DE19728434C2 - Screw compressors for compressible media - Google Patents

Description

The invention relates to a screw compressor according to the preamble of claim 1.

Screw compressors, also called screw screw compressors, are both as compressors and for generating a negative pressure known and usually have intermeshing screws constant diameter.

With such screw compressors, there is the required sealing the need to screw each to be provided with several turns or loops and with each other to comb. This leads to a Pressure increase due to the heating of the medium on the one hand and by Reverse flows at the gaps between the screws and the housing on the other hand arises. The actual compression takes place practically table in the last turns, so that strong pulsations occur, which cause corresponding loads, especially in the axial direction. This has a negative impact on the fixed camp of each Screw. Therefore, this has so far to accommodate such dynamic Forces are oversized.  

A screw compressor of the type mentioned is from the Publications DE 29 34 065 A1 and DE-PS 6 09 405 known. The intermeshing screws have a in the conveying direction steady increase in the root circle or inner diameter and accordingly a constant decrease in the tip circle or outer diameter as well the inner wall of the housing, which leads to a compression of the com pressible medium already during the funding. The of the Manufacturing apparently inexpensive conical shape of the interacting parts has the disadvantage, however, that the ratio of radial thermal expansion to axial Thermal expansion changes constantly over the length of the screws, because there is a defined radial at every point of the screws Thermal expansion takes place, which takes place simultaneously axial thermal expansion of the screws but over their entire Add length. This results in a continuous course of Increase in diameter of the inner wall of the housing at a Arrangement of the fixed bearing in the area of the largest diameter that the screws are pushed into the conical housing in the sense that they can get stuck, or the gaps between the Screws and the inner wall of the housing must be chosen as large be that this is avoided, but the efficiency worsened accordingly at the same time. The fixed camp is located on the other hand, on the side of the smallest diameter of the housing the screws are pushed out of this housing so that due to the conical design, the gap width between Screws and housing increases. This also leads to an un beneficial deterioration in efficiency.

Not least because of these disadvantages, screws compressors according to DE-29 34 065 A1 not implemented in practice, but are still practically exclusively screws compressor with constant over the length of the screw Diameter ratios in trade and in use, on which internal compression is already omitted in the course of the screws must become.  

Such a non-generic screw compressor over the length the screw has a constant head and foot diameter known for example from DE 195 22 559 A1. To a temperature counteract changes in the gap between the screws, are the screws on this screw compressor their area adjacent to the pressure side cooled more than on their area adjacent to the suction side. However, it results from a comparatively complicated screw compressor.

There is therefore the task of a screw compressor to create the kind mentioned at the beginning with inner compression which despite the increase in the root diameter of the screws favorable in the conveying direction over the entire length of the screw, in particular largely constant gap widths realized can be.

The screw compressor mentioned at the beginning is for the solution compressible media characterized in that the fixed bearing in Area of the outlet of the compressed medium are arranged, that the increase in the root diameter of the screws and the corresponding decrease in the tip diameter of the screws and the diameter of the inner wall of the housing in accordance with the increase the temperature of the compressed gas and the screws in Direction of delivery is continuous and non-linear, that is, from Screw tooth base, the screw tooth tip and the inner wall in the Axial section plane formed surface lines a non-linear course and that the greatest slope (increase, decrease) of this Surface lines in the area of the fixed bearing is.

This measure ensures that the greatest increase in Root diameter with the corresponding largest decrease in Diameter of the inner wall of the housing in the area of the fixed bearing the screws is located where the outlet for the compressed Medium or gas. The changes are correspondingly small of the root circle, the tip circle diameter and the diameter of the  Inner wall of the housing at the opposite end of the screw where such a change can even go down to zero, so that there may even be the inner wall of the housing and the Outside of the screw practically parallel to the axis of rotation run. Since the thermal expansion of that in the area of the outlet of the compressed medium and thus fixed bearing located on the pressure side starting towards the ends of the screws added, where the diameter change on is least where there is also radial thermal expansion is the smallest, gap widths with usual tolerances sufficient to prevent jamming between the outside of the screws and to avoid the inner wall of the housing. Because in this area greatest axial thermal movement of the screws hardly or none Diameter changes are provided, so there is a risk of Avoid jamming. Because the axial movement of the screws is relative to the housing due to thermal expansion towards the fixed bearing, the diameter increase can increase accordingly in this direction or by such a disproportionate increase in diameter of the Base diameter of the screws with a corresponding decrease in the The diameter of the inner wall of the housing can be the screw compressor best possible due to the thermal expansion in different places the relative movements of the screws are adjusted, so that practically at all points of the screws despite the Thermal expansion largely constant gap widths be kept. The invention is based on the finding that by a disproportionate change in the diameter in Delivery direction due to the temperature profile and the changing Expected thermal expansion in a way can be compensated that the gap widths within ge desired values remain. Thus, the desired inner Compression can be realized without loss of efficiency or even contact between the screws and the inner wall of the Housing must be expected. The curvature can increase the root diameter of the screws depending on the temperature profile, but also adapted and calculated depending on the material used  and / or determined by experiments.

