EP1936194A1 - Suction valve with removal gripper - Google Patents

Abstract

The valve has a valve guard (2) with an unloader (22) that is arranged in a non-rotational manner relative to a valve seat (3). An annular flow passage (20) is arranged with respect to the valve seat. A cylinder-shaped lock sleeve (25) is provided with a base area with a non-circular outer contour. The unloader is provided with a central section (28) formed with an axial through-going concentric opening. The central section of the unloader is arranged on the lock sleeve for guidance and anti- rotation of the unloader.

Description

The subject invention relates to a suction valve with a valve seat and a valve catcher, between which a valve element is arranged reciprocally, and with a Abhebegreifer with a number of Abhebegreiferfingern which pass through passageways in the valve seat and abut the valve element, the Abhebegreifer means of a Abhebegreiferverdrehsicherung arranged against rotation with respect to the valve seat and guided in the axial direction

Suction valves of compressors or compressors are often designed with lift-off. These serve essentially, as is well known, to start the compressor without load or to switch the compressor to idle mode.

For years, guide belts and guide rings in the gripper guides have been used to prevent wear of the unloader on the guide, especially in dry compressors EP 686 770 A2 or the DE 44 31 512 A1 shown. In addition, the rotation of the lift-off gripper is limited by the use of plastic start-up blocks 21, as in FIG Fig. 3 shown. In this case, these starting blocks 21 by means of screws 23, preferably radially inside, screwed to the valve seat 3. In the event that this rotation is omitted, the gripper fingers would rub 24 by the rotation of the Abhebegreifers on the webs of the through holes 13 on the valve seat 3 and could cause damage to the valve and / or the Abhebegreifers itself due to the resulting high wear damage. Due to the geometric diversity of the valve versions, these starting blocks 21 would also have to be custom-made for each valve in a costly manner and procured and stored in small quantities. The resulting costs are correspondingly high. In addition, the starting blocks 21, in particular for smaller valves, adversely affect the flow conditions in the valve.

Object of the subject invention is therefore to provide a Abhebegreiferverdrehsicherung and leadership for a Abhebegreifer a suction valve, which is equally applicable to suction valves of different geometries and without adverse effects on the function of the suction valve.

This object is achieved by the Abhebegreiferverdrehsicherung is designed as a cylindrical Verdrehsicherungshülse, which is arranged against rotation on and concentric with the valve seat and the cylindrical Verdrehsicherungshülse on a valve seat facing away from an area having a base with a non-circular outer contour, the Abhebegreifer a centrally arranged Section with an axially continuous concentric opening with an outer contour gegengleicher inner contour is arranged and arranged to guide and anti-rotation of the Abhebegreifers the Abhebegreifer with the central portion on the anti-rotation sleeve. Such anti-rotation sleeve arranged centrally radially inwards can be used in valves with a wide variety of geometries, since the rotation is independent of the geometry of the suction valve. In addition, the flow conditions of the suction valve in the region of the flow channels can not be influenced by the special arrangement of the anti-rotation sleeve. Nevertheless, with the anti-rotation sleeve, a simple and secure rotation and guidance of the lift-off gripper can be realized.

The anti-rotation sleeve is simply arranged secured against rotation in the valve seat, if in the valve seat a concentric recess is provided with an outer contour opposite inner contour, in which the anti-rotation sleeve is inserted. Alternatively, an axially protruding projection is provided on the valve seat facing end surface of the anti-rotation sleeve, which is arranged in a recess in the valve seat.

A simple limitation of the axial movement of the lift-off gripper can be achieved by providing an annular section extending in the axial direction in a region of the anti-rotation sleeve facing the valve seat. With such an arrangement creates a stop in the axial direction for the lifting gripper. Due to the height of the annular portion, the axial movement limit of the lift-off gripper can be easily adjusted.

The outer contour of the anti-rotation sleeve or the inner contour of the Abhebegreifers can be chosen almost arbitrarily. It is particularly advantageous to form the contour wavy, as a polygonal or polygonal, since such contours can be easily and accurately produced.

