The present invention relates to a scroll pump, which is often referred to as a scroll compressor.
A prior art scroll compressor, or pump, 100 is shown in
The fixed scroll 112 comprises a scroll wall 118 which extends perpendicularly to a generally circular base plate 120. The orbiting scroll 110 comprises a scroll wall 124 which extends perpendicularly to a generally circular base plate 126. The orbiting scroll wall 124 co-operates, or meshes, with the fixed scroll wall 118 during orbiting movement of the orbiting scroll. Relative orbital movement of the scrolls causes a volume of gas to be trapped between the scrolls and pumped from the inlet to the outlet.
A scroll may be used as a vacuum pump for example for evacuating a process chamber in which semiconductor products are processed. The scroll may be arranged in series with a high vacuum pump such as a turbo molecular pump or may be connected directly to a process chamber. When initial evacuation is commenced the inlet and the exhaust of the scroll pump are at atmosphere. This initial phase is often referred to as roughing and a scroll pump used in this way is referred to as a roughing pump. During roughing, gas is compressed by the scroll pump, but since the inlet is initially at atmosphere, the pump may generate over-compression in the pump. Over-compression in this context means that a pressure is generated in the pump which is above atmosphere. Over-compression is undesirable because it increases the load on the pump and therefore increases the power requirement of the pump motor.
The discussion above is merely provided for general background information and is not intended to be used as an aid in determining the scope of the claimed subject matter. The claimed subject matter is not limited to implementations that solve any or all disadvantages noted in the background.
The present invention provides a vacuum pump comprising a scroll pumping mechanism which comprises:
Other preferred and/or optional aspects of the invention are defined in the accompanying claims.
The Summary is provided to introduce a selection of concepts in a simplified form that are further described in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
In order that the present invention may be well understood, several embodiments thereof, which are given by way of example only, will now be described with reference to the accompanying drawings, in which:
A vacuum pump 10 comprising a scroll pumping mechanism 11 is shown in
The fixed scroll 22 comprises a scroll wall 28 which extends perpendicularly to a generally circular base plate 30. The orbiting scroll 20 comprises a scroll wall 34 which extends perpendicularly to a generally circular base plate 36. The two scrolls 20, 22 are co-operable for pumping gas along a pumping channel 32 from a radially outer scroll inlet 25 to a radially inner scroll outlet 27 of the mechanism on relative orbiting motion of the scrolls.
A gas conduit 38 has an inlet 40 at a first location of the pumping channel 32 and an outlet 42 at a second location of the pumping channel for allowing over-compression at the first location of the pumping channel to be exhausted to the second location of the pumping channel. The first location 40 of the pumping channel is between the scroll inlet and the scroll outlet and the second location of the pumping channel is at the scroll outlet 26.
Those skilled in the art of scroll pumping arrangements will be aware that fluid is pumped along two pumping channels. The pumping channels are generally parallel and are located on either side of one of the scrolls, usually the orbiting scroll. The above described gas conduit may be arranged to relieve over-compression in both of the pumping channels, or the conduit may comprise two separate elements for relieving over-compression in respective pumping channels.
Two one-way valves 44 are located in the gas conduit 38 for allowing the passage of gas through the conduit from the conduit inlet to the conduit outlet only in the direction shown by the arrow in
The one-way valve arrangement has an internal resistance which must be overcome by pressure differential across the arrangement before gas will be allowed to pass along the conduit. For example, a pressure differential of 0.5 bar may be required in order to switch the arrangement from an open condition to a closed condition, although other pressure differentials may be selected depending on requirements. The valves may take any suitable form, but typical have a moveable valve plate which is biased against a valve seat by a spring. The internal resistance of the spring must be overcome in order to move the valve plate away from the seat to provide a gas passage through the valve. The internal resistance should be selected such that the valve does not open during typically encountered normal working conditions and only opens when a predetermined pressure differential between the first and second locations of the pumping channel is generated during roughing when the scroll inlet is at or close to atmosphere. That is, when the pump is initially operated, the scroll inlet is at atmosphere and the scroll outlet is at atmosphere. The scroll mechanism 11 achieves compression such that the first location 40 of the pumping channel is at a pressure higher than atmosphere so that over-compression is generated. In order to blow-off or release this pressure when the over-compression reaches a predetermined pressure of for example 1.5 bar, the pressure differential between the conduit inlet 40 and the conduit outlet 42 (which is at approximately 1 bar) is sufficient to overcome the internal resistance of the valve arrangement allowing release of over-compression to the scroll exhaust 26. Over-compression at the first location may continue while the pressure at the scroll inlet is reduced although depending on where the first location is in the pumping channel and other characteristics of the pump over-compression is not generated when the scroll inlet pressure is below 100 mbar. Therefore, over-compression may be generated when the scroll inlet is at a pressure of between 100 mbar and 1 bar.
