Claims
- 1. Roller vane pump suitable for pumping transmission fluid in an automatic transmission for motor vehicles, in particular a continuously variable transmission, comprising:a pump housing (2); a drivably rotatable carrier (3) having a substantially circular cross section and being located in the interior of the pump housing (2), at its radial periphery being provided with slots (6) that extend in a direction substantially inward from the periphery; a cam ring (5) having a non-circular inner surface (5a) and surrounding the carrier (3) in radial direction; substantially cylindrical roller elements (7) being slidably provided in the slots (6) of the carrier (3), wherein the spaces between the pump housing (2), the carrier (3), the cam ring (5) and the roller elements (7) define pump chambers (8), wherein said pump chambers (8) are divided into cam chambers (8b) and carrier chambers (8a), the cam chambers (8b) ranging from tangential centre planes of the roller elements (7) radially outward, and the carrier chambers (8a) ranging from tangential centre planes of the roller elements (7) radially inward, each carrier chamber (8a) being associated with a leading cam chamber (8b) in rotational direction and a trailing cam chamber (8b) in anti-rotational direction; at least one feed aperture (9) having a substantially elongated shape, a long axis of said feed aperture (9) extending in a substantially tangential direction, said feed aperture (9) being arranged in the pump housing (2) such that at least one pump chamber (8) is associated with a feed channel (11) in the pump housing (2) through the feed aperture (9), wherein said feed aperture (9) is divided into an inner feed aperture (9a) and an outer feed aperture (9b) by a ridge (12) having an inner surface (12a) and an outer surface (12b), said surfaces (12a,12b) extending in a substantially axial direction as well as in a substantially tangential direction; and at least one discharge aperture (10) having a substantially elongated shape, a long axis of said discharge aperture (10) extending in a substantially tangential direction, said discharge aperture (10) being arranged in the plump housing (2) such that at least one pump chamber (8) is associated with a discharge channel in the pump housing (2) through the discharge aperture (10), wherein said discharge aperture (10) is divided into an inner discharge aperture (10a) and an outer discharge aperture (10b) by a ridge (12) having an inner surface (12a) and an outer surface (12b), said surfaces (12a,12b) extending in a substantially axial direction as well as in a substantially tangential direction, wherein the feed aperture (9) is shaped such that the leading cam chamber (8b) arrives into communication with the outer feed aperture (9b) before the corresponding carrier chamber (8a) arrives into communication with the inner feed aperture (9a); wherein the discharge aperture (10) is shaped such that the carrier chamber (8a) arrives into communication with the inner discharge aperture (10a) before corresponding leading cam chamber (8b) arrives into communication with the outer discharge aperture (10b); wherein the feed aperture (9) is further shaped such that the communication between the carrier chamber (8a) and the inner feed aperture (9a) is cut off before the communication between the leading cam chamber (8b) and the outer feed aperture (9b) is cut off; and wherein the discharge aperture (10) is further shaped such that the communication between the leading cam chamber (8b) and the outer discharge aperture (10b) is cut off after the communication between the carrier chamber (8a) and the inner discharge aperture (10a) is cut off.
- 2. Roller vane pump according to claim 1, wherein the outer feed aperture (9b) extends beyond the inner feed aperture (9a) in anti-rotational direction; and wherein the inner discharge aperture (10a) extends beyond the outer discharge aperture (10b) in anti-rotational direction.
- 3. Roller vane pump according to claim 1, wherein the feed aperture (9) is shaped such that the outer feed aperture (9b) extends beyond the inner feed aperture (9a) in rotational direction.
- 4. Roller vane pump according to claim 1, wherein the outer feed aperture (9b) extends beyond the inner feed aperture (9a) in anti-rotational direction as well as in rotational direction; and wherein the inner discharge aperture (10a) extends beyond the outer discharge aperture (10b) in anti-rotational direction and the outer discharge opening (10b) extends beyond the inner discharge opening (10a).
- 5. Roller vane pump according to claim 1, wherein an inner or an outer aperture (9a,10a;9b,10b) is provided with an end part (9c,10c) extending in anti-rotational direction, such that at the location of said end part (9c,10c) said pump chamber (8) arrives into communication with said aperture (9a,10a;9b,10b) through an opening in the pump housing (2) having a small, however constant, radial width, which is significantly less than that of the widest part of the aperture (9a,10a;9b,10b).
- 6. Roller vane pump according to claim 5, wherein the opening is a groove (13) formed in the pump housing (2), whereby the axial depth of the groove (13) increases in rotational direction.
- 7. Roller vane pump according to claim 5, wherein the opening is a slit (14) formed by co-operation between the cam ring (5) and the respective end part (9c), and wherein the respective end part (9c) is shaped such that it overlaps a part of the cam ring (5) in axial direction.
- 8. Roller vane pump according to claim 1, wherein the pump is provided with a gap (15) between the roller elements (7) and the carrier (3) in tangential direction allowing fluid communication there between for achieving a substantially equal fluid pressure in the carrier chamber (8a) and the cam chamber (8b).
- 9. Roller vane pump according to claim 8, wherein the width of said gap (15) in tangential direction is dimensioned such that a rate at which the fluid pressure changes in the cam chamber (8b) corresponds to a rate at which the fluid pressure changes in the carrier chamber (8a).
- 10. Roller vane pump according to claim 8, wherein the width of the gap (15) in tangential direction has a value in the range from 0.03 to 0.18 millimeter.
- 11. Roller vane pump according to claim 8, wherein the width of the gap (15) in tangential direction is about 0.5 percent to 2.5 percent of a diameter of a roller element (7).
