JP2003327392A - Fluid pressure jack - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fluid pressure jack with a fluid storing tank reducible in size or omissible, developing almost the same output at its push and pull sides. <P>SOLUTION: The fluid pressure jack comprises a cylinder body 20 having a cylinder chamber 23, a piston body 30 having a piston portion 31 partitioning the cylinder chamber 23 into a first pressure chamber 21 and a second pressure chamber 22 having almost the same cross section area, a pump 40 having a supply port 42 and a delivery port 41 for the fluid, built in the cylinder body 20 or the piston body 30 and adapted to be manually driven for delivering the fluid to the first pressure chamber 21 and the second pressure chamber 22, and a flow path change-over mechanism 50 for changing over a flow path among the delivery port 41, the supply port 42, the first pressure chamber 21 and the second pressure chamber 22 between the state of the delivery port 41 and the first pressure chamber 21 being communicated with each other and of the second pressure chamber 22 and the supply port 42 being communicated with each other and the state of the delivery port 41 and the second pressure chamber 22 being communicated with each other and of the first pressure chamber 21 and the supply port 42 being communicated with each other. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid pressure jack, and more particularly to improvement of a fluid pressure jack having a manually driven pump.

[0002]

2. Description of the Related Art Conventionally, various types of fluid pressure jacks have been devised as fluid pressure jacks that utilize fluid pressure such as hydraulic pressure and water pressure used in manufacturing and repairing various articles. Here, at the work site, it may be difficult to secure a power source for driving the fluid pressure jack, or the fluid pressure jack may be moved and used, and it is driven manually, and it is small and lightweight and portable. It is desired to have a fluid pressure jack that is easy to operate.

Therefore, a fluid pressure jack as shown in FIG. 5 has been newly devised. The fluid pressure jack 100 includes a cylinder body 110 having a cylinder chamber 113 and a piston body 120 having a piston portion 121, and a fluid such as oil is sent to the cylinder chamber 113 by a built-in manual type pump 130. The piston portion 121 in the cylinder chamber 113 is slid by pressure to move the piston body 120 forward and backward with respect to the cylinder body 110. here,
The cylinder chamber 113 is divided into a first pressure chamber 111 and a second pressure chamber 112 by the piston portion 121, and when fluid is sent to the first pressure chamber 111, the cylinder body 110
The piston body 120 moves forward with respect to the second pressure chamber 112.
When the fluid is sent to the cylinder body 110, the piston body 120 retracts with respect to the cylinder body 110. Therefore, this fluid pressure jack 1
00 is not only excellent in usability driven manually, but also the operation on the push side where the piston body 120 advances relative to the cylinder body 110, and the cylinder body 110.
On the other hand, it is excellent in convenience that it is possible to obtain the push-pull operation in both the pull-side operation in which the piston body 120 retracts. In addition, the manually driven pump 13
The flow path switching mechanism 140 for switching between 0 and the operation of pushing and pulling is compactly housed in the cylinder body 110, which is small and lightweight and easy to carry. The flow path switching mechanism 140 includes the first pressure chamber 111, the second pressure chamber 112, the delivery port 131 of the pump 130 for delivering the fluid, and the supply port 132 of the pump 130 for delivering the fluid.
The communication state of the flow path formed between the two is switched, and the specific configuration is as follows.

