JP4156641B2 - Work support - Google Patents

Description

  The present invention relates to a work support used for a machine tool or the like.

Conventionally, this type of work support is described in Patent Document 1 below.
JP-A-10-146733

The problem to be solved by the present invention is to delay the timing of the piston locking start for locking the support rod of the work support.

In order to achieve the above object, according to the first aspect of the present invention, for example, as shown in FIG. 1 or FIG. 4, the work support is configured as follows.
A work pallet (1) screwed possible housing (3) in the housing hole (1a) of the support rod (8, which is raised by its housing (3) vertically movably inserted into the Rutotomoni advancing means (53) And an annular collet (11) fitted on the outer periphery of the support rod (8), and an annular piston between the cylinder hole (21) of the housing (3) and the collet (11). (22), and the piston (22) is driven downward to lock the support rod (8) via the collet (11).
A spring (24) for urging the piston (22) upward is provided in the radial direction of the piston (22) in the vertical region of the piston (22).
The upper part of the piston (22) is connected to the housing ( via the sealing member (26) provided on the upper inner peripheral surface of the piston (22) so as to form an annular pressure receiving surface on the upper part of the piston (22). 3) is supported so as to be movable up and down, and when the piston (22) is raised, the sealing member (26) contacts the upper end wall (4) of the housing (3). ,
An annular pressure receiving surface of smaller area than the annular pressure receiving surface to form the bottom of the piston (22), another sealing provided with a lower inner circumferential surface of the same piston (22) to the housing (3) It is supported on the housing (3) through the tool (27) so as to be movable up and down.
Due to the pressure of the working chamber (23) formed outside the piston (22) and communicating with the supply / discharge port (42) on the bottom wall of the receiving hole (1a), An upward force is applied to the small-area annular pressure-receiving surface formed in the lower part of the piston (22), and a vertical gap formed between the cylinder hole (21) and the piston (22) ( G), a downward force is applied to the large-area annular pressure-receiving surface formed on the upper portion of the piston (22), and the upper and lower differential forces against the spring (24) The piston (22) is driven downward.

As shown in FIG. 1 (or FIG. 4), the present invention has the following effects.
In the released state shown in FIG. 1 (or FIG. 4), the piston 22 is raised and the sealing tool 26 provided on the upper inner peripheral surface of the piston 22 is in contact with the upper end wall 4. For this reason, since the area of the annular pressure receiving surface of the upper part of the piston 22 before the start of the lowering of the piston 22 is small at the start of the work support lock driving, the piston 22 is increased after the pressure in the working chamber 23 is sufficiently increased. Begins to descend. When the sealing member 26 is separated from the upper end wall 4 by the lowering of the piston 22, the area of the annular pressure receiving surface at the upper part of the piston 22 is increased, so that the piston 22 is strongly pushed down.

As described above, when switching from the released state to the locked state, the piston starts to descend after the pressure in the working chamber is sufficiently increased, so that it is possible to delay the timing for starting the locking of the piston.
For this reason, it is ensured that the support rod is locked after the support rod is moved to the raised position by the advancing means.

  1 and 2A to 2F and FIGS. 3A to 3F show a first embodiment of the present invention. First, the structure of the work support will be described with reference to a cross-sectional view in an elevational view in FIG.

  The housing 3 of the work support 2 is screwed to the accommodation hole 1a of the work pallet 1 in an airtight manner. The housing 3 includes an upper end wall 4, a lower block 5 constituting a lower end wall, and a body portion 6. A support rod 8 is inserted into the housing 3 so as to be movable in the vertical direction. On the upper portion of the support rod 8, a push bolt 9 that is brought into contact with the workpiece W is provided.

A holding and fixing region R is provided in the lower half portion of the outer peripheral surface of the support rod 8, and a cylindrical collet 11 is fitted on the holding and fixing region R. The collet 11 is provided with a tapered outer peripheral surface 12 having an upper concavity, and is elastically reduced in diameter by one slit 13 extending in the vertical direction. An annular transmission 15 is disposed on the outer peripheral side of the collet 11, and the tapered inner peripheral surface 16 of the transmission 15 is opposed to the tapered outer peripheral surface 12 of the collet 11 from above.
A number of balls 18 are inserted into an annular taper gap 17 formed between the tapered outer peripheral surface 12 and the tapered inner peripheral surface 16.

