A spool valve V1 includes a valve element 11 and a cylinder 12 having a bore 12a which accommodates the valve element 11 to be movable in an axial direction. In this spool valve V1, when the valve element 11 in an initial position moves in the axial direction in relation to the cylinder 12, a supply valve port Vi formed between the valve element 11 and the cylinder 12 opens, whereby a working fluid is introduced from a hydraulic pressure source into a hydraulic chamber through the supply valve port Vi. A throttle portion O1 is provided in a fluid channel formed on the hydraulic chamber side of the supply valve port Vi. The throttle portion O1 is configured such that in a throttle valid region which extends from the initial position to a position where the amount of axial movement of the valve element 11 from the initial position becomes equal to a predetermined value, the area of the opening formed between the valve element 11 and the cylinder 12 is constant, and in a throttle invalid region where the amount of axial movement of the valve element 11 exceeds the predetermined value, the area of the opening increases. Thus, it becomes possible to restrain occurrence of oil impact within the hydraulic chamber to which the working fluid is supplied through the spool valve V1.

A spool valve V1 includes a valve element 11 and a cylinder 12 having a bore 12a which accommodates the valve element 11 to be movable in an axial direction. In this spool valve V1, when the valve element 11 in an initial position moves in the axial direction in relation to the cylinder 12, a supply valve port Vi formed between the valve element 11 and the cylinder 12 opens, whereby a working fluid is introduced from a hydraulic pressure source into a hydraulic chamber through the supply valve port Vi. A throttle portion O1 is provided in a fluid channel formed on the hydraulic chamber side of the supply valve port Vi. The throttle portion O1 is configured such that in a throttle valid region which extends from the initial position to a position where the amount of axial movement of the valve element 11 from the initial position becomes equal to a predetermined value, the area of the opening formed between the valve element 11 and the cylinder 12 is constant, and in a throttle invalid region where the amount of axial movement of the valve element 11 exceeds the predetermined value, the area of the opening increases. Thus, it becomes possible to restrain occurrence of oil impact within the hydraulic chamber to which the working fluid is supplied through the spool valve V1.

Systems and methods for filter orientation on a control valve are provided. In particular, systems and methods are provided for rotationally orienting a filter retention feature with respect to an application fluid passageway to control forces and stresses exerted on the filter retention feature. Additionally, methods for manufacturing a control valve are provided that enable a rotational relationship between a filter retention feature and an application fluid passageway to be constrained.

Systems and methods for filter orientation on a control valve are provided. In particular, systems and methods are provided for rotationally orienting a filter retention feature with respect to an application fluid passageway to control forces and stresses exerted on the filter retention feature. Additionally, methods for manufacturing a control valve are provided that enable a rotational relationship between a filter retention feature and an application fluid passageway to be constrained.

A way valve (1) with a 5/2 way valve function has a valve member (13) moveable between two switching positions in a valve member accommodation space (8). The valve member (13) has a valve disk (49) arranged in an inlet section (24) of the valve member accommodation space (8) connected to a feed channel (36), the valve disk having an axially oriented annular valve member sealing surface (56) and being located opposite an annular body sealing surface (54) formed on the valve body (3). So as to close a fluid connection between the inlet section (24) and an attached outlet section (25, 26) of the valve member accommodation space (8) connected to a working channel (37, 38), the valve disk (49) is located with its valve member sealing surface (56) on the opposite body sealing surface (54). Either the body sealing surface (54) or preferably the valve member sealing surface (56) is formed on a collar-like, axially raised sealing edge (57), which has a non-circular, elongated shape, whereby the way valve (1) possesses a high power density.

A water control valve includes a valve body defining a valve body internal cavity, a first air inlet passageway in communication with the valve body internal cavity, a first water outlet passageway in communication with the valve body internal cavity, and a water inlet passageway. The water control valve further includes a valve cartridge removably coupled to the valve body. The valve cartridge is sized to fit at least partially within the valve body internal cavity. The valve cartridge defines a second air inlet passageway and a second water outlet passageway. The first air inlet passageway is aligned with the second air inlet passageway and the first water outlet passageway is aligned with the second water outlet passageway when the valve cartridge is coupled to the valve body.

A control valve includes a valve housing extending along a longitudinal axis. The valve housing defines an inlet port, a first outlet port, and a second outlet port. In addition, the control valve includes a spool guide disposed inside the valve housing and a flow guide belt disposed around the spool guide. The flow guide belt is disposed inside the valve housing. The control valve further includes a spool movably disposed in the spool guide. The spool can move relative to the valve housing along the longitudinal axis between a first spool position and a second spool position. The first outlet port is in fluid communication with the inlet port when spool is disposed in the first spool position.

A control valve for a reverse osmosis water purifying system provides a feed water port, a squeeze water port, a drain port, and a product water connection, each of which open into a bore. A first, second, and third O-rings are located in the bore successively between the feed water port, the squeeze water port, the drain port, and the product water connection. A control piston is moveably located in the bore of the housing. The control piston includes a vent/drain well in which a side is chamfered and at least one recess disposed around an end of the control piston. The vent/drain well provides a fluid passage between the squeeze water port and the drain port when the vent/drain well passes over the second O-ring. The fluid passage includes an opening formed between the second O-ring and the chamfered side of the vent/drain well, where the size of the opening is responsive to the position of the control piston.

A meter bar includes a housing comprising an inflow end and an outflow end, a key assembly arranged within housing, the key assembly including a key, the key defining an interior and providing a fluid pathway from the inflow end to the outflow end; the key defining a pair of upper portals, one upper portal proximate the inflow end and one upper portal proximate the outflow end; the key defining a pair of lower portals, one lower portal proximate the inflow end and one lower portal proximate the outflow end; the key defining a pair of bypass portals; the key assembly arrangeable within the housing to selectably direct fluid flow from the inflow end to the outflow end either through a meter or bypassing the meter.

A meter bar includes a housing comprising an inflow end and an outflow end, a key assembly arranged within housing, the key assembly including a key, the key defining an interior and providing a fluid pathway from the inflow end to the outflow end; the key defining a pair of upper portals, one upper portal proximate the inflow end and one upper portal proximate the outflow end; the key defining a pair of lower portals, one lower portal proximate the inflow end and one lower portal proximate the outflow end; the key defining a pair of bypass portals; the key assembly arrangeable within the housing to selectably direct fluid flow from the inflow end to the outflow end either through a meter or bypassing the meter.