The flow path switching mechanism 140 includes a first switching valve 141.
And the second switching valve 142. Here, the first switching valve 141 communicates with the first pressure chamber 111 by connecting the pump outlet 130 of the pump 130 or the supply port 1 of the pump 130.
32 for switching to the second switching valve 1
The reference numeral 42 switches the communication with the second pressure chamber 112 to either the delivery port 131 of the pump 130 or the supply port 132 of the pump 130. Then, the first switching valve 14
The first pressure chamber 11 is operated by operating the first and second switching valves 142 respectively.
1 is in communication with the delivery port 131 of the pump 130, and the second pressure chamber 112 is in communication with the supply port 132 of the pump 130. When the pump 130 is driven, fluid flows from the pump 130 to the first pressure chamber 111. While being sent, the fluid is returned from the second pressure chamber 112 to the pump 130. As a result, the piston body 120 advances relative to the cylinder body 110, and the fluid pressure jack 100 operates in the pushing direction. On the contrary, as shown in FIG. 5, the second pressure chamber 112 communicates with the delivery port 131 of the pump 130, and the first pressure chamber 1
11 is in communication with the supply port 132 of the pump 130, when the pump 130 is driven, the fluid is sent from the pump 130 to the second pressure chamber 112, while the fluid is sent from the first pressure chamber 111 to the pump 130. Will be returned. As a result, the piston body 120 retracts with respect to the cylinder body 110, and the fluid pressure jack 100 operates in the pulling direction.

[0005]

The above-described fluid pressure jack is small and lightweight and has excellent convenience, but there is room for further improvement in the following points.

In the fluid pressure jack 100 shown in FIG.
The cross-sectional area of the first pressure chamber 111 and the cross-sectional area of the second pressure chamber 112 are different. Therefore, the obtained output differs depending on whether the push side is used or the pull side. In particular,
Inside the second pressure chamber 112, the rod portion 12 of the piston body 120
Since 2 penetrates, the cross-sectional area of the second pressure chamber 112 is smaller than the cross-sectional area of the first pressure chamber 111, and the output when used on the pull side is lower than the output when used on the push side. . Regarding this point, by making the same output when used on the push side and when used on the pull side,
There was room to improve usability.

Further, when the piston body 120 moves back and forth with respect to the cylinder body 110, the volumes of the first pressure chamber 111 and the second pressure chamber 112 partitioned by the piston portion 121 change. Since the cross-sectional area of the first pressure chamber 111 and the cross-sectional area of the second pressure chamber 112 are different, the amount of change in the volume of the first pressure chamber 111 and the amount of change in the volume of the second pressure chamber 112 are not the same amount. Specifically, the first pressure chamber 11
The change amount of the volume of 1 is larger than the change amount of the volume of the second pressure chamber 112. Therefore, when the piston body 120 is moved forward with respect to the cylinder body 110, the first pressure chamber 11
Since the increase in the volume of 1 is larger than the decrease in the volume of the second pressure chamber 112, the fluid must be replenished in the fluid circuit. On the contrary, when the piston body 120 is retracted with respect to the cylinder body 110, the first pressure chamber 111
Since the amount of decrease in the volume is larger than the amount of increase in the volume of the second pressure chamber 112, the fluid has to be discharged out of the fluid circuit. Therefore, in this fluid pressure jack 100,
A tank 150 is required to store a fluid to be replenished in the circuit or a fluid to be discharged to the outside of the circuit. In particular, the cylinder body 1
When the stroke of the piston body 120 with respect to 10 is set to be large, the first pressure chamber 111 and the second pressure chamber 112 are set.
Since there is a large difference in the amount of volume change with
Need 0. In this respect, the fluid pressure jack 1 can be constructed by reducing the size of the tank 150 or omitting it.
There was room for further reduction in size and weight of the entire 00.

The present invention has been made in view of the above situation, and it is possible to obtain substantially the same output on the pushing side and the pulling side, and further, to reduce the size or omit the tank for storing the fluid. An object is to provide a fluid pressure jack that can be used.

[0009]

According to the invention described in claim 1,
The fluid pressure jack is a cylinder body having a cylinder chamber.
And the cylinder chamber and a first pressure chamber having substantially the same cross-sectional area.
Piston body having a piston section that is partitioned into a second pressure chamber
And a fluid supply port and a fluid outlet,
Or built in the piston body and driven manually
Is delivered to the first pressure chamber and the second pressure chamber.
Pump, the delivery port, the supply port, and the first pressure
A flow path between the chamber and the second pressure chamber, and
A first pressure chamber communicates with the second pressure chamber and the supply port.
Communicate with each other, or the delivery port and the second pressure chamber
And the first pressure chamber communicates with the supply port.
And a flow path switching mechanism for switching to
It is what

