode region of the fuel cell in a fuel cell structure. Its advantages are low pressure fluctuations and quiet operation in the anode path.

The drawings show examples of a metering valve according to the invention for controlling the gas supply of hydrogen, in particular to the fuel cell. The drawings show the following:

It is a vertical sectional view which shows the Example of the metering valve by this invention. FIG. 1 is an enlarged partial view showing a metering valve according to the present invention of FIG. 1 as a vertical sectional view in a region of a valve seat. FIG. 1 is an enlarged partial view showing the metering valve according to the present invention of FIG. 1 as a vertical cross-sectional view in the region of the valve seat when the closing member is tilted at the valve seat.

Components with the same function are represented by the same code.

FIG. 1 is a vertical sectional view showing an embodiment of the metering valve 100 according to the present invention. The metering valve 100 has a valve housing 12 having an internal space 26 inside. An electromagnet 130 including a magnetic coil 13, an inner pole 10 and an outer pole 11 is arranged in the internal space 26. The inner pole 10 is coupled to the valve housing 12 via a spacer bush member 14 made of a non-magnetic material.

Further, in the armature space 9 surrounded by the internal space 12, a stroke-movable magnetic armature 6 having a pin-shaped member 5 is arranged, and the pin-shaped member 5 is fixedly coupled to the magnetic armature 6. At the same time, it is accommodated and guided in the notch 27 of the inner pole 10 and the notch 28 of the valve housing 12. The magnetic armature 6 is configured as a plunger-type armature and is housed in the notch 22 of the inner pole 10 during stroke motion.

The valve housing 12 and the inner pole 10 separate the spring space 8, and the dish-shaped end 16 of the pin-shaped member 5 of the magnetic armature 6 is inserted into the spring space 8. A closing spring 15 is supported by the dish-shaped end 16 of the pin-shaped member 5, and the magnetic armature 6 is subjected to initial stress together with the pin-shaped member 5 by the closing spring. The end of the pin-shaped member 5 facing away from the closing spring 15 is fixedly coupled to the flat closing member 2. The closing member 2 has an elastic sealing member 3 at an end opposite to the pin-shaped end 5, and is arranged in the inflow region 7 of the metering valve 100. The spring space 8 and the armature space 9 are fluidly connected to each other via the first connecting passage 24, and the armature space 9 and the inflow region 7 are fluidly connected to each other via the second connecting passage 25.

An inflow passage 31 is configured in the radial direction with respect to the major axis 18 of the metering valve 100, and the inflow region 7 of the metering valve 100 can be filled with a gaseous medium by the inflow passage. The inflow region 7 is divided by a nozzle 1 in addition to the valve housing 12, and the nozzle has a passage opening 21. A seal edge 20 that faces the elastic sealing member 3 and circulates around the seating surface 1a of the nozzle 1 that is radially tapered with respect to the major axis 18 of the metering valve 100 is configured. The seat 4 is configured. The orbiting seal edge 20 has a height R of between 0.04 mm and 0.2 mm, preferably 0.1 mm, in the axial direction. When the metering valve 100 is in the closed position, the elastic sealing material 3 abuts on the valve seat 4 by the force of the closing spring 15, thereby closing the connection between the inflow region 7 and the passage opening 21. Be done.

Functional form of metering valve

The metering valve 100 is configured here as a proportional valve. When the magnetic coil 13 is not energized, the closing member 2 is pressed against the valve seat 4 through the closing spring 15, thereby breaking the connection between the inflow region 7 and the passage opening 21 to allow gas flow through. No.

When the magnetic coil 13 is energized, a magnetic force directed in the direction opposite to the closing force of the closing spring 15 is generated with respect to the magnetic armature 6. This magnetic force is transmitted to the closing member 2 via the pin-shaped member 5, whereby the closing force of the closing spring 15 is excessively compensated, and the closing member 2 is lifted from the valve seat 4. A gas flow from the inflow region 7 toward the passage opening 21 is released.

The stroke of the closing member 2 can be adjusted through the height of the current strength in the magnetic coil 13. The higher the current strength in the magnetic coil 13, the larger the stroke of the closing member 2 and the larger the gas flow through the metering valve 100. This is because the force of the closing spring 15 is stroke-dependent. When the current strength in the magnetic coil 13 decreases, the stroke of the closing member 2 also decreases, and thus the gas flow through is narrowed.

When the current in the magnetic coil 13 is cut off, the magnetic force on the magnetic armature 6 decreases, whereby the force on the closing member 2 by the pin-shaped member 5 decreases. The closing member 2 moves in the direction of the passing opening 21 and seals with the valve seat 4 with the elastic sealing member 3. The gas flow through the metering valve 100 is cut off.

