DE102012003505A1 - Valve - Google Patents

Abstract

A valve (2) for controlling a fluid flow, in particular a gas flow, with a valve seat (3), a valve closing element (5) which seals between a closed position in which it seals against the valve seat (3) and an open position in which it is spaced from the valve seat (3) and permits fluid flow through the valve (2), is operable in the axial direction (21), and a coil spring (12) which moves the valve closure member (5) to the closed position along the axial direction (21 ) and in the radial direction (37) presses against an adjacent element (11).

Description

Technical area

The present invention relates to a valve for controlling a fluid flow, in particular a gas flow.

State of the art

Valves for controlling a gas flow are known. These are used for example in Luftentölelementen in vacuum pumps.

Such valves tend due to component tolerances in interaction with the partly pulsating gas flow to flutter and rattling. This can lead to various problems, such as increased wear or excessive noise. To avoid this flapping or rattling, there are different approaches based on tolerance compensation or damping.

Disclosure of the invention

It is an object of the present invention to provide an improved valve in which the flapping or rattling is reduced, without the need for additional components must be provided.

To solve this problem, a valve for controlling a fluid flow, in particular a gas flow, is proposed. The valve has a valve seat, a valve closing element and a coil spring. The valve closing element seals in a closed position against the valve seat or it partially closes up to a minimum opening cross-section. In an open position, the valve closure member is spaced from the valve seat and allows fluid flow through the valve. The valve closing element can be actuated between the closed position and the open position in the axial direction. The coil spring biases the valve closing member along the axial direction to the closed position. Further, the coil spring presses the valve closing element in the radial direction against an adjacent element.

The fact that the coil spring presses the valve closing element against the adjacent element, resulting in friction that prevents fluttering or rattling or at least reduced. The coil spring is thus assigned a double function, namely once to bias the valve closing element along the axial direction in the closed position and also to press the valve closure member in the radial direction against the adjacent element. Additional components to counteract the flutter or rattle are therefore not required. The axial and radial directions are perpendicular to each other.

According to one embodiment, the coil spring rests on the one hand against the valve closing element and on the other hand against an abutment, wherein a contact surface of the valve closing element and / or the abutment is arranged obliquely with respect to the axial direction. "Oblique" means in the present case that the contact surface with the axial direction forms an angle between 0 and 90 degrees, preferably between 90 and 60 degrees and more preferably between 65 and 80 degrees. The oblique abutment surface causes the coil spring to curve and not extend straight, as in solutions known from the prior art. This curvature leads to transverse forces which press the valve closing element against the adjacent element. The oblique contact surface may be formed on the valve closing element or on the counter bearing or on both. Alone due to the inclined contact surface thus the flutter or rattle can be at least reduced without additional components, such as a leaf spring would be needed.

According to a further embodiment, the adjacent element is formed as a guide sleeve, within which a valve cone of the valve closing element is arranged in the open position. Preferably, the coil spring presses the poppet against an inner surface of the guide sleeve.

According to one embodiment, the valve closing element has a valve stem which is arranged inside the spiral spring. A deformation of the coil spring, in particular a buckling thereof, can be limited to a defined extent. Alternatively, it would also be possible that, for example, three of the coil springs are provided and the valve stem (or more valve stems) extend outside of the coil springs.

A valve stem of the valve closure member may extend into an aperture in the anvil. The valve stem can thus be performed at least to some extent in the anvil. The opening may for example have a diameter which is several 100 microns larger than the diameter of the valve stem. In this way, a tilting of the valve stem can be ensured, so that the valve cone comes into contact with the inner surface of the guide sleeve.

According to a further embodiment, the oblique abutment surface is formed on an edge of the opening of the abutment. An edge is provided by the house and is particularly suitable as a contact surface.

The counter-bearing may be in the form of a sleeve. In particular, it may be a circular cylindrical sleeve. According to one embodiment, the edge extends along a sectional surface of a plane oriented obliquely to the axial direction. As a result, the inclined contact surface is generated in a simple manner.

According to another embodiment, an annular segment-shaped portion extends in the axial direction from the edge of the sleeve. At the ring segment-shaped portion, the coil spring and / or the valve stem can be supported in particular. In particular, in the open position of the valve cone of the valve stem is tilted relative to the anvil. This tilting can be limited by the ring segment-shaped section.

