The present invention discloses a power system and a traveling power station, and belongs to the technical field of engineering machinery. The power system includes a first main pump, a second main pump, an auxiliary pump, a first switching unit, a first logical unit, a second logical unit, and a control system. The auxiliary pump is connected to the first switching unit. A first traveling motor is connected to the first logical unit. A second traveling motor is connected to the second logical unit. The control system is connected to the first switching unit, the first main pump, the second main pump, and the auxiliary pump. According to the present invention, the hydraulic power can be provided to transfer the drill rig, to ensure simplicity in operation and reduce risks and costs.

A flow control manifold that routes pressurized fluid from one of a first fluid manifold connection and a second fluid manifold connection of the flow control manifold to an input of a work tool and directs return fluid from an outlet of the work tool to the other of the first and second fluid manifold connections not receiving pressurized fluid.

A hydraulic energy recovery system (101) has an output drive unit (103), which can be actuated by a driver (102), and by which a hydraulic motor-pump unit (104) can be driven. In at least one energy feed position, the motor-pump unit supplies an energy storage device (106) and/or working hydraulics (107) with fluid. In a recuperation position, the motor-pump unit discharges fluid under pressure from the energy storage device (106) at least to the working hydraulics (107) and/or is used to actuate the output drive unit (103).

A valve for a hydraulic system is provided including a work port channel, a load sense channel, and a tank channel. Additionally, a body cavity extends between the work port channel and the tank channel, and a spool is movably positioned in the body cavity. The body cavity defines an inner surface and the spool defines an outer surface. The inner surface of the body cavity and the outer surface of the spool together define a interface between the body cavity and the spool that extends outwardly from a longitudinal axis, such that an increased pressure differential between the work port channel and a load sense channel increases a sealing force, allowing for a more responsive valve in the hydraulic system with less leakage.

A hydraulic drive system includes an oil supply device, an oil return device and a hydraulic cylinder circuit component. The circuit component includes a hydraulic cylinder, a first and a second two-position two-way electromagnetic directional valves. The cylinder includes a first chamber and a second chamber that has a piston rod. A first port of the first valve connects with the first chamber and a first port of the second valve connects with the second chamber. When the oil supply device connects to a second port of the first valve and a second port of the second valve connects to the oil return device, the piston rod is extended outwards. When the oil supply device connects to the second port of the second valve and the second port of the first valve connects to the oil return device, the piston rod is retracted.

The present invention discloses a power system and a traveling power station, and belongs to the technical field of engineering machinery. The power system includes a first main pump, a second main pump, an auxiliary pump, a first switching unit, a first logical unit, a second logical unit, and a control system. The auxiliary pump is connected to the first switching unit. A first traveling motor is connected to the first logical unit. A second traveling motor is connected to the second logical unit. The control system is connected to the first switching unit, the first main pump, the second main pump, and the auxiliary pump. According to the present invention, the hydraulic power can be provided to transfer the drill rig, to ensure simplicity in operation and reduce risks and costs.

A spool assembly is disclosed for use in a valve. The spool assembly may have a cylindrical body that is hollow and has a least one radially oriented orifice that passes through a wall of the cylindrical body. The spool assembly may also have an insert slidably disposed inside the cylindrical body. The insert may have a land that axially divides a space inside the cylindrical body.

A valve is for controlling flow of a pressurized fluid to a tool. The valve has a manifold, a poppet biased into an unseated position in which the pressurized fluid may flow from the manifold via a tank outlet, a piston configured to move the poppet into a seated position when the pressurized fluid flows into the manifold via the manifold inlet at a first fluid pressure, and a check valve biased into a closed position in which the pressurized fluid is prevented from flowing from the manifold via the tool outlet. A retainer retains the poppet relative to the piston and is configured so that when the poppet is in the seated position, the piston is independently movable relative to the poppet and thus permits the poppet to remain in the seated position upon variations in fluid pressure in the manifold.

A valve assembly having a supply fluid flow path which passes from a first supply point via a pressure reducing valve, further via a first control point, and further via a 2/2-way poppet valve to a discharge point. The pressure reducing valve is adjustable using a first actuating solenoid. The first control point is connected on the inlet side to a shuttle valve. A first 3/2-way switching valve is arranged in the supply fluid flow path between the pressure reducing valve and the first control point, and is configured such that the first control point is selectively connected to the pressure reducing valve or to the first return flow point. The first 3/2-way switching valve is adjustable at least indirectly using a second actuating solenoid. A second control point is arranged between the pressure reducing valve and the first 3/2-way switching valve in the supply fluid flow path.

[Object] To make it possible to detect, with a single pressure sensor, a malfunction of two solenoid valves for switching flow paths and to quickly and reliably exhaust residual pressure in an air device through a solenoid valve. [Solution] A residual pressure exhaust air circuit 1 includes: a main flow path 9 through which air from an air source 2 is supplied to an air cylinder 100; an exhaust flow path 10 through which air in the air cylinder 100 is exhausted; a first sensor 8 for detecting a malfunction of solenoid valves 12, 13; a detection flow path 11 through which air from the air source 2 is supplied to the first sensor 8; and the two solenoid valves 12, 13 that switch communication states among the main flow path 9, the exhaust flow path 10, and the detection flow path 11. The two solenoid valves 12, 13 are formed of two-position valves having first positions 12a, 13a at the time of OFF and second positions 12b, 13b at the time of ON and are synchronously ON/OFF controlled. When the two solenoid valves 12, 13 do not operate in synchronization with each other, the air from the air source 2 is supplied to the first sensor 8 to detect a malfunction of the two solenoid valves 12, 13, and at the same time, the air in the air cylinder 100 is exhausted through the solenoid valve 12, 13.