Hydraulic unit

Abstract

A hydraulic unit is provided with: a manifold which forms a hydraulic circuit; a tank which is joined to the manifold; and a hydraulic pump which suctions hydraulic fluid in the tank and supplies the hydraulic fluid to the manifold, wherein the base end portion of a suction strainer is fitted into the hydraulic pump, and the suction strainer has such a shape that the base end portion of the suction strainer is not separated from the hydraulic pump in a state where the leading end portion of the suction strainer is in contact with the tank and an opening through which the hydraulic fluid is introduced from the tank is provided at the leading end portion.

Claims

1. A hydraulic unit comprising: a manifold which forms a hydraulic circuit; a tank which is joined to the manifold; a hydraulic pump which suctions a hydraulic fluid in the tank and supplies the hydraulic fluid to the manifold; and a suction strainer in which a base end portion of the suction strainer is fitted into the hydraulic pump; wherein the suction strainer is located within the tank and has such a longitudinal dimension that the base end portion of the suction strainer is not separated from the hydraulic pump in a state where the suction strainer is lowered to a maximum and a leading end portion of the suction strainer is in contact with an inner wall of the tank, and an opening through which the hydraulic fluid is introduced from the tank is provided at the leading end portion of the suction strainer in the state where the leading end portion is in contact with the inner wall of the tank.

2. A hydraulic unit comprising: a manifold which forms a hydraulic circuit; a tank which is joined to the manifold; and a return pipe in which a base end portion of the return pipe is fitted into the manifold; wherein the return pipe is located within the tank and has such a longitudinal dimension that the base end portion of the return pipe is not separated from the manifold in a state where the return pipe is lowered to a maximum and a leading end portion of the return pipe is in contact with an inner wall of the tank, and an opening through which a hydraulic fluid is circulated in the state where the leading end portion is in contact with the inner wall of the tank is provided at the leading end portion of the return pipe, wherein the hydraulic fluid is introduced via the opening of the leading end portion of the return pipe into the tank.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic view showing a hydraulic circuit which uses a hydraulic unit of one embodiment of the disclosure.

(2) FIG. 2 is a front view showing a hydraulic unit, partly in cross-section, of the same embodiment.

(3) FIG. 3 is a front view showing a base end portion of a suction strainer of the same embodiment.

(4) FIG. 4 is a side view showing the hydraulic unit, partly in cross-section, of the same embodiment.

(5) FIG. 5 is a longitudinal sectional view showing an enlarged major portion of a return pipe of the same embodiment.

DESCRIPTION OF THE EMBODIMENTS

(6) One embodiment of the disclosure is described below with reference to FIG. 1 through FIG. 5.

(7) A hydraulic unit 1 of the embodiment supplies a hydraulic fluid to a cylinder C which constitutes an actuator for lifting and lowering a loading platform of a logistics machine, such as a fork lift, which is a driven object, and as shown in FIG. 1, FIG. 2 and FIG. 4, includes: a manifold 2 which forms a hydraulic circuit; a tank 3 which is joined to the manifold 2; a hydraulic pump 4 which suctions the hydraulic fluid in the tank 3 and supplies the hydraulic fluid to the manifold 2; a suction strainer 5 in which the base end portion 5a is fitted into the hydraulic pump 4; and a return pipe 6 in which the base end portion 6a is fitted into the manifold 2.

(8) The manifold 2 includes, as shown in FIG. 1, a hydraulic fluid inflow port 2a which receives a supply of the hydraulic fluid from the hydraulic pump 4; a hydraulic fluid supply port 2b which allows the hydraulic fluid in or out between the manifold 2 and the cylinder C; and a hydraulic fluid discharge port 2c which introduces the hydraulic fluid discharged from the cylinder C to the tank 3 via the return pipe 6. Besides, the manifold 2 includes the following built-in parts, that is, a hydraulic fluid supply path 2d, a check valve 21, a hydraulic fluid discharge path 2e, a solenoid valve 22, a flow control valve 23, a relief passage 2f, and a relief valve 24. The hydraulic fluid supply path 2d is a passage which links the hydraulic fluid inflow port 2a and the hydraulic fluid supply port 2b. The check valve 21 is arranged in the hydraulic fluid supply path 2d, and suppresses a backflow of the hydraulic fluid from the cylinder C side, that is, the hydraulic fluid supply port 2b side to the hydraulic pump 4 side, that is, the hydraulic fluid inflow port 2a side. The hydraulic fluid discharge path 2e diverges from the hydraulic fluid supply port 2b side of the check valve 21 in the hydraulic fluid supply path 2d, and communicates with the hydraulic fluid discharge port 2c. The solenoid valve 22 is arranged in the hydraulic fluid discharge path 2e, and selectively takes any one of a first state of obstructing a flow of the hydraulic fluid from the hydraulic fluid supply port 2b side to the hydraulic fluid discharge port 2c side, and a second state of allowing the flow of the hydraulic fluid from the hydraulic fluid supply port 2b side to the hydraulic fluid discharge port 2c side. The flow control valve 23 is arranged between the solenoid valve 22 and the hydraulic fluid discharge port 2c. The relief passage 2f diverges from the hydraulic fluid inflow port 2a side of the check valve 21 in the hydraulic fluid supply path 2d, and short-circuits a part on the hydraulic fluid discharge port 2c side of the flow control valve 23 in the hydraulic fluid supply path 2d and the hydraulic fluid discharge path 2e. The relief valve 24 is arranged in the relief passage 2f, opens when the hydraulic pressure of a part on the hydraulic pump 4 side of the check valve 21 in the hydraulic fluid supply path 2d exceeds a predetermined hydraulic pressure, and closes in other cases. Furthermore, a filter 25 is arranged on the upstream side of the solenoid valve 22 in the hydraulic fluid discharge path 2e.