If the anti-rotation sleeve is designed as a hollow cylinder and in the anti-rotation sleeve, a cylindrical sleeve is arranged, the materials of the anti-rotation sleeve and the sleeve of the associated function can be selected accordingly. The anti-rotation sleeve may e.g. are made of a material that ensures the lowest possible friction between anti-rotation sleeve and Abhebegreifer, and the inner sleeve can be made of a material of high strength in order to transmit the Schraubenvorspannkraft safely on the valve seat can.

• Fig. 1 einen Schnitt durch ein erfindungsgemäßes Saugventil mit einem Abhebegreifer,
• Fig. 2 eine Explosionsdarstellung dieses Saugventils,
• Fig. 3 eine Verdrehsicherung für den Abhebegreifer nach dem Stand der Technik,
• Fig. 4 und 5 je ein Beispiel einer möglichen Grundfläche der zylinderförmigen Verdrehsicherungshülse,
• Fig. 6 eine Detailansicht einer zylinderförmigen Verdrehsicherungshülse und
• Fig. 7 und 8 eine weitere erfindungsgemäße Ausgestaltung einer Verdrehsicherungshülse.

The subject invention will be described below with reference to the schematic, non-limiting FIGS. 1 to 8 , each showing a preferred embodiment of the invention described. It shows

• Fig. 1 a section through an inventive suction valve with a lift-off gripper,
• Fig. 2 an exploded view of this suction valve,
• Fig. 3 an anti-rotation device for the Abhebegreifer according to the prior art,
• 4 and 5 one example of a possible base area of the cylindrical anti-rotation sleeve,
• Fig. 6 a detailed view of a cylindrical anti-rotation sleeve and
• FIGS. 7 and 8 a further embodiment of a Verdrehsicherungshülse invention.

The basic structure of a suction valve 1 is well known, which is why only briefly with reference to the Figs. 1 and 2 will be discussed. A suction valve 1, for example for use in compressors, consists of a valve seat 3 and a valve catcher 2. In between, a valve element 4 is arranged, which is reciprocated between the valve seat 3 and valve catcher 2 and takes over the sealing function in cooperation with the valve seat 3 in that it closes and releases the annular through-channels 13 in the valve seat 3. The individual parts of the suction valve 1 are held together by a continuous bolt 8, which is screwed into the valve catcher 2, and an opposite nut 10. The distance between the valve seat 3 and valve plug 2, and thus the possible valve lift, is adjusted by an intermediate spacer 9, which is arranged on the bolt 8. In the valve catcher 2 further annular outflow 14 are arranged.

At the end of the bolt 8 facing away from the valve element 4, a lift-off gripper 22 is arranged, the lift-off gripper fingers 24 of which pass through the through-channels 13 of the valve seat 3 and rest on the valve element 4. The lift-off gripper 22 is held by a disc 18 of the nut 10 on a sleeve 25 which transmits the screw biasing force to the valve seat 3. On the disc 18 is located on a spring 17, the opposite end of a second, from the valve seat 3 further away disc 27 rests. The second disc 27 is held here via a retaining ring 29 in the Abhebegreifer 22. Due to this arrangement, the lift-off gripper 22 can be moved in the axial direction against the spring force of the spring 17 in the direction of the valve catcher 2, whereby the valve element 4 is lifted off the valve seat 3 and the through-channels 13 are released. Of course, the axial mobility of the Abhebegreifers 22 also by any other suitable arrangement than those described here can be realized.

The valve element 4 comprises in this example concentrically arranged sealing rings 5, which cooperate sealingly with the valve seat 3. For this purpose, respectively associated and cooperating sealing surfaces are arranged on the sealing rings 5 and the valve seat 3. The sealing surfaces on the sealing rings 5 may for example be flat (ie in a normal plane of the Axis of the suction valve 1 are), the sealing rings 5 may have as sealing surfaces but also bevelled edges or the sealing rings 5 could also have toric sealing surfaces. In principle, however, other arbitrarily shaped sealing surfaces are possible. The correspondingly associated sealing surfaces on the valve seat 3 are in any case also correspondingly shaped.