FIG. 2 shows an enlarged partial view of a region of the valve seat 4 of the metering valve according to the present invention of FIG. 1 in a vertical cross section. When the metering valve 100 is in the closed position, the elastic seal member 3 abuts on the valve seat 4, and the orbiting seal edge 20 enters the elastic seal member 3. Due to the tapered seating surface 1a of the nozzle 1, the closing member 2 has an elastic sealing member 3 extending from the center of the orbiting seal edge 20 to the outer peripheral edge 17 of the closing member 10 from 0.2 mm to 2 mm. It preferably has a radial protrusion 10 having a width X of 0.5 mm to 1 mm.

The angle tolerance between the valve seat 4 and the elastic sealing member 3 leads to the tilt of the entire closing member 2 including the elastic sealing member 3. This is shown in FIG. Here, the tilted posture of the closing member 10 formed to the maximum is shown. At that time, the radial protrusion 19 limits the maximum tilted position of the closing member 2 on the seating surface 1a of the nozzle 1. The opening angle β of the tapered seating surface 1a is in the value range between 172 ° and 178 °. When the closing member 2 is tilted to the maximum, the radial protrusion 19 forms an angle α corresponding to 180 ° −β with the contact line 30 with the seating surface 1a. This angle α is in the range of values between 2 ° and 8 °. In spite of the tilting of the closing member 2 in this way, the airtightness of the valve seat 4 can be realized even in the tilted posture of the closing member 2 formed to the maximum.

1 Nozzle 1a Seating surface 2 Closing member 3 Elastic sealing member 4 Valve seat 6 Magnetic armature 7 Inflow area 12 Valve housing 18 Long axis 19 Long axis 19 Radial protrusion 20 Seal edge 21 Passing opening 31 Inflow passage 100 Metering valve 130 electromagnet

Claims (10)

A metering valve (100) having a valve housing (12) for controlling a gaseous medium, for opening and closing an opening cross section from an inflow region (7) to a passage opening (21). A longitudinally movable flat closing member (2) that cooperates with the valve seat (4) is arranged in the valve housing (12), and the valve seat (4) is placed in the valve housing (12). The nozzle (1) housed and fixedly coupled to it is configured as an orbiting seal edge (20) on a seating surface (1a) facing the closure member (2). In a smooth metering valve, the seating surface (1a) of the nozzle (1) is configured to be tapered, and the closing member (2) rotates when the metering valve (100) is in the closed position. It has a radial protrusion (19) in contact with the seal edge (20), and the radial protrusion (19) places the maximum tilt position of the closing member (2) on the seating surface (1a). in limit, Ri value ranges near between the aperture angle β is 178 ° from the 172 ° of tapered the seating surface (1a),
The closure member (2) is longitudinally movable by an electromagnet (130) and by a magnetic armature (6) acting and connected to the closure member (2).
The metering valve (100) is a closing spring (15) that presses the closing member (2) toward the seal edge (20) via a pin-shaped member (5) coupled to the magnetic armature (6). ), A spring space (8) accommodating the closing spring (15), and an armature space (9) accommodating the magnetic armature (6).
The spring space (8) and the armature space (9) are communicated with each other by a first connecting passage (24).
The armature space (9) and the inflow region (7) are communicated with each other by a second connecting passage (25).
It said first connecting passage (24) and said second connecting passage (25) is a metering valve, characterized in Rukoto formed in the longitudinal direction. The radial protrusion (19) extends from the center of the circumferential seal edge (20) to the outer circumferential edge (17) of the closure member (2) and has a width X of 0.2 mm to 2 mm. The metering valve (100) according to claim 1. The radial protrusion (19) extends from the center of the circumferential seal edge (20) to the outer circumferential edge (17) of the closure member (2) and has a width X of 0.5 mm to 1 mm. The metering valve (100) according to claim 1. The one according to any one of claims 1 to 3, wherein the orbiting seal edge (20) of the nozzle (1) has a height R between 0.04 mm and 0.2 mm. Measuring valve (100). The metering valve (100) according to any one of claims 1 to 3, wherein the circumferential seal edge (20) of the nozzle (1) has a height R of 0.1 mm. .. Claims 1 to 5, wherein an elastic sealing member (3) to be sealed by the valve seat (4) is arranged between the valve seat (4) and the closing member (2). The metering valve (100) according to any one of the above items. An inflow passage (31) is configured in the valve housing (12) in the radial direction with respect to the long axis (18) of the metering valve (100), and the inflow region of the metering valve (100) is provided by the inflow passage. The metering valve (100) according to any one of claims 1 to 6 , wherein the metering valve (7) can be filled with a gaseous medium. The metering valve (100) according to any one of claims 1 to 7 , wherein the metering valve (100) is configured as a proportional valve. The metering valve (100) according to any one of claims 1 to 8 , wherein the gaseous medium is hydrogen. A fuel cell structure comprising the metering valve (100) according to any one of claims 1 to 9 for controlling the supply of hydrogen to the fuel cell.

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