- 12. Roller vane pump according to claim 8, wherein the width of said gap (15) in tangential direction is dimensioned such that the fluid pressures in the carrier chamber (8a) and in the cam chamber (8b) substantially correspond.
- 13. Roller vane pump according to claim 12, wherein the width of said gap (15) in tangential direction corresponds to a minimum width required for fluid pressures in the carrier chamber (8a) and in the cam chamber (8b) to substantially correspond.
- 14. Roller vane pump according to claim 1, wherein at least one of the inner surface (12a) and the outer surface (12b) of at least one ridge (12) extends substantially parallel to the cam ring surface (5a) over a substantial part of the tangential dimension of said ridge (12).
- 15. Roller vane pump according to claim 14, wherein at least one ridge (12) is located such that the radial distance between the centre line of the ridge (12) and the cam ring surface (5a) is smaller than the radius of the roller elements (7).
- 16. Roller vane pump according to claim 14, wherein a radially outermost boundary surface of at least one outer aperture (9b,10b) extends substantially parallel to the cam ring surface (5a) over a substantial part of the tangential dimension of said boundary surface.
- 17. Roller vane pump according to claim 14, wherein a radially innermost boundary surface of at least one inner aperture (9a,10a) is shaped like a segment of a circle.
- 18. Roller vane pump according to claim 17, wherein the radial position of the radially innermost boundary surface of the inner aperture (9a,10a) coincides with radially innermost parts of the slots (6).
- 19. Automatic transmission for motor vehicles, in particular a continuously variable transmission, provided with a roller vane pump according to claim 1.
- 20. Motor vehicle provided with an automatic transmission, in particular a continuously variable transmission, the transmission being provided with a roller vane pump according to claim 1.
- 21. Roller vane pump suitable for pumping transmission fluid in an automatic transmission for motor vehicles, in particular a continuously variable transmission, comprising:a pump housing (2); a drivably rotatable carrier (3) having a substantially circular cross section and being located in the interior of the pump housing (2), at its radial periphery being provided with slots (6) that extend in a direction substantially inward from the periphery; a cam ring (5) having a non-circular inner surface (5a) and surrounding the carrier (3) in radial direction; substantially cylindrical roller elements (7) being slidably provided in the slots (6) of the carrier (3), wherein the spaces between the pump housing (2), the carrier (3), the cam ring (5) and the roller elements (7) define pump chambers (8), wherein said pump chambers (8) are divided into cam chambers (8b) and carrier chambers (8a), the cam chambers (8b) ranging from tangential centre planes of the roller elements (7) radially outward, and the carrier chambers (8a) ranging from tangential centre planes of the roller elements (7) radially inward, each carrier chamber (8a) being associated with a leading cam chamber (8b) in rotational direction and a trailing cam chamber (8b) in anti-rotational direction; at least one feed aperture (9) having a substantially elongated shape, a long axis of said feed aperture (9) extending in a substantially tangential direction, said feed aperture (9) being arranged in the pump housing (2) such that at least one pump chamber (8) is associated with a feed channel (11) in the pump housing (2) through the feed aperture (9), wherein said feed aperture (9) is divided into an inner feed aperture (9a) and an outer feed aperture (9b) by a ridge (12) having an inner surface (12a) and an outer surface (12b), said surfaces (12a,12b) extending in a substantially axial direction as well as in a substantially tangential direction; and at least one discharge aperture (10) having a substantially elongated shape, a long axis of said discharge aperture (10) extending in a substantially tangential direction, said discharge aperture (10) being arranged in the pump housing (2) such that at least one pump chamber (8) is associated with a discharge channel in the pump housing (2) through the discharge aperture (10), wherein said discharge aperture (10) is divided into an inner discharge aperture (10a) and an outer discharge aperture (10b) by a ridge (12) having an inner surface (12a) and an outer surface (12b), said surfaces (12a,12b) extending in a substantially axial direction as well as in a substantially tangential direction, wherein the feed aperture (9) is shaped such that the leading cam chamber (8b) arrives into communication with the outer feed aperture (9b) before the corresponding carrier chamber (8a) arrives into communication with the inner feed aperture (9a); wherein the discharge aperture (10) is shaped such that the carrier chamber (8a) arrives into communication with the inner discharge aperture (10a) before corresponding leading cam chamber (8b) arrives into communication with the outer discharge aperture (10b); wherein an inner or an outer aperture (9a,10a; 9b,10b) is provided with an end part (9c, 10c) extending in anti-rotational direction, such that at the location of said end part (9c, 10c) said pump chamber (8) arrives into communication with said aperture (9a, 10a; 9b, 10b) through an opening in the pump housing (2) having a small, however constant, racial width, which is significantly less than that of the widest part of the aperture (9a, 10a; 9b, 10b) and wherein the opening is a groove (13) formed in the pump housing (2), whereby the axial depth of the groove (13) increases in rotational direction.
CROSS-REFERENCE TO RELATED APPLICATION
This application is a continuation of prior application no. PCT/NL00/00333, filed May 17, 2000.
The present invention relates to a mechanically driven roller vane pump used for operating an automatic transmission for motor vehicles, in particular a continuously variable transmission (CVT).
US Referenced Citations (7)
Foreign Referenced Citations (3)
Number |
Date |
Country |
3014080 |
Oct 1981 |
DE |
0 921 314 |
Jun 1999 |
EP |
2 118 247 |
Oct 1983 |
GB |
Continuations (1)
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Number |
Date |
Country |
Parent |
PCT/NL00/00333 |
May 2000 |
US |
Child |
09/675837 |
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US |