At the valve seat 3 are distributed over the circumference and arranged at different radial distances a number of protruding in the direction of the sealing rings 5 ring guide lugs 15, between which the individual sealing rings 5 are arranged guided both in the radial and in the axial direction. The ring guide lugs 15 are at least as far out of the valve seat 3 that the sealing rings 5 remain guided during the entire ring opening movement.

The valve element 4 further comprises a synchronizing plate 7, which is arranged on the valve seat 3 opposite sides of the sealing rings 5 and covers the sealing rings 5. The synchronizing plate 7 is spring-loaded by a series of coil springs 11 arranged in spring springs 16 on the valve catcher 2. The coil springs 11 thus press the sealing rings 5 against the valve seat 3 via the synchronizing plate 7. During the ring opening movement, the sealing rings 5 are lifted off the valve seat 3 by the applied gas pressure against the force of the spiral springs 11. Instead of the coil springs 11 but spring plates could be provided in a known manner or it could be done by feathering out of the synchronizing plate 7 out resilient arms.

Between the synchronizing plate 7 and the sealing rings 5, a metallic separating plate 6 is further arranged, which prevents the synchronizing plate 7 and the sealing rings 5 from touching each other directly and thus could wear each other. The partition plate 6 is e.g. as a thin flat metal disc, but could also be shaped differently (according to the shape of the synchronizing plate 7 and / or the sealing rings 5), e.g. be curved. In the synchronous plate 7 and the partition plate 6 are of course again a series of, preferably annular (actually a series of circular ring sections, which are separated by radial webs), flow openings arranged so that the gaseous medium can pass as lossless through the suction valve 1.

The synchronizing plate 7, the partition plate 6 and the sealing rings 5 in this example form the valve element 4 of the suction valve 1, lie loosely together and are moved together during the ring opening movement. Due to the separation of the synchronizing plate 7 and sealing rings 5 through the partition plate 6, they can no longer wear each other due to the constant movement of the valve element 4. Of course, the valve element can also be designed differently, eg without a separator plate 6 or without a synchronous plate 7 or with a sealing plate instead of the sealing rings 5, which is incidental to the subject invention.

Thus, the flow-through openings 20 of the timing plate 7 and the partition plate 6 to the through channels 13 of the valve seat 3 and the outflow 14 of the valve plug 2 remain properly positioned (and not reduce the available flow area), prevents these parts rotate relative to each other, which can be achieved by an inserted through these parts anti-rotation pin 12, which is also in the valve catcher 2 and in the valve seat 3, can be achieved. Of course, this valve rotation lock can also be made in other possible ways, e.g. by corresponding projections and stops on the individual parts.

In order to prevent the Abhebegreifer 22 relative to the valve seat 3 is rotated, as this the Abhebegreiferfinger 24 abut and rub against the radial webs between the passageways 13, resulting in increased wear and / or damage to the Abhebegreiferfinger 24 and / or Valve seat 3 can lead, a Abhebegreiferverdrehsicherung is provided. This consists of a cylindrical Verdrehsicherungshülse 20 which is held against rotation in the valve seat 3. This anti-rotation sleeve 20 is arranged concentrically around the bolt 8 and between the valve seat 3 and nut 10. The anti-rotation sleeve 20 can also be used to transfer the screw bias, whereby the sleeve 25 could also be omitted entirely, or the anti-rotation sleeve 20 could be placed on the sleeve 25 or arranged in any other way around this. The anti-rotation sleeve 20 can be made of metal, such as. Bronze, brass or similar material, as well as plastic or filled or fiber reinforced plastic, e.g. PEEK, PPS, PTFE, POM or PA. In principle, the material of the anti-rotation sleeve 20, depending on the material of the Abhebegreifers 22 course should be chosen so that the resulting friction between Abhebegreifer 22 and anti-rotation sleeve 20 is minimized to minimize wear by the guide. The sleeve 25 is preferably made of metal or a material of similar strength in order to transmit the Schraubenvorspannung can.

