Structure for stabilizing an orbiting scroll in a scroll compressor

What is claimed is: 1. A scroll compressor, comprising: a compressor housing; an output stage of compression disposed within the compressor housing, the output stage comprising: a first, stationary, scroll member comprising a base and a spiral wrap extending from the base of the first, stationary, scroll member; and a second, orbiting, scroll member comprising a base and a spiral wrap extending from the base of the second, orbiting, scroll member; a coupling disposed between the base of the first, stationary, scroll member and the base of the second, orbiting, scroll member and in surrounding relationship to the spiral wrap of the first, stationary, scroll member and the spiral wrap of the second, orbiting, scroll member; an orbiting scroll hydrostatic thrust bearing configured to limit thrust loading on the base of the second, orbiting, scroll member; the scroll compressor further comprising at least one of: one or more protrusions disposed on the base of the first, stationary, scroll member and configured to at least partially stabilize an axial thrust force between the coupling and the base of the first, stationary, scroll member to at least partially prevent tipping of the second, orbiting, scroll member, the one or more protrusions disposed between the first, stationary, scroll member and the second, orbiting, scroll member, wherein a gap is maintained between the one or more protrusions and the second, orbiting, scroll member; one or more protrusions disposed on the base of the second, orbiting, scroll member and configured to at least partially stabilize an axial thrust force between the coupling and the base of the second, orbiting, scroll member to at least partially prevent tipping of the second, orbiting, scroll member, the one or more protrusions disposed between the first, stationary, scroll member and the second, orbiting, scroll member, wherein a gap is maintained between the first, stationary, scroll member and the one or more protrusions; one or more protrusions disposed on a first, stationary, scroll member base side of the coupling and configured to at least partially stabilize an axial thrust force between the coupling and the base of the first, stationary, scroll member to at least partially prevent tipping of the second, orbiting, scroll member, the one or more protrusions disposed between the first, stationary, scroll member and the coupling, wherein a gap is maintained between the first, stationary, scroll member and the one or more protrusions, or between the one or more protrusions and the second, orbiting, scroll member; and one or more protrusions disposed on a second, orbiting, scroll member base side of the coupling and configured to at least partially stabilize an axial thrust force between the coupling and the base of the second, orbiting, scroll member to at least partially prevent tipping of the second, orbiting, scroll member, the one or more protrusions disposed between the second, orbiting, scroll member and the coupling, wherein a gap is maintained between the first, stationary, scroll member and the one or more protrusions, or between the one or more protrusions and the second, orbiting, scroll member. 2. The scroll compressor according to claim 1 , further comprising: an input stage of compression disposed within the compressor housing, the input stage comprising: a third, stationary, scroll member comprising a base and a spiral wrap extending from the base of the third, stationary, scroll member; and a fourth, orbiting, scroll member comprising a circular base and a spiral wrap extending from the base of the fourth, orbiting scroll member; another coupling disposed between the base of the third, stationary, scroll member and the base of the fourth, orbiting, scroll member and in surrounding relationship to the spiral wrap of the third, stationary, scroll member and the spiral wrap of the fourth, orbiting, scroll member; the scroll compressor further comprising at least one of: one or more protrusions disposed on the base of the third, stationary, scroll member and configured to at least partially stabilize an axial thrust force between the another coupling and the base of the third, stationary, scroll member to at least partially prevent tipping of the fourth, orbiting, scroll member, the one or more protrusions disposed between the third, stationary, scroll member and the fourth, orbiting, scroll member, wherein a gap is maintained between the fourth, orbiting, scroll member and the one or more protrusions; one or more protrusions disposed on the base of the fourth, orbiting, scroll member and configured to at least partially stabilize an axial thrust force between the another coupling and the base of the fourth, orbiting, scroll member to at least partially prevent tipping of the fourth, orbiting, scroll member, the one or more protrusions disposed between the third, stationary, scroll member and the fourth, orbiting, scroll member, wherein a gap is maintained between the third, stationary, scroll member and the one or more protrusions; one or more protrusions disposed on a third, stationary, scroll member base side of the another coupling and configured to at least partially stabilize an axial thrust force between the another coupling and the base of the third, stationary, scroll member to at least partially prevent tipping of the fourth, orbiting, scroll member, the one or more protrusions disposed between the third, stationary, scroll member and the another coupling, wherein a gap is maintained between the third, stationary, scroll member and the one or more protrusions, or between the one or more protrusions and the fourth, orbiting, scroll member; and one or more protrusions disposed on a fourth, orbiting, scroll member base side of the another coupling and configured to at least partially stabilize an axial thrust force between the another coupling and the base of the fourth, orbiting, scroll member to at least partially prevent tipping of the fourth, orbiting, scroll member, the one or more protrusions disposed between the fourth, orbiting, scroll member and the another coupling, wherein a gap is maintained between the third, stationary, scroll member and the one or more protrusions, or between the one or more protrusions and the fourth, orbiting, scroll member. 3. The scroll compressor according to claim 2 , wherein the input stage of compression further comprises a backpressure valve configured to create a predetermined minimum axial thrust pressure differential across the fourth, orbiting, scroll member. 4. The scroll compressor according to claim 1 , wherein the scroll compressor is one of a single-stage scroll compressor, a double-ended two-stage scroll compressor, and a scroll compressor comprising more than two sets of single stage compression. 5. The scroll compressor according to claim 1 , wherein the scroll compressor is a horizontal scroll compressor. 6. The scroll compressor according to claim 1 , wherein the output stage further comprises a backpressure valve configured to create a predetermined minimum axial thrust pressure differential across the second, orbiting, scroll member. 7. A scroll compressor, comprising: an output stage of compression disposed within a compressor housing, the output stage comprising: a first, stationary, scroll member comprising a base and a spiral wrap extending from the base of the first, stationary, scroll member; and a second, orbiting, scroll member comprising a base and a spiral wrap extending from the base of the second, orbiting, scroll member; a coupling disposed between the base of the first, stationary, scroll member and the base of the second, orbiting, scroll member and in surrounding relationship to the spiral wrap of the first, stationary, scroll member