The fluid pressure jack which the inventors of the present application have already devised is a cylinder body having a cylinder chamber, and a piston body having a piston portion partitioning the cylinder chamber into a first pressure chamber and a second pressure chamber. A pump that has a fluid supply port and a fluid delivery port, is incorporated in the cylinder body or the piston body, and is manually driven to deliver the fluid to the first pressure chamber and the second pressure chamber; The delivery port and the first pressure chamber communicate with each other through a flow path between the outlet, the supply port, the first pressure chamber and the second pressure chamber,
A flow path switching mechanism that switches between a state in which the pressure chamber and the supply port communicate with each other, or a state in which the delivery port and the second pressure chamber communicate with each other and the first pressure chamber and the supply port communicate with each other. Is simply provided.

On the other hand, in the fluid pressure jack according to the present invention, in the above fluid pressure jack, the first pressure chamber and the second pressure chamber are formed in substantially the same sectional area. Therefore, the output on the push side and the output on the pull side are substantially the same output. Further, when operating on the push side or the pull side, the amount of change in the volume of the first pressure chamber and the amount of change in the volume of the second pressure chamber become substantially the same amount, so the amount of fluid fluctuation in the circuit decreases. . Therefore, it is possible to reduce the size of the tank that stores the fluid that varies in the circuit.

Further, in the fluid pressure jack according to the present invention,
In the case of operating at low output, the amount of change in volume of the first pressure chamber and the amount of change in volume of the second pressure chamber are substantially the same, so the amount of fluid fluctuation in the circuit is small, but operating at high output. In this case, the fluctuation amount of the fluid in the circuit increases. This is because when operating at high power, the pressure chamber on the side where the volume increases becomes high pressure, so in order to increase the volume of the pressure chamber, the fluid is pressurized by an amount that is compressed by the high pressure. This is because the chamber must be filled. Therefore, in order to absorb the fluctuation amount of the fluid, it is preferable to provide a tank for storing the fluid, but when the fluctuation amount of the fluid can be absorbed in the flow path inside the fluid pressure jack, It is also possible to omit the tank.

A fluid pressure jack according to a second aspect of the present invention is the fluid pressure jack according to the first aspect, wherein the flow path switching mechanism communicates with the first pressure chamber through the delivery port or the outlet. It is characterized by comprising a first switching valve for switching to a supply port and a second switching valve for switching communication with the second pressure chamber to the delivery port or the supply port.

The flow path switching mechanism can be constructed by using various switching valves, but in the fluid pressure jack according to the present invention, the communication with the first pressure chamber is switched to the delivery port or the supply port of the pump. The flow path switching mechanism is configured by using two three-way valves, that is, the first switching valve and the second switching valve that switches the communication between the first pressure chamber and the second pressure chamber to the pump outlet or the supply port. Therefore, the structure is simplified without using a switching valve having a complicated structure as the flow path switching mechanism. Further, by individually operating each of the two three-way valves of the first switching valve and the second switching valve, it is possible to reliably switch the operation on the pushing side or the pulling side. Moreover, by individually operating the first switching valve and the second switching valve, both the first pressure chamber and the second pressure chamber are communicated with the delivery port or the supply port of the pump, and the first pressure chamber and the second pressure chamber are connected to each other. It is also possible to make the two pressure chambers communicate with each other. In such a state, the first pressure chamber and the second pressure chamber have the same pressure, and the amount of advance / retreat of the piston body with respect to the cylinder body can be manually changed. Therefore, it is possible to easily set the advance / retreat amount of the piston body with respect to the cylinder body to an initial desired amount.

A fluid pressure jack according to a third aspect is the fluid pressure jack according to the first or second aspect, wherein:
The cylinder chamber is recessed in the outer surface of the cylinder body, the piston body is externally fitted to the cylinder body, and the pump and the flow path switching mechanism are built in the cylinder body. It is characterized by that.