The sleeve 25 and the anti-rotation sleeve 20 can of course also be manufactured as a composite part, as in Fig. 6 shown. The cylindrical sleeve 25, for example made of metal, has a ribbed or grooved outer contour 31, which is encapsulated in an injection molding process for forming the anti-rotation sleeve 20 with the abutment surfaces 30, for example with a suitable plastic. The sleeve 25 and the anti-rotation sleeve 20 are so positively connected together to form a composite part.

The anti-rotation sleeve 20 has a base surface with a non-circular outer contour, so that a cylindrical sleeve is formed, which has a lateral surface with axially aligned abutment surfaces 30 which prevent rotation in conjunction with a corresponding counter-profile has. At Abhebegreifer 22 a corresponding counter-profile with the matching inner contour is incorporated at a radially central portion 28. The Abhebegreifer 22 is pushed by means of this central portion 28 on the anti-rotation sleeve 20, so that the outer contour of the anti-rotation sleeve 20 and the inner contour of this section 28 cooperate. As a result, rotation of the lift-off gripper 22 with respect to the anti-rotation sleeve 20 and thus also with respect to the valve seat 3 is prevented.

The outer contour of the base of the anti-rotation sleeve 20 can be formed almost arbitrarily, a very simple form would be, for example, an ellipse. Examples of possible outer contours are in the FIGS. 4 and 5 shown. To Fig. 4 the outer contour is formed by juxtaposed, oppositely curved circular sections, so that a wave-shaped outer contour is formed. The wave flanks form the abutment surfaces 30 of the lateral surface. The outer contour could also be formed by any polygonal or polygonal. In Fig. 5 is the outer contour as a hexagon, here with rounded edges, formed (of course, can be any other polygon), wherein the abutment surfaces 30 by the side surfaces of the hexagon (or polygon) are formed. The inner contour of the counter-profile in the Abhebegreifer 22 would then be shaped correspondingly opposite, so here a wavy contour or a hexagon - so in turn includes corresponding stop surfaces. Due to the cooperating abutment surfaces 30 on the outer contour of the anti-rotation sleeve 20 and on the inner contour of the Abhebegreifers 22, this can no longer rotate relative to the anti-rotation sleeve 20. In order to prevent rotation of the anti-rotation sleeve 20, at least two cooperating abutment surfaces 30 on the inner and outer contour are required.

However, the anti-rotation sleeve 20 also has a guide function in which the Abhebegreifer 22 is guided by the non-circular base surface of the anti-rotation sleeve 20 in the axial direction. For this purpose, the outer contour and the associated inner contour can be performed with a suitable game that allows the least possible unimpeded and frictionless axial movement. However, the play should not be too large to avoid that the anti-rotation sleeve 20 can rotate back and forth in a small area, which can increase the wear. Convenient in this context are contours with steep flanks, such as in Fig. 4 shown, since then the lift-off gripper can be aligned very accurately, a very safe guidance is ensured and a game of Lifting gripper 22 in the circumferential direction (and thus a back and forth turning) can be kept very small. Likewise, by a suitable choice of material, the friction between anti-rotation sleeve 20 and Abhebegreifer 22 can be reduced.

A prerequisite for the functioning of the rotation is, of course, that the anti-rotation sleeve 20 is arranged against rotation even with respect to the valve seat 3. This can most easily be achieved by a non-positive connection in that the anti-rotation sleeve 20 is pressed against the valve seat 3 by the screw biasing force, so that it can no longer or only with great difficulty be twisted by the resulting frictional forces. However, a form-locked connection is more secure, as in the exemplary embodiment described here Fig. 1 and 2 shown. For this purpose, a recess 26 is arranged in the valve seat 3, which has an inner contour which represents the counter profile to the outer contour of the anti-rotation sleeve 20 (as described above). In this connection, no clearance must be present, but it could also be provided a press fit, so that the anti-rotation sleeve 20 relative to the valve seat 3 can not rotate at all and is securely held in the valve seat 3. This recess 26 can be produced with a common method, such as milling, eroding, drilling, etc. If the contour consists of circular sections, the contour can be produced particularly easily by drilling.

