A medical fluid pneumatic manifold system includes a first plate including a plurality of apertures, a second plate attached to the first plate so as to form a plurality of pneumatic flowpaths sealed between the first plate and the second plate, a plurality of tubing connections and a plurality of pneumatic tubes connected to the plurality of tubing connections, the plurality of tubing connections placing the plurality of pneumatic tubes in pneumatic communication with the plurality of pneumatic flowpaths via the plurality of apertures of the first plate, and a pneumatic reservoir in pneumatic communication with the plurality of pneumatic flowpaths, the pneumatic reservoir configured to provide pneumatic pressure to the plurality of pneumatic tubes.

An example valve section includes: a housing having: (i) a longitudinal bore, (ii) a first and second workport passages configured to be fluidly coupled to an actuator, (iii) a first and second return passages, (iv) an open-center passage configured to be fluidly coupled to a source of fluid, and (v) a supply passage disposed between the first and second workport passages. The valve section also includes a spool movable in the longitudinal bore to shift between: (i) a neutral position that allows the open-center passage to permit fluid flow therethrough, and (ii) a shifted position that allows fluid to be diverted from the open-center passage to the supply passage, and connects the supply passage to either the first or second workport passage while connecting the other workport passage to a corresponding return passage of the first and second return passages.

A hydraulic flange for connecting a drive device to a fluid reservoir includes a first hydraulic port and a second hydraulic port, and the first hydraulic port includes a radially inwardly extending, circumferential wall forming a shoulder therein that divides the first hydraulic port into an axially outer portion having a first diameter and an axially inner portion having a second diameter. The axially outer portion is configured to receive a first annular seal element having a third diameter and the axially inner portion is configured to receive a second annular seal element having a fourth diameter.

An example valve section includes: a housing having: (i) a longitudinal bore, (ii) a first and second workport passages configured to be fluidly coupled to an actuator, (iii) a first and second return passages, (iv) an open-center passage configured to be fluidly coupled to a source of fluid, and (v) a supply passage disposed between the first and second workport passages. The valve section also includes a spool movable in the longitudinal bore to shift between: (i) a neutral position that allows the open-center passage to permit fluid flow therethrough, and (ii) a shifted position that allows fluid to be diverted from the open-center passage to the supply passage, and connects the supply passage to either the first or second workport passage while connecting the other workport passage to a corresponding return passage of the first and second return passages.

A pneumatic multi-valve device, (valve block), comprising a housing (21), which has a plurality of electromagnetic valve actuators (1), each having coil elements (2) arranged in the housing (21) in a stationary manner, a core (4) arranged in the housing (21), and armature elements (24), which can be displaced along a displacement axis (V) in the housing (21) relative to the core (4) and to a pneumatic connection (12) of the housing (21) as a response to energization of the coil elements (2), wherein the displacement axes (V) of the armature elements (24) of the valve actuators (1) are oriented parallel and the pneumatic connections (12) associated with the armature elements (24) are arranged adjacent to each other on a connection housing side (23), which is spaced apart from a housing back side (25) facing away therefrom along the displacement axes (V), wherein the cores (4) each have a venting bore (5), which is connected in an air-conducting manner to a venting collection channel (14) on the side of the cores (4) facing away from the connection housing side (23), which venting collection channel is connected in an air-conducting manner to a venting opening (28) of the housing (21), which venting opening is arranged on a housing side different from the housing back side (25), in particular on the connection housing side (23) having the pneumatic connections (12), wherein the venting collection channel (14) is formed by a plurality of venting channel elements (13), which are connected to each other in an air-conducting manner.

The present application relates to a switching valve, a switching hydraulic system, and a crane, in which the switching valve having an oil inlet and an oil outlet comprises at least two pairs of valve oil ports, a pair of cartridge valves provided between each pair of valve oil ports, and the oil inlet and the oil outlet are controlled such that the oil inlet and the oil outlet are capable of shifting between communications with the at least two pairs of valve oil ports. The switching valve switches on and off communication between the oil inlet and the oil outlet and the at least two pairs of valve oil ports by controlling opening or closing of the cartridge valves.

A unitary valve trim assembly that can be easily installed in and removed from a valve body of a process control valve. The valve trim assembly includes a valve cage and a valve seat. The valve cage has a first projection that extends in a first direction that is perpendicular to a longitudinal axis of the valve cage. The valve seat has a second projection that extends in a second direction, opposite the first direction, that is perpendicular to the longitudinal axis. The second projection is arranged to engage the first projection to removably couple the valve seat to the valve cage.

An example valve section includes: a housing having: (i) a longitudinal bore, (ii) a first and second workport passages configured to be fluidly coupled to an actuator, (iii) a first and second return passages, (iv) an open-center passage configured to be fluidly coupled to a source of fluid, and (v) a supply passage disposed between the first and second workport passages. The valve section also includes a spool movable in the longitudinal bore to shift between: (i) a neutral position that allows the open-center passage to permit fluid flow therethrough, and (ii) a shifted position that allows fluid to be diverted from the open-center passage to the supply passage, and connects the supply passage to either the first or second workport passage while connecting the other workport passage to a corresponding return passage of the first and second return passages.

A hydraulic valve body, comprising two main lines for bringing pressurized hydraulic fluid into the body's channel system and further out of the channel system. The body further comprises at least two outlet fittings for conducting hydraulic fluid from the body's channel system to actuators and two respective inlet fittings for conducting hydraulic fluid from the actuators back into the channel system.

Disclosed herein is a valve body (10) for a hydraulic control system. The valve body (10) has a plurality of valve insertion holes (33, 34) into which a plurality of valves are inserted, respectively, and a plurality of oil passages (69) each communicating with at least one of the valve insertion holes (33, 34). The valve body (10) includes: an insertion hole arrangement member (11) provided with the valve insertion holes (33, 34) of the valve body (10), which are arranged in a concentrated manner; and an oil passage arrangement member (12) placed on the insertion hole arrangement member (11), and provided with the oil passages (69) of the valve body (10), which are arranged in a concentrated manner.