Another advantage of this arrangement is that the Screws in the area of the fixed bearing their greatest radial Aus stretch and thus have their greatest moment of inertia, so that both with flying storage as well as with a storage Floating bearing in the area of the inlet of the medium to be compressed the cheapest in terms of possible bending deformations Relationships exist and such bending of the screws remain a minimum.

A particularly good adaptation to the changing in the conveying direction Effect of thermal expansion due to the increase in temperature veaus can be reached if the surface lines of the tooth base, of the tooth head and the surface lines according to the inner wall of the housing an exponential function.

Here the intersection line of a plane is under a surface line, in which the axis of the respective screw is arranged, and the Surface of the screw head, the screw base or the inner wall understood the housing. The surface line of the inner wall of the housing thus corresponds to the generatrix of the inner wall.

The arcuate surface lines lead to a continuous Increase in the root diameter of the screws with corresponding adaptation to that also taking place in this direction internal compression and the resulting temperature increased, its effects on thermal expansion due to the Arc shape of the surface lines can be compensated so that the Gaps between screws and housing in the conveying direction during of the company practically unchanged and in all places Screws remain approximately the same size.

For manufacturing reasons, however, it can be useful if at least the surface lines of the inner wall of the housing - and  preferably the corresponding surface lines of the screws - through several straight lines are approximated, which in the conveying direction below increasing angle with respect to the respective axis of rotation of the associated screw are arranged. This allows the manufacture compared to the continuous increase, which is more favorable in terms of flow technology the curvature in the conveying direction can be made easier. This applies all the more, even if the diameter increase of Base diameter of the screws on the one hand and the corresponding Reduction of the tip diameter of the screws on the other hand in the same way in such sections, each with a straight line extending surface lines is provided.

The straight-line sections can be derived, for example Tangent pieces on an arcuate course, as above has already been mentioned, for example on a course according to a Exponential function. This means that despite the subdivision into individual, approximately straight jacket sections a best possible Adaptation to the desired change in diameter accordingly the increase in temperature level reached. It is useful if the transitions between the straight sections of the surface lines the inner wall is curved or rounded.

In all these cases, the advantages according to the invention are retained. that namely the gap losses between screws and housing can be minimized. It can namely in the interpretation of the Screws and the housing take into account that the Thermal expansion of the screws along the axis from the fixed bearing seen more and more increases, the amount of radial expansion but remains approximately constant. It is according to the invention takes into account that for the total extent resulting from these two components - on the one hand in axial and on the other hand in radial direction - results in direction and amount changing. The Attention to these physical conditions through the disproportion tional diameter change in the course of the screws allows a Minimization of the gap between screws and housing from the fixed bearing  out in such a way that despite being over the screw lengths also changing temperature a predominantly constant gap between Screws and housing are preserved. Thus, with optimal Gap width adjustment an inner compression and a front compression achieved during the conveyance by the screws be so that a pulsation is significantly reduced.

Furthermore, the invention opens up the possibility of one in the course deterioration in efficiency over time increasing gap losses caused, for example, by wear of the Screw and the housing can arise, the screws in readjust the axial direction while doing so within the housing more towards the fixed bearing, i.e. in the direction of the decrease in diameter the inner wall of the case, adjusting it, causing the gap again is reduced. This saves a complete exchange of the Screws.

It should be mentioned that the surface lines along the foot and Tip diameter of the screws - and thus also the inner wall of the housing - parallel in the inlet area of the screw compressor can be formed to the respective axis of rotation and themselves with this course preferably extend over several turns can. So it is possible to increase the slope of the Base diameter of the screws and accordingly the decrease in Tip diameter of the screws and the diameter of the To let the inner wall of the housing start at zero and this beginning may even include an area To connect screw sections of constant diameter, if the medium to be transported and compressed and the target pressure ratios appear advantageous to let. An axial adjustment caused by thermal expansion this initial area of the screws then no longer leads to any change in the gap width, especially a radial one Thermal expansion in this initial area due to the very beginning small temperature difference compared to the ambient temperature  is not or not to be expected to any appreciable extent.

Both when combining one or more of the above Features and measures gives the possibility of the screws on the one hand and the housing on the other hand made of materials to produce different coefficients of thermal expansion, thereby also the increase in the temperature level in the conveying direction in to take into account the fact that the gap width is as small as possible can be selected and also the disproportionate diameter Changes to the screws and the inner wall of the housing also can be designed specifically for the material.

The screws on the one hand and the housing on the other hand can made of different materials and the screws for example made of plastic or ceramic and the housing made of metal, which in turn accommodates manufacturing. Furthermore, Find material pairs in which the differences of Temperatures of the screws compared to those of the housing can be taken into account that thermal expansion in particular not differ too much in the axial direction or even the same turn out big. Such material can also be used in production engineering Have advantages because, for example, flow or injection molding procedures can be used. Furthermore, through such Material selection a weight reduction can be achieved.

Another embodiment of the invention to enlarge the Increasing the internal compression of the compressible medium during its transportation through the screws may consist of that in addition to increasing the root diameter of the Screws while reducing their tip circle knife and the inner wall of the housing the pitch of the screws in the direction of conveyance, in particular, decreases continuously or Screws with sections lying one behind the other in the conveying direction in each case compared to the previous section of smaller incline to have. This leads to an even greater reduction in the medium  receiving rooms in the direction of conveyance, i.e. one corresponding stronger compression already in the area of the intermeshing Screws.

The inventive design of the screws and the inner wall the housing allows a practical design in that that the screws in particular starting from the side of the hard Bearing adjustable in the axial direction and thereby the gap width can be adjustable. This allows the one already mentioned Adjustment, for example in the event of wear.

For example, between the outside of the fixed bearing and the Housing an adjusting bush arranged across the fixed bearing be together with the fixed bearing relative to the housing axial direction can be adjustable and fixable. At a such adjusting bush can be corresponding, in the axial direction attack the adjusting screws so that they are axial Adjustment of the fixed bearing also the screws held in it axial direction can also be adjusted.

Overall, this results especially when combining individual or several of the features and measures described a screw ben or screw compressor for compressible media, it as a pressure, be it as a vacuum pump, in which the enclosed space for the compressible medium during its passage increase and reduced disproportionately to the conveyor length. This means an improvement in compaction, which is no longer only on the last turn, and at the same time one Temperature reduction or better distribution of the Temperature or warming, which in turn is an improvement in Cooling over a greater length enables. Most of all, it will the increasing thermal expansion in axial direction in the manner depending on the temperature profile takes into account that the gap between the screws and the Inner wall of the case remains largely the same, although the  Screws the largest when heated in the inlet area experience corresponding axial movements, because there are according to the invention, the smallest changes in diameter and decrease practically asymptotically or even completely a cylindrical screw and housing area in which thus an axial movement no longer influences the gap width Has. The curve of the diameter changes can thus be chosen in this way and be adjusted that between this area and the area immediately adjacent to the fixed bearing, where the axial movement is due to thermal expansion is lowest, i.e. the change in diameter can be greatest, a largely even transition of Diameter changes are provided, the respective Axial movements take into account in the sense that everywhere constant gap widths can be achieved.

The cooling can be in the first part of the screws - in conveyor seen direction - by means of cooling fins on the outside of the housing take place while in the last part of the screws and thus in the area liquid cooling are arranged at the highest compression can. It also advantageously results that the inertia torque of the screws in the main load area, namely near the Fixed storage, is largest, so that correspondingly low through bends occur.

Below is an embodiment with reference to the drawing described.

The only figure shows a partially schematic Longitudinal section of a screw compressor according to the invention two parallel meshing screws or Screw spindles whose root circle diameter in the conveying direction increases while the tip diameter as well as the diameter the inner wall of the housing decreases to the same extent as this root circle diameter increases.  

A whole by 1, designated screw compressor for compressive media has two about parallel axes 2 and 3 counter-rotating and intermeshing screws 4 and 5, each of them called on a common side of an axially defining fixed bearing 6 in the following fixed bearing 6 held and are tightly enclosed by the inner wall 7 of a housing 8 up to a gap distance, the outlet 9 of the compressed medium shown in the drawing only with respect to a channel section being arranged in the region of the fixed bearing 6 . In the area of the inlet in the screw compressor 1 , which is not visible in the drawing due to the course of the cut, bearings 10 can be seen in the exemplary embodiment which permit axial movement. These floating bearings 10 can be dispensed with if the screws 4 and 5 are stored on the fly.

Above all, it is clear from the drawing that the root circle diameter of the two screws 4 and 5 in the conveying direction, i.e. from the area of the bearings 10 to the fixed bearings 6 and the outlet 9 , increases in each case and the tip circle diameter, that is the diameter of the turns 11 of the Screws 4 and 5 , and the diameter of the inner wall 7 of the housing 8 decreases to the extent in the conveying direction in which the root diameter of the screws 4 and 5 increases. As can be clearly seen, the result is that the screw threads and turns 11 mesh with one another over the entire conveying path with the usual small gap spacing or, if appropriate, touching each other and likewise there is only the gap spacing or a slight play on the outside relative to the inner wall 7 of the housing 8 , but which provides a good seal for sealing between inlet and outlet 9 due to the relatively large number of turns 11 .

There is therefore a change in profile along the longitudinal axes 2 and 3 in the sense that an "inner" compression of the compressible medium takes place already on this conveying path, since the enclosed space in which this medium is located is preferably when the compressible medium passes through steady, downsized. The temperature rise caused in particular by the compression is thus also equalized.

Above all, it is clear from the drawing that the larger cross section or the greater moment of inertia of the screws 4 and 5 is achieved in the area of the fixed bearing 6 , which advantageously counteracts deflection in this area of the greatest load.

The increase in the root circle diameter of the screws 4 , 5 and the corresponding decrease in the tip circle diameter of the screws 4 , 5 and the cross section of the inner wall 7 of the housing 8 can be chosen to be disproportionate to the length of the screws 4 and 5 in accordance with the increase in the temperature level. As a result, the dimension of the gap between the tip circle diameter of the screws 4 and 5 and the inner wall 7 of the housing 8 can be kept as small as possible over the entire screw length, that is to say the efficiency of the compressor 1 can be increased. The dimension of this gap is so small that it is not visible in the drawing.

In the exemplary embodiment, it is particularly clear from the longitudinal section of the housing 8 that the surface lines along the inner wall 7 of the housing wall are curved, for example approximately parabolically, with increasing curvature toward the outlet 9 . In a corresponding manner, surface lines are curved along the root circle diameter of the screws 4 , 5 and along the tip circle diameter of the screws 4 , 5 , in order in turn to achieve an adaptation to the expected temperature profile and a correspondingly disproportionate internal compression.

However, it would also be conceivable, in particular for manufacturing reasons, to have the diameter reduction of the inner wall of the housing in the conveying direction steady and straight or in several sections, whereby in the case of section-by-section diameter reduction the surface lines are each rectilinear in the conveying direction but at increasing angles with respect to the respective axis of rotation 2 or 3 of the associated screw 4 or 5 can be done. However, the transitions between such sections could be curved or rounded.

The screws 4 and 5 and / or their housing 8 can be made entirely or partially of plastic, which complies with the production and is also possible for reasons of strength due to the favorable increase in the moment of inertia.

At least the respective outer layer of the screws 4 and 5 could be made of plastic in the region of the root diameter and the threads 11 and / or the inner wall 7 of the housing 8 could be coated with plastic so that the diameter changes, for example in the injection molding process, can be produced relatively easily.

It should also be mentioned that in addition to increasing the root diameter of the screws 4 , 5 while simultaneously reducing the tip diameter of the screws 4 , 5 and the inner wall 7 of the housing 8, the pitch of the screws 4 and 5 or their threads 11 in the conveying direction, that is decrease towards the outlet 9 , in particular could decrease continuously. This would further increase the "inner" compression.

In the drawing it can still be seen that in the first conveying and compression area on the outside of the housing 8 cooling fins 12 for air cooling and in the last part of the conveying path liquid channels 13 are provided for liquid cooling.

In the drawing it is also indicated that the screws 4 and 5 can be adjusted in the axial direction in the area of their fixed bearings 6 and the gap width can thereby be adjusted. For this purpose, the fixed bearing 6 and the housing 8 is arranged a fixed bearing 6 on cross adjusting bushing 14 between the outer side of which is adjustable relative to the housing 8 in the axial direction and can be fixed with the fixed bearing 6 together, and thus also together with the respective screw 4 or 5 , preferably using adjusting screws. This means that the gap width can be optimized after installation or can be adjusted over a longer period of time, taking wear into account.