  The first working cylinder 20 has a first cylinder hole 21 formed in the inner periphery of the body portion 6 of the housing 3, and an annular shape inserted between the first cylinder hole 21 and the transmission tool 15. The first piston 22, the working chamber 23 that lowers the first piston 22, and the first spring 24 that raises the first piston 22. The first spring 24 is mounted in a spring chamber 25 on the lower side of the transmission tool 15.

  More specifically, the upper part of the first piston 22 is guided in an airtight manner to the upper end wall 4 by the sealing tool 26, and the lower part of the first piston 22 is the other sealing tool 27. The lower block 5 is guided in an airtight manner. Then, by supplying compressed air to the working chamber 23, a downward force acts on the large-area annular pressure receiving surface formed at the upper end of the first piston 22, and the lower end of the first piston 22. An upward force acts on the small-area annular pressure receiving surface formed in the above, and the first piston 22 descends due to the differential force between the upper and lower sides.

  Here, the first spring 24 is composed of a compression coil spring, and is mounted between an upper spring receiver 29 mounted on the lower surface of the transmission 15 and a lower spring receiver 30 mounted on the lower end of the collet 11. . The upper spring support 29 receives the numerous balls 18. The urging force of the first spring 24 causes the lower end of the collet 11 to contact the lower block 5 via the lower spring receiver 30.

A second cylinder 32 for advancing and retreating is provided in the lower block 5. The second cylinder 32 is configured as follows.
A large-diameter second cylinder hole 33 and a small-diameter rod hole 34 communicate with the lower block 5 in series upward. The second piston 35 is fitted into the second cylinder hole 33, and the piston rod 36 is inserted into the rod hole 34 with a predetermined annular gap (throttle path) 37. The annular gap 37 constitutes at least a part of the flow resistance applying means K.
Here, the annular gap 37 is formed in a gap larger than the fitting gap between the second cylinder hole 33 and the second piston 35, but is a small gap smaller than the piston fitting gap. There is no problem.
Further, here, both the second piston 35 and the piston rod 36 are integrally formed, but both of them may be formed separately.

  Here, the lower end wall (first end wall) 40 of the second cylinder hole 33 is constituted by the bottom wall of the accommodation hole 1 a, and between the lower end wall 40 and the second piston 35. An inlet chamber 41 is formed in the front. A compressed air supply / exhaust port 42 communicates with the inlet chamber 41. An outlet chamber 45 is formed between the upper end wall (second end wall) 44 of the second cylinder hole 33 and the second piston 35. A second spring (return means) 46 for retracting the second piston 35 downward is mounted between the upper end wall of the rod hole 34 and the piston rod 36. Here, the second spring 46 is constituted by a compression coil spring.

A closing portion 47 that blocks communication between the outlet chamber 45 and the annular gap 37 is provided at the end of the advance movement of the second piston 35. Here, the closing portion 47 is constituted by a valve seat 48 provided on the upper end wall 44 of the second cylinder hole 33 and a valve surface 49 provided on the upper end surface of the second piston 35. Yes.
The valve surface 49 (or the valve seat 48) is preferably constituted by a seal member (not shown) attached to the second piston 35 (or the upper end wall 44). In this case, the sealing function of the closing portion 47 can be improved by the sealing member.

An operation bolt (operation tool) 51 is inserted into the rod hole 34, and a leg portion of the operation bolt 51 is screwed to the piston rod 36. The head 52 of the operation bolt 51 is engaged with the operated portion 8a of the support rod 8 from above. Further, an advancing spring (advancing means) 53 for urging the support rod 8 upward is mounted between the head 52 of the operation bolt 51 and the push bolt 9. Here, the advancing spring 53 is constituted by a compression coil spring.
The annular gap 37 is formed in the rod hole 34, the communication groove 55 on the upper side of the lower block 5, the spring chamber 25, the vertical hole 56 in the lower block 5, and the The work pallet 1 communicates with the outside air through the exhaust holes 57 in order.

  Further, switching means 61 is provided for communicating the working chamber 23 with one of the inlet chamber 41 and the outlet chamber 45. More specifically, a communication hole 62 is formed between the working chamber 23 and the upper portion of the second cylinder hole 33. The switching means 61 is constituted by the opening of the communication hole 62 and the outer peripheral surface of the second piston 35.

  When the work support 2 is locked, the first cylinder 20 and the second cylinder 32 operate as shown in FIGS. 2A to 2E and 2F. 2A to 2E are schematic diagrams for explaining the operation. FIG. 2F is a graph showing changes in the pressure M in the inlet chamber 41 and the pressure N in the working chamber 23, and schematically shows the relationship between the pressure P and time T. is there.

