The invention relates to a pump with a housing, having an inlet and an outlet, a fixed cylinder central to a mid-axis of the pump, a displacer, rotating eccentrically within the cylinder, a crank drive for the displacer, a circumferential sickle-shaped pumping chamber between the cylinder and displacer and a helical sealing element in the pumping chamber. Moreover, the present invention relates to a method for operating such a pump.
A pump having the characteristics mentioned is known from EP-A-464 683. It has the function of a compressor and is preferably intended for compressing the gas of a refrigerant circuit.
It is the task of the present invention to design a pump of the aforementioned kind such that it may be employed as a dry running vacuum pump.
This task is solved through the characterising features of the patent claims.
Over the past years, the customers have required from the manufacturers of vacuum pumps, dry running vacuum pumps at an increasing rate. These are to be understood as pumps, the pumping chambers of which are free of lubricant. In the instance of pumps of this kind there no longer exists the risk of hydrocarbons diffusing into the chambers to be evacuated by the pumps and thereby impairing the processes (semiconductor production, evaporation processes, chemical processes etc.) being performed within the chambers.
Dry running rotary vane pumps are known. The parts (vanes, inside wall of the pumping chamber) which slide under friction exhibit a comparatively high relative velocity. For this reason, the service life of the vanes and thus the pumps themselves is limited. Scroll vacuum pumps are better suited for dry operation. These comprise a fixed and a revolving component which support helical pumping elements engaging into each other. Their manufacturing costs are high. Moreover, they need to be subjected to maintenance frequently so as to ensure reliable continuous operation. Also dry piston vacuum pumps are offered on the market. Their manufacturing costs are also high, their construction volume is large. Other disadvantage are noise production and the unavoidable vibrations. Finally, dry two-shaft vacuum pumps (screw, Roots, claws vacuum pumps) are known. These offer pumping capacities commencing at approximately 20 m3/h. Manufacture and deployment of vacuum pumps of this kind is usually, however, no longer economical at pumping capacities below 50 m3/h.
The eccentric vacuum pump in accordance with the present invention does no longer exhibit the disadvantages detailed. Friction is substantially limited only to the movement of the helical sealing element in its groove. Significantly less is the friction between the sealing element and the inside wall of the cylinder or the outside surface of the displacer, depending on the location of the groove guiding the pumping element. Since the displacer orbits, the relative velocities between the friction partners are, however, not high so that the wear is negligible, in particular when employing suitable materials.
Further advantages and details of the present invention shall be explained with reference to the schematically presented examples of embodiments in the drawing FIGS. 1 to 5.
drawing
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drawing
The vacuum pump 1 depicted in drawing
A further component of the rotating system 8 is a crank 13 which is located at the level of the cylindrical housing 2. e designates the eccentricity. The end sections 14 and 15 of the crank 13 are equipped with bearings 16 and 17 which support a hollow (hollow space 20) revolving displacer 18. The revolving movement of the substantially cylindrical displacer 18 is effected about the rotary axis 9. The crank axis is designated as 19. For the purpose of securing the axial position of the displacer 18, one of the two bearings 16, 17—in this instance bearing 16—is designed by way of a spherical roller bearing.
The cylindrical housing 2 which simultaneously has the function of a cylinder stator of pump 1 is arranged centrally with respect to the axis of rotation 9. The diameter of the displacer 18 is selected such that it does not make contact with the inner wall of housing 2. The smallest distance between housing 2 and displacer 18 shall be as small as possible, expediently significantly less than 1 mm, 0.2 mm for example.
In order to prevent the turning motion of a circulating displacer it is known to employ torque supports (Oldham coupling, leaf springs, wire springs or alike). In the embodiment in accordance with drawing
The middle, substantially cylindrical section 22 of the crank 13 with its axis 23 is also arranged eccentrically with respect to axis of rotation 9, specifically exhibiting eccentricity E. The directions of the eccentricities e and E are opposed to each other. The eccentricity E and the mass of the middle section 22 are selected such that unbalance forces causing the masses of the rotating crank sections 14 and 15 with bearings 16 and 17 as well as the mass of the rotating displacer 18 during operation of the pump 1, are compensated.
Located between the housing 2 and the displacer 18 is the sickle-shaped pumping chamber 26. A helical sealing element or band 27 forms the pumping chambers which move from the inlet 28 of the pump 1 to the outlet 29. On the inlet side, pumping chambers are created continuously which close during the rotary movement of the displacer 18 and which only open again on the outlet side. In the embodiment depicted in drawing
The sealing element 27 is a helical, flexible rectangular band, the cross-section of which is long stretched out. It is guided in a groove 30 in the displacer 18. In the relaxed state the sealing element 27 exhibits an outside diameter which is slightly larger than the inside diameter of the bore in cylinder 2. Thus, in the fitted state it is subjected to an initial tension acting radially towards the outside, so that leak tight resting of the sealing element 27 against the inside wall of the housing 2 is ensured. The width b of the sealing element 27 is greater then twice the magnitude of the eccentricity e. Thus the closed state of the pumping chambers during their motion from inlet 28 to outlet 29 as well as reliable guidance of the sealing element 27 within the groove 30 is ensured, and reverse flows are prevented. Play of the sealing element 27 within the groove 30 should be as small as possible, for example 0.2 mm.