The counter-bearing can be connected by means of a plurality of webs with the guide sleeve. Openings may be formed between the lands for passage of the fluid toward or away from an opening defined by the valve seat. The opening delimited by the valve seat is the opening which is closed by the valve plug when it is in the closed position. This results in a compact design.

According to a further embodiment, the webs extend radially away from the anvil towards the guide sleeve. For example, the webs can connect radially on the outside to the sleeve forming the counterbearing on the one hand and to the inner surface of the guide sleeve on the other hand.

According to a further embodiment, the valve seat is formed in a cover of the valve. The cover, the guide sleeve, the webs, the anvil, the valve cone and the valve stem can each be formed from plastic.

Furthermore, an air de-oiling element and a vacuum pump are provided with the valve according to the invention. The Luftentölelement is particularly interchangeable used in the vacuum pump.

Further possible implementations of the invention also include not explicitly mentioned combinations of features or embodiments of the valve, the air de-oiling element or the vacuum pump described above or below with reference to the exemplary embodiments. The skilled person will also add or modify individual aspects as improvements or additions to the respective basic form of the invention.

Further embodiments of the invention are the subject of the dependent claims and the embodiments of the invention described below. Furthermore, the invention will be explained in more detail by means of embodiments with reference to the accompanying figures.

Brief description of the drawings

It shows:

1 schematically an air de-oiling element, in particular a vacuum pump with a Luftentölelement, with a perspective, broken and shown in exploded view valve;

2 a side view of the valve 1 wherein the curvature of a coil spring is illustrated;

3 a sectional view III-III from 1 ;

4 an enlarged detail IV 3 ; and

5 a view V from 3 ,

In the figures, like reference numerals designate like or functionally identical elements, unless indicated otherwise.

Embodiment (s) of the invention

1 shows schematically a Luftentölelement 1 and in particular a vacuum pump containing the air de-oiling element 1 ,

The air deoiling element 1 includes a perspective broken out and shown in exploded view valve 2 , The valve 2 is designed to control a fluid flow, in particular a gas flow. This control function may be a complete shut-off of the fluid flow or also a reduction or increase in the flow rate of the fluid flow through the valve 2 include.

The valve 2 has a valve seat 3 on which one on a lid 4 of the valve 2 is formed and an opening 6 Are defined.

Furthermore, the valve comprises 2 a valve closing element 5 , which consists of a valve cone 8th and a valve stem 9 composed. The valve cone 8th is located in the 1 shown position in a closed position, in which he against the valve seat 3 fluid-tight, in particular gas-tight, seals and thus the opening 6 closes. However, the poppet can 8th groove 7 which, even in the closed position of the valve cone 8th some fluid flow through the valve 2 allow. The valve cone 8th is further positionable in an open position in which he from the valve seat 3 is spaced. In this position is a fluid flow through the valve 2 authorized. Depending on the distance, the fluid flow can be reduced or increased.

The valve 2 also has a guide sleeve 11 on. The valve cone 8th is in the in 2 shown open position of the valve cone 8th partially within the guide sleeve 11 arranged. 2 shows a side view 1 ,

Now returning to 1 , there is a coil spring 12 shown, which also part of the valve 2 is and on the one hand to the valve cone 8th and on the other hand at an abutment 13 of the valve 2 supported. The spiral spring 12 clamps the valve cone 8th in the closed position, see 1 , in the axial direction 21 in front. The valve stem 9 is inside the coil spring 12 arranged. The spiral spring 12 For example, it can be made of helically bent wire. The wire may in particular have a circular cross-section.

The spiral spring 12 rests against the valve cone 8th on a dashed, because hidden, illustrated contact surface 14 tapered off. Counter bearing side, the coil spring is supported 12 on an inclined contact surface 15 from. "Oblique" here means an angle 16 between a level 17 (please refer 2 ) and the axial direction 21 , which is not equal to 90 °. The angle 16 is for example between 90 and 60 °, preferably between 65 and 80 °. The axial direction 21 is opposite to the main flow direction of the fluid through the valve 2 , The axial direction 21 but can also the main flow direction of the fluid through the valve 2 correspond.

The construction of the counter-holder 13 is detailed below in connection with the 3 - 5 explained in more detail, wherein 3 a sectional view III-III from 1 . 4 an enlarged view IV 3 and 5 a view V from 3 shows.

