DE102013101754A1 - Fluidic adjusting element e.g. hydro-pneumatic adjusting element used in backrest adjustment of seats in flight, has crash element that receives externally applied forces during overload condition and protects extensible piston rod - Google Patents

Abstract

The fluidic adjusting element (1) has a fluid-filled cylinder (2) that is provided with an extensible piston rod (6) filled with fluid and a piston (5). A crash element (11) is arranged for receiving externally applied forces during overload and for protecting the extensible piston rod. The crash element is designed and dimensioned for receiving forces and loads that occur during normal operation of the adjusting element. The crash element is designed as deformation element (12) for recording the overload force during overload deformation.

Description

The invention relates to a fluidic, in particular hydropneumatic adjusting element with the features in the preamble of the main claim.

Such a fluidic adjusting element with a fluid-filled cylinder, a piston and a piston rod is known from practice. Such adjusting elements are designed with their damping technology and their strengths to the forces acting in normal operation loads. Such e.g. hydropneumatic and lockable adjustment members are e.g. used for the backrest adjustment of seats in aircraft or vehicles. In case of accidents or the like. An overload case may occur, acting on the outside of the much higher forces on the adjustment. The usual and known adjustment fail in case of overload and are destroyed or so badly damaged, especially deformed that they can pose a source of danger to a passenger.

The DE 31 51 070 A1 shows a safety gas spring for hoods or trunk flaps of motor vehicles. This gas spring is arranged in a crumple zone region of the vehicle, wherein in the event of a body crash, the piston rod can be pushed further than normal in the cylinder, which could result in a correspondingly strong compression of the spring means increased reaction and Ausschubkräfte result. The safety gas spring is intended to prevent this and to prevent the body collision from extending the piston rod, which is achieved by a claw spring or a special piston rod seal. The gas spring itself is not protected against overloading.

The DE 197 27 931 A1 and the EP 0 473 955 A2 deal with impact absorbers for motor vehicles, which are inactive during normal driving and only come into effect during vehicle crash.

A piston-cylinder unit of a vibration damper is in the DE 10 2009 025 142 A1 addressed, which has an end cap which communicates with an additional spring means of the vibration damper. By venting burrs in the cap, compressed air from the cap may be recirculated back to atmosphere upon impact of the auxiliary spring means. This is to prevent ingress of the compressed air into the working space of the cylinder. An overload protection is not effected.

From the DE 1 284 692 A For example, there is known a shock absorbing post for a seat that has two interengaging cylinders an inner support spring and grooves with a spring loaded shear pin.

The DE 198 09 389 C1 relates to a length-adjustable column for furniture, wherein in the column tube, a gas spring is arranged, the piston rod is movably connected via a thrust bearing with a bottom plate of the column.

It is an object of the invention to show a better adjustment.

The invention solves this problem with the features in the main claim.

With the invention, the use of a crash element is proposed, which absorbs the externally applied forces in case of overload and protects the other components of the adjustment. The crash element intercepts the e.g. occurring in a collision and an extreme negative acceleration pulse and gives the adjustment time for the retraction of the piston rod.

The claimed fluidic adjustment has the advantage that it can be designed and dimensioned to the forces and loads occurring during normal operation, wherein the crash element is the assurance and protection for the overload case. The adjusting element does not have to be oversized. This saves construction costs, size and costs. This is especially for the use in seat reclining advantageous in which the space is limited, on the other hand can affect the passenger weight and the backrest in accidents very high negative accelerations and correspondingly high forces from the outside.

There are various possibilities for the formation of the crash element. In particular, the crash element may be formed as a deformation element, which provides a deformation path for power absorption and for buckling and fracture protection of the piston rod in case of overload and otherwise is dimensionally stable. It can collapse especially in case of overload. By a deformation gradient, the deformation can be designed force-dependent. On the other hand, can be done by such a gradient, an appropriate force distribution, which is favorable for a simultaneous retraction of the adjusting element and its piston rod. The deformation element can act as a buffer that provides the deformation path itself. It can also act as an opening closure, which is deactivated in case of overload in its closing function, in particular destroyed and causes a deflection of the fluid associated with a substantial facilitation of the retraction movement of the piston rod.

In another variant, the crash element may be formed as a support tube, which the stabilized extended piston rod and protects against buckling to pressure load.

