A first electrode coolant path is configured to cool a first welding electrode by liquid coolant flowing from a supply path through the first electrode coolant path to a return path. A second electrode coolant path is configured to cool a second welding electrode by liquid coolant flowing from the supply path through the second electrode coolant path to the return path. Three or more valves are configured to stop or reduce liquid coolant flow through the first or second electrode coolant path and configured to stop or reduce liquid coolant backflow from the return path when the first or second welding electrode is at least partially detached. At least one valve is coupled in the first or second electrode coolant path. A drawback apparatus generates a suction force to draw liquid coolant away from a gap formed when the first or second welding electrode is at least partially detached.

The present invention discloses an executive system for driving a valve to open and close, comprising a first housing, a linkage block, a first drive rod and a drive mechanism. Wherein, the first housing has a first inner cavity; a medium channel is provided in a side wall of the first housing; an outer peripheral wall of the linkage block is arranged on a wall of the first inner cavity in a slidable and sealed manner, and the linkage block partitions the first inner cavity into an upper cavity and a lower cavity; the medium channel is communicated with the upper cavity; a bottom part of the first drive rod sequentially passes through a top part of the first housing and the linkage block and extends into the lower cavity; a position-limiting part on the bottom part of the first drive rod blocks the linkage block within a region between the position-limiting part and the top part of the first housing; the drive mechanism is provided on top of the first drive rod. The degree of friction between an outer peripheral wall of the linkage block and an inner surface of the first housing is reduced, and the probability of a gap being produced between the peripheral wall of the linkage block and the inner wall of the first housing is reduced, so that the first drive rod can drive the valve stem to move into position, thereby increasing the reliability of the executive system controlling the valve to open and close.

The embodiments disclosed herein relate to a bracket for a valve system, having an actuator side of the bracket, defining a first set of one or more holes; a valve side of the bracket, wherein the valve side is opposite the actuator side, and further wherein the valve side defines a second set of one or more holes; a wall connecting the actuator side and the valve side; and a strain gauge mounted to the wall.

A diaphragm valve includes an inlet port, an outlet port, and a valve seat proximate one of the inlet port or the outlet port. A diaphragm is positioned relative to the valve seat and has an open state wherein the diaphragm is spaced from the valve seat to enable a fluid path between the inlet port and the outlet port. The diaphragm has a closed state wherein the diaphragm is seated on the valve seat to block the fluid path. A coupling member is coupled between the diaphragm and a reciprocatable member and configured to maintain the diaphragm in the open state while the reciprocatable member is in the opened position. The coupling member may have a clearance gap relative to the reciprocatable member when the reciprocatable member is in the closed position. Other diaphragm valves and methods of operating diaphragm valves are also disclosed.

The present disclosure provides a rotary device and a rotary system, to which a press-actuated gate valve mechanism is applied. In the rotary device and the rotary system, a pressure fluid chamber is disposed on an outside of a gate valve groove so that an action of a gate valve is controlled by means of a fluid pressure. Based on the rotary device and the rotary system, the present disclosure also provides a fluid motor, a compressor, a pump and a compressor corresponding to the rotary device and the rotary system.

A hydraulic pressure amplifier arrangement (1) is described comprising a supply port (A1), a pressure outlet (A2) connected to the supply port via check valve means (3), an intensifier section (5) having a high pressure piston (6) in a high pressure cylinder (7), a low pressure piston (8) in a low pressure cylinder (9) and connected to the high pressure piston (6), and a control valve (12) controlling a pressure in the low pressure cylinder (9), wherein the control valve (12) comprises a hydraulically actuated valve element (13). Such a pressure amplifier arrangement should have a good operational behavior in a cost effective manner. To this end the control valve (12) comprises spring means 16 acting on the valve element (1) in a direction towards a starting position of the control valve.

This system is a pneumatic actuation valve assembly that can include a frame; a timing spool housing; a timing spool carriage; a timing spool; a magnet configured to bias the timing spool in a forward position; a main spool and configured to travel toward a frame forward portion when a fluid is received into a mid-main spool pressure area wherein the main spool actuates a bolt carried by the frame and is configured to receive a projective in an open position and chamber the projective in a closed position; and, a bore defined in the timing spool configured to allow pressure in a rear main spool pressure area to escape through the bore releasing rearward pressure on the timing spool allowing the timing spool to travel from the rearward position to the forward position according to an attraction of the magnet.

This system is a pneumatic actuation valve assembly that can include a frame; a timing spool housing; a timing spool carriage; a timing spool; a magnet configured to bias the timing spool in a forward position; a main spool and configured to travel toward a frame forward portion when a fluid is received into a mid-main spool pressure area wherein the main spool actuates a bolt carried by the frame and is configured to receive a projective in an open position and chamber the projective in a closed position; and, a bore defined in the timing spool configured to allow pressure in a rear main spool pressure area to escape through the bore releasing rearward pressure on the timing spool allowing the timing spool to travel from the rearward position to the forward position according to an attraction of the magnet.

A pivoting support assembly with a selective position locking capability may include a base, a first support arm movable with respect to the base, and a first movable joint movably mounting the first support arm to the base that includes a first component and a second component. A first position locking assembly may lock a selected position of the support arm with respect to the base, and may include a drum structure of one of the first and second components of the first movable joint and a shoe structure of another one of the first and second components of the first movable joint. The shoe structure may be movable to selectively move outwardly against the drum structure to resist rotation of the drum structure with respect to the shoe structure and thereby resist movement of the first support arm with respect to the base.

A pivoting support assembly with a selective position locking capability may include a base, a first support arm movable with respect to the base, and a first movable joint movably mounting the first support arm to the base that includes a first component and a second component. A first position locking assembly may lock a selected position of the support arm with respect to the base, and may include a drum structure of one of the first and second components of the first movable joint and a shoe structure of another one of the first and second components of the first movable joint. The shoe structure may be movable to selectively move outwardly against the drum structure to resist rotation of the drum structure with respect to the shoe structure and thereby resist movement of the first support arm with respect to the base.