JP2004067322A - Fluid pressure jack - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a small sized lightweight fluid pressure jack which is excellent in convenience and operability. <P>SOLUTION: The jack is equipped with a cylinder body 20, a piston body 30, a pump 40, and a switching valve 50. The cylinder body 20 has a cylinder chamber 23, and the piston body 30 has a piston part 31 which partitions the cylinder chamber 23 into a first pressure chamber 21 and a second pressure chamber 22. The pump 40 has a supply port 41 and a delivery port 42, and delivers the fluid into the first pressure chamber 21 and the second pressure chamber 22. The switching valve 50 which is manually operated through a single operation part 95, switches the communication state between the respective flow paths of a supply flow path K connected to the delivery port 41, a drain flow path H connected to the supply port 42, a first flow path R1 connected to the first pressure chamber 21, and a second flow path R2 connected to the second pressure chamber 22. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to hydraulic jacks and, more particularly, to improvements in hydraulic jacks having a manually driven pump.
[0002]
[Prior art]
2. Description of the Related Art Various types of fluid pressure jacks that use fluid pressure such as hydraulic pressure and water pressure used in manufacturing and repairing various articles have been proposed. Here, at the work site, there are cases where it is difficult to secure a power source for driving the hydraulic jack, and there are cases where the hydraulic jack is moved and used, and it is driven manually, and it is small, lightweight and portable. A fluid pressure jack that is easy to operate is desired.
[0003]
Therefore, the present inventors have newly devised a fluid pressure jack as shown in FIGS. 5 and 6 (Japanese Patent Application No. 2002-136525). The fluid pressure jack 100 includes a cylinder body 20 having a cylinder chamber 23 and a piston body 30 having a piston portion 31. A fluid such as oil is sent to the cylinder chamber 23 by a built-in manual pump 40. The piston portion 31 in the cylinder chamber 23 is slid by pressure to move the piston body 30 forward and backward with respect to the cylinder body 20. Here, the cylinder chamber 23 is divided into a first pressure chamber 21 and a second pressure chamber 22 by a piston portion 31, and when a fluid is sent to the first pressure chamber 21, the piston body is moved relative to the cylinder body 20. When the fluid advances to the second pressure chamber 22, the piston body 30 moves backward with respect to the cylinder body 20. Therefore, this hydraulic jack 100 is not only excellent in usability driven manually, but also has a push-side operation in which the piston body 30 moves forward with respect to the cylinder body 20 and a piston with respect to the cylinder body 20. It is excellent in convenience that the operation in both the push-pull direction and the pull-side operation in which the body 30 moves backward can be obtained. The pump 40, which is manually driven, and the switching valves 151, 152 for switching the operation of pushing and pulling are compactly housed in the cylinder body 20, so that the pump is small, lightweight and easy to carry. The switching valves 151 and 152 are provided between the first pressure chamber 21, the second pressure chamber 22, the outlet 41 of the pump 40 for sending out the fluid, and the supply port 42 of the pump 40 for supplying the fluid. The communication state of the road is switched, and a specific configuration is as follows.
[0004]
The switching valve 151 connects the flow path communicating with the first flow path R1 connected to the first pressure chamber 21 to the supply flow path K connected to the outlet 41 of the pump 40 or the supply port 42 of the pump 40. The switching valve 152 switches the flow path communicating with the second flow path R2 connected to the second pressure chamber 22 to the discharge port 41 of the pump 40. The flow is switched to either the connected supply channel K or the discharge channel H connected to the supply port 42 of the pump 40. Then, each of the switching valves 151 and 152 is individually operated so that the first flow path R1 communicates with the supply flow path K and the second flow path R2 communicates with the discharge path H as shown in FIG. When the pump 40 is driven in this state, the fluid is sent from the pump 40 to the first pressure chamber 21, while the fluid is returned from the second pressure chamber 22 to the pump 40. Thereby, the piston body 30 advances with respect to the cylinder body 20, and the hydraulic jack 100 operates in the pushing direction. Conversely, as shown in FIG. 6, when the pump 40 is driven in a state where the second flow path R2 and the supply flow path K are in communication and the first flow path R1 and the discharge flow path H are in communication, the pump While fluid is sent from 40 to the second pressure chamber 22, fluid is returned from the first pressure chamber 21 to the pump 40. As a result, the piston body 30 retreats with respect to the cylinder body 20, and the fluid pressure jack 100 operates in the pulling direction.
