WO2000063557A1

WO2000063557A1 - Piston vacuum pump with a gas inlet and a gas outlet

Info

Publication number: WO2000063557A1
Application number: PCT/EP2000/001845
Authority: WO
Inventors: Thomas Dreifert; Lutz Arndt; Jürgen Meyer
Original assignee: Leybold Vakuum Gmbh
Priority date: 1999-04-15
Filing date: 2000-03-03
Publication date: 2000-10-26
Also published as: AU3163600A; EP1169572A1; TW571025B; EP1169572B1; DE50010975D1; DE19917009A1

Abstract

The invention relates to piston vacuum pump with a gas inlet, a gas outlet, at least one piston (2), at least one cylinder (3), a pump chamber (5) that is defined by said piston (2) and said cylinder (3), with a gas inlet, a gas inlet valve (12) and a gas outlet and a gas outlet valve (7) that is located on the face of the cross-sectional surface of the cylinder bore. The aim of the invention is to improve the gas inlet of such a pump. To this end, the gas inlet valve (12) is pressure-controlled and located in such a manner that it is opened during the intake stroke, preferably during the first phase of the intake stroke.

Description

Piston battery pump with gas inlet and gas outlet

The invention relates to a piston vacuum pump according to the preamble of patent claim 1.

Single-stage and multi-stage piston vacuum pumps of this type are known from EU-A-85 687. Compared to comparable rotary piston vacuum pumps, they have proven to be inexpensive and wear-resistant and are therefore successful on the market.

In the case of piston vacuum pumps, each of the cylinder / piston systems is equipped with a valve-controlled gas inlet and with a valve-controlled gas outlet. For example, from DE-A-196 34 517 a piston-controlled gas inlet valve (the gas inlet line opens into an annular groove in the cylinder wall, which is closed or released by the piston itself) and a pressure-controlled or piston-controlled gas outlet valve, which are known about the entire valve face extending cylinder end. When the valve disc is raised, the compressed gas enters a chamber in the cylinder head to which the gas outlet line is connected. The outlet valve closes when the piston begins its movement phase (suction stroke) that increases the volume after reaching its dead center. At this time, the scoop is not yet connected to the gas inlet, so that the pressure in the scoop decreases. Precisely because piston vacuum pumps have the advantage, among other things, that they can be built and operated without dead space, very low pressures arise during the described movement phase of the piston, which make the piston movement more difficult and strain the piston drive. To relieve the drive, it is known from DE-A-196 34 517 to connect the scooping chamber to the gas outlet chamber via a line with a check valve. When the pressure in the pump chamber decreases, the check valve opens and prevents very low pressures from developing. A disadvantage of the previously known solution is that gases which have already been conveyed get back into the scooping chamber and have to be conveyed again or even several times.

The present invention is based on the object of improving a piston vacuum pump of the type concerned here with regard to the gas entry. Furthermore, the gas inlet should be designed in such a way that no or only negligible negative pressures occur in the pumping chamber during the suction stroke of the piston. Finally, the realization of the advantages of the pump known from DE-A-196 34 517 - large-area inlet slots for gas exchange at low intake pressures and large-area and low-exhaust valves - should not be impaired. According to the invention, these ^objects are achieved by the characterizing features of the claims.

In contrast to the prior art mentioned, a pressure-controlled inlet valve is provided in the piston vacuum pump according to the invention, which opens during the suction stroke, preferably in the first phase of the suction stroke. In addition to a simple and inexpensive construction, this solution has the advantage that the drive is not subjected to negative pressures. There is also no longer the disadvantage that gas components have to be pumped several times.

The pressure-controlled gas inlet valve can be the only inlet valve. However, if large inlet openings are to be provided at low intake pressures in order to achieve as complete a filling of the scooping space as possible before the start of the pressure stroke, it is expedient if the gas inlet according to the invention is present in addition to a second gas inlet, e.g. a gas inlet with a piston-controlled gas inlet valve, as is known from DE-A-196 34 517.

