Scissor type compression and expansion machine used in a thermal energy recuperation system

The invention claimed is: 1. A compression and expansion machine comprising: a body with at least one chamber about an axis of symmetry; pistons rotating about the axis of symmetry and dividing the chamber into cells rotating with the pistons; and a coordination device for coordinating the movement of the pistons, the coordination device configured so that, during one rotation cycle, each of the cells performs at least one first expansion/contraction cycle corresponding to a stage of compressing a first stream of gas passing through said each of the cells, and at least one second expansion/contraction cycle corresponding to a stage of expanding a second stream of gas passing through said each of the cells, wherein the body further comprises a gas inlet opening and a gas outlet opening for each expansion/contraction cycle of said each of the cells, and wherein a passage cross-section of the gas inlet opening of the at least one first expansion/contraction cycle is larger than a passage cross-section of the outlet opening of the at least one first expansion/contraction cycle, and a passage cross-section of the gas inlet opening of the at least one second expansion/contraction cycle is smaller than a passage cross-section of the outlet opening of the at least one second expansion/contraction cycle. 2. The compression and expansion machine as claimed in claim 1 , wherein the coordination device is configured such that said each of the cells performs a same number of the at least one first expansion/contraction cycle corresponding to a stage of gas expansion as the at least one second expansion/contraction cycle corresponding to a stage of gas compression. 3. The compression and expansion machine as claimed in claim 1 , wherein the gas inlet opening of the at least one first expansion/contraction cycle is close to the gas outlet opening of the at least one second expansion/contraction cycle. 4. The compression and expansion machine as claimed in claim 1 , wherein the gas outlet opening of the at least one first expansion/contraction cycle is close to the gas inlet opening of the at least one second expansion/contraction cycle. 5. The compression and expansion machine as claimed in claim 1 , wherein the gas inlet opening of the at least one first expansion/contraction cycle and the gas outlet opening of the at least one second expansion/contraction cycle are diametrically opposed relative to the gas inlet opening of the at least one second expansion/contraction cycle and the gas outlet opening of the at least one first expansion/contraction cycle respectively. 6. The compression and expansion machine as claimed in claim 1 , wherein the passage cross-section of the gas inlet opening of the at least one first expansion/contraction cycle and the passage cross-section of the gas outlet opening of the at least one second expansion/contraction cycle is larger than the passage cross-section of the gas outlet opening of the at least one first expansion/contraction cycle and the passage cross-section of the gas inlet opening of the at least one second expansion/contraction cycle. 7. The compression and expansion machine as claimed in claim 1 , comprising two pairs of pistons, wherein each of the cells, during the one rotation cycle, performs only one of the at least first expansion/contraction cycle, and only one of the at least second expansion/contraction cycle, an intake stage of the at least one first expansion/contraction cycle on one of the cells having a time period common to an exhaust stage of the at least one second expansion/contraction cycle on the other cell which follows the one of the cells in the rotation cycle. 8. The compression and expansion machine as claimed in claim 7 , wherein the intake stage of the at least one first expansion/contraction cycle on one of the cells is offset in time relative to the exhaust stage of the at least one second expansion/contraction cycle on the other cell which follows the one of the cells in the rotation cycle. 9. The compression and expansion machine as claimed in claim 1 , wherein the coordination device comprises means for coordinating the movement of the pistons are fluidically separated from the chamber. 10. The compression and expansion machine as claimed in claim 1 , further comprising sealing means between the pistons and an inner wall of the chamber to separate said each of the cells and allow dry friction on the inner wall of the chamber. 11. The compression and expansion machine as claimed in claim 1 , wherein a cross-section of the chamber on an axial plane is rounded. 12. A device for recovering energy from a hot thermal source, said device comprising: a heat exchanger between a working fluid and the hot thermal source; and a compression and expansion machine comprising: a body with at least one chamber about an axis of symmetry; pistons rotating about the axis of symmetry and dividing the chamber into cells rotating with the pistons; and a coordination device for coordinating the movement of the pistons, the coordination device configured so that, during one rotation cycle, each of the cells performs at least one first expansion/contraction cycle corresponding to a stage of compressing a first stream of gas passing through said each of the cells, and at least one second expansion/contraction cycle corresponding to a stage of expanding a second stream of gas passing through said each of the cells, wherein the body further comprises a gas inlet opening and a gas outlet opening for each expansion/contraction cycle of said each of the cells, and wherein a passage cross-section of the gas inlet opening of the at least one first expansion/contraction cycle is larger than a passage cross-section of the outlet opening of the at least one first expansion/contraction cycle, and a passage cross-section of the gas inlet opening of the at least one second expansion/contraction cycle is smaller than a passage cross-section of the outlet opening of the at least one second expansion/contraction cycle wherein, at a given instant, the working fluid of the compression and expansion machine returns to the heat exchanger after having undergone the stage of compressing in the at least one first expansion/contraction cycle of the compression and expansion machine and leaves the heat exchanger in order to undergo the stage of expanding in the at least one second expansion/contraction cycle of the compression and expansion machine. 13. The device for recovering energy from a hot thermal source as claimed in claim 12 , wherein an entire stream of the working fluid passing through one of the at least one first expansion/contraction cycle is processed by only one of the at least one second expansion/contraction cycle of the compression and expansion machine. 14. The device for recovering energy from a hot thermal source as claimed in claim 12 , wherein one expansion/contraction cycle is open to ambient atmosphere. 15. The device for recovering energy from a hot thermal source as claimed in claim 12 , wherein exhaust gases of an internal combustion engine form the hot thermal source. 16. A compression and expansion machine comprising: a body with at least one chamber about an axis of symmetry; two pairs of pistons rotating about the axis of symmetry and dividing the chamber into cells rotating with the pistons; and a coordination device for coordinating the movement of the pistons, the coordination device configured so that, during one rotation cycle, each of the cells performs at least one first expansion/contraction cycle corresponding to a stage of compressing a first