[0005]
[Problems to be solved by the invention]
Although the above-mentioned fluid pressure jack is small and lightweight and excellent in convenience, there is room for further improvement in the following points.
[0006]
In the above-described fluid pressure jack 100, the two switching valves 151 and 152 must be individually operated to switch the communication state of the flow path, whereby the operating direction must be switched to the pushing direction or the pulling direction. Thus, the operation may be complicated, and there is room for improving the operability in this regard.
[0007]
The present invention has been made in view of the above situation, and has as its object to provide a fluid pressure jack which is not only compact and lightweight and has excellent convenience but also has excellent operability.
[0008]
[Means for Solving the Problems]
The fluid pressure jack according to the first aspect of the present invention provides a cylinder body having a cylinder chamber, a piston body having a piston section dividing the cylinder chamber into a first pressure chamber and a second pressure chamber, and a fluid supply. A pump having a mouth and a delivery port, which is built into the cylinder body or the piston body and is manually driven to deliver fluid to the first pressure chamber and the second pressure chamber, and a single operation unit A supply flow path connected to the supply port, a discharge flow path connected to the supply port, a first flow path connected to the first pressure chamber, and the second pressure chamber A communication state between the respective flow paths of the second flow path connected to the supply flow path and the first flow path, and a communication state between the second flow path and the discharge flow path, or The supply flow path and the second flow path communicate with each other, and the first flow path A discharge passage is characterized in that and a switching valve for switching a state, communicating.
[0009]
In the present invention, the communication state between the supply flow path, the discharge flow path, the first flow path, and the second flow path is set such that the supply flow path communicates with the first flow path, and the second flow path and the discharge flow form. A switching valve is provided for switching between a state in which the flow paths communicate with each other, or a state in which the supply flow path and the second flow path communicate with each other, and the first flow path and the discharge flow path communicate with each other. The valve is operated via a single control. Therefore, the operating direction of the fluid pressure jack can be switched between the pushing direction and the pulling direction by operating the single operation unit, and the operability is improved.
[0010]
A hydraulic jack according to a second aspect of the present invention is the hydraulic jack according to the first aspect of the present invention, wherein the switching valve connects the supply region to which the supply flow path is connected and the discharge flow path. Main chamber having a connected discharge area, a first chamber connected to the first flow path, a second chamber connected to the second flow path, a supply area of the main chamber, and the first chamber. And a second valve port provided between the supply area of the main chamber and the second chamber and opposed to the first valve port; and the first valve A first valve portion that opens and closes a port, and a second valve portion that opens and closes the second valve port, wherein the first valve portion is movably provided in a direction opposite to the first valve port and the second valve port; A main valve body that is urged in a direction to close one valve port and partitions the main chamber into the supply area and the discharge area; and a main valve body provided inside the main valve body. A first chamber side valve port opening to the first chamber side and a second chamber side valve port opening to the second chamber side, and the first chamber, the second chamber and the discharge area are formed. A direction for closing the first chamber side valve port and closing the second valve port by moving forward and backward by the operation path provided in the first chamber and operated by the operation unit, and connecting the communication path between them; A first valve body that moves the main valve body, and is urged by the first valve body that is provided in the second chamber and is urged in a direction to close the second chamber side valve port and moves forward. A second valve body that opens the second chamber side valve port.