A cylinder chamber is recessed on the inner surface of the cylinder body,
In the structure in which the piston body is fitted in the cylinder body and the pump and the flow passage switching mechanism are built in the cylinder body, the first pressure chamber or the second pressure chamber partitioned by the piston portion of the piston body, the pump and the flow passage switching mechanism are provided. A flow path for communicating with and must be formed in a portion of the cylinder body around the cylinder chamber. Therefore, the cylinder body is inevitably increased in size. For example, in the fluid pressure jack 100 shown in FIG. 5, a flow passage R communicating with the second pressure chamber 112 has to be formed in a portion of the cylinder body 110 around the cylinder chamber 113, and this flow passage R is formed. The cylinder body 110 is enlarged by the amount corresponding to the increase.

On the other hand, in the fluid pressure jack according to the present invention, since the cylinder chamber is recessed on the outer surface of the cylinder body which houses the pump and the flow path switching mechanism, the first pressure chamber or the second pressure chamber is formed. It is possible to form a flow path that connects the pump and the flow path switching mechanism in a region inside the cylinder chamber of the cylinder body. Therefore, the cylinder body is not unnecessarily increased in size.

A fluid pressure jack according to a fourth aspect of the present invention is the fluid pressure jack according to the first or second aspect, wherein the cylinder chamber is recessed in the inner surface of the cylinder body. The piston body is internally fitted to the cylinder body, and the pump and the flow path switching mechanism are
It is characterized in that it is built in the piston body.

In the fluid pressure jack according to the present invention, since the pump and the flow passage switching mechanism are built in the piston body fitted in the cylinder body, the first pressure chamber or the second pressure chamber and the pump and the flow passage are provided. It is possible to form a flow path that communicates with the switching mechanism at a portion inside the cylinder chamber of the piston body. Therefore, it is not necessary to form a flow path in the cylinder body around the cylinder chamber, and the cylinder body is not unnecessarily enlarged.

A fluid pressure jack according to a fifth aspect of the present invention is the fluid pressure jack according to any one of the first to fourth aspects, which stores fluid and supplies the fluid to the pump. It is characterized in that a tank is provided.

As described above, the amount of fluid in the circuit fluctuates when a high-power operation is to be obtained by the fluid pressure jack. Therefore, in the present invention, the variation amount of the fluid in the circuit is absorbed by providing the tank. Since the first pressure chamber and the second pressure chamber have substantially the same cross-sectional area, the amount of fluctuation of the fluid in the circuit is small, and even if a tank is provided, this tank should have a small volume and a small size. All that is required is that the entire fluid pressure jack does not unnecessarily increase in size. When the tank is provided, it may be provided outside the cylinder body or the piston body, or may be provided inside the cylinder body or the piston body. Particularly, in the present invention, since the tank may be a small one having a small volume, it is easy to provide the tank inside the cylinder body or the piston body.

A fluid pressure jack according to a sixth aspect of the present invention is the fluid pressure jack according to the fifth aspect, wherein the tank is provided on the outer surface of the cylinder body or the piston body, and the posture of the cylinder body or the piston body is provided. Accordingly, the pump is rotatably supported so that the fluid discharge port to the pump is located below.

The tank has a discharge port for discharging the fluid to the pump. If the tank is fixed, the discharge port may be stored depending on the posture when the fluid pressure jack is used. The exposed fluid may be exposed, which may prevent the fluid from being sent from the tank to the pump, which may cause malfunction. Therefore, if the tank is fixed, the usable posture of the fluid pressure jack is limited, and the usability is poor.

On the other hand, in the fluid pressure jack according to the present invention, since the tank is rotatably supported, the tank is always rotated by rotating the tank according to the posture when the fluid pressure jack is used. It is possible to position the outlet so that it is submerged in the fluid. Therefore, it is possible to reliably operate the fluid pressure jack regardless of its posture. Further, since the tank is supported on the outer surface of the cylinder body or the piston body, it is possible to accurately rotate the tank according to the posture when the fluid pressure jack is used.

