An embodiment of the present disclosure relates to an industrial rechargeable wireless solenoid valve system, and a technical problem to be solved is to provide an industrial rechargeable wireless solenoid valve system which is controlled by a wireless control signal and receives power supplied from a rechargeable battery. To this end, the present disclosure provides an industrial rechargeable wireless solenoid valve system comprising: a wireless communication unit for receiving a command from a factory control unit; a solenoid valve control unit which receives input of the command from the wireless communication unit to output an operation signal corresponding to the command; an output unit which receives input of the operation signal from the solenoid valve control unit to drive a solenoid valve; and a power supply unit for supplying power to the wireless communication unit, the solenoid valve control unit, and the output unit, respectively.

An electro-hydraulic circuit includes a supply line that connects between a hydraulic supply device that supplies hydraulic fluid and a driving part to be driven by a hydraulic pressure of the hydraulic fluid; a switching valve disposed in the supply line to switch between switching lines for the hydraulic fluid supplied to the driving part; a pilot hydraulic line connected to the switching valve to supply the hydraulic fluid for switching between the switching lines; a check valve disposed in the pilot hydraulic line; a solenoid valve disposed in the pilot hydraulic line to change a supply state of the hydraulic fluid to the switching valve; a sealing material disposed in the switching valve to seal the hydraulic fluid; and a relief valve disposed in the pilot hydraulic line to release the pilot hydraulic pressure

A switching valve includes a sleeve on which a plurality of ports are disposed; a spool that is disposed inside the sleeve to move in an axial direction by a pilot hydraulic pressure to switch between switching lines each serving as a flow channel for hydraulic fluid that is formed by a combination of the ports; a first energizing unit that energizes the spool against the pilot hydraulic pressure; a relief hole that is disposed on the spool to discharge the hydraulic fluid with the pilot hydraulic pressure; a valve body that closes the relief hole; and a second energizing unit that energizes the valve body toward the relief hole of the spool against the pilot hydraulic pressure, and when the pilot hydraulic pressure exceeds a predetermined value, opens the relief hole.

A method of controlling an actuator includes switching a primary solenoid valve to a first mode to fluidically connect a supply pressure source to a control chamber of a pilot valve. A fluid from the supply pressure source is directed through the primary solenoid valve to fill the control chamber of the pilot valve and put the pilot valve in a first position. The first position fluidically connects a second chamber of the actuator to a return pressure source. The actuator includes a cylinder between the first chamber and the second chamber and a rod attached to the cylinder. The fluid from the supply pressure source is directed into the first chamber of the actuator to move the cylinder and the rod in a first direction while the pilot valve is in the first position.

A four-position switching valve includes first and second pistons for driving a spool in a valve body, and a spool moving mechanism part that moves the spool to first and second intermediate switching positions between one-end side and the other-end-side switching positions. The spool moving mechanism part includes a compression spring that moves the spool back in the opposite direction by moving to the switching position on one end side and the other end side of the spool. The compression spring moves the spool to the first intermediate switching position when the spool moves to one-end-side switching position and the pressure on the second piston is released, and moves the spool to the second intermediate switching position when the spool moves to the other-end-side switching position and the pressure on the first piston is released.

A four-position switching valve includes first and second pistons for driving a spool in a valve body, and a spool moving mechanism part that moves the spool to first and second intermediate switching positions between one-end side and the other-end-side switching positions. The spool moving mechanism part includes a compression spring that moves the spool back in the opposite direction by moving to the switching position on one end side and the other end side of the spool. The compression spring moves the spool to the first intermediate switching position when the spool moves to one-end-side switching position and the pressure on the second piston is released, and moves the spool to the second intermediate switching position when the spool moves to the other-end-side switching position and the pressure on the first piston is released.

When viewed in section, a cylinder hole in a fluid pressure cylinder has a polygonal shape including inner circumferential surfaces parallel to a plurality of surfaces constituting a body. A piston has a polygonal outer edge having a shape corresponding to the shape of the cylinder hole and partitions the cylinder hole into a head-side cylinder chamber and a rod-side cylinder chamber. The body is cut off so that a first side surface has a stepped shape, and a solenoid valve is disposed in a solenoid valve arrangement space formed by cutting off the body. The solenoid valve is disposed inside a virtual outer shape defined by most-protruding faces in the respective surfaces.

An energy saving directional-control valves (2-position and 3-position) are configured with standard manual override functionality and with the same steady-state input-output behavior as each respective standard/non-energy saving directional-control valve. This allows a standard non-energy saving valve to be replaced with an energy saving valve without reconfiguring the external electrical and manual override command logic.

A valve arrangement for a fluidic supply of a fluid load, with several main valves designed for influencing fluid flows at the fluid ports, and with electrically controllable pilot valves designed for fluidic control of the main valves. A base body is assigned a connection plate lying opposite a connection face and having a fluid passage which leads into an operating port for the connection of a fluid load wherein, between the connection face and the connection plate there is provided a separate passage body which has at least one connection passage for a fluidically communicating link between at least one of the fluid ports and the operating port, and at least one connecting conduit for a fluidic coupling of at least two fluid ports.

In a fluid pressure cylinder having a body having a pair of cylinder holes, a pair of pistons movably accommodated respectively in the pair of cylinder holes, a pair of piston rods secured respectively to the pair of pistons, and an end plate connected to end portions of the pair of piston rods, each of the pistons partitions the corresponding cylinder hole into a head-side cylinder chamber and a rod-side cylinder chamber. The body includes a solenoid valve configured to switch between supply of pressurized fluid to the head-side cylinder chambers or the rod-side cylinder chambers and discharge of the pressurized fluid from the head-side cylinder chambers or the rod-side cylinder chambers, and the solenoid valve is disposed inside a surface of the body.