[0011]
Through a single operation unit, a plurality of flow paths, specifically, four flow paths of a supply flow path, a discharge flow path, a first flow path, and a second flow path, and a communication state between the flow paths. In a state where the supply flow path and the first flow path communicate with each other and the second flow path and the discharge flow path communicate with each other, or the supply flow path and the second flow path communicate with each other, and the first flow path and the discharge flow As the switching valve for switching to a state in which it communicates with the flow path, for example, a switching valve having various structures such as a valve employing a spool type valve mechanism can be applied. However, in the case of adopting the spool type valve mechanism, since the valve body and the valve seat are in sliding contact with each other, when the fluid is at a high pressure, leakage tends to occur. It is not suitable as a switching valve for switching between.
[0012]
On the other hand, in the present invention, a plurality of valve mechanisms constituting one switching valve, specifically, a first valve portion that opens and closes a first valve port, a second valve portion that opens and closes a second valve port, All of a plurality of valve mechanisms, such as a first valve body that opens and closes the first chamber side valve port and a second valve body that opens and closes the second chamber side valve port, advance and retreat with respect to the valve port to open and close the valve port. This is a so-called “lift type” valve mechanism. Therefore, even if the fluid is at a high pressure, leakage hardly occurs, the operation is reliable, and the fluid can be satisfactorily applied as a fluid pressure jack that obtains a high output by the high-pressure fluid.
[0013]
According to a third aspect of the present invention, in the hydraulic jack according to the second aspect, the first valve body is attached to the operating portion so as to be freely movable in the reciprocating direction. It is a feature.
[0014]
The first valve body is moved forward and backward by the operation unit to open and close the first chamber side valve port. However, when closing the first chamber side valve port, the first valve body is operated by operating the operation unit. The valve must be advanced sufficiently to firmly close the first chamber side valve port. Therefore, when the first valve body is advanced to close the first chamber-side valve port, a large operation force is required, which may impair operability.
[0015]
On the other hand, in the present invention, since the first valve body is movably attached to the operating portion in the reciprocating direction, the first valve body is sufficiently advanced by the operating portion to open the first chamber side valve port. Even when not firmly closed, when the first valve body closes the first chamber side valve port to operate the fluid pressure jack, that is, the supply flow path and the first flow path are communicated. When operating the fluid pressure jack, the first valve body is pressed against the first chamber side valve port by the fluid pressure applied to the first chamber. Therefore, it is possible to reliably close the first chamber side valve port with the first valve body without requiring a large operation force.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
An example of an embodiment of a fluid pressure jack according to the present invention will be described in detail with reference to the drawings.
[0017]
As shown in FIG. 1, the fluid pressure jack 10 has a cylinder body 20 having an attachment 25 attached to one member A on which a push / pull operation is performed, and a push / pull operation similarly performed on the other side. And a piston body 30 attached to the cylinder body 20 so as to advance and retreat.
[0018]
Here, in the fluid pressure jack 10, the pump 40 driven by the operation unit 44 such as a lever is built in the cylinder body 20, and the pump 40 is manually driven by operating the operation unit 44. .
[0019]
Next, the detailed structure of the hydraulic jack 10 will be described. As shown in FIG. 2, a cylinder chamber 23 is recessed on the outer peripheral surface of the upper part of the cylinder body 20, and the piston body 30 is movable on the upper part of the cylinder body 20 so as to cover the cylinder chamber 23. Fitted outside. Here, the piston body 30 includes a piston portion 31 extending from the inner peripheral surface to the cylinder chamber 23, and the cylinder portion 23 is partitioned into the first pressure chamber 21 and the second pressure chamber 22 by the piston portion 31. Have been. The first pressure chamber 21 and the second pressure chamber 22 are formed to have substantially the same cross-sectional area, respectively, through the shaft portion 24 of the cylinder body 20.
