A motor includes a shaft rotatable about an axis, an engaged component engaged by the shaft, a sleeve fixed to the shaft to rotate therewith, and a seal at least partly circumscribing the shaft. The shaft includes an engagement region presenting a substantially variable outer shaft surface that at least in part engages the engaged component. The sleeve includes a first section that at least partly circumscribes and engages the engagement region of the shaft. The first section of the sleeve presents an outer seal-engaging surface and an outer bearing-engaging surface. The seal and the bearing each at least partly circumscribe the engagement region of the shaft and the first section of the sleeve to engage the seal-engaging surface and the bearing-engaging surfaces, respectively, of the sleeve.

Technologies for managing pressure across one or more chamber seals in machines handling process fluids. The machine includes a pressure chamber and another pressure chamber, both of which are pressurized by the process fluid. The pressure differential between these chambers is maintained by one or more chamber seals. Dynamic coupled elements may be configured within the pressure chamber and/or the other pressure chamber. The other pressure chamber is fluidly connected to a lower-pressure point via a pressure balancing line, facilitating controlled fluid flow through the seals. The induced pressure differential directs a cascading flow of process fluid from the pressure chamber to the other pressure chamber, and subsequently to the lower-pressure point. This arrangement improves pressure regulation, fluid flow management, and seal efficiency, enhancing the overall performance of various machines and industrial applications.

Technologies for managing pressure across one or more chamber seals in machines handling process fluids. The machine includes a pressure chamber and another pressure chamber, both of which are pressurized by the process fluid. The pressure differential between these chambers is maintained by one or more chamber seals. Dynamic coupled elements may be configured within the pressure chamber and/or the other pressure chamber. The other pressure chamber is fluidly connected to a lower-pressure point via a pressure balancing line, facilitating controlled fluid flow through the seals. The induced pressure differential directs a cascading flow of process fluid from the pressure chamber to the other pressure chamber, and subsequently to the lower-pressure point. This arrangement improves pressure regulation, fluid flow management, and seal efficiency, enhancing the overall performance of various machines and industrial applications.

A rotary piston machine is disclosed. In one aspect, the machine includes a piston chamber that is defined in a housing by a first sidewall, a second sidewall and a peripheral wall interconnecting these sidewalls and a rotary piston that is rotatably arranged in the piston chamber and has a first face and a second face. The first face of the rotary piston faces an interior of the first sidewall of the piston chamber and the second face of the rotary piston faces an interior of the second sidewall of the piston chamber. at least one ventilation bore is provided in the first and/or the second sidewall of the piston chamber and connected to at least one ventilation channel, wherein the at least one ventilation bore is arranged at a location that radially lies within at least one first lateral seal.

A rotary piston machine is disclosed. In one aspect, the machine includes a piston chamber that is defined in a housing by a first sidewall, a second sidewall and a peripheral wall interconnecting these sidewalls and a rotary piston that is rotatably arranged in the piston chamber and has a first face and a second face. The first face of the rotary piston faces an interior of the first sidewall of the piston chamber and the second face of the rotary piston faces an interior of the second sidewall of the piston chamber. at least one ventilation bore is provided in the first and/or the second sidewall of the piston chamber and connected to at least one ventilation channel, wherein the at least one ventilation bore is arranged at a location that radially lies within at least one first lateral seal.

A housing assembly has: a rotor housing extending around a rotation axis and from a first side to a second side, and having an inner face; a housing secured to the first side; and a seal received within a groove at an interface between the rotor housing and the housing, the groove extending around a perimeter of the first side and located radially outwardly of the inner face, the seal including: an elastomeric member; and a shield disposed inwardly of the elastomeric member and in contact with both the housing and the rotor housing, the shield including a thermoset plastic member extending along at least a portion of a perimeter of the groove and axially overlapping the elastomeric member, the thermoset plastic member circumferentially overlapping a combustion region of the rotor cavity where combustion occurs during operation of the rotary internal combustion engine.

A housing assembly has: a rotor housing extending around a rotation axis and from a first side to a second side, and having an inner face; a housing secured to the first side; and a seal received within a groove at an interface between the rotor housing and the housing, the groove extending around a perimeter of the first side and located radially outwardly of the inner face, the seal including: an elastomeric member; and a shield disposed inwardly of the elastomeric member and in contact with both the housing and the rotor housing, the shield including a thermoset plastic member extending along at least a portion of a perimeter of the groove and axially overlapping the elastomeric member, the thermoset plastic member circumferentially overlapping a combustion region of the rotor cavity where combustion occurs during operation of the rotary internal combustion engine.