2A, the compressed air in the working chamber 23 is discharged to the outside, and the compressed air in the inlet chamber 41 is also discharged to the outside. Therefore, the first piston 22 is retracted by the first spring 24, the second piston 35 is lowered by the second spring 46, and the working chamber 23 is the outlet chamber. 45.

When switching from the released state shown in FIG. 2A to the locked state shown in FIG. 2E, compressed air is supplied from the supply / exhaust port 42 to the inlet chamber 41, and the pressure M in the inlet chamber 41 is set to a set pressure for locking ( Here, it is increased to about 0.45Mpa).
By supplying the compressed air to the inlet chamber 41, first, as shown in FIG. 2B, the second piston 35 starts to rise. In this case, the second piston 35 rises in a state where the pressure M in the inlet chamber 41 is lower than the first set pressure P1 (here, about 0.25 Mpa) which is the pressure for starting the lock of the working chamber 23. The biasing force of the second spring 46 is set so as to start. In this embodiment, the compressed air in the inlet chamber 41 slightly leaks into the outlet chamber 45 through the fitting gap between the outer peripheral surface of the second piston 35 and the second cylinder hole 33. The leaked compressed air is smoothly discharged to the outside through the annular gap 37 and the rod hole 34.

  Next, as shown in FIG. 2C, when the second piston 35 is raised near the top dead center, the working chamber 23 starts to communicate with the inlet chamber 41 through the opening of the communication hole 62. Therefore, the pressure N in the working chamber 23 starts to increase. The urging force of the second spring 46 is set so that the pressure M of the inlet chamber 41 at this time is also lower than the first set pressure P1 (about 0.25 Mpa).

  Subsequently, as shown in FIG. 2D, when the second piston 35 reaches top dead center, the valve surface 49 comes into contact with the valve seat 48 to close the annular gap 37. At almost the same time, the opening degree of the communication hole 62 is maximized. As a result, the pressure N in the working chamber 23 rapidly increases and exceeds the first set pressure P1 (about 0.25 Mpa). For this reason, as shown in FIG. 2E, the first piston 22 advances against the first spring 24 by the pressure of the working chamber 23, and the first piston 22 passes through the collet 11. The support rod 8 is locked.

  When the work support 2 is released, the first cylinder 20 and the second cylinder 32 operate as shown in FIGS. 3A to 3E and 3F. 3A to 3F are similar to FIGS. 2A to 2F.

  When switching from the locked state of FIG. 3A to the released state of FIG. 3E, as shown in FIG. 3A, the compressed air in the inlet chamber 41 is discharged to the outside through the supply / discharge port 42, and the inlet chamber The pressure M of 41 is rapidly reduced. Then, first, as shown in FIG. 3B, the second piston 35 is lowered by the second spring 46 to separate the valve surface 49 from the valve seat 48 and the opening of the communication hole 62. Begins to communicate with the outlet chamber 45. For this reason, the compressed air in the working chamber 23 begins to be discharged to the outside through the communication hole 62, the outlet chamber 45, the annular gap 37, and the rod hole 34.

  Subsequently, as shown in FIG. 3C, the second piston 35 is lowered by the second spring 46. In this case, since the discharge of the compressed air from the working chamber 23 to the outside is limited by the throttle action of the annular gap 37, the working chamber 23 has a lower pressure than the pressure M in the inlet chamber 41. The decrease in pressure N is delayed. In this embodiment, when the second piston 35 is lowered, the head 52 (see FIG. 1) of the operation bolt 51 is engaged with the engaged portion 8a of the support rod 8 in the locked state (see FIG. 1). It touches from above. For this reason, it can prevent reliably that the said support rod 8 raises with the urging | biasing force of the said advance spring 53 (refer FIG. 1).

  At this time, since the support rod 8 is in the locked state as described above, the operation bolt 51 and the second piston 35 are prevented from descending. For this reason, first, as shown in FIG. 3D, the pressure M in the inlet chamber 41 is lowered in a state where the second piston 35 is held at the same height as that in FIG. 3C. The pressure N in the chamber 23 is lower than a second set pressure P2 (here, about 0.15 MPa) that is a pressure for starting release. As a result, as shown in FIG. 3E, the first piston 22 is retracted by the first spring 24, and the lock state of the support rod 8 by the collet 11 is released. The two pistons 35 and the operation bolt 51 are further lowered by the second spring 46.