[0020]
The cylinder body 20 has a fluid supply port 42 and a delivery port 41, a pump 40 for delivering the fluid supplied from the supply port 42 from the delivery port 41, and a supply flow connected to the delivery port 41 of the pump 40. A passage K, a discharge passage H connected to the supply port 42 of the pump 40, a first passage R1 connected to the first pressure chamber 21, and a second passage R2 connected to the second pressure chamber 22. And a switching valve 50 for switching the communication state of the supply flow path K, the discharge flow path H, the first flow path R1, and the second flow path R2. Here, the switching valve 50 is in a state where the supply flow path K and the first flow path R1 are communicated and the second flow path R2 is communicated with the discharge flow path H (solid line in the drawing), or the switching flow path K And the second flow path R2 and the first flow path R1 and the discharge flow path H are communicated (broken line in the drawing).
[0021]
The switching valve 50 includes a single operation unit including an operation shaft (not shown) projecting from the cylinder body 20 and a handle (not shown) attached to the operation shaft. It is operated by manually rotating the operation unit. In addition, a round handle is employed as a handle of the operation unit, which facilitates a rotating operation. The handle may be formed of a looped steel wire, a flat plate, or the like so as to be wider than the operation shaft, and may be foldable with respect to the operation shaft. When such a handle is employed, the handle can be folded and stored compactly when not operated.
[0022]
The supply flow path K is provided with a check valve 70 whose forward direction is toward the switching valve 50, and the discharge flow path H is provided with a reverse direction whose forward direction is toward the pump 40. A stop valve 70 is provided. In the present example, the pump 40 is configured to send out the fluid supplied from the supply port 42 from the delivery port 41 by the advance and retreat of the delivery piston 43.
[0023]
Further, in this example, the tank 60 is connected to the discharge flow path H, and the fluid is stored in the tank 60, so that the fluctuation amount of the fluid in the flow path is compensated. Here, the tank 60 includes a sealing body 62 that moves according to the amount of the stored fluid, and the sealing body 62 seals the fluid stored in the tank 60. Further, an appropriate air pressure is applied to the sealing body 62 by a screw operation or the like. Therefore, even if the attitude of the tank 60 is not changed according to the attitude of the fluid pressure jack 10, the discharge port 61 is not exposed from the stored fluid. Thereby, the hydraulic jack 10 can be reliably operated regardless of the posture of the hydraulic jack 10.
[0024]
In the hydraulic jack 10 of the present embodiment configured as described above, the switching valve 50 is operated to connect the supply flow path K and the first flow path R1, and the second flow path R2 and the discharge flow path H When the pump 40 is driven in a state (solid line in the drawing) in which the fluid is communicated, the fluid is sent to the first pressure chamber 21, the volume of the first pressure chamber 21 increases, and the fluid is discharged from the second pressure chamber 22. The volume of the second pressure chamber 22 decreases, and the piston body 30 moves forward with respect to the cylinder body 20 to operate on the pushing side. On the other hand, when the pump 40 is driven in a state where the supply flow path K and the second flow path R2 are in communication with each other and the first flow path R1 and the discharge flow path H are in communication (broken line in the drawing), the second pressure chamber 22 And the volume of the second pressure chamber 22 increases, the fluid is discharged from the first pressure chamber 21 and the volume of the first pressure chamber 21 decreases, and the piston body 30 moves backward with respect to the cylinder body 20. Then, it operates on the pulling side. Here, since the first pressure chamber 21 and the second pressure chamber 22 have substantially the same sectional area, the outputs obtained on the push side and the pull side are substantially the same.
[0025]
Next, the switching valve 50 will be described in detail with reference to FIGS. FIG. 3 shows a state in which the supply flow path K and the first flow path R1 communicate with each other, and the second flow path R2 and the discharge flow path H communicate with each other. FIG. This shows a state where K and the second flow path R2 are communicated and the first flow path R1 and the discharge flow path H are communicated.
[0026]
The cylinder body 20 is provided with a through hole, and a main chamber 53 is formed at the center of the through hole. The main chamber 53 is connected to a supply channel K and a discharge channel H. Here, the supply flow path K is branched into two supply flow paths K1 and K2, the branched supply flow paths K1 and K2 are connected to both sides of the main chamber 53, and the discharge flow path H is The main chamber 53 is connected between the supply channels K1 and K2. In the main chamber 53, a supply area 53a is formed at a portion where the supply flow paths K1 and K2 are connected, and a discharge area 53b is formed at a part where the discharge flow path H is connected.