Another way to arrange the anti-rotation sleeve 20 against rotation is based on the FIGS. 7 and 8 described. Here are at the valve seat 3 associated end face of the anti-rotation sleeve 20 protruding from this protrusions 32, here cylindrical pins, which are placed in associated recesses 33, here holes on the valve seat 3, bringing the anti-rotation sleeve 20 relative to the valve seat 3 is no longer can twist.

Furthermore, it can be provided that on an area of the anti-rotation sleeve 20 assigned to the valve seat 3 an annular section 34 extending in the axial direction is formed, which here has a (not necessarily) larger radius, such as the radius of the envelope of the lateral surface of the anti-rotation sleeve 20 , as in FIGS. 7 and 8 shown. Characterized a projection 35 is formed at the transition to the annular portion 34, which can be used as an axial stop for the Abhebegreifer 22. Thus, the axial movement of the Abhebegreifers 22 are limited. However, a corresponding stop for the lifting gripper 22 can also be achieved without a projection 35, for example, in which the annular section has the radius of the envelope of the outer surface of the anti-rotation sleeve 20 as outer radius.

Claims (10)

A suction valve having a valve seat (3) and a valve catcher (2) between which a valve element (4) is reciprocally arranged, and a lift-off gripper (22) having a number of lift-off gripper fingers (24) passing through passageways (13). pass through in the valve seat (3) and rest on the valve element (4), wherein the Abhebegreifer (22) by means of Abhebegreiferverdrehsicherung against the valve seat (3) arranged secured against rotation and guided in the axial direction, characterized in that the Abhebegreiferverdrehsicherung as cylindrical anti-rotation sleeve (20) is executed, which is arranged against rotation and concentric with the valve seat (3) and the cylindrical Verdrehsicherungshülse (25) has a base with a non-circular outer contour that the Abhebegreifer (22) has a centrally disposed portion (28) with an axially continuous concentric opening arrange with an outer contour opposite inner contour t is and that for guiding and preventing rotation of the Abhebegreifers (22) of the Abhebegreifer (22) with the central portion (28) on the anti-rotation sleeve (25) is arranged. Suction valve according to claim 1, characterized in that in the valve seat (3) has a concentric recess (26) is provided with an outer contour opposite inner contour, in which the anti-rotation sleeve (20) is arranged. Suction valve according to claim 1, characterized in that on the valve seat (3) facing the end face of the anti-rotation sleeve (20) one in the axial direction protruding projection (32) is provided which is arranged in a recess (33) in the valve seat (3) , Suction valve according to one of claims 1 to 3, characterized in that in an area facing the valve seat (3) of the anti-rotation sleeve (20) is provided in the axial direction extending annular portion. Suction valve according to one of claims 1 to 4, characterized in that the outer contour of the anti-rotation sleeve (20) or the inner contour of the central portion (28) of the Abhebegreifers (22) is wave-shaped, preferably with circular sections with alternately opposite curvatures. Suction valve according to one of claims 1 to 4, characterized in that the outer contour of the anti-rotation sleeve (20) or the inner contour of the central portion (28) of the Abhebegreifers (22) is formed as a polygonal line. Suction valve according to one of claims 1 to 4, characterized in that the outer contour of the anti-rotation sleeve (20) or the inner contour of the central portion (28) of the Abhebegreifers (22) is formed as a polygon. Suction valve according to one of claims 1 to 7, characterized in that the anti-rotation sleeve (20) is made of metal or plastic or filled or fiber-reinforced plastic. Suction valve according to one of claims 1 to 8, characterized in that the anti-rotation sleeve (20) is designed as a hollow cylinder and in the anti-rotation sleeve (20) has a cylindrical sleeve (25) is arranged. Suction valve according to claim 9, characterized in that the anti-rotation sleeve (20) and the cylindrical sleeve (25) are formed as a composite part.

Images