A pressing tool is described for plastically deforming a workpiece. The pressing tool comprises a piston pump driven by a motor that rotates in operating rotation direction RA and a pressure release valve and a coupling arrangement, which mechanically couples the motor to the pressure relief valve, so that the motor opens the pressure relief valve when operated in a loosening rotation direction RL opposite to the operating rotation direction RA. Also described is a corresponding method of operating a pressing tool.

The present disclosure provides a system and associated method for a positive retraction bypass valve. The positive retraction bypass valve can include a dump cartridge in a valve body with a valve stem biased to an open position to allow flow through a drain path. An adjuster can advance toward the valve stem and oppose the bias to at least partially close the valve. Upon retraction of the adjuster from the valve body, a retraction rod assembly with a retraction rod coupled to the adjuster and the valve stem can pull the valve stem toward the adjuster if the bias or fluid pressure on the valve stem does not move the valve stem toward the adjuster.

A pump includes a pair of valves, coupled to a camshaft that selectively opens and closes the valves such that when one valve opens the other valve closes. The valves are in fluid communication with a piston chamber. A crankshaft operates a piston in a piston cylinder with the opening and closing of the valves such that as the piston is drawn from the piston chamber, the inlet valve is open and the outlet valve is closed and when the piston is forced into the chamber, the outlet valve is open and the inlet valve is closed. The camshaft and crankshaft are coupled together to cause synchronous operation of the valves and piston.

A compressor assembly is provided and may include a first compression cylinder, a first compression piston disposed within the first compression cylinder that compresses a vapor disposed within the first compression cylinder, and a crankshaft that cycles the first compression piston within the first compression cylinder. The compressor assembly may additionally include a first control piston moveable between a first state restricting passage of intermediate-pressure fluid into the first compression cylinder and a second state permitting passage of intermediate-pressure fluid into the first compression cylinder.

A compressor may include a compression cylinder, a compression piston, a crankshaft, an injection bore, a position sensor, and a valve assembly. The compression piston is disposed within the compression cylinder and is operable to compress a vapor disposed within the compression cylinder from a suction pressure to a discharge pressure. The crankshaft is operable to cycle the compression piston within the compression cylinder. The injection bore may be in fluid communication with the compression cylinder and may be operable to selectively communicate intermediate-pressure vapor at a pressure between the suction pressure and said discharge pressure to the compression cylinder. The position sensor may measure a rotational position of the crankshaft. The valve assembly may be associated with the injection bore. The valve assembly may be operable to control passage of fluid from the injection bore into the compression cylinder in response to data provided by the position sensor.

Cam actuated valves for compressors including mechanisms for changing an instant when the cam actuated valve is opened and/or a time interval during which the cam actuated valve is in an open state within the time range of a compression cycle. A reciprocating compressor has: a body including a compression chamber; a cam having an oblong portion, being located inside the body and being configured to be rotated around a rotation axis, to perform a rotation during each compression cycle; an actuating element located inside the body and configured to receive a linear displacement or an angular displacement due to the oblong portion of the cam; and a valve located on a flow path of the fluid toward or from the compression chamber and configured to be switched to an open state by the actuating element. The reciprocating compressor also includes a controller configured to adjust timing of the valve.

The present disclosure provides a system and associated method for a positive retraction bypass valve. The positive retraction bypass valve can include a dump cartridge in a valve body with a valve stem biased to an open position to allow flow through a drain path. An adjuster can advance toward the valve stem and oppose the bias to at least partially close the valve. Upon retraction of the adjuster from the valve body, a retraction rod assembly with a retraction rod coupled to the adjuster and the valve stem can pull the valve stem toward the adjuster if the bias or fluid pressure on the valve stem does not move the valve stem toward the adjuster.

The present invention is provided to suppress occurrence of free flow. An infusion pump includes: a sliding clamp closing and releasing an infusion tube; a pump body including a tube attachment portion to which the infusion tube is to be attached detachably and forcibly transferring liquid in the infusion tube; and a door pivotably supported by the pump body so that the tube attachment portion is openable and closable by the door. The pump body includes: a clamp attachment portion into which the sliding clamp having the infusion tube set therein is to be inserted and set; and a release operator being operated in the clamp attachment portion to transfer the sliding clamp from a close mode to a release mode, the release operator being configured to be locked, in response to opening movement of the door, so that the release operator is inoperable for releasing, and to be unlocked in response to closing movement of the door.

A gear pump comprising a bearing and first and second high pressure feeds from a bearing lube supply source to a lube pad disposed on an inside diameter of the bearing. Each of the first and second high pressure feeds includes an orifice. At least one of the first and second high pressure feeds includes a valve configured to selectively control the feed path and orifice within which it is installed. A method of controlling flow to a gear pump bearing is also disclosed.

A drive assembly and system include a drive, controllable to exhibit a selected one of a plurality of drive modes that include driving the drive in one of a first driving direction and a second driving direction, the second driving direction being directed opposite relative to the first driving direction, a pump that is drivable by the drive and configured to produce a hydraulic flow to flow in a flow direction independent of the first or second driving direction of the selected drive mode, and a control valve that is configured to be set in a valve position associated with the selected drive mode and configured to thereby direct the hydraulic flow produced by the pump depending on the selected drive mode of the drive along a selected one or more of a plurality of flow paths that are arranged downstream of the pump.