Further advantages and details of the invention will be explained with reference to exemplary embodiments schematically shown in FIGS. 1 to 11. Show it Figures 1 to 5 solutions in which a gas inlet valve is part of the cylinder head,

Figures 6 to 9 solutions in which a gas inlet valve is arranged in the piston wall and

Figures 10 and 11 further exemplary embodiments.

All figures each show a partial section through a piston-cylinder system 1 of a piston vacuum pump which has one or more stages (be it that it has several piston-cylinder systems or that both piston ends have pump functions, cf., for example, FIG. 10 in DE- A-196 34 517) can be formed. In all figures, the piston is labeled 2, the cylinder wall 3, the cylinder head 4 and the scooping chamber (compression chamber) 5. In all exemplary embodiments, the outlet valve 7 is located in the region of the end face of the cylinder shown. It comprises the largest possible valve plate 8, which is attached to the cylinder head 4. The front edge of the cylinder wall 3 (or a section thereof) serves as the valve seat 9. In the cylinder head 4 there is a gas outlet chamber 11 to which a gas outlet (not shown) is connected. The gas inlet valve according to the invention is designated 12 in each case.

In the exemplary embodiments according to FIGS. 1 to 5, the inlet valve 12 - like the outlet valve 7 - is in the region of the end face of the cylinder shown. linders arranged. In the cylinder head 4, in addition to the gas outlet chamber 11, there is a gas inlet chamber or line 14. The gas inlet valve 12 is located between the gas inlet chamber 14 and the scooping chamber 5. It is pressure-controlled and opens as soon as a sufficiently low pressure is created in the scooping chamber 5 during the suction stroke of the piston .

In the embodiment of Figures la and lb inlet valve 12 and outlet valve 7 are arranged side by side. The valve plate 8 of the outlet valve 7 is fastened to the cylinder head 4 by means of the screw 15. It is actuated by the plunger 16 on the piston 2. The closure piece of the inlet valve 12 is a spring tongue 18, which is part of a valve plate 19 fastened between the cylinder and cylinder head 4. When the inlet valve 12 is closed, the spring tongue 18 of the mouth 20 of the inlet chamber or line 14 rests.

FIGS. 2a to 2c show an inlet valve 12 fastened approximately centrally on the cylinder head 4, the closure piece 21 of which comprises a rotationally symmetrical valve tongue 22 which is connected to an edge 24 via annular spring sections 23 (FIG. 2b). A sleeve 25 with a collar 26 and a fastening nut 27, which can be screwed into a threaded bore 28 in the cylinder head 4, serve to fasten the closure piece 21 designed as a valve plate to the cylinder head 4. When the valve 12 is closed, the spring tongue 22 of the mouth 20 of the gas inlet chamber 14 lies in the scooping chamber 5. Either the sleeve 26 itself (eg from Viton) or an elastomer ring 29 form the valve seat. The edge 24 of the closure piece 21 is clamped between the fastening nut 27 and an elastomer ring 31. The fastening nut 27 has a hollow shaft which is equipped with cutouts 32 for the passage of the spring sections 23. There is the possibility of prestressing the spring tongue 22 when the clamping plane for the edge of the closure piece is set back from the plane of the spring tongue 22 and by an amount a. The valve plate 8 of the gas outlet valve 7 surrounds the inlet valve 12 and can be pressure-controlled or - via the tappet 16 - piston-controlled.

In the exemplary embodiments according to FIGS. 3 and 4, the closure piece 8 of the gas outlet valve 7 is fastened to the cylinder head 4 with the aid of an elastic bellows 35 (metal or elastomer material). The interior of the bellows 35 forms the gas inlet chamber 14. The gas enters the scoop chamber 5 via a bore 36 in the valve plate 8.

In the solution according to FIG. 3, the plate 8 of the gas outlet valve 7 is equipped or coated with an elastomer membrane 37. In the area of the bore 36, the membrane 37 is equipped with openings 39 which are arranged offset with respect to the bore 36 and which, with sufficient negative pressure in the scoop chamber 5, allow the gases to pass through (shown in FIG. 3, left half). In the embodiment of Figure 4 is Bore 36 a spring tongue 40 - similar to the solution according to Figure 1 - assigned, which is fastened to the valve plate 8 by means of the screw 41.