From a synopsis of 1 and 3 it can be seen that the counterpart 13 a tubular sleeve 22 having a circular cross-section. However, elliptical, oval or polygonal cross sections are also possible. On its outside, the sleeve closes 22 over several bridges 23 to an inner surface 24 the guide sleeve 11 at. The guide sleeve 11 , the footbridges 23 and the counter bearing 13 can as a one-piece component 25 , which is produced in particular by injection molding, be formed. The valve stem 9 on the one hand to the valve cone 8th attached. On the other hand, so at its free end, the valve stem protrudes 9 in the opening 35 the tubular sleeve 22 into it.

As based on the 3 and 4 to recognize forms the tubular sleeve 22 at one end an edge, which in the plane 17 lies and the sloping contact surface 15 forms. In addition, at the edge is preferably a projection 26 molded, see 4 , The lead 26 is how in 5 to recognize ring-shaped. The wall thickness 27 (please refer 4 ) of the projection 26 is opposite the wall thickness 31 the tubular sleeve 22 in particular tapered or offset formed. In addition, the lead can 26 at its free end a slope 32 exhibit.

Based on 5 you can see how the bars are 23 with each other and in cooperation with the tubular sleeve 22 and the guide sleeve 11 openings 33 for adding or removing fluid to or away from the opening 6 form.

Subsequently, the operation of the valve will be briefly 2 to reduce rattling or flapping:
Due to the inclined contact surface 15 the spiral spring curves 12 away from the axial direction 21 or the longitudinal axis of the valve stem 9 , The curving of the spiral spring 12 causes the valve plug 8th in the open position at its edge 36 in the radial direction 37 against the inner surface 24 the guide sleeve 11 is pressed. This creates friction between the valve cone 8th and the guide sleeve 11 which reduces or eliminates chattering or rattling. The lead 26 serves as a lateral attachment for the coil spring 12 and supports them in sections.

Claims (10)

Valve ( 2 ) for controlling a fluid flow, in particular a gas flow, with a valve seat ( 3 ), a valve closing element ( 5 ), which between a closed position in which it against the valve seat ( 3 ) seals or partially closes to a minimum opening cross-section, and an open position in which it from the valve seat ( 3 ) and a fluid flow through the valve ( 2 ), in the axial direction ( 21 ) is actuated, and a coil spring ( 12 ), which the valve closing element ( 5 ) in the closed position along the axial direction ( 21 ) and in the radial direction ( 37 ) against an adjacent element ( 11 ) presses. Valve according to claim 1, wherein the spiral spring ( 12 ) on the one hand against the valve closing element ( 5 ) and on the other hand against an abutment ( 13 ), wherein a contact surface ( 15 ) of the valve closing element ( 5 ) and / or the abutment ( 13 ) obliquely with respect to the axial direction ( 21 ) is arranged. Valve according to claim 1 or 2, wherein the adjacent element as a guide sleeve ( 11 ) is formed, within which a poppet ( 8th ) of the valve closing element ( 5 ) in the open position is arranged, wherein the spiral spring ( 12 ) the valve cone ( 8th ) against an inner surface ( 24 ) of the guide sleeve ( 11 ) presses. Valve according to one of claims 1-3, wherein the valve closing element ( 5 ) a valve stem ( 9 ), which within the spiral spring ( 12 ) is arranged. Valve according to one of claims 1-4, wherein the valve closing element ( 5 ) a valve stem ( 9 ), which in an opening ( 35 ) in the counter bearing ( 13 ). Valve according to claim 5, wherein the inclined contact surface ( 15 ) at one edge of the opening ( 35 ) of the counter bearing ( 13 ) is trained. Valve according to claim 6, wherein the abutment ( 13 ) in the form of a sleeve ( 22 ) is formed and the edge ( 15 ) along a sectional surface of an oblique to the axial direction ( 21 ) of the sleeve ( 22 ) oriented level ( 17 ). Valve according to claim 6 or 7, wherein from the edge ( 15 ) of the sleeve ( 22 ) a ring segment-shaped section ( 26 ) in the axial direction ( 21 ), at which the spiral spring ( 12 ) and / or the valve stem ( 9 ). Valve according to one of claims 2-8, wherein the abutment ( 13 ) by means of several webs ( 23 ) with the guide sleeve ( 11 ), between which openings ( 33 for passing the fluid toward or away from one of the valve seats ( 3 ) limited opening ( 6 ) are formed. Air deoiling element ( 1 ) with a valve ( 2 ) according to any one of claims 1-9, in particular in a vacuum pump ( 1 ).

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