A fluid pressure jack according to a seventh aspect of the present invention is the fluid pressure jack according to the fifth or sixth aspect, wherein the tank moves according to the amount of stored fluid to seal the fluid. It is characterized by comprising a sealing body.

In the present invention, since the fluid stored in the tank is sealed by the sealing body, even if the posture of the fluid pressure jack is changed, the discharge port is always submerged in the fluid. It is possible to reliably operate the fluid pressure jack regardless of the posture of the jack. In addition to providing a sealing body for sealing the fluid, if the tank is rotatably supported on the outer surface of the cylinder body or the piston body, the discharge port of the tank will move downward depending on the posture of the fluid pressure jack. It can be positioned and the fluid pressure jack can be operated more reliably.

[0027]

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.

As shown in FIG. 1, the fluid pressure jack 10 of this embodiment has a cylinder body 20 having an attachment 25 attached to one member A which is pushed and pulled.
And the attachment 35 attached to the other member B, which is similarly pushed and pulled, is attached to the cylinder body 2
And a piston body 30 which is assembled so as to be able to move back and forth.

Here, in the fluid pressure jack 10, the pump 40 driven by the operating portion 44 such as a lever is built in the cylinder body 20, and the pump 40 is manually operated by operating the operating portion 44. Driven. Further, when a tank 60 for storing fluid such as oil is rotatably supported (arrow T) laterally on the outer surface of the cylinder body 20, and the fluid pressure jack 10 is used in the lateral direction as shown in the drawing. Has
The tank 60 can be rotated to bring the tank 60 into a vertical state.

Next, the detailed structure of the fluid pressure jack 10 will be described. As shown in FIG. 2, a cylinder chamber 23 is recessed on the outer peripheral surface of the upper portion of the cylinder body 20, and a piston body 30 is movable forward and backward on the upper portion of the cylinder body 20 so as to cover the cylinder chamber 23. It is fitted over. Here, the piston body 30 includes a piston portion 31 extending from the inner peripheral surface into the cylinder chamber 23.
The cylinder chamber 23 is divided into a first pressure chamber 21 and a second pressure chamber 22 by 1. The first pressure chamber 21 and the second pressure chamber 22 are formed to have substantially the same cross-sectional area by penetrating the shaft portion 24 of the cylinder body 20.

The cylinder body 20 has a fluid supply port 42 and a delivery port 41. The pump 40 delivers the fluid supplied from the supply port 42 from the delivery port 41, the delivery port 41 of the pump 40, and the delivery port. 42, a flow path for appropriately communicating the first pressure chamber 21 and the second pressure chamber 22, and a flow path switching mechanism 50 for switching the communication state of the flow paths. Here, in this example, the check valve 70 having the forward direction of the fluid delivery direction is provided in the flow passage on the delivery port 41 side connected to the pump 40, and the check valve 70 on the supply port 42 side is provided. A check valve 70 having a fluid supply direction as a forward direction is provided, and the pump 40 moves the delivery piston 43 forward and backward to move the supply port 42.
It is configured to deliver the fluid supplied from the delivery port 41. The flow path switching mechanism 50 includes a first switching valve 51, which is a three-way valve that switches communication with the first pressure chamber 21 to either the outlet 41 or the supply port 42 of the pump 40, and the second pressure chamber 22. And a second switching valve 52 which is a three-way valve for switching the communication between the delivery port 41 and the supply port 42 of the pump 40. Each of the first switching valve 51 and the second switching valve 52 has an operating shaft (not shown) projecting from the cylinder body 20, and an operating portion (not shown) such as a handle attached to the operating shaft. And is operated by manually rotating the operation unit. Further, the operating portion is formed wider than the operating shaft by a looped steel wire or flat plate, and is provided so as to be foldable with respect to the operating shaft. Therefore, the operating portion can be operated by a small turning force during operation, and can be folded to be compact when not operating.