The screw compressor 1 is used to compress compressible media, be it to create a negative pressure or a vacuum in front of its inlet and / or to create an excess pressure behind its outlet or outlet 9 , and for this purpose it has two axially parallel, counter-rotating and intermeshing screws 4 and 5 . The root circle diameter of the two screws 4 and 5 increases disproportionately in the conveying direction, while the tip circle diameter of these two screws 4 and 5 and the diameter of the inner wall 7 of the housing 8 decrease to the same extent in the conveying direction in which the root circle diameter increases, so that with the usual small gaps already during the transport by the screws 4 and 5 a compression takes place and thereby the effectiveness of the screw compressor 1 is increased without thermal expansions, in particular in the axial direction, to intolerances in the gap widths between the screws 4 and 5 and the inner wall 7 of the housing 8 .

Claims (10)

1. Screw compressor ( 1 ) for compressible media with two screws ( 4 , 5 ) that can rotate and mesh with each other in opposite directions about parallel axes ( 2 , 3 ), which are each held on a common side by a fixed bearing ( 6 ) and by the inner wall ( 7 are tightly enclosed) of a housing (8) except for a gap distance, wherein the root diameter of the two screws (4, 5) in the conveying direction respectively increases and the tip circle diameter of the two screws (4, 5) and the diameter of the inner wall (7) of the housing ( 8 ) decreases to the extent in the conveying direction in which the root circle diameter increases, characterized in that the fixed bearings ( 6 ) are arranged in the region of the outlet ( 9 ) of the compressed medium such that the increase in the root circle diameter of the screws ( 4 , 5 ) and the corresponding decrease in the tip circle diameter of the screws ( 4 , 5 ) and the diameter of the inner wall ( 7 ) of the housing ( 8 ) in accordance with the increase the temperature of the compressed gas and the screws ( 4 , 5 ) is continuous and non-linear in the conveying direction, that is to say that the surface lines formed by the screw tooth base, the screw tooth tip and the inner wall in the axial section have a non-linear course, and that the greatest slope (increase, Decrease) of these surface lines in the area of the fixed bearing ( 6 ). 2. Screw compressor according to claim 1, characterized in that the surface lines of the tooth base, the tooth head and the surface lines of the inner wall ( 7 ) of the housing ( 8 ) run according to an exponential function. 3. Screw compressor according to claim 1 or 2, characterized in that at least the surface lines of the inner wall ( 7 ) of the housing ( 8 ) - and preferably the corresponding surface lines of the screws - are approximated by several straight lines, which in the conveying direction at an increasing angle relative to the respective axis of rotation ( 2 , 3 ) of the associated screw ( 4 , 5 ) are arranged. 4. Screw compressor according to claim 3, characterized in that the line segments derived tangent segments on the arcuate course of the surface lines are. 5. Screw compressor according to one of claims 3 or 4, characterized in that the transitions between the straight pieces of the surface lines of the inner wall ( 7 ) are curved or rounded. 6. Screw compressor according to one of claims 1 to 5, characterized in that the along the root diameter of the screws ( 4 , 5 ) extending generatrices in the inlet region of the screw compressor are formed parallel to the respective axis of rotation and extend with this course preferably over several threads. 7. Screw compressor according to one of claims 1 to 6, characterized in that the screws ( 4 , 5 ) on the one hand and the housing ( 8 ) on the other hand from different materials, if necessary from materials of different thermal expansion coefficients, and thereby the screws ( 4 , 5 ) for example made of plastic or ceramic and the housing ( 8 ) made of metal. 8. Screw compressor according to one of claims 1 to 7, characterized in that in addition to increasing the root diameter of the screws ( 4 , 5 ) while simultaneously reducing their tip diameter and the inner wall ( 7 ) of the housing ( 8 ), the pitch of the screws ( 4 , 5 ) decreases continuously in the conveying direction, in particular, or the screws ( 4 , 5 ) have sections lying one behind the other in the conveying direction, each having a smaller pitch than the previous section. 9. Screw compressor according to one of claims 1 to 8, characterized in that the screws ( 4 , 5 ) adjustable in the axial direction and thereby the gap width are adjustable. 10. Screw compressor according to claim 9, characterized in that between the outside of the fixed bearing ( 6 ) and the housing ( 8 ) a fixed bearing ( 6 ) overlapping adjusting bush ( 14 ) is arranged, which together with the fixed bearing ( 6 ) relative to the Housing ( 8 ) is adjustable and fixable in the axial direction.