JPH0530760B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field) The present invention relates to a multi-stage jack using pressure fluid such as hydraulic oil and a tube propulsion device suitable as a source pushing device for a tube propulsion method.

(Prior Art) As one of the original pushing jacks for propelling a pipe used in the pipe propulsion construction method, a piston rod is equipped with a first connecting part connected to one of the reaction force body and the pressed body at the rear end. , a first cylinder that receives the piston rod movably in its axial direction from the tip end side of the piston rod, and a second cylinder that receives the first cylinder movably in its axial direction and that There is a jack that includes a force body and a second cylinder having a second connecting part connected to the other of the pressed body at the tip (Japanese Patent Application Laid-Open No.
59-118697).

However, the conventional jack has a structure in which most of the first cylinder is accommodated in the second cylinder when the jack is contracted. and the distance between the second connecting portions is long. If the long-distance jack is used in a tube propulsion device, the length of the shaft in which the tube propulsion device is installed must be increased in the tube propulsion direction.

A piston/cylinder device for construction machinery includes a piston rod having a first connecting portion connected to a reaction body at both ends, and a first cylinder receiving the piston rod movably in the axial direction. There is a second cylinder that movably receives the first cylinder and includes a second connecting portion that is connected to a member to be moved (Japanese Patent Application Laid-Open No. 57-19912). -85432).

However, in this piston-cylinder device, since the rod passes through the first cylinder and the first connecting portions are provided at both ends of the rod, the rod always protrudes from the cylinder by at least the stroke length. Therefore, the rod interferes with various operations. In particular, when such a piston-cylinder device is used as a jack for a tube propulsion device, the rods obstruct the placement and connection work of the propulsion tubes, thus requiring a shaft with a large length in the tube propulsion direction. do.

(Object of the invention) The present invention can shorten the distance between the first and second connecting parts without reducing the stroke of the jack, and does not interfere with the arrangement and connection work of the propulsion pipe. It is an object of the present invention to provide a jack that does not require increasing the length of a shaft in the propulsion direction, and a pipe propulsion device using the same.

(Structure of the Invention) The jack of the present invention includes a rod having a first connecting portion at one end that is connected to one of a reaction force body and a pressed body, and a rod that is provided around the rod in a radial direction of the rod. and a plurality of cylinders arranged coaxially and relatively movable in the axial direction of the rod.
The outermost cylinder includes a second connecting portion connected to the other of the reaction force body and the pressed body. The innermost cylinder allows the rod to be inserted into the rod at its other end without allowing the rod to protrude from the innermost cylinder towards the other end of the rod in the axial direction. is relatively movably received in the axial direction from the side of the rod, and when the first and second connecting portions are closest to each other, the position of the second connecting portion in the axial direction of the rod is It projects toward the other end of the rod.

The tube propulsion device of the present invention includes at least a pair of jacks arranged in parallel at intervals in the horizontal direction, and a moving body that is moved by each jack in the axial direction of the jack. Each of the above-mentioned jacks includes a rod having a first connecting portion connected to the reaction force body at its rear end, and a rod that moves coaxially around the rod in the radial direction of the rod and relatively in the axial direction. and a plurality of cylinders arranged in a manner that is possible. The outermost cylinder includes a second connecting portion connected to the movable body. The innermost cylinder allows the rod to be moved from its distal end side without allowing the rod to protrude from the innermost cylinder to the other end of the rod in the axial direction. The first
and when the second connection is closest,
The movable body is protruded forward from the position of the movable body in the axial direction.

(Operations and Effects of the Invention) When the jack extends, the innermost cylinder and the rod are moved relative to each other so that the rod protrudes from the innermost cylinder to one side, and The inner and outer adjacent cylinders are moved relative to each other such that the inner cylinder moves in the same direction as the rod relative to the outer cylinder.