[0027]
A cap C1 is attached to one end of the through hole, and a first chamber 51 is formed by the internal space of the cap C1, and a first flow path R1 is connected to the first chamber 51. I have. Further, a first valve port 51a provided between the supply area 53a of the main chamber 53 and the first chamber 51 is constituted by the end of the cap C1. On the other hand, a cap C2 is attached to the other end of the through hole, and a second chamber 52 is formed by the internal space of the cap C2, and a second flow path R2 is formed in the second chamber 52. It is connected. Further, a second valve port 52a provided between the supply area 53a of the main chamber 53 and the second chamber 52 is constituted by the end of the cap C2. Here, the second valve port 52a is arranged to face the first valve port 51a.
[0028]
The main chamber 53 has a main valve body 80 incorporated therein so as to be movable between a first valve port 51a and a second valve port 52a. A discharge area 53b is defined. Here, the main valve body 80 is urged toward the first valve port 51a by a spring 83 mounted in the internal space of the cap C2. The main valve body 80 has a first body 81 having a first valve portion 81a for opening and closing the first valve port 51a, and a second valve portion 82a for opening and closing the second valve port 52a. And a second body 82 formed separately and integrated with the first body 81. Here, the first valve portion 81a and the second valve portion 82a are respectively inserted into the first valve port 51a and the second valve port 52a formed in a substantially circular shape, and the first valve port 51a and the second valve port are respectively inserted. The mouth 52a is closed.
[0029]
Further, inside the main valve body 80, a communication path 85 having a first chamber side valve port 85a opening on the first chamber 51 side and a second chamber side valve port 85b opening on the second chamber 52 side is provided. It is provided in a penetrating manner. The communication path 85 is also open to the peripheral surface of the main valve body 80 and communicates with the discharge area 53b of the main chamber 53 to communicate between the first chamber 51, the second chamber 52, and the discharge area 53b. Is what you do.
[0030]
In the first chamber 51 formed by the internal space of the cap C <b> 1, a first valve body 91 attached to the operation unit 95 and driven to move forward and backward by the operation unit 95 is incorporated. Here, the end of the first valve body 91 is connected to the operation section 95 via a pin 96, and the insertion hole of the pin 96 in the first valve body 91 or the insertion of the pin 96 in the operation section 95. At least one of the holes is formed to be larger in the advancing and retreating direction of the first valve body 91 than the outer diameter of the pin 96. Thus, the first valve body 91 attached to the operation unit 95 is freely movable in the forward and backward directions. The operating section 95 is screwed into the cap C1. By rotating the operating section 95, the first valve body 91 is advanced and retracted via the pin 96. An insertion portion 94 inserted into the communication path 85 of the main valve body 80 is provided at a portion of the first valve body 91 opposite to the operation section 95.
[0031]
At the end of the main valve body 80 on the side of the second chamber 52, a housing portion 84 is recessed, and a second chamber side valve port 85b of the communication path 85 is opened in the housing portion 84. . Here, the accommodation section 84 constitutes the second chamber 52 together with the internal space of the cap C2. The accommodation portion 84 accommodates a spherical second valve body 92 that opens and closes the second chamber-side valve port 85b. The second valve body 92 is inserted into the accommodation portion 84 via the spring receiver B. The second chamber side valve port 85b is urged by the attached spring 93 in a direction to close the valve port 85b.
