KR20130057956A - Arrestable piston-cylinder-unit - Google Patents

Abstract

PURPOSE: A piston cylinder unit capable of applying a brake to a cylinder is provided to apply a brake to a piston by using an operating force of a valve. CONSTITUTION: A piston cylinder unit comprises a cylinder space and a closing member. The cylinder space is subdivided into a first operating chamber(5) and a second operating chamber(6) by a piston. The operating chambers are filled with fluid while receiving pressure. The closing member is operated to the closing position by the pressure of the first operating chamber. The closing member moves to opening position from the closing position by the power of a valve from the outside of a cylinder. The closing member is supported by the cylinder or components connected to the cylinder and are directly or indirectly operated to the opening position by a spring element receiving compressive stress.

Description

Brakeable piston-cylinder unit {ARRESTABLE PISTON-CYLINDER-UNIT}

The present invention relates to a brakeable piston-cylinder-unit with a cylinder, a piston rod and a valve, in which case the cylinder space of the cylinder is subdivided into a first working chamber and a second working chamber by a piston, and the working chamber Are filled with fluid under pressure, in which case the piston rod protrudes through the first or second working chamber and leads out of the cylinder in a sealed state, in which case the valve Has a closing member capable of connecting the first working chamber to a second working chamber, the closing member being actuated to its closed position by the pressure of the first working chamber, the closing member being driven by a valve acting power outside the cylinder. It can be operated to move from its closed position to its open position.

In such a brakeable piston-cylinder-unit, the valve member of the valve is operated in a permanently closed position by the pressure inside the first working chamber. Since the size of the surface capable of effectively operating the closing member cannot be arbitrarily small, the power for operating the closing member in the closing direction is relatively high.

Therefore, in order to open the valve in order to be able to move the piston rod in the cylinder, the closing member must be operated in the open direction indirectly or directly by a power larger than the power for operating the closing member in the closing direction.

Such high power is not particularly comfortable when this power must be provided manually.

It is an object of the present invention to manufacture a brakeable piston-cylinder-unit of the type mentioned in the preamble, which is simple in construction and can cause braking of the piston with low valve actuation force.

The problem is solved by operating the closing member indirectly or directly in the open direction by means of a compressive stressed spring element supported in a cylinder or in a component firmly coupled to the cylinder, in accordance with the invention, wherein the spring element The compressive stress of is smaller than the closing force acting on the closure member by the pressure inside the first working chamber.

By such an embodiment, slightly more power is provided to cause braking of the piston than the differential power between the closing force for actuating the closing member and the spring element power acting against the closing member against it. Can be. Such differential power can be very small. The differential power only needs to ensure that the closing member is moved to its closed position and securely held there in order to induce braking if no valve actuation power is provided.

The closure member may be actuated to move from its closed position to its open position by means of an actuating element leading axially from the cylinder.

In this case the closing member can be driven to move from its closed position to its open position by means of an actuator, but also indirectly or directly by manual operation.

In a simple embodiment the actuating element is preferably an acting tappet.

If the spring element is embodied as a screw compression spring which encloses the closing member or the actuating element at intervals, only a small installation space is required, in which case one end of the screw compression spring is in a part tightly coupled to the cylinder. Supported, the other end of the screw compression spring actuates the closing member or actuating element.

Thereby, a whole piston-cylinder-unit with a low structural height can also be formed.

Screw compression springs are also simple and inexpensive components.

In order to enable operation in the transverse direction with respect to the longitudinal axis of the cylinder by manual operation or with an actuator, the front face of the closing member or end of the actuating element protruding from the cylinder extends transversely with respect to the longitudinal axis of the cylinder and It can be actuated by a first arm of a lever consisting of two arms capable of pivoting about a pivot axis which is tightly coupled to the cylinder, in which case the lever is moved with respect to the front of the closure member or the actuating element. It is actuated by a spring element to exert an action, and the second arm of the lever is actuated by the valve actuation power.

In this case the spring element may be a tension spring supported on the cylinder or on a component associated with the cylinder, and in a simple embodiment the worm spring surrounding the second arm of the lever arm and the component engaged with the cylinder. spring).

The valve may be a poppet valve or may be a sliding valve.

In one embodiment, the valve is disposed in a valve body that closes the cylinder at one end region.

Such a piston-cylinder-unit may preferably be applied for the purpose of adjusting the height of the seat surface or the height of the table plate in an object carrier column such as a chair column or a table column.

In one other embodiment, the valve may be disposed in the piston.

Such an embodiment can be applied for the purpose of braking flaps and covers, which preferably have a high intrinsic weight, but can also be applied in other applications which require fastening at different positions.

Embodiments of the present invention are illustrated in the drawings and described in detail below.

