This connection device (D) comprises a shaft (17) which is mobile in translation, a piston (19) integral with the shaft (17), a sleeve (35) which extends around the shaft (17), this sleeve being movable between a rear position and a forward position, and locking members housed in the sleeve (35), each locking member being movable relative to the sleeve between a locking configuration and a release configuration. The shaft (17) is movable between a disconnected position in which the shaft (17) does not oppose movement of the locking members to their release configuration, and the sleeve (35) is in the forward position, and a connected position in which the shaft (17) opposes movement of the locking members into their release configuration and the sleeve (35) is in the rear position, through an intermediate position, in which the shaft (17) opposes movement of the locking members into their release configuration and the sleeve (35) is in the forward position.

A hydraulic system has a fluid path which connects two system components fluidically to one another and which comprises a hydraulic hose. It is known to form a fluid path between two components of a hydraulic system, for example between a pump and a control block, by a single hydraulic hose which is designed in accordance with the maximum volume flow and the maximum pressure. A hydraulic hose for large volume flows and high pressures is disproportionately expensive relative to a hydraulic hose for smaller volume flows and, on account of its larger internal and external diameters, has a larger minimum bending radius than a hydraulic hose for smaller volume flows. In order to provide a cost-effective and compact structure, a hydraulic system according to the disclosure has the fluid path formed by at least two hydraulic hoses arranged fluidically parallel to one another.

A hydraulic system has a fluid path which connects two system components fluidically to one another and which comprises a hydraulic hose. It is known to form a fluid path between two components of a hydraulic system, for example between a pump and a control block, by a single hydraulic hose which is designed in accordance with the maximum volume flow and the maximum pressure. A hydraulic hose for large volume flows and high pressures is disproportionately expensive relative to a hydraulic hose for smaller volume flows and, on account of its larger internal and external diameters, has a larger minimum bending radius than a hydraulic hose for smaller volume flows. In order to provide a cost-effective and compact structure, a hydraulic system according to the disclosure has the fluid path formed by at least two hydraulic hoses arranged fluidically parallel to one another.

The invention relates to a coupling device for simultaneously coupling and decoupling a number of coupling pairs, which coupling device includes:—a number of coupling pairs, each having a first coupling part and a second coupling part;—a first mounting frame on which the first coupling parts of the number of coupling pairs are arranged;—a second mounting frame arranged parallel to the first mounting frame, wherein the second coupling parts of the number of coupling pairs are arranged to the second mounting frame, and wherein the second mounting frame is movable towards to and away from the first mounting frame between a connected position, in which each first coupling part is connected with the corresponding second coupling part, and a disconnected position;—guiding mechanism arranged to the first mounting frame and the second mounting frame for guiding the movement between the connected and disconnected position;—at least one rack and pinion drive arranged between the first and second mounting frame, wherein the pinion is arranged on a shaft rotatable arranged in the first mounting frame and wherein the rack extends from the second mounting frame in the direction of movement of said second mounting frame into the first mounting frame along the pinion; wherein the shaft extends with at least one end out of the first mounting frame and wherein an operating lever is arranged on the shaft.

The invention relates to a coupling device for simultaneously coupling and decoupling a number of coupling pairs, which coupling device includes:—a number of coupling pairs, each having a first coupling part and a second coupling part;—a first mounting frame on which the first coupling parts of the number of coupling pairs are arranged;—a second mounting frame arranged parallel to the first mounting frame, wherein the second coupling parts of the number of coupling pairs are arranged to the second mounting frame, and wherein the second mounting frame is movable towards to and away from the first mounting frame between a connected position, in which each first coupling part is connected with the corresponding second coupling part, and a disconnected position;—guiding mechanism arranged to the first mounting frame and the second mounting frame for guiding the movement between the connected and disconnected position;—at least one rack and pinion drive arranged between the first and second mounting frame, wherein the pinion is arranged on a shaft rotatable arranged in the first mounting frame and wherein the rack extends from the second mounting frame in the direction of movement of said second mounting frame into the first mounting frame along the pinion; wherein the shaft extends with at least one end out of the first mounting frame and wherein an operating lever is arranged on the shaft.

A multi-coupler of a work vehicle includes a first portion and a cover. The first portion has a coupling surface. The first hydraulic connector is arranged on the coupling surface. The cover is movable between a first position in which the cover covers the coupling surface and a second position in which the coupling surface is uncovered by cover. The cover has a cover shell defining an interior cavity. The cover also includes an insert received into the interior cavity of the cover shell. The insert is operable to absorb a fluid that escapes from the first hydraulic connector.

This multi-couplings plate (P1) includes a locking device comprising a frame (14) fixed on the plate (P1), locking members and a drive mechanism, comprising a rotary element (18) rotatable in the frame (14), a sliding element translatable relative to the frame (14) and which cooperates with the locking members. The locking device also comprises several ratchet notches (301-309) secured to an element (18) of the drive mechanism (16) and juxtaposed in the movement direction relative to the frame (14) of the element (18) of the drive mechanism, the ratchet notches (301-309) comprising a final notch (309) and at least one intermediate notch (303-308), and a pawl movable in a housing (326) of the frame (14) and pushed back by a spring (28) toward one of the ratchet notches (301-309). When the pawl cooperates with the intermediate notch (303-308), the pawl limits the movement of the sliding element toward its forward position to a position midway between the forward position and the withdrawn position, and in the coupled configuration, the pawl cooperates with the final notch (309) and keeps the sliding element in the withdrawn position.

This multi-couplings plate (P1) includes a locking device comprising a frame (14) fixed on the plate (P1), locking members and a drive mechanism, comprising a rotary element (18) rotatable in the frame (14), a sliding element translatable relative to the frame (14) and which cooperates with the locking members. The locking device also comprises several ratchet notches (301-309) secured to an element (18) of the drive mechanism (16) and juxtaposed in the movement direction relative to the frame (14) of the element (18) of the drive mechanism, the ratchet notches (301-309) comprising a final notch (309) and at least one intermediate notch (303-308), and a pawl movable in a housing (326) of the frame (14) and pushed back by a spring (28) toward one of the ratchet notches (301-309). When the pawl cooperates with the intermediate notch (303-308), the pawl limits the movement of the sliding element toward its forward position to a position midway between the forward position and the withdrawn position, and in the coupled configuration, the pawl cooperates with the final notch (309) and keeps the sliding element in the withdrawn position.

A quick release coupling includes male and female connector assemblies releasably secured together. The male connector assembly includes two parallel male connectors and the female connector assembly includes two parallel female connectors. A sleeve assembly is releasably connected to one ends of the female connectors. A plunger assembly is provided in each of the sleeve assembly and female connector. A sleeving assembly is provided on each of the female connector and the sleeve assembly. The parallel female connectors can be disconnected from the parallel male connectors or connected together at the same time. After the female connectors have disengaged from the male connectors, leakproof arrangements in the female connector assembly act to prevent water in the female connector assembly from leaking.

A quick connector includes a socket having a socket opening and a plug inserted and coupled to the socket opening. The socket includes a socket body having a socket space into which the plug is inserted and a latch that hampers insertion of the plug into the socket space or stops the plug from escaping to the outside. The plug includes an insert body, an insert O-ring that surrounds the insert body, and an insert hook protruding outward from the insert body. The latch includes a latch frame, a latch opening formed in the latch frame, and a latch step that hides part of the latch opening, the latch step being disposed on the latch frame such that when the insert body is inserted into the socket space, the insert O-ring does not make contact with the latch step, but the insert hook makes contact with the latch step.