In the fluid pressure jack 10 of the present embodiment having the fluid circuit constructed as described above, as shown in FIG. 2, the first switching valve 51 is operated so that the delivery port 41 and the first pressure chamber of the pump 40 are operated. 21 to communicate with each other and operate the second switching valve 51 to
When the pump 40 is driven in a state where the pressure chamber 22 and the supply port 42 of the pump 40 are in communication with each other, the fluid is sent to the first pressure chamber 21 to increase the volume of the first pressure chamber 21 and increase the volume of the second pressure chamber 21.
The fluid is discharged from the pressure chamber 22 to reduce the volume of the second pressure chamber 22, the piston body 30 advances with respect to the cylinder body 20, and operates on the pushing side. On the other hand, as shown in FIG. 3, the second switching valve 52 is operated to operate the delivery port 4 of the pump 40.
When the pump 40 is driven in a state where the first pressure chamber 21 and the supply port 42 of the pump 40 are in communication with each other by operating the first switching valve 51 by connecting the first and second pressure chambers 22 to each other, The fluid is sent to the pressure chamber 22 to increase the volume of the second pressure chamber 22 and the fluid is discharged from the first pressure chamber 21 to decrease the volume of the first pressure chamber 21. 30 moves backward and operates on the pulling side. Here, since the first pressure chamber 21 and the second pressure chamber 22 have substantially the same cross-sectional area, the outputs obtained on the pushing side and the pulling side are substantially the same.

Although not shown, the first switching valve 51
When the second switching valve 52 is operated to bring both the first pressure chamber 21 and the second pressure chamber 22 into communication with the delivery port 41 or the supply port 42 of the pump 40, the first pressure chamber 21 and the second pressure chamber 21 are connected to each other. The two pressure chambers 22 are in communication with each other. In this state, the pressure of the fluid filled in the first pressure chamber 21 and the pressure of the fluid filled in the second pressure chamber 22 become the same, and the piston body 30 is manually moved forward and backward with respect to the cylinder body 20. You can Therefore, prior to using the fluid pressure jack 10, the work for setting the total length of the fluid pressure jack 10 to a desired length is easy.

By the way, in the fluid pressure jack 10 of the present embodiment, if the first pressure chamber 21 and the second pressure chamber 22 have the same sectional area, even if the fluid pressure jack 10 is operated on the pushing side, Even if it is operated on the pulling side, the amount of fluid in the circuit is not changed. However, when the fluid pressure jack 10 is operated at high output, the fluid is compressed at high pressure,
The amount of fluid in the circuit changes. So, in this example,
As shown in FIGS. 2 and 3, a tank 60 is connected to a flow path between the first switching valve 51 and the second switching valve 52 and the supply port 42 of the pump 40. By storing, the fluctuation amount of the fluid in the circuit is compensated. Here, the tank 60 is the cylinder body 20.
As described above, it is rotatably supported by the tank 6. In addition, the tank 6 is provided with the sealing body 62 that moves according to the amount of the stored fluid.
The fluid stored at 0 is sealed. Therefore, by rotating the tank 60 in accordance with the posture of the fluid pressure jack 10, not only can the discharge port 61 of the tank 60 be positioned below, but even if the tank 60 is not rotated, The fluid stored in 60 is the sealing body 62
Since it is sealed by the
1 is never exposed. Thereby, no matter what posture the fluid pressure jack 10 has, the fluid pressure jack 1
0 can be operated reliably.

Next, another example of the fluid pressure jack according to the present invention will be described with reference to FIG. In addition, about the structure similar to the above-mentioned example, the detailed description is abbreviate | omitted by giving the same code | symbol.

In the fluid pressure jack 10a of this embodiment, the cylinder chamber 23 is provided in the inner surface of the cylinder body 20a,
A piston body 30a, which is slidably inserted into the cylinder chamber 23 and has a piston portion 31 that divides the cylinder chamber 23 into a first pressure chamber 21 and a second pressure chamber 22, is movable back and forth in the cylinder body 20a. It is fitted inside. The pump 40 and the flow path switching mechanism 50 are built in the piston body 30a, and the tank 60 is rotatably supported on the outer surface of the piston body 30a. Here, the piston body 30
a is a first shaft portion 32 penetrating the first pressure chamber 21 and a second shaft portion 32.
A second shaft portion 33 penetrating the pressure chamber 22 is provided, and the first shaft portion 32 and the second shaft portion 33 are formed to have substantially the same diameter. As a result, the first pressure chamber 21 and the second pressure chamber 22 have substantially the same cross-sectional area.