1 is a longitudinal sectional view of a first embodiment of a brakeable piston-cylinder-unit,
2 is a longitudinal cross-sectional view of an end region of a second embodiment of a brakeable piston-cylinder-unit,
3 is a longitudinal sectional view of a third embodiment of a brakeable piston-cylinder unit, and
4 is a longitudinal sectional view of a fourth embodiment of a brakeable piston-cylinder unit.

The brakeable piston-cylinder unit shown in FIGS. 1 to 3 has a tubular housing 1, on which a cylinder 2 is arranged coaxially. An annular gap 3 is formed between the tubular housing 1 and the cylinder 2 which forms a flow path due to the different diameters.

Inside the cylinder 2 a piston 4 is arranged to move along an axis, which divides the piston 4 into a first work chamber 5 and a second work chamber 6.

The piston rod 7, one end of which is connected to the piston 4, passes through the second working chamber 6 and is guided outward in a sealed state by the piston rod guide 8.

In the end region close to the piston rod guide 8, the second working chamber 6 is connected to an annular gap 3 via a radial opening 9.

A valve body 10 is inserted in the end of the cylinder 2 opposite the piston rod guide 8, and the end of the valve body projecting from the cylinder 2 is sealed in the tubular housing. Adjacent to the inner wall of (1).

Between the valve body 10 and the upper end of the tubular housing 1 there is a gap piece 11, which is at its end opposite the valve body 10. It is surrounded by a bead at the end of the housing 1.

A stepped coaxial guide bore 13 is formed in the gap filling member 11, and a step 12 having a large size of the guide bore is directed toward the valve body 10.

In the step 15 where the size of the guide bore 13 is small, the actuating tappet 14 is movably guided, and one end of the actuating tappet protrudes outward from the guide bore 13 and moves inward along the axis. It can be operated manually by means of the directed valve actuation power.

The actuating tappet 14 is arranged with a retaining washer 16 (FIG. 1). The fixing washer ensures an assembly that is suitable for manufacturing and safe for the process.

Alternatively, the actuating tappet 14 may also have a radially protruding nose 14 having the same function (FIG. 2).

At its end facing towards the valve body 10, the actuating tappet 14 is adjacent to the spool 18 of the poppet valve 19, forming a closing member.

The spool 18 is movably disposed in a recess 20 of the valve body 10 continuous along an axis and in communication with the first working chamber 5, the first working chamber 5 It has an extension 21 in the form of a flange at its end facing towards the side, the flange-like extension 22 forming a sealing ring 22 which forms a valve seat disposed in the valve body 10. ) May be installed in the withdrawal direction.

Inside the valve body 10 the spool 18 has a region 23 having a reduced diameter. The radial bore 24 in the valve body 10 connects the recess 20 to the annular gap 3 in the area covered by the reduced area 23 of the spool 18.

In the embodiment according to FIG. 3, in the region of the gap member 11 protruding from the tubular housing 1, a lever 25 consisting of two arms extends transversely with respect to the longitudinal axis 26 of the cylinder 2. It is supported so that it can turn around the turning shaft 27 which becomes.

The first arm 28 of the lever 25 consisting of the two arms is adjacent to the outer front of the actuating tappet 14, while the second arm 29 of the lever is substantially parallel to the longitudinal axis 26. It extends and has a connecting member 30 at its free end, in which the valve actuation power can act transversely with respect to the longitudinal axis 26.

By means of the worm spring 32 subjected to compressive stress around the portion 31 of the gap receding member 11 extending in parallel with the second arm 29 and the longitudinal axis 26, the first arm 28 is adjacent to the actuating tappet 14 by a corresponding compressive stress and through the actuating tappet 14 in the lifting direction of the flange-shaped extension 21 from the sealing ring 22. Activate the spool (18).

In the embodiments according to FIGS. 1 and 2, the actuating tappet 14 is surrounded by a compressive stressed screw compression spring 13 in the region of the large step 12 of the guide bore 13, One end of the screw compression spring is supported between the large step 12 and the small step 15 of the guide bore 13, and the other end of the screw compression spring of the actuating tappet 14 Supported by the flanged extension 21, the spool 18 is operated in the lifting direction of the flanged extension 21 from the sealing ring 22 via the actuating tappet 14.

The two working chambers 5 and 6 are filled with gas under pressure.

This gas pressure inside the first working chamber 5 also acts on the flanged extension 21 of the spool 18 and presses the flanged extension toward the sealing ring 22.

Thereby, the flow passage starts from the first working chamber 5 and passes through the recess 20 and the radial bore 24 and the annular gap 3 and the radial opening 9 to the second working chamber 6. Can be kept closed.

The power of the worm spring 32 or the screw compression spring 33 which actuates the actuating tappet 14 in the valve closing direction is applied to the spool 18 by the gas pressure inside the first working chamber 5. Less than the power exerted in the valve closing direction.

