Claims
- 1. A valve assembly, comprising:
a valve having i) a bobbin/valve body defining a common port, a normally closed port, and a normally open port, port nipples projecting outwardly away from one side of the body in parallel relation to one another, a longitudinal bore within the body, and respective passageways between the longitudinal bore and the three ports; ii) a selectively energizeable solenoid to produce a magnetic field; and iii) a plunger including a plunger body which moves within the bore in response to energization/deenergization of the solenoid between a first position whereat the passageway to the normally closed port is sealed from the longitudinal bore and the passageway to the normally open port communicates with the longitudinal bore, and a second position whereat the passageway to the normally closed port communicates with the longitudinal bore and the passageway to the normally open port is sealed from the longitudinal bore; and a manifold including channels aligned with the port nipples such that each port nipple is received within a respective channel, the manifold formed of a resilient material and the channels dimensioned such that the port nipples are press-fit in the respective channels and provide a fluid-tight seal, without the need for mechanical seal devices.
- 2. The valve assembly as in claim 1, wherein the bobbin/valve body is located adjacent the manifold, without any O-ring seals between the port nipples and the manifold.
- 3. The valve assembly as in claim 2, wherein each port nipple includes an annular radial barb projecting outwardly, away from the port nipple, the radial barb providing an interference fit within the respective channel.
- 4. The valve assembly as in claim 3, wherein the manifold is formed from an elastomeric material.
- 5. The valve assembly as in claim 4, wherein the manifold is molded from polyurethane.
- 6. The valve assembly as in claim 1, wherein each port nipple includes an annular radial barb projecting outwardly, away from the port nipple, the radial barb providing an interference fit within the respective channel.
- 7. The valve assembly as in claim 1, wherein the manifold includes a generally flat mounting surface and the channels open to the mounting surface.
- 8. A manifold for a valve assembly, the manifold formed of a resilient elastomeric material and including channels for receipt of a respective port nipple from the valve assembly, the manifold having a generally flat mounting surface, the channels each having an end opening to the mounting surface.
- 9. The manifold as in claim 8, wherein the manifold is molded from a polyurethane.
- 10. The manifold as in claim 8, wherein the mounting surface is on one end of the manifold, and the manifold includes connecting passages through side surfaces of the manifold for fluidly interconnecting adjacent modules, and connection means for connecting adjacent manifolds.
- 11. The manifold as in claim 8, wherein the connection means includes fittings received with a press-fit in the connection channels.
- 12. The manifold as in claim 11, wherein the fittings each include at least one annular radial barb projecting outwardly away from the fitting.
- 13. The manifold as in claim 8, wherein the connection means includes fittings formed unitary with the manifold.
- 14. The manifold as in claim 13, wherein the fittings include at least one annular radial barb projecting outwardly away from the fitting.
- 15. The manifold as in claim 8, wherein the channels have another end open to a surface on the manifold other than the mounting surface, and further including connection means for connecting the manifold with other components.
- 16. The manifold as in claim 15, wherein the connection means includes fittings received with a press-fit in the other end of the channels.
- 17. The manifold as in claim 11, wherein the fittings each include at least one annular radial barb projecting outwardly away from the fitting.
- 18. A manifold formed of a resilient elastomeric material and having a generally flat mounting surface, the manifold having channels, the channels each having one end opening to the mounting surface.
- 19. The manifold as in claim 18, wherein the manifold is molded from a polyurethane.
- 20. The manifold as in claim 18, wherein the mounting surface is on one end of the manifold, and the manifold includes connecting passages through side surfaces of the manifold for fluidly interconnecting adjacent modules, and connection means for connecting adjacent manifolds.
- 21. The manifold as in claim 18, wherein the connection means includes fittings received with a press-fit in the connection channels.
- 22. The manifold as in claim 21, wherein the fittings each include at least one annular radial barb projecting outwardly away from the fitting.
- 23. The manifold as in claim 18, wherein the connection means includes fittings formed unitary with the manifold.
- 24. The manifold as in claim 23, wherein the fittings include at least one annular radial barb projecting outwardly away from the fitting.
- 25. The manifold as in claim 18, wherein the channels have another end open to a surface on the manifold other than the mounting surface, and further including connection means for connecting the manifold with other components.
- 26. The manifold as in claim 25, wherein the connection means includes fittings received with a press-fit in the other end of the channels.
- 27. The manifold as in claim 26, wherein the fittings each include at least one annular radial barb projecting outwardly away from the fitting.
RELATED CASES
[0001] This application is continuation-in-part of U.S. patent application Ser. No. 09/564,529, filed May 4, 2000, the disclosure of which is incorporated herein by reference.
Continuation in Parts (1)
|
Number |
Date |
Country |
Parent |
09564529 |
May 2000 |
US |
Child |
09800558 |
Mar 2001 |
US |