(9) As shown in FIG. 2 and FIG. 4, the tank 3 is mounted downward the manifold 2 and stores the hydraulic fluid inside.

(10) As shown in FIG. 2 and FIG. 4, the hydraulic pump 4 is mounted under the manifold 2, suctions the hydraulic fluid inside the tank 3 via the suction strainer 5, and discharges the hydraulic fluid toward the hydraulic fluid inflow port 2a of the manifold 2. Besides, the hydraulic pump 4 receives a power supply from a motor 7. The motor 7 is mounted above the manifold 2, and an output shaft of the motor 7 is connected to the hydraulic pump 4. The motor 7 operates when a relay switch 8 is energized.

(11) In regard to the suction strainer 5, as described above, and as shown in FIG. 2, the base end portion 5a is fitted into the hydraulic pump 4, and the leading end portion 5b is close to or in contact with a bottom wall 3a of the tank 3. More specifically, as shown in FIG. 2 and FIG. 3, the base end portion 5a of the suction strainer 5 has a larger outer diameter than that of the adjacent part, and includes an O-ring insertion groove 5x capable into which an O-ring 91 which is a seal member can be inserted. In regard to the O-ring 91, the inner side part is arranged in the O-ring insertion groove 5x, and the outer side elastically adheres to the outer wall of a hydraulic fluid suction port 4a of the hydraulic pump 4. On the other hand, the leading end portion 5b is provided, at a plurality of locations, with projections 51 which contact with the bottom wall 3a of the tank 3 prior to other parts, and the part between the projections 51 is set as an opening 5c through which the hydraulic fluid is introduced from the inside of the tank 3.

(12) In regard to the return pipe 6, as described above, and as shown in FIG. 4, the base end portion 6a is fitted into the manifold 2, and on the other hand the leading end portion 6b is close to or in contact with the bottom wall of the tank 3. More specifically, as shown in FIG. 4 and FIG. 5, the base end portion 6a of the return pipe 6 has a larger outer diameter than that of the adjacent part, and includes an O-ring insertion groove 6x into which an O-ring 92 which is a seal member can be inserted. In regard to the O-ring 92, an inner side part is arranged in the O-ring insertion groove 6x, and the outer side elastically adheres to the hydraulic fluid discharge port 2c of the manifold 2. On the other hand, the leading end portion 6b is cut in an inclined direction with respect to an extending direction of the return pipe 6, and an opening 6c obliquely facing downward is formed. The hydraulic fluid is introduced into the tank 3 through the opening 6c. Besides, the leading end 6b1 of the return pipe 6 contacts with the bottom wall of the tank 3 prior to other parts.

(13) Here, the suction strainer 5 is arranged so that the leading end 5b1 is separated from the bottom wall 3a of the tank 3 at first. Then, when the suction strainer 5 moves downward with the passage of time, the projection 51 contacts with the bottom wall 3a of the tank 3 prior to other parts, and the hydraulic fluid can be introduced from the tank 3 to the hydraulic pump 4 via the opening 5c. On the other hand, the longitudinal dimension of the suction strainer 5 is set so that the base end portion 5a does not fall off out of the hydraulic pump 4 even in a state where the projection 51 arranged in the leading end portion 5b is in contact with the bottom wall 3a of the tank 3.