Although there exists between housing 2 and the sealing element 27 no significant friction, torque caused by friction between sealing element 27 and groove 30 is exerted on the sealing element 27 during operation of the pump 1. A therefrom resulting axial shift of the sealing element 27 is expediently prevented by barriers. Such a barrier may, for example, be designed by way of a stop within the groove 30 of the displacer 18. Another possibility exists in that an end section of the sealing element 27 is affixed at the housing 2 or at one cap piece 3, 4 in such a manner that the end section cannot turn about the axis 9, but nonetheless exhibits in the axial direction a slight amount of play (see drawing
In the embodiments depicted in drawing
In the example of the embodiment according to drawing
The embodiment depicted in drawing
Two variants for a gas ballast supply are depicted. In the first variant, the ballast gas enters through a line 51 from outside through a bore, not specifically depicted, in housing 2 into the pumping chamber 26. In the line 51 there are present a blocking valve 52, a non-return valve 53 and a differential pressure valve 54. A gas ballast facility of this kind is known from DE-A-199 62 445.
In the second variant the ballast gas is supplied through the hollow space 20 of the displacer 18. A system of channels 55 in the rotating system 8 forms the link to the outside. Ballast gas (arrows 56) supplied through the system of channels passes through a bore 57 (depicted by dashed lines) in the displacer wall into the pumping chamber 26. The advantage of this embodiment is such that the displacer is cooled from the inside by the ballast gas.
In the embodiment in accordance with drawing
Drawing
The special advantage of the embodiment in accordance with drawing
In the embodiment in accordance with drawing
Both the crank 13 (crank section 14) and also the rotating displacer 18 are cantilevered such that in the area of the side face 31 bearings are no longer required. The crank section 14 exhibits a step. The displacer 18 is supported in a cantilevered manner by the two bearings 16, 17 having different diameters.
In the example of the depicted two-stage version, a further pump stage is located upstream of the pump stage formed by the sealing elements 27, 27″ and the outside wall of the displacer 18. To this end, the displacer 18 is designed according to the type of a double pot.
Located in one of the hollow spaces on the face side are the crank 13 as well as the bearings 16, 17. Located in the second—opposite—hollow space 36 with the side face 31, is a further pumping stage. In the housing 2, a cylindrical component 35 is affixed centrally with respect to axis 9 by means of a flange 34, the cylindrical component extending into the inner space 36 of the displacer 18. The diameter of the cylindrical component is so selected that its outside wall and the inside wall of the displacer 18 form a further sickle-shaped pumping chamber 37. The outside wall of the cylindrical component 35 (or the inside wall of the displacer 18) is equipped with a helical groove 38 in which a further sealing element 39 is guided.
The pump stage formed by component 35, displacer 18 and the sealing element 39 serves as the first stage of a two-stage pump 1 in accordance with the present invention. It pumps from the bearing side in the direction of the side face 31. In this area, the pumping chambers 37 and 26 are linked to each other. The inlet 28 is formed by a central bore 60 in component 35. The pitches of the groove 38 in the component 35 and the grooves 30, 30′ in housing 2 are constant (easy to manufacture) but selected to differ in size. The pitch of the groove 38 is greater than the pitch of the grooves 30, 30′. During the passage through the two-stage pump 1 a compression of the pumped gases is effected. A special advantage of the embodiment detailed is that the high-pressure stage is located outside. The heat mostly generated in the high-pressure stage can be simply dissipated, be it through cooling channels in housing 2 or—as shown—through heat sinks 51 having a relatively large surface area.
The helical sealing element 27, 27′, 27″, 39 has the task of mutually sealing the pumping chambers moving from the intake side to the delivery side. Moreover, the frictional resistance between the sealing element and the involved components 2, 18, 35 is minimal. In the drawing
The examples of embodiments detailed differ chiefly with respect to their bearings as well as with respect to the number, pitch and selection of the location of the guide grooves for the sealing element(s). As a precaution it is pointed out that the variants detailed here can be implemented in any of the examples of embodiments detailed. The present invention permits, at low manufacturing cost, the production of a compact, dry running, low noise and low vibration vacuum pump which is also economical at low pumping capacities (under 50 m3/h). It suffices when the rotational speed of the rotating components is between 1500 and 3600 rpm. Cooling of the pump is simple since all important components are in contact with the atmosphere.
Of importance to the service life of the pump is the selection of the materials for the components between which there is friction. For the helical sealing element 27, 27′, 39, PTFE or a PTFE compound is well proven, as employed also in piston or scroll vacuum pumps. The displacer 18 and/or the housing 2 as well as the component 35 consist expediently of an aluminium material, preferably of a hard anodized aluminum alloy, AlMgSi1, for example. When employing these or similar materials it is possible, in spite of the absence of lubricants in the pumping chamber, to permit high sliding velocities between the sealing element(s) and the related grooves. The sliding velocity depends on the rotational speed of the crank and on the degree of eccentricity e. The higher these values are, the more compact a pump offering a certain pumping performance can be manufactured. Expediently rotational speed and eccentricity are so selected that the sliding velocity ranges between 1 and 5 m/s, preferably 4 and 5 m/s.
Number | Date | Country | Kind |
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102 12 940.1 | Mar 2002 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP03/01597 | 2/18/2003 | WO |