In the fluid pressure jack 10a of this embodiment, the first pressure chamber 21 and the second pressure chamber 2 are provided by the flow path switching mechanism 50.
2 is connected to the outlet 41 of the pump 40 or the supply port 42.
By switching to one or the other of the two, the piston body 30a is advanced and retracted with respect to the cylinder body 20a, and the push side and the pull side operate with the same output. In addition,
In FIG. 4, the second switching valve 52 that constitutes the flow path switching mechanism 50.
By operating the delivery port 41 of the pump 40 and the second pressure chamber 22.
Shows a state in which the first pressure chamber 21 and the supply port 42 of the pump 40 are in communication with each other by operating the first switching valve 51 to operate the fluid pressure jack 10a on the pulling side.

Although the example of the fluid pressure jack according to the present invention has been described above, the fluid pressure jack according to the present invention is not limited to this, and various modifications can be made as follows.

A tank for storing the fluid may be provided inside the cylinder body or the piston body. Further, if a sufficient volume is secured by the flow passage formed in the cylinder body or the piston body, and the flow passage itself can compensate for the fluctuation amount of the fluid in the circuit, the tank can be omitted. .

The flow path switching mechanism may be constructed by using a multi-way valve of three-way valve or more, and may be constructed by a single multi-way valve when adopting a multi-way valve of four-way valve or more. .
Furthermore, an on-off valve that opens and closes each flow path may be used.

In the fluid pressure jack shown in FIG. 5, a shaft portion having substantially the same diameter as the rod portion penetrating the second pressure chamber is extended below the piston portion, and the shaft portion penetrates the first pressure chamber. Thus, the fluid pressure jack according to the present invention may be configured such that the first pressure chamber and the second pressure chamber have substantially the same cross-sectional area.

Further, the fluid pressure jack according to the present invention is small and lightweight, and is manually driven, and various members are used for manufacturing and repairing various machines and articles in factories and outdoors. It can be suitably used for the work of pushing and pulling. In particular, it can be suitably used outdoors at a construction site that requires work in high places. For example, when building a building, in the upper part of the lower structure formed of steel or the like, the upper structure also formed of steel or the like is stacked and integrated by welding or bolting, Fluid for construction that is interposed between the lower structure and the upper structure and that pushes and pulls the upper structure with respect to the lower structure to ensure accurate verticality and levelness of the upper structure. Suitable as a pressure jack.

[0043]

According to the present invention described in detail above, the following effects can be obtained.

According to the invention of claim 1, since the first pressure chamber and the second pressure chamber have substantially the same cross-sectional area, the outputs obtained on the pushing side and the pulling side can be made substantially the same. Also,
Whether operating on the push side or the pull side, the amount of fluid in the circuit does not fluctuate so that the tank for storing the fluid can be downsized or omitted.

According to the second aspect of the invention, the flow path switching mechanism is constituted by the two three-way valves having a simple structure of the first switching valve and the second switching valve. It is possible to simplify. In addition, the first switching valve and the second
By individually operating the switching valve, the fluid pressure jack can be reliably operated to the push side or the pull side. further,
The first pressure chamber and the second pressure chamber can be made to communicate with each other by operating the first switching valve and the second switching valve individually, whereby the amount of advance and retraction of the piston body with respect to the cylinder body, that is, the fluid pressure jack. The total length can be easily set by hand, further improving usability.

According to the third aspect of the present invention, since the cylinder chamber is provided on the outer surface of the cylinder body, it is possible to form the flow passage in a portion inside the cylinder chamber, and the cylinder body is unnecessarily enlarged. Can be suppressed.