If two one-way valves 44 are included in the valve arrangement, and each valve has an internal resistance, then the differential pressure between the first location 40 and the second location 42 must be sufficient to overcome the internal resistances of both valves.
The conductance of the gas conduit and the valves when open should be sufficient to allow relatively rapid release of over-compression in the pump without increasing the load on the pump for a substantial time. Preferably, pressure should be released in less than about 5 seconds.
The location of the gas conduit inlet 40 depends upon the pumping characteristics of the scroll pumping mechanism 11. The inlet should be at least one wrap (or) 360° from the scroll inlet i.e. where over-compression may commence and at least one wrap away from the scroll outlet. For example, it may be desired to locate inlet 40 at the second wrap where an over-compression of 0.5 bar is to be relieved (i.e. a pressure of 1.5 bar being atmospheric pressure plus 0.5 bar). In this case, the spring pressure of the valve or valves is selected to be 0.5 bar such that when the pressure at the inlet reaches 1.5 bar, gas flows through the conduit to atmosphere. It will be apparent that the location of the inlet 40 and the spring pressure of the valves can be changed to meet various different pumping and power consumption requirements.
In use, during roughing when the pump inlet 24 and scroll inlet 25 are at or close to atmosphere, co-operation of the two scrolls 20, 22 compresses gas along the pumping channel 32. Over-compression is generated at the first location 40 of the pumping channel and when the over-compression reaches a predetermined level above the inlet pressure, valves 44 are opened allowing gas to be released to the pump exhaust 26 which is at atmosphere thereby decreasing load on the pump and reducing the power consumption of the motor 18. During this initial stage, the co-operating wraps of the two scrolls 20, 22 between the first location 40 and the exhaust 26 are not used to compress gas. Over continued use of the pump, the pressure at the inlet 24 is reduced which in turn reduces pressure at the first location 40 of the pumping channel 32. When the over-compression drops below the predetermined level the valves 44 close and gas is conveyed along the remainder of the pumping channel 32 at the exhaust 26 rather than being released to atmosphere through the valves 44.
In a first condition of the pump during roughing when the scroll inlet is at or close to atmosphere the valve arrangement is closed. In a second condition when a predetermined pressure differential is generated between the first and second locations of the pumping channel during roughing and the first location is above atmosphere the valve arrangement is open. In a third condition when pressure at the scroll inlet is reduced below atmosphere (typically less than 0.5 bar) and the pressure differential between the first and second locations of the pumping channel is less than the predetermined pressure the valve arrangement is closed. In the third condition of the pump, the scroll inlet is reduced to vacuum pressures between about 10-1 mbar and 10 mbar and therefore the pressure differential across the valve arrangement is reversed compared to the pressure differential in the second condition.
In the alternative vacuum pump 50 shown in
During roughing when the scroll inlet 25 is at or close to atmosphere, and over-compression is generated at the first location 54, gas is released through the gas conduit 52 when the pressure differential between the conduit inlet 54 and the conduit outlet 56 is above a predetermined level thereby decreasing load on the pump and reducing power requirements. This arrangement is effective during the initial stages of roughing. Although the pressure at the scroll inlet does not decrease significantly during the initial stage of pump down, gas continues to be pumped from the processing chamber connected to the scroll inlet. In this way, the gas conduit 52 and valve arrangement reduces the power requirement during roughing.
In a further vacuum pump 60 shown in
During roughing when over-compression is generated at the first location 64, gas is released through the gas conduit 62 when the pressure differential between the conduit inlet 64 and the conduit outlet 66 is above a predetermined level thereby decreasing load on the pump and reducing power requirements. The first location 64 is typically at a lower pressure than the upstream second location 66.
In a further arrangement, vacuum pump 70 as shown in
As shown in
A modified scroll pumping mechanism 78 is shown in
The scroll pumping mechanism 78 comprises a first section adjacent the scroll inlet 25 and a second section adjacent the scroll outlet 27 and the pumping capacity of the first section is larger than the pumping capacity of the second section, and wherein the first location of the pumping channel is downstream of a transition between the first section and the second section. In
In the scroll pumping mechanism of
In
Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims.
Number | Date | Country | Kind |
---|---|---|---|
1113843.5 | Aug 2011 | GB | national |
This Application is a Section 371 National Stage Application of International Application No. PCT/GB2012/051930, filed Aug. 9, 2012, which is incorporated by reference in its entirety and published as WO 2013/021203 A2 on Feb. 14, 2013 and which claims priority of British Application No. 1113843.5, filed Aug. 11, 2011.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/GB2012/051930 | 8/9/2012 | WO | 00 | 1/15/2014 |