As a result, the flange-shaped extension is adjacent to the sealing ring 22, whereby the valve passage is kept closed.

Once the actuation tappet 14 is actuated in the valve opening direction by additional valve actuation power, the power exerting action on the actuation tappet 14 by the worm spring 32 or the screw compression spring 33 is applied. Only when the sum is greater in total than the power to operate the spool 18 in the closing direction, the spool 18 is moved and the valve passage is opened.

Thereby, the piston 4 and the piston rod 7 together with it can be moved into the cylinder 2.

When the operation is finished by the valve operating power, the valve passage is closed again, and the piston 4 is fixed at its captured position.

The embodiment according to FIG. 4 has the same overall structure as the embodiment according to FIGS. 1 to 3, and correspondingly has the same reference numeral.

Unlike the embodiments according to FIGS. 1 to 3, the poppet valve 19 is not arranged in the valve body, but rather in the piston 4.

When the valve passage is open, the first working chamber 5 is connected to the second working chamber 6 via a recess 20 and a radial bore 24.

The actuating tappet 14 is guided through the inside of the piston rod 7 by a guide bore 13.

1: tubular housing 2: cylinder
3: annular gap 4: piston
5: first working chamber 6: second working chamber
7: Piston Rod 8: Piston Rod Guide Part
9: radial opening 10: valve body
11: gap member 12: large step
13: guide bore 14: working tappet
15: Small Step 16: Fixed Washer
17: Nose 18: Spool
19: poppet valve 20: recess
21: flange-shaped extension 22: sealing ring
23: Zone 24: Radial Bore
25: lever 26: longitudinal axis
27: pivot axis 28: first arm
29: second arm 30: connecting member
31: part of the gap member 11 32: worm spring
33: screw compression spring

Claims (10)

A brakeable piston-cylinder unit with a cylinder, a piston rod and a valve,
At this time, the cylinder space of the cylinder is subdivided into a first working chamber and a second working chamber by a piston, and the working chambers are filled with the fluid under pressure, wherein the piston rod is the first or second working chamber. Protruding through the chamber and leading out of the cylinder in a sealed state, wherein the valve is capable of connecting the first working chamber to the second working chamber, the pressure of the first working chamber itself A closing member actuated to a closed position of the closure member, which may be operable to move from its closed position to its open position by means of valve actuation power outside the cylinder,
In a braking piston-cylinder unit,
The closing member is actuated in the open direction indirectly or directly by a spring element, supported by the cylinder 2 or a component firmly coupled to the cylinder 2, and subjected to a compressive stress, the compression of the spring element The stress is characterized in that it is smaller than the closing force acting on the closing member by the pressure inside the first working chamber 5,
Brakeable piston-cylinder unit.
The method of claim 1,
Characterized in that the closing member is operable to be moved from its closed position to its open position by means of an actuating element lead axially from the cylinder (2),
Brakeable piston-cylinder unit.
3. The method according to claim 1 or 2,
Characterized in that the closure member can be driven to be moved from its closed position to its open position indirectly or directly by manual operation,
Brakeable piston-cylinder unit.
The method according to any one of claims 1 to 3,
Characterized in that the actuation element is an actuation tappet 14,
Brakeable piston-cylinder unit.
The method according to any one of claims 1 to 4,
The spring element is a screw compression spring 33 which surrounds the closing member or the actuating element at intervals, one end of the screw compression spring being supported by a component securely connected to the cylinder 2, the screw The other end of the compression spring actuates the closure member or actuating element,
Brakeable piston-cylinder unit.
The method according to any one of claims 1 to 4,
The front face of the closing member or end of the actuating element projecting from the cylinder 2 extends in the transverse direction with respect to the longitudinal axis 26 of the cylinder 2 and is securely coupled to the cylinder 2. 27 can be actuated by a first arm 28 of a lever 25 that is pivotable about two arms, the lever 25 being operated against the front of the closure member or actuating element. It is characterized in that the first arm 28 is actuated by a spring element to exert an action, and the second arm 29 of the lever is actuated by valve actuation power,
Brakeable piston-cylinder unit.
7. The method according to any one of claims 1 to 6,
Characterized in that the valve is a poppet valve 19,
Brakeable piston-cylinder unit.
7. The method according to any one of claims 1 to 6,
Characterized in that the valve is a sliding valve,
Brakeable piston-cylinder unit.
The method according to any one of claims 1 to 8,
The valve is characterized in that it is arranged in the valve body 10 closing the cylinder 2 in the region at the end,
Brakeable piston-cylinder unit.
The method according to any one of claims 1 to 8,
Characterized in that the valve is arranged in the piston (4),
Brakeable piston-cylinder unit.

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