[0032]
Next, an operation mode of the switching valve 50 will be described. When the operation portion 95 is rotated to advance the first valve body 91, as shown in FIG. 3, the first chamber side valve port 85a opening at the end of the main valve body 80 on the first chamber 51 side is formed. It is closed by the first valve body 91. Further, the second valve body 92 is pushed against the urging force of the spring 93 by the insertion portion 94 of the first valve body 91 inserted into the communication path 85 of the main valve body 80, and the second chamber side valve is opened. The mouth 85b is opened. When the first valve element 91 is further advanced, the main valve element 80 is pushed by the first valve element 91 against the urging force of the spring 83, and the main valve element 80 is closed. The first valve port 51a is opened, and the second valve port 52a is closed. In this state, the supply flow path K and the first flow path R1 communicate with each other, and the second flow path R2 and the discharge flow path H communicate with each other, so that the fluid pressure jack 10 operates on the pushing side. Become. In this state, the first valve body 91 is pressed by the first chamber side valve port 85a by the pressure of the fluid in the first chamber 51, and accordingly, the second valve portion 82a of the main valve body 80 is moved to the second valve section 82a. It is pressed by the two valve ports 52a. Therefore, the second valve port 52a and the first chamber side valve port 85a are reliably and firmly closed.
[0033]
By the way, if high pressure due to fluid is applied to the second chamber 52 with the main valve body 80 closing the first valve port 51a, the main valve body 80 is moved to the side that opens the first valve port 51a. Therefore, a large amount of operation force is required. However, in the switching valve 50 of the present example, at a stage before the main valve body 80 is moved to the side where the first valve port 51a is opened, the second valve body 92 is pushed and the second chamber side valve port 85b is pushed. Is released, the fluid pressure in the second chamber 52 passes through the communication path 85 of the main valve body 80 to the discharge flow path H. Therefore, a large operation force is not required to move the main valve body 80 to the side where the first valve port 51a is opened. In a state where the second valve body 92 closes the second chamber side valve port 85b, the fluid pressure of the second chamber 52 is applied to the second valve body 92. Is smaller than the main valve body 80 and has a smaller pressure receiving area, so that the stress applied to the second valve body 92 is very small. Therefore, the second valve body 92 can be pushed by a small operation force, and the second chamber side valve port 85b can be opened without any trouble.
[0034]
When the operation portion 95 is rotated from the state shown in FIG. 3 to retreat the first valve body 91, the main valve body 80 is moved toward the first valve port 51a by the urging force of the spring 83 as shown in FIG. Then, the second valve port 52a is opened and the first valve port 51a is closed. When the first valve body 91 is further retracted, the first chamber side valve port 85a closed by the first valve body 91 is opened, and the second valve body 92 is moved by the urging force of the spring 93. Thus, the second chamber-side valve port 85b is closed by the second valve body 92. In this state, the supply passage K and the second passage R2 communicate with each other, and the first passage R1 and the discharge passage H communicate with each other, and the fluid pressure jack 10 operates on the pulling side. Become. In this state, the fluid pressure of the second chamber 52 is applied to the main valve body 80 in addition to the urging force of the spring 83, and the first valve port 51a is maintained in a tightly closed state. Also, the fluid pressure in the second chamber 52 is applied to the second valve body 92 in addition to the urging force of the spring 93, and the second chamber-side valve port 85b is kept tightly closed.
[0035]
The example of the fluid pressure jack according to the present invention has been described above, but the present invention is not limited to this, and various modifications are possible as follows.
[0036]
The switching valve 50 employed in the fluid pressure jack 10 according to the present invention is not limited to one in which all of the plurality of valve mechanisms are of the lift type, one in which all the valve mechanisms are of the spool type, a spool type, a lift type, and the like. Other structures may be employed, such as those appropriately combining various types of valve mechanisms. In addition, the cylinder chamber 23 of the cylinder body 20 is not limited to the first pressure chamber 21 and the second pressure chamber 22 having substantially the same area by the piston portion 31 of the piston body 30, but the first pressure chamber 21 and the second pressure chamber The pressure chamber 22 and the pressure chamber 22 may have different areas. Further, the cylinder chamber 23 is not limited to the one recessed on the outer peripheral surface of the cylinder body 20, but may be recessed inside the cylinder body 20. It is good also as a structure which fits.
[0037]
【The invention's effect】
According to the present invention described in detail above, the following effects can be obtained.