A specific operation of the work support 2 will be described with reference to FIG.
In the released state shown in FIG. 1, the first piston 22 and the transmission tool 15 are lifted by the first spring 24 to release the reduced diameter of the collet 11. Further, the second piston 35 and the piston rod 36 are lowered by the second spring 46, so that the head 52 of the operation bolt 51 resists the advance spring 53 and the support rod 8. Is lowered.

  In the released state, the workpiece W is carried in a horizontal direction to a position above the push bolt 9. Thereafter, compressed air is supplied from the supply / discharge port 42 to the inlet chamber 41. Then, due to the pressure of the supplied compressed air, first, the second piston 35 and the operation bolt 51 are lifted against the second spring 46, and the rise above a predetermined amount is increased. The upper end wall 44 of the first cylinder hole 33 is blocked. Simultaneously with the raising of the operation bolt 51, the support rod 8 is raised by the advance spring 53, and the push bolt 9 comes into contact with the workpiece W as shown in a one-dot chain line diagram. In this state, a contact gap is formed in the vertical direction between the lower surface of the head 52 of the operation bolt 51 and the engaged portion 8 a of the support rod 8.

Next, as described above, the movement of the second piston 35 to the top dead center causes the compressed air of the supply / exhaust port 42 to pass through the inlet chamber 41 and the communication hole 62 in order, and the operation is performed. It is supplied to the chamber 23. When the pressure in the working chamber 23 exceeds the first set pressure P1 (in this case, about 0.25 MPa) in FIG. 2F, the difference in the vertical direction of the air pressure acting from the working chamber 23 to the first piston 22 is detected. The transmission 15 is moved downward by force, and the tapered inner peripheral surface 16 of the transmission 15 is smoothly engaged with the tapered outer peripheral surface 12 of the collet 11 while rolling the ball 18. The collet 11 is reduced in diameter. As a result, the collet 11 whose diameter has been reduced presses the holding and fixing region R of the support rod 8 in the centripetal direction, and the support rod 8 is held and fixed at the height position in the dashed line diagram.
The upper surface of the workpiece W is machined in the locked state, and the pressing force during the machining is strongly received in the axial direction by the support force of the support rod 8.

  After the machining is completed, the compressed air in the inlet chamber 41 is discharged. Then, first, the second piston 35 and the operation bolt 51 are lowered, and the head 52 of the operation bolt 51 comes into contact with the engaged portion 8a of the support rod 8 in the locked state from above. . For this reason, the operation bolt 51 reliably prevents the support rod 8 from being lifted by the advance spring 53, and then the locked state of the support rod 8 is released. More specifically, it is as follows.

  By the discharge of the compressed air, first, the second piston 35 and the operation bolt 51 are lowered by the second spring 46. Next, as described above, the compressed air in the working chamber 23 is discharged to the outside through the communication hole 62, the outlet chamber 45, and the annular gap 37. When the pressure in the working chamber 23 falls below the second set pressure P2 (in this case, about 0.15 MPa) in FIG. 3F, the first piston 22 and the transmission 15 are moved upward by the first spring 24. The tapered inner peripheral surface 16 of the transmission tool 15 smoothly moves upward while rolling the ball 18, and the pressed state of the tapered outer peripheral surface 12 of the collet 11 is released. Thereby, said collet 11 expands by self elastic restoring force, and the locked state of the said support rod 8 is cancelled | released. Therefore, the second piston 35 and the operation bolt 51 are further lowered to return the support rod 8 to the lowered position in FIG.

The first embodiment has the following advantages.
When the work support 2 is released, the operation bolt 51 is first lowered to prevent the support rod 8 from being raised by the urging force of the advance spring (advance means) 53, and then the collet. 11, the support rod 8 is held and fixed. For this reason, it is possible to prevent the urging force of the advance spring 53 from pushing up the workpiece W via the support rod 8 when the clamping and fixing state is released.

Further, as described above, when the sealing member (not shown) is provided in the closing portion 47, the upward pressure receiving area at the top dead center position of the second piston 35 can be reduced. The second piston 35 starts to descend when the pressure in the inlet chamber 41 (and the outlet chamber 45) is high. This ensures that the support rod 8 is unlocked after the operation bolt 51 is lowered.
The closing portion 47 is formed by replacing the combination of the upper end surface of the second piston 35 and the upper end wall 44 of the second cylinder hole 33 with the outer peripheral surface of the second piston 35 and the second portion. A combination with the peripheral surface of the cylinder hole 33 is also possible.