The solution according to FIG. 5 shows a valve seat 43 screwed tightly into a thread on the cylinder head 4 (elastomer ring 42) with passage bores 44. The passage bores 44 arranged on a circle are assigned an annular closure piece 45 which is under the action of a compression spring 46. The spring 46 is supported on a stroke limiter 47 and determines the pretension of the gas inlet valve 12.

In the solutions according to FIGS. 1 to 5, part of the cross-sectional area of the cylinder bore is used for the arrangement of the gas inlet 12; the majority, however, is available for the large-area gas outlet 7. The position of the gas inlet valve 12 is particularly advantageous since it can initiate its opening movement under pressure control immediately after the start of the suction stroke.

In the embodiments according to FIGS. 6 to 9, the gas entry takes place via an opening 50 (bore or slot) opening laterally into the scooping chamber 5. The inlet valve 12 is located in a chamber 51 in the cylinder wall 3. The gas inlet line 14 opens into the chamber 51. The locking mechanisms of the solutions according to FIGS. 6 to 8 are similar to the locking mechanisms according to FIGS. 1, 2 and 5 (spring tongues 18, 21 or spring-loaded annular closure piece 45). In the embodiment according to FIG. is found in the chamber 51 a per se known non-return valve with a under the action of the compression spring 52 ^¬ stationary ball 53 as a closure piece, which is associated with a conically shaped seat 54.

The bores 50 in the solutions according to FIGS. 6 to 9 are each located in the immediate vicinity of the end face of the cylinder wall 3 facing the outlet valve 7, so that the valves 12 open under pressure control as early as possible when the suction stroke begins. In a manner known per se, there is advantageously a further gas inlet 55 controlled by the piston 2 (FIG. 8), which is designed as a circumferential groove 56 in the cylinder wall 3. The gas inlet line 14 also opens into this groove 56.

The solutions according to FIGS. 6 to 9 have the advantage that the cross section of the outlet valve 7 is not impaired by the arrangement of a gas inlet valve 12 and that there is sufficient space on the side next to the cylinder for accommodating the gas inlet valve 12. In addition, an exhaust valve that is free of damage is easy to implement. It is essential in these solutions that the gas inlet 50 is located in the immediate vicinity of the end face of the cylinder bore, so that the gas inlet valve 12 is able to open under pressure control when the suction stroke begins.

In the solution according to FIG. 10, the piston 2 is equipped on the end face with a sleeve 61 with an outer lip 62. Furthermore, the piston 2 with one axially extending groove 63, which - when the piston 2 is at its top dead center - extends from the piston end to the gas inlet 55 (ring ^¬ groove 56 in the cylinder wall 3). At the beginning of the suction stroke and sufficient negative pressure in the scoop chamber 5, the lip 62, which forms the gas inlet valve 12 together with the cylinder wall, lifts off the cylinder wall, so that the connection between the gas inlet 55 and the scoop chamber 5 is established via the groove 63. The function of the groove 63 can also fulfill an annular gap between the piston skirt and the cylinder wall. The inlet 55 expediently has the form of a circle of holes so that the sleeve can be moved to the bottom dead center via the inlet.

Finally, the gas inlet can be located in the end face 66 of the piston 2. In the embodiment shown in Figure 11, the gas inlet valve 12 is designed as a tongue valve (Figures 1 and 6). The spring tongue 18 is fastened to the piston 2 by means of the screw 65 and lies in the closed state of the mouth 20 of the gas inlet channel 14. Other valve shapes are also possible (e.g. ball valve). This solution requires that the step is allowed to suck through the crankcase. To do this, the crankcase must be sealed and the gases drawn in must not damage the components in the crankcase. The advantage of this construction is that it is very simple and inexpensive.

Some of the figures show that the components of the solutions described can be coated. NEN (valve plate 8 in Figure 3, piston face in Figures 4 and 10, piston shirt in Figure 5, cylinder wall in Figure 6). The closure elements and / or seats of the inlet valves 12 can also be equipped with a layer. Depending on the function of the coating (sealing, damping, wear protection), the materials are selected (e.g. elastomer or polytetrafluoroethylene). The actuation of the outlet valve 7 can be pressure- or piston-controlled.