[0038]
According to the first aspect of the present invention, the operating direction of the fluid pressure jack can be switched between the pushing direction and the pulling direction by operating the single operating portion. A fluid pressure jack excellent in operability can be obtained.
[0039]
According to the second aspect of the present invention, even if the fluid has a high pressure, leakage hardly occurs, and a fluid pressure jack with reliable operation can be provided.
[0040]
According to the third aspect of the present invention, since the first valve body can reliably close the first chamber side valve port without requiring a large amount of operating force, the fluid pressure jack with further improved operability is provided. It can be.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an example of a hydraulic jack according to the present invention.
FIG. 2 is an explanatory view schematically showing the structure of the hydraulic jack shown in FIG.
FIG. 3 is an explanatory view schematically showing a structure of a switching valve.
FIG. 4 is an explanatory view schematically showing the structure of a switching valve.
FIG. 5 is an explanatory view schematically showing the structure of a conventional hydraulic jack.
FIG. 6 is an explanatory view schematically showing the structure of a conventional hydraulic jack.
[Explanation of symbols]
K (K1, K2) Supply flow path H Discharge flow path R1 First flow path R2 Second flow path 10 Fluid pressure jack 20 Cylinder body 21 First pressure chamber 22 Second pressure chamber 23 Cylinder chamber 30 Piston body 31 Piston section 40 Pump 41 Delivery port 42 Supply port 50 Switching valve 51 First chamber 51a First valve port 52 Second chamber 52a Second valve port 53 Main chamber 53a Supply area 53b Drain area 60 Tank 80 Main valve body 81 First body 81a First Valve part 82 Second body 82a Second valve part 84 Housing part 85 Communication path 85a First chamber side valve port 85b Second chamber side valve port 91 First valve body 92 Second valve body 95 Operation unit

Claims (3)

A cylinder body having a cylinder chamber;
A piston body having a piston section that partitions the cylinder chamber into a first pressure chamber and a second pressure chamber;
A pump that has a fluid supply port and a delivery port, is built into the cylinder body or the piston body, and is manually driven to deliver fluid to the first pressure chamber and the second pressure chamber;
Manually operated through a single operation unit, a supply flow path connected to the outlet, a discharge flow path connected to the supply port, a first flow path connected to the first pressure chamber, and The communication state between the respective flow paths of the second flow path connected to the second pressure chamber is such that the supply flow path and the first flow path communicate with each other, and the second flow path and the discharge flow path communicate with each other. And a switching valve that switches between a state in which the supply flow path and the second flow path communicate with each other and a state in which the first flow path and the discharge flow path communicate with each other. Fluid pressure jack. The switching valve,
A main chamber having a supply area to which the supply flow path is connected and a discharge area to which the discharge flow path is connected, a first chamber to which the first flow path is connected, and a connection to the second flow path The second room,
A first valve port provided between the supply area of the main chamber and the first chamber, and a first valve port provided between the supply area of the main chamber and the second chamber and opposed to the first valve port A second valve opening,
It has a first valve portion that opens and closes the first valve port and a second valve portion that opens and closes the second valve port, and is provided movably in a direction opposite to the first valve port and the second valve port. A main valve body which is urged in a direction to close the first valve port and partitions the main chamber into the supply region and the discharge region;
A first chamber side valve port that is provided inside the main valve body and opens to the first chamber side and a second chamber side valve port that opens to the second chamber side, and the first chamber, A communication path communicating between the second chamber and the discharge area;
The main valve body is provided in the first chamber and moved forward and backward by the operation unit to move forward, thereby closing the first chamber side valve port and moving the main valve body in a direction to close the second valve port. A first valve body,
A second valve that is provided in the second chamber, is urged in a direction to close the second chamber-side valve port, and is pushed by the first valve body that moves forward to open the second chamber-side valve port. Body and
The hydraulic jack according to claim 1, further comprising: The fluid pressure jack according to claim 2, wherein the first valve body is attached to the operation unit so as to be freely movable in a reciprocating direction.

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