A vacuum valve comprises a valve suction port flange; a valve exhaust port flange having a greater opening diameter than that of the valve suction port flange; a valve plate; a valve driver configured to slidably drive the valve plate between a closed position and an opening position; and a gas flow path region including an opening of the valve exhaust port flange and having a changing flow path sectional area. In the gas flow path region, a flow path sectional area of an upstream region end is set to an opening sectional area of the valve suction port flange, and increases toward the opening of the valve exhaust port flange.

A drum unloader may include a pump assembly, a motor, a plate, a piston-cylinder assembly, and a sensor. The motor drives the pump assembly. The plate is mounted to the pump assembly and includes an inlet to the pump assembly. The piston-cylinder assembly includes a housing, a piston, and a piston rod. The housing defines a bore. The piston is received within the bore and cooperates with the housing to define a first cavity and a second cavity. The piston rod is attached to and extends from the piston such that the piston rod extends through the first cavity. The piston rod is coupled to the pump assembly, the motor and the plate such that movement of the piston within the bore causes corresponding movement of the pump assembly, the motor and the plate relative to the housing. The sensor measures a pressure within the second cavity.

An air motor assembly includes an exhaust block with an exhaust port that conveys exhaust air into an exhaust manifold. The exhaust port includes an expansion chamber that creates a pressure drop in the exhaust gas, thereby decreasing the temperature of the exhaust gas. The expansion chamber is defined between a first wall that is tangential to the air motor cylinder and a second wall that is transverse to an axis of the exhaust port. Poppet valves control actuation of a shuttle. The poppet valves are disposed on the exterior of the air motor assembly and are thermally insulated from the air motor assembly.

An air motor assembly includes an exhaust block with an exhaust port that conveys exhaust air into an exhaust manifold. The exhaust port includes an expansion chamber that creates a pressure drop in the exhaust gas, thereby decreasing the temperature of the exhaust gas. The expansion chamber is defined between a first wall that is tangential to the air motor cylinder and a second wall that is transverse to an axis of the exhaust port. Poppet valves control actuation of a shuttle. The poppet valves are disposed on the exterior of the air motor assembly and are thermally insulated from the air motor assembly.

A positive displacement pump for dispensing fluid includes a fluid body sub-assembly including a fluid body and a negating check valve. The negating check valve includes a negating body defining a dispensing opening. The fluid body and the negating body form a flow path for the fluid. The fluid is dispensed through the dispensing opening. The positive displacement pump is primed by allowing trapped air within the flow path to flow out of the dispensing opening. The negating check valve may be fully or partially attached to the fluid body. The trapped air within the flow path flows out of the dispensing opening when the negating check valve is partially attached to the fluid body.

A pump moves fluid by a piston reciprocating inside a cylinder. Fluid enters the cylinder through an inlet valve that passes through the cylinder head, and has an enlarged surface inside the cylinder, which seals against the cylinder head. This valve is normally held closed by a spring. As the piston advances, fluid is forced out of the cylinder through a passage in the cylinder head and a check valve. A rod is affixed to the piston and passes through the inlet valve. As the piston retracts, the rod slides through the inlet valve, until a stop, affixed to the rod, encounters the stem of the inlet valve. The spring holding the valve closed is overcome and the valve opens as the piston and rod move farther, until the piston is in its fully retracted position. Fluid enters the cylinder until the piston again begins to advance. The stop ceases to push the inlet valve open, and the spring again holds it closed.

A pilot valve for reliably moving a switching valve of a gas control valve. The pilot valve includes a bottomed cylinder-shaped valve body having an opening at one end, spools slidably accommodated in the valve body, and resilient members disposed at other ends of the spools opposite to the opening side to urge the spools toward the opening side. The valve body has at least three through-hole portions substantially equally spaced in a longitudinal direction. The spools allow communication between at least two mutually adjacent through-hole portions. The resilient members are configured to press the spools toward the opening side of the valve body in cooperation with a pressing device, thereby switching the spools from a state where the spools are positioned at a side of the valve body opposite to the opening side to a state where the spools are positioned at the opening side.

An apparatus for cooling-water extraction for a robot installation plate is characterized by an adjustable extraction volume. The extraction volume is achieved by a sufficiently large extraction cylinder which has a maximum extraction volume, wherein the extraction volume is adjusted by a mechanical stroke limit of a piston located in the extraction cylinder. In at least one embodiment, the mechanical stroke limit is realized by an adjustment screw that is on or in the extraction cylinder. The adjustment screw forms a stop that provides an end position limit or stroke limit of the piston.

An apparatus for cooling-water extraction for a robot installation plate is characterized by an adjustable extraction volume. The extraction volume is achieved by a sufficiently large extraction cylinder which has a maximum extraction volume, wherein the extraction volume is adjusted by a mechanical stroke limit of a piston located in the extraction cylinder. In at least one embodiment, the mechanical stroke limit is realized by an adjustment screw that is on or in the extraction cylinder. The adjustment screw forms a stop that provides an end position limit or stroke limit of the piston.

The utility model discloses a pneumatic automatic reversing feeding pump, which belongs to the technical field of pneumatic pumps, and it comprises a pneumatic part, a connecting part, and a pumping part. The pneumatic part adopts the design structure of a square cylinder; the design structure of a square integrated reversing valve and valve plate; the spherical piston rod connection structure; the pneumatic part and the hydraulic part are easy to install and dismantle with the clamp design structure. The hydraulic part includes a bung adapter assembly, a pump body, a up suction tube, a lower suction tube, an intake valve, and other related parts. It has a reasonable structural design, simple operation, seamless transition between forward and reverse strokes, easy installation, and maintenance, better sealing effect, strong reliability, and can be applied to various working environments