According to the invention of claim 4, since the passage is formed in the piston body fitted in the cylinder body, it is not necessary to form the passage in the cylinder body, and the cylinder body is unnecessarily increased in size. Can be suppressed.

According to the fifth aspect of the invention, the fluctuation of the fluid amount in the circuit caused by the high-power operation can be reliably absorbed by the tank. Since the amount of fluctuation of the fluid that needs to be absorbed is small, a large tank is not required, and the fluid pressure jack does not unnecessarily increase in size.

According to the sixth aspect of the present invention, by rotating the tank in accordance with the posture of the fluid pressure jack, the tank can be placed in the vertical state and the discharge port can be positioned below. Therefore, various fluid pressure jacks can be used. It can be used in various postures and the convenience of use can be improved.

According to the seventh aspect of the invention, since the fluid stored in the tank is sealed by the sealing body, the discharge port of the tank is not exposed from the stored fluid and various fluid pressure jacks can be used. It can be used in various postures and the convenience of use can be improved.

[Brief description of drawings]

FIG. 1 is a perspective view showing an example of a fluid pressure jack according to the present invention.

FIG. 2 is an explanatory view schematically showing the structure of the fluid pressure jack shown in FIG.

FIG. 3 is an explanatory diagram schematically showing the structure of the fluid pressure jack shown in FIG.

FIG. 4 is an explanatory view schematically showing the structure of another example of the fluid pressure jack.

FIG. 5 is an explanatory view schematically showing the structure of a conventional fluid pressure jack.

[Explanation of symbols]

10 (10a) fluid pressure jack 20 (20a) cylinder body 21 First pressure chamber 22 Second pressure chamber 23 Cylinder chamber 30 (30a) Piston body 31 Piston part 40 pumps 41 exit 42 Supply port 50 flow path switching mechanism 51 First switching valve 52 Second switching valve 60 tanks 61 outlet 62 sealed body

Claims (7)

[Claims] 1. A cylinder body having a cylinder chamber, a first pressure chamber and a second pressure chamber having substantially the same cross-sectional area in each of the cylinder chambers.
A piston body having a piston portion that is partitioned into a pressure chamber; a fluid supply port and a delivery port; and being incorporated in the cylinder body or the piston body and being driven manually, the first pressure chamber and the first pressure chamber A pump for delivering fluid to the two pressure chambers, the delivery port, the supply port, the first pressure chamber and the second
In the flow path between the pressure chambers, the delivery port and the first pressure chamber communicate with each other, and the second pressure chamber and the supply port communicate with each other, or the delivery port and the second pressure chamber. Communicates,
A fluid pressure jack comprising: a flow path switching mechanism that switches to a state in which the first pressure chamber and the supply port communicate with each other. 2. The flow path switching mechanism includes a first switching valve for switching communication with the first pressure chamber to the outlet port or the supply port, and communication with the second pressure chamber for the outlet port. The fluid pressure jack according to claim 1, further comprising a second switching valve that switches to the supply port. 3. The cylinder chamber is recessed in an outer surface of the cylinder body, the piston body is externally fitted to the cylinder body, and the pump and the flow path switching mechanism are the cylinder body. The fluid pressure jack according to claim 1 or 2, wherein the fluid pressure jack is incorporated in the. 4. The cylinder chamber is recessed in the inner surface of the cylinder body, the piston body is fitted in the cylinder body, and the pump and the flow path switching mechanism are the piston body. The fluid pressure jack according to claim 1 or 2, wherein the fluid pressure jack is incorporated in the. 5. A tank for storing a fluid and supplying the fluid to the pump is provided.
5. The fluid pressure jack according to claim 4. 6. The tank is rotatable on an outer surface of the cylinder body or the piston body so that a fluid discharge port to the pump is located downward depending on a posture of the cylinder body or the piston body. The fluid pressure jack according to claim 5, wherein the fluid pressure jack is supported by. 7. The fluid pressure jack according to claim 5, wherein the tank includes a sealing body that moves in accordance with the amount of stored fluid to seal the fluid.