(14) Besides, the return pipe 6 is arranged so that the leading end 6b1 is separated from the bottom wall 3a of the tank 3 at first. Then, when the return pipe 6 moves downward with the passage of time, the leading end 6b1 of the return pipe 6 contacts with the bottom wall 3a of the tank 3, the opening 6c of the leading end portion 6b of the return pipe 6 keeps open obliquely downward, and the hydraulic fluid can be discharged into the tank 3 via the opening 6c. On the other hand, the longitudinal dimension of the return pipe 6 is set so that the base end portion 6a does not fall off out of the manifold 2 even in a state where the leading end 6b1 is in contact with the bottom wall 3a of the tank 3.

(15) That is, according to the mounting structure of the suction strainer 5 of the embodiment, the base end portion 5a of the suction strainer 5 is fitted into the hydraulic pump 4, so that it is unnecessary to perform a processing for arranging a screw thread on the suction strainer 5 and the hydraulic pump 4, and thus man-hours needed for processing or man-hours needed for assembly can be reduced. Besides, because it is unnecessary to perform the processing for arranging a screw thread on the suction strainer 5 and the hydraulic pump 4, the occurrence of a defect that chips generated in the processing for arranging a screw thread are mixed into the hydraulic fluid can be prevented. Moreover, the longitudinal dimension of the suction strainer 5 is set so that the base end portion 5a does not fall off out of the hydraulic pump 4 even in a state where the projection 51 arranged in the leading end portion 5b is in contact with the bottom wall 3a of the tank 3, so that the suction strainer 5 can be stably mounted to the hydraulic pump 4 by the simple constitution and few man-hours is needed for processing or few man-hours is needed for assembly. Then, the opening 5c is arranged in the leading end portion 5b of the suction strainer 5, so that the flow path of the hydraulic fluid can be ensured even in a state where the leading end 5b1 of the suction strainer 5 is in contact with the bottom wall 3a of the tank 3.

(16) Besides, according to the mounting structure of the return pipe 6 of the embodiment, the base end portion 6a of the return pipe 6 is fitted into the manifold 2, so that it is unnecessary to perform a processing for arranging a screw thread on the return pipe 6 and the manifold 2, and thus man-hours needed for processing or man-hours needed for assembly can be reduced. Besides, because it is unnecessary to perform the processing for arranging a screw thread on the return pipe 6 and the manifold 2, so that the occurrence of a defect that chips generated in the processing for arranging a screw thread are mixed into the hydraulic fluid can be prevented. Moreover, the longitudinal dimension of the return pipe 6 is set so that the base end portion 6a does not fall off out of the manifold 2 even in a state where the leading end 6b1 is in contact with the bottom wall 3a of the tank 3, so that the return pipe 6 can be stably mounted to the manifold 2 by the simple constitution and few man-hours is needed for processing or few man-hours is needed for assembly. Then, the opening 6c is arranged in the leading end portion 6b of the return pipe 6, so that the flow path of the hydraulic fluid can be ensured even in a state where the leading end 6b1 of the return pipe 6 is in contact with the bottom wall 3a of the tank 3.

(17) Furthermore, the disclosure is not limited to the above embodiment.

(18) For example, the shape of the leading end of the suction strainer may be optionally set, as long as the entire leading end surface of the suction strainer is not in contact with the tank at the same time, that is, as long as an opening for circulating the hydraulic fluid is ensured even in a state where the suction strainer is lowered to the maximum. That is, the number and location of the projection which is arranged in the leading end of the suction strainer may be optionally set; besides, instead of arranging a projection in the leading end of the suction strainer, other constitutions may be adopted, for example, a constitution in which a notch is arranged in the leading end portion of the suction strainer, and the notch is set as an opening through which the hydraulic fluid is introduced from inside the tank.

(19) On the other hand, the shape of the leading end of the return pipe may also be optionally set, as long as the entire leading end surface of the return pipe is not in contact with the tank at the same time, that is, as long as an opening for circulating the hydraulic fluid is ensured even in a state where the return pipe is lowered to the maximum.

(20) Furthermore, the constitution of the disclosure may be adopted to only one of the suction strainer and the return pipe, and the constitution of the disclosure is a constitution which has such a shape that the base end portion is fitted into the hydraulic pump or the manifold, and the base end portion is not separated from the hydraulic pump or the manifold in a state where the leading end portion is in contact with the tank, and which has an opening through which the hydraulic fluid is introduced from inside the tank at the leading end portion.

(21) In addition, various alterations may be made in a scope that does not impair the gist of the disclosure.

DESCRIPTION OF THE SYMBOLS

(22) 1 Hydraulic unit 2 Manifold 3 Tank 4 Hydraulic pump 5 Suction strainer 5a Base end portion 5b Leading end portion 6 Return pipe 6a Base end portion 6b Leading end portion