On the other hand, when the jack is retracted, the innermost cylinder and rod are moved relative to each other so that the rod is accommodated in the innermost cylinder, and the rod is moved inwardly. Adjacent cylinders are moved relative to each other such that the cylinder located outside projects from the cylinder located outside of it.

According to the present invention, when the first and second connecting portions are closest to each other, the innermost cylinder is closer to the first connecting portion than the second connecting portion in the axial direction of the rod. Because it protrudes to the opposite side, even if the stroke is shortened due to the relative movement between the outermost cylinder and the cylinder located inside it, the relative movement between the rod and the cylinder located inside it will be reduced accordingly. The stroke caused by the movement can be lengthened, and the distance between the first and second connecting parts is shortened by the fact that the inner cylinder protrudes from the position of the second connecting part.

Further, according to the present invention, when the jack is retracted, most of the rod is accommodated in its outer cylinder, which, together with the shortening of the distance between the first and second connecting portions, Even when applied to a jack for a propulsion device, it does not interfere with the arrangement and connection work of propulsion pipes, and there is no need to increase the length of the shaft in the direction of pipe propulsion.

According to the pipe propulsion device of the present invention using the above-mentioned jack, the part of the cylinder protruding from the second connecting part can be placed in the space necessary for arranging the pipe, thereby eliminating the need for a large shaft. do not.

(Example) Hereinafter, an example of the present invention shown in the drawings will be described.

The jack 10 shown in FIG. 1 includes a rod 12,
a first cylinder 14 for receiving the rod so as to be movable relative to the axis thereof; and a second cylinder 14 disposed around the first cylinder so as to be movable relative to the axis of the first cylinder. cylinder 16.

The rod 12 is inserted into a first cylinder chamber 18 provided in a first cylinder 14 from the distal end side. A flange 20 is provided at the tip of the rod 12 to partition the first cylinder chamber 18 into two chambers 18a and 18b. On the other hand, a connecting portion 24 connected to the reaction force body 22 is attached to the rear end of the rod 12 by welding or bolts. The rod 12 is formed with a passage 26a for supplying a working fluid such as hydraulic oil to the chamber 18a, and a passage 26b for supplying working fluid to the chamber 18b.

The first cylinder 14 includes a main body 28 that defines a first cylinder chamber 18 that opens rearward, and an end plate 3 that airtightly closes the opening of the first cylinder chamber 18.
0. The end plate 30 is releasably fixed to the main body portion 28 with a plurality of bolts. End plate 3
0 has a hole 32 through which the rod 12 can slide.
is provided.

The second cylinder 16 includes a cylindrical main body 36 that defines a second cylinder chamber 34 together with the first cylinder 14, and a rear end of the main body 36 for airtightly closing the rear end of the second cylinder 34. and an end plate 38 releasably fixed by a plurality of bolts. A connecting portion 40 to which a pressed body such as a push plate is attached is provided at the tip of the main body 36 . The connecting portion consists of a flange in the illustrated example. The end plate 38 is provided with a hole 42 through which the main body 28 of the first cylinder 14 can slide.

On the outer periphery of the main body portion 28 of the first cylinder 14,
The second cylinder chamber 34 is divided into two chambers 34a and 34b.
A flange 44 is provided that partitions into. 1st
The main body portion 30 of the cylinder 14 also includes a chamber 18a of the first cylinder chamber 18 and a second cylinder chamber 3.
A flow path 46a that connects the chamber 34a of the first cylinder chamber 18 and the second cylinder chamber 3;
A flow path 46b connecting the fourth chamber 34b is provided.

between the rod 12 and the end plate 30; between the flange 20 of the rod 12 and the main body 28 of the first cylinder 14; and between the main body 28 of the first cylinder 14 and the end plate 3.
0, between the main body 28 of the first cylinder 14 and the main body 36 of the second cylinder 16, between the main body 36 of the second cylinder 16 and the end plate 38, and between the main body 36 of the first cylinder 14 Airtightness between the portion 28 and the end plate 38 of the second cylinder 16 and between the flange 44 of the first cylinder 14 and the main body 36 of the second cylinder 16 is maintained by the sealing material 48 .

When the jack 10 is used in a tube propulsion device,
As shown in FIG. 2, a plurality of jacks 10 are used. Each jack 10 is releasably secured to the reaction body 22 at the connection of the rod 12 so that they extend parallel to each other at intervals.
A common push plate 50 is attached to the connecting portion 40 of the second cylinder 16, and the tube 5 to be propelled
2 is located between the jacks and connected to the push plate 50.

When the jack 10 is retracted, as shown in FIG. is the connecting part 40
It is projected forward by a distance L.

For this reason, according to Jacky 10, the connecting portion 2
The distance between 4 and 40 is short, and there is no need to increase the diameter of the shaft. Further, the tip of the first cylinder 14 that protrudes forward from the connecting portion 40 is connected to the pipe 52.
The first cylinder 14 is lengthened to reduce the stroke due to relative movement between the rod 12 and the first cylinder 14.
Even if L ₁ is increased, a large shaft is not required.
Therefore, according to Jacki 10, the first and second
Even if the stroke _L2 due to the relative movement of the first cylinders 14 and 16 is shortened, the stroke _L1 due to the relative movement between the rod 12 and the first cylinder 14 can be lengthened accordingly.

When working fluid is supplied to the flow path 26a in the state shown in FIG. 2, the first and second cylinder chambers 18
Since the working fluid is supplied to a and 34a, the first cylinder 14 moves a distance forward with respect to the rod 12.
L ₁ is moved and the second cylinder 16 is moved forward relative to the first cylinder 14 a distance L ₂ . This causes the jack 10 to extend L ₀ and advance the tube 52 the same distance. Jack 1
The stroke L ₀ of zero is L ₁ +L ₂ .

When working fluid is supplied to the flow path 26b in the extended state, the first and second cylinder chambers 18
b, 34b, the first cylinder 14 moves a distance backward with respect to the rod 12.
L ₁ is moved and the second cylinder 16 is moved rearwardly relative to the first cylinder 14 a distance L ₂ . As a result, the jack 10 is deflated.

The jack 60 shown in FIG. 3 includes a cylindrical auxiliary cylinder 62 in which a first cylinder 14 is arranged around a second cylinder 16, and a second cylinder chamber 34 is arranged between the auxiliary cylinder 62 and the second cylinder. 28 and further defined by a second cylinder chamber 34
A flange 6 that divides the room into two chambers 34a and 34b.
The jack 10 is different from the jack 10 shown in FIG. The auxiliary cylinder 62 is fixed to the main body 28 at its rear end.

When the jack 60 is used in a tube propulsion device, a plurality of jacks 60 are used as shown in FIG. Each jack 10 is releasably secured to the reaction body 22 at a connection 24 of the rod 12 such that they extend parallel to each other at intervals. A common push plate 50 is attached to the connecting portion 40 of the second cylinder 16, and a tube 52 to be propelled is connected to the push plate 50 between the jacks.

When the jack 60 is retracted, the rod 12
is housed in the first cylinder chamber 18, and the first and second cylinders 14, 16 are housed in the first cylinder chamber 18.
The cylinder 14 is projected forward by a distance L relative to the second cylinder 16. In this state, when working fluid is supplied to the flow path 26a, the first cylinder 14 is moved forward by a distance L ₁ relative to the rod 12, and the second cylinder 16 is moved relative to the first cylinder 14. It is moved forward by a distance L ₂ .
This causes the jack 60 to extend L ₀ and advance the tube 52 the same distance.

When the working fluid is supplied to the flow path 26b in the extended state, the first cylinder 14 is moved rearwardly by a distance L ₁ with respect to the rod 12, and the second cylinder 16 is moved from the first cylinder 14. is moved backward by a distance L ₂ . Thereby, the jack 60 is deflated.

The jack 60 also connects the first and second connecting parts 2.
The distance between 4 and 40 is short, and there is no need to increase the diameter of the shaft. In addition, since the distal end of the first cylinder 14 is arranged in the space necessary for arranging the tube 52, the first cylinder 14 is lengthened and the relative movement between the rod 12 and the first cylinder 14 is Even if the stroke L ₁ is increased, a large shaft is not required, and therefore the stroke due to the relative movement of the first and second cylinders 14, 16 can be increased.
Even if L ₂ becomes shorter, the stroke due to the relative movement between the rod 12 and the first cylinder 16
L ₂ can be made longer.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an embodiment of the jack of the present invention, FIG. 2 is a sectional view of an embodiment of the tube propulsion device using the jack of FIG. 1, and FIG. 3 is a sectional view of the jack of the present invention. 4 is a cross-sectional view showing another embodiment of the tube propulsion device using the jack of FIG. 3. FIG. 10, 60: Jack, 12: Rod, 14:
First cylinder, 16: Second cylinder, 24,
40: Connection part, 26a, 26b, 46a, 46
b: flow path for working fluid; 28: main body; 50: push plate or moving body; 62: auxiliary cylinder.

Claims (1)

[Scope of Claims] 1. A rod having at one end a first connecting portion connected to one of the reaction force body and the pressed body, and a rod located around the rod and coaxially in the radial direction of the rod. a plurality of cylinders disposed so as to be movable relative to each other in the axial direction of the rod, the innermost cylinder being arranged such that the rod is moved in the axial direction from the innermost cylinder; an outermost cylinder that receives the rod so as to be relatively movable in the axial direction from the other end of the rod without allowing the rod to protrude toward the other end; includes a second connecting portion connected to the other of the reaction force body and the pressed body, and the innermost cylinder has the first and second connecting portions closest to each other. and a jack protruding toward the other end of the rod from the position of the second connecting portion in the axial direction of the rod. 2. When the first and second connecting portions are closest to each other, the cylinder located on the inside projects from the cylinder located on the outside thereof to the side opposite to the first connecting portion; A jack according to claim 1. 3. The jack according to claim 2, wherein the second connecting portion is located at an end of the outermost cylinder opposite to the first connecting portion. 4. The innermost cylinder has a main body portion that receives the rod from the other end thereof so as to be relatively movable in the axial direction, and the outermost cylinder Claim 1, further comprising an auxiliary cylinder part connected to the main body part, the auxiliary cylinder part movably receiving an externally arranged cylinder from its end on the side of the first connecting part. Jyatsuki. 5. A jack according to claim 1, wherein the rod is provided with two passages for a working fluid to move the rod and the innermost cylinder relative to each other. 6. The jack according to claim 1, wherein the inner cylinder among the adjacent cylinders is provided with two flow paths for a working fluid that relatively moves both adjacent cylinders. . 7. A tube propulsion device including at least a pair of jacks arranged parallel to each other at intervals in the horizontal direction, and a moving body that is moved by each jack in the axial direction of the jack, wherein each jack has a reaction force. a rod having a first connecting portion connected to the body at its rear end; and a plurality of rods disposed around the rod coaxially in the radial direction of the rod and movable relatively in the axial direction. a cylinder, the innermost cylinder being able to hold the rod without allowing the rod to protrude from the innermost cylinder toward the other end of the rod in the axial direction; The cylinder is received from the distal end side thereof so as to be relatively movable in the axial direction, and the outermost cylinder is provided with a second connecting part connected to the movable body, and the innermost cylinder is provided with a second connecting part connected to the movable body. A tube propulsion device, wherein the cylinder is protruded forward from a position of the movable body in the axial direction when the first and second connecting portions are closest to each other. 8. The tube propulsion device according to claim 7, wherein the second connecting portion is disposed at the tip of the outermost cylinder.