4 to 6 show a second embodiment of the present invention. FIG. 4 is a sectional view of the work support 1 in an elevational view, which is similar to FIG. FIG. 5 is a view similar to the partial view of FIG. 4 showing the raised state of the second piston 35. 6 shows a state in which the second piston 35 is being lowered, and is similar to FIG.
In the second embodiment, components having the same configuration as in the first embodiment are given the same reference numerals in principle, and a configuration different from the first embodiment will be described.

A sealing tool 65 is mounted on the outer peripheral surface of the second piston 35, and the communication hole 62 is opened at a middle height portion of the second cylinder hole 33. The switching means 61 is constituted by the opening of the communication hole 62 and the sealing member 65 described above.
Then, when compressed air is supplied to the inlet chamber 41 in the released state of FIG. 4, the second piston 35 starts to rise. The compressed air in the inlet chamber 41 does not flow out into the working chamber 23 by the sealing member 65 from the early stage to the late stage of the rising of the second piston 35. When the second piston 35 reaches the raised position in FIG. 5 (or when the second piston 35 reaches a position immediately before the raised position), the compressed air in the inlet chamber 41 flows into the communication hole 62. It begins to flow out to the working chamber 23 through the above. For this reason, the pressure in the working chamber 23 rises as shown by the one-dot chain line diagram N ′ in FIG. 2F.

In addition, a throttle path 66 is provided in the communication hole 62, and the throttle path 66 constitutes at least a part of the flow resistance applying means K. Further, at least a part of the flow resistance applying means K is constituted by a fitting gap 67 between the peripheral surface of the second cylinder hole 33 and the outer peripheral surface of the upper half of the second piston 35.
When the compressed air in the inlet chamber 41 is discharged to the outside through the supply / discharge port 42 in the state shown in FIG. 5, the second piston 35 is lowered. When the second piston 35 is lowered to the position shown in FIG. 6, the compressed air in the working chamber 23 passes through the throttle path 66 and the fitting gap 67 in order and enters the outlet chamber 45 by a small amount. Only a small amount of compressed air is discharged through the rod hole 34 to the outside.

  At this time, due to the flow resistance provided by the throttle path 66 and the fitting gap 67, the pressure drop in the working chamber 23 is delayed, and the start of the first piston 22 is delayed. Therefore, the start of unlocking of the support rod 8 by the first piston 22 can be delayed, and the support rod 8 can be unlocked after the second piston 35 and the operation bolt 51 are lowered. It becomes possible.

The second embodiment has the above-mentioned advantages of the first embodiment and further has the following advantages.
The sealing tool 65 can reliably prevent the compressed air supplied to the inlet chamber 41 from leaking to the outlet chamber 45. For this reason, when supplying the compressed air, it is possible to prevent the compressed air from leaking from the outlet chamber 45 to the outside, and the consumption of the compressed air is reduced. In addition, it is possible to prevent the support rod 8 from rising more rapidly than necessary due to the leaked compressed air.

In the second embodiment, as in the first embodiment, a valve seat (not shown here) is provided on the upper end wall 44 of the second cylinder hole 33 and the second piston 35 is provided. A valve face (not shown here) may be provided in the upper part. In this case, even when the sealing member 65 attached to the second piston 35 is damaged, the compressed air in the working chamber 23 passes through the rod hole 34 in the state shown in FIG. Leakage can be reliably prevented by the closing portion comprising the valve seat and the valve face.
Further, the sealing device 65 may be mounted in the second cylinder hole 33 instead of mounting on the second piston 35.

The first and second embodiments described above are preferably configured as follows in order to delay the start of lowering and the start of rising of the first piston 22.
In the state where the first piston 22 is located at the top dead center as shown in FIG. 1 or FIG. 4, the sealing member 26 of the first piston 22 is also brought into sealing contact with the upper end wall 4. . In this case, since the area of the annular pressure receiving surface at the upper end of the first piston 22 is small before the first piston 22 starts to descend, the first chamber 22 is increased after the pressure in the working chamber 23 is sufficiently increased. The piston 22 begins to descend. When the sealing member 26 is separated from the upper end wall 4 by the lowering of the first piston 22, the area of the annular pressure receiving surface at the upper end of the first piston 22 is increased. Is strongly pushed down.

Further, as shown in FIGS. 4 to 6, the throttle path 66 is provided in the communication hole 62. Instead of or in addition to this, the first cylinder hole 21 and It is preferable to set the annular gap G between the first piston 22 to a small value. In this case, since the flow resistance of the annular gap G and the communication hole 62 is increased, the pressure increase time and pressure decrease time of the working chamber 23 are increased. As a result, the lowering start and the rising start of the first piston 22 are delayed.
As described above, the start and unlocking of the support rod 8 by the first piston 22 can be delayed, so that the support rod 8 is locked and unlocked after the operation bolt 51 is raised and lowered. That is certain.

The first and second embodiments described above can be modified as follows.
The flow resistance applying means K may use at least one of the annular gap 37 in FIG. 1, the throttle path 66 in FIG. 4, and the fitting gap 67 in FIG. Furthermore, you may utilize some exhaust passages, such as the communication groove | channel 55 mentioned above in FIG. 1 or FIG. Further, the flow resistance applying means K may be an elongated hole, an orifice, a needle valve, or the like instead of the annular gap or the throttle path.

  The switching means 61 only needs to switch the working chamber 23 to the inlet chamber 41 and the outlet chamber 45 so as to communicate with each other. Therefore, there is no problem even if there is a moment when the outer peripheral surface of the second piston 35 fully closes the opening of the communication hole 62, or the communication hole 62 has the inlet chamber 41 and the outlet chamber 45. There is no problem even if there is a moment to communicate with both. Further, it goes without saying that the switching means 61 is not limited to the combination of the opening of the communication hole 62 and the outer peripheral surface of the second piston 35.

The means for advancing the support rod 8 upward may be an elastic body such as rubber instead of the illustrated advance spring 53, and may be compressed air or the like.
Further, the means for retracting the second piston 35 downward may be an elastic body such as rubber instead of the illustrated second spring 46, and may be compressed air or the like.

1 is a cross-sectional view of a work support according to a first embodiment of the present invention. 2A to 2F are operation explanatory diagrams when the work support is driven to be locked. 3A to 3F are operation explanatory diagrams when the work support is driven to release. FIG. 4 is a sectional view of the work support in an elevational view, showing a second embodiment of the present invention, and is similar to FIG. It is drawing similar to the partial figure in said FIG. 4 which shows the raising state of the 2nd piston provided in the said work support. FIG. 6 is a view similar to FIG. 5, showing a state in which the second piston is being lowered.

Explanation of symbols

1: Work pallet, 1a: receiving hole, 3: housing, 4: upper end wall, 8: support rod, 11: collet, 21: cylinder hole (first cylinder hole), 22: piston (first piston), 23: Working chamber, 24: Spring (first spring), 26: Sealing tool, 27: Another sealing tool, 42: Supply / exhaust port, 53: Advancement means (advance spring), G: Gap.

Claims (1)

A work pallet (1) screwed possible housing (3) in the housing hole (1a) of the support rod (8, which is raised by its housing (3) vertically movably inserted into the Rutotomoni advancing means (53) And an annular collet (11) fitted on the outer periphery of the support rod (8), and an annular piston between the cylinder hole (21) of the housing (3) and the collet (11). (22) is provided, and the piston (22) is driven downward to lock the support rod (8) via the collet (11).
A spring (24) for urging the piston (22) upward is provided in the radial direction of the piston (22) in the vertical region of the piston (22).
The upper part of the piston (22) is connected to the housing ( via the sealing member (26) provided on the upper inner peripheral surface of the piston (22) so as to form an annular pressure receiving surface on the upper part of the piston (22). 3) is supported so as to be movable up and down, and when the piston (22) is raised, the sealing member (26) contacts the upper end wall (4) of the housing (3). ,
An annular pressure receiving surface of smaller area than the annular pressure receiving surface to form the bottom of the piston (22), another sealing provided with a lower inner circumferential surface of the same piston (22) to the housing (3) It is supported on the housing (3) through the tool (27) so as to be movable up and down.
Due to the pressure of the working chamber (23) formed outside the piston (22) and communicating with the supply / discharge port (42) on the bottom wall of the receiving hole (1a), An upward force is applied to the small-area annular pressure-receiving surface formed in the lower part of the piston (22), and a vertical gap formed between the cylinder hole (21) and the piston (22) ( G), a downward force is applied to the large-area annular pressure-receiving surface formed on the upper portion of the piston (22), and the upper and lower differential forces against the spring (24) A work support characterized in that the piston (22) is driven downward.

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