As described in connection with the exemplary embodiments, various designs are possible for the pressure-controlled inlet valves:

a) tongue valves with metallic seal and those with elastomer seal.

b) Spring-loaded valve plate with a central guide if necessary.

c) Valves made of spring steel sheet, which combine the valve plate and spring tongues in one piece.

d) spring-loaded ball valves.

e) elastomeric membranes that are stretched over a valve body.

f) Cuffs on the piston head, which leak under pressure in the direction of the working area and thus enable pressure equalization. This valve shape is for suction through the Crankcase or suitable for suction via the piston skirt.

The proposals according to the invention ensure that the piston vacuum pump equipped with it has the following advantageous properties:

• inexpensive,

• robust, reliable, insensitive to dirt,

• high tightness,

• small dead space,

• low noise,

• little intervention in the adjacent construction, space-saving,

• easy to manufacture and assemble,

• sufficient cross sections and timing.

Claims

PATENT CLAIMS

1. Piston vacuum pump with a gas inlet, with a gas outlet, with at least one piston (2), with at least one cylinder (3), with a scooping space formed by piston (2) and cylinder (3)

(5), with a gas inlet, with a gas inlet valve (12) as well as with a gas outlet and a gas outlet valve (7) arranged on the end face in the cross-sectional area of the cylinder bore, characterized in that the gas inlet valve (12) is pressure-controlled and arranged in such a way that it is during of the suction stroke, preferably in the first phase of the suction stroke.

2. Pump according to claim 1, characterized in that the gas inlet valve (12) is also located on the end face in the cross-sectional area of the cylinder bore.

3. Pump according to claim 1 or 2, characterized in that the gas inlet valve (12) and the gas outlet valve (7) are components of a cylinder head (4).

4. Pump according to claim 1, 2 or 3, characterized in that gas inlet valve (12) and gas outlet valve (7) are arranged side by side in the cross-sectional area of the cylinder bore.

5. Pump according to claim 4, characterized in that there is a gas inlet chamber or line (14) in the cylinder head (4) and that the mouth (20) of the gas inlet chamber (14) in the pump chamber (5) is associated with the gas inlet valve.

6. Pump according to claim 4 or 5, characterized in that the gas inlet valve (12) is part of the valve plate (8) of the gas outlet valve (7).

7. Pump according to claim 6, characterized in that the valve plate (8) is attached to an elastic bellows (35) and that the interior of the bellows forms the gas inlet chamber (14).

8. Pump according to claim 7, characterized in that the valve plate (8) with an elastomeric bran (37) and that part of the elastomer membrane has a valve function.

9. Pump according to claim 1, characterized in that the pressure-controlled gas inlet valve (12) is arranged laterally next to the pump chamber (5) in the cylinder wall (3).

10. Pump according to claim 9, characterized in that the gas entry takes place via an opening (50) (bore or slot) opening laterally into the scooping space (5).

11. Pump according to claim 9 or 10, characterized in that the gas inlet valve is located in a chamber (51) formed in the cylinder wall (3), which is connected to the gas inlet line (14).

12. Pump according to claim 1, characterized in that the pressure-controlled gas inlet valve

(12) in the piston end wall (66).

13. Pump according to one of claims 1 to 12, characterized in that a further piston-controlled gas inlet (55) is present.

14. Pump according to one of claims 1 to 13, characterized in that the pressure-controlled inlet valve (12) is designed as a tongue valve, spring-loaded valve, ball valve or the like.

15. Pump according to one of claims 1 to 14, characterized in that one or more of its components are coated, with a sealing, noise or vibration damping or wear protection layer.

16. Pump according to claim 1, characterized in that a piston-controlled gas inlet (55) is present, that the piston (2) is equipped on the end face with a sleeve (61), that a connection (63) is present, which extends from the sleeve (61) extends to the gas inlet (55), and that the sleeve (61) together with the cylinder wall (3) forms the pressure-controlled gas inlet valve (12).