This application relates to a scroll compressor, wherein one of the two scroll members is formed of a significantly harder material than the other such that run-in can occur at start-up of the scroll compressor.
Scroll compressors are known, and are becoming widely utilized in fluid compression applications. In a typical scroll compressor, one scroll member has a base and a generally spiral wrap extending from its base. The generally spiral wrap of this scroll member interfits with a generally spiral wrap of a second scroll member. The wraps interfit to define compression chambers. One of the two scroll members is caused to orbit relative to the other, and as the orbiting movement occurs, the size of the compression chambers decrease and an entrapped fluid is compressed.
One challenge with scroll compressor designs is the creation of a separating force between the two scroll members. As the fluid is compressed, the pressure within the compression chambers increases, and tends to force the two scroll members away from each other. To address this, it is typical that a force is applied behind one of the two scroll members tending to bias it toward the other.
Thus, one of the two scroll members is typically capable of some limited axial movement toward the other.
In addition, it is important for there to be tight tolerances, and that the tip of the spiral wrap of one scroll member is close to the base of the opposed scroll member. However, due to tolerances, etc., it is often the case that some of the scroll wrap may be spaced from the opposed base.
Also, the actual shape of a scroll member in operation may change significantly from the machined shape. This can occur due to mechanical stresses, thermal stresses, and the internal pressures.
It is known to form the scroll compressor members of various materials.
A scroll compressor comprises a non-orbiting scroll member having a base and a generally spiral wrap extending from its base, and an orbiting scroll member having a base and a generally spiral wrap extending from its base. The wraps of the non-orbiting and orbiting scroll members interfit to define compression chambers. A drive shaft causes the orbiting scroll member to orbit relative to the non-orbiting scroll member. At least one of the non-orbiting and orbiting scroll operate to move in an axial direction toward the other of the non-orbiting and orbiting scroll members. The scroll compressor supplies a bias force to bias the at least one scroll member toward the other. A first of the non-orbiting and orbiting scroll members have at least a portion of its surface formed of a material that is harder than the material that it will contact on a second of the non-orbiting and orbiting scroll members, such that upon start-up there will be run-in and removal of the material.
These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.
A crankcase 32 supports the orbiting scroll 24, and a housing 30 surrounds the non-orbiting scroll 26.
As shown in
The amount of the tolerance problem is exaggerated to illustrate the problem.
Another problem that occurs is that since the portions 100 of the wrap 56 that is in contact with area 51 will also tend to force the other portions of the wrap away from the base 50. Thus, as shown in
As shown in
The initial clearance between the non-orbiting scroll base 54 and the stop 62 may be set higher than a nominal wrap height tolerance. That is, the scroll compressor wrap may be designed such that the height of the orbiting scroll wraps 52 is selected such that there will be initial clearance until run-in achieves a perfectly tailored shape.
In the inventive scroll compressor, the non-orbiting scroll 54 is formed of a hardened material. In one example, 6061 aluminum alloy may be utilized. After the scroll wrap is machined, it is hard anodized treated, and then coated with Teflon to seal surface porosity.
At the same time, the orbiting scroll member 50 is also made of 6061 aluminum alloy, but without any hardening treatment or Teflon treatment.
With this arrangement, at start-up of the scroll compressor, the wrap portion 56 which was in contact with the area 51 will wear into the base, such as shown at 53. With this wearing, there will be a tight tolerance fit across the entire scroll compressor wrap.
In addition, there are stops 60 and 62 that are formed within the scroll compressor, and which serve to limit the axial movement of the non-orbiting scroll 54. The stop 60 is important because a pressure spike could force the non-orbiting scroll member 54 away from the orbiting scroll member 50. Stop 60 will then serve to limit this movement.
On the other hand, as shown in
As shown in
In another option, the height of the wrap of the softer scroll member may be selected to be slightly higher than the wrap of the harder scroll member. This will reduce the duration of the run-in period, and reduce the amount of debris that is generated.
Although an embodiment of this invention has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.