In the subclaims further advantageous embodiments of the invention are given.

The invention is illustrated by way of example and schematically in the drawings. In detail show:

1 : A hydro-pneumatic adjusting element with a deformable crash element,

2 to 4 : Variants too 1 with other deformable crash elements and

5 An adjusting element with a crash element designed as a support tube.

The invention relates to a fluidic adjustment element ( 1 ) and its education.

Such a fluidic adjustment element ( 1 ) is in 1 to 5 shown in various embodiments. It is designed, for example, as a hydropneumatic adjusting element or as a gas spring. The adjusting element ( 1 ) has a cylinder filled with a fluid, eg a compressed gas or an oil-gas mixture ( 2 ), in which a piston ( 5 ) together with a piston rod ( 6 ) with a central axis ( 7 ) is arranged. The piston divides the interior of the cylinder into chambers ( 8th . 9 ) on. For the passage of fluid from one chamber to the other ( 8th . 9 ), a bypass (not shown) is provided, which can develop a throttling or damping effect and, if necessary, with a blocking mechanism ( 10 ) is closed together with valve. The piston rod can be used with the actuatable locking mechanism ( 10 ) are locked in different extended positions.

The cylinder ( 2 ) is designed as a pressure tube, which holds, for example, in the case of a hydropneumatic gas spring and very high internal pressures stand. The cylinder ( 2 ) is at the front with an end wall ( 3 ), which has a passage opening with a guide and a seal for the exit of the piston rod ( 6 ) having. At the back is the cylinder ( 2 ) through a floor ( 4 ) locked. The cylinder ( 2 ) also has suitable connections for mounting or storage.

In the embodiment shown, the hydropneumatic adjusting element ( 1 ) for reclining installation and for use on a backrest adjustment of a seat in an aircraft or vehicle. By the body weight of the passenger in the backrest adjustment, for example, forces of up to about 15 kN on the adjustment ( 1 ) from the outside. In the case of an accident, very high negative accelerations, for example of approximately 16 g, can occur in aircraft, which can result in significantly higher impulsive loads and forces of, for example, up to approximately 40 kN. After seats are installed in or against the direction of travel or movement, the relevant loads and forces in the extension and retraction can act as compressive or tensile forces.

For compressive forces, the piston rod ( 6 ) loaded on pressure. Because of damping and the corresponding inertia of the retraction movement of the piston ( 5 ) and the piston rod ( 6 ) exists in the aforementioned extremely high and very short-term pulse-like stress kinking for the piston rod ( 6 ). The same applies to a blockable adjustment ( 1 ). These occur in an accident, especially in an impact of a very fast moving vehicle or aircraft on a stationary obstacle impulsive loads represent the so-called. Overload.

To safeguard against such an overload case, the adjusting element ( 1 ) a crash element ( 11 ), for that in the 1 to 5 various embodiments are given. The crash element ( 11 ) absorbs the external forces acting on overload and protects the other components of the adjusting element ( 1 ), in particular the piston rod ( 6 ). In particular, this can be forces with a predominant direction component in the axial direction of the piston rod (FIG. 6 ) be. In particular, the crash element ( 11 ) the pulse occurring in a collision and an extreme negative acceleration and gives the adjusting time for a possible retraction movement of the piston rod ( 10 ). The fluidic adjustment element ( 1 ) can otherwise be designed and dimensioned in terms of its design and dimensioning to the forces and loads occurring in the aforementioned normal load.

In the embodiments of the 1 to 4 is the crash element ( 11 ) as a deformation element ( 12 ), which provides a deformation path for the pulse and power consumption in case of overload. As a result, in the event of overload, the extended piston rod ( 6 ) relieved and protected against buckling and breakage. The deformation element ( 12 ) has a matched to the overload case and the particular application load threshold, which is dimensionally stable at loads and forces below this threshold and deformed when the threshold is exceeded very quickly, in particular collapses. The threshold can be defined by a breaking strength on pressure.

The deformation element ( 12 ) may have a deformation gradient in the loading direction. In particular, it can be a deformation resistance which increases in load direction of action so that it initially deforms more slowly and more slowly with increasing travel, or that the deformation resistance increases with progressive deformation in the loading direction of action.

The deformation element ( 12 ) may consist of any suitable material having the properties described above. In a preferred embodiment, a technical foam is provided. This can be carried out, for example, on the basis of plastics and / or light metals. As light metals are particularly suitable aluminum, magnesium and their alloys. The technical foam can also consist of other suitable materials, in particular also of composite materials.

To form a deformation gradient, the technical foam may have a density gradient. In particular, it can have a foam density which increases in the direction of loading and which builds up an increasing deformation resistance or an increasing breaking strength in this effective direction.

The deformation element ( 12 ) can act in different ways. It can on the one hand a buffer ( 13 ), which itself provides the deformation path. On the other hand, the deformation element ( 12 ) as an opening closure ( 14 ) is formed, which is deactivated in case of overload, in particular destroyed and an escape of the fluid in cylinder ( 2 ) and thus a reduction of the resistance against a retraction movement of pistons ( 5 ) and piston rod ( 6 ).

In the embodiment of 1 is the deformation element ( 12 ) in the interior of the cylinder ( 2 ) and located in the bottom area behind a support piston ( 15 ). In case of overload, the piston rod ( 6 ), The piston ( 5 ) and the fluid as a rigid body and direct the impulsive load or axial force on the support piston ( 15 ) and further on the deformation element ( 12 ). This acts as a buffer ( 13 ) and deforms abruptly under this load, in particular collapsing, reducing its volume and thereby retracting the piston rod ( 6 ).

In the embodiment of 2 is the deformation element ( 12 ) on the outside and in the load acting direction behind the cylinder ( 2 ) arranged. It is located in a cup-shaped outer cylinder ( 16 ), which the cylinder ( 2 ) at the rear and in a part of its rear jacket area. The deformation element ( 12 ) is located between the floor ( 4 ) of the cylinder ( 2 ) and the bottom of the outer cylinder ( 16 ).

The outer cylinder ( 16 ) is with the cylinder ( 2 ) by a resilient in load action connection ( 17 ) connected. As a result, in the case of overloading during a deformation and in particular a collapse of the deformation element ( 12 ) the cylinder ( 2 ) in total in the outer cylinder ( 6 ) dive deeper and thereby absorb the impulse. The deformation element ( 12 ) is again in this case as a buffer or as a pressure pad ( 13 ) educated.

The connection ( 17 ) is designed as a latching connection, for example. On the mantle of the cylinder ( 2 ) is a form-fitting, for example, designed as a spring ring locking element ( 18 ), which in an opening on the inner surface of the outer cylinder ( 16 ) engages positively. This opening has an oblique and the bottom side to the rear facing sliding surface ( 19 ), which allows said immersion movement. The ring ( 18 ) may be formed, for example, as a spring ring, which gives way radially in this movement and evades.

In the embodiment of 3 is the cylinder ( 2 ) from an outer cylinder ( 16 ) surrounded by a radial distance, whereby a receiving space ( 21 ) for the cylinder ( 2 ) and in particular in its rearward inner chamber ( 9 ) fluid is formed. The mantle of the cylinder ( 2 ) forms a partition ( 20 ) opposite the outside receiving space ( 21 ), which has an overflow opening ( 22 ) between the inner chamber ( 9 ) in the reception room ( 21 ) having. In the overflow opening ( 22 ) is the deformation element ( 12 ), which in this variant an opening closure ( 14 ). In case of overload, the deformation element collapses ( 12 ) under the increased pressure and gives the Überstömöffnung ( 22 ) free. The fluid can suddenly escape from the inner chamber ( 9 ) in the exception room ( 21 ) and allows a retraction movement of the piston ( 5 ) and the piston rod ( 6 ).

4 shows a variant of 3 in which the receiving space ( 21 ) in the interior of the cylinder ( 2 ) is arranged and at the bottom area behind a transverse partition ( 20 ) is located. The partition ( 20 ) is positively and by an embossing or other suitable manner in the cylinder ( 2 ) held. It has eg a central overflow opening ( 22 ) with a deformation element ( 12 ) or an opening closure ( 14 ) on. In case of overload, the opening closure collapses ( 14 ) and leaves the fluid from the rearward inner chamber ( 9 ) in the reception room ( 21 ) flow, which allows the said retraction movement.

5 shows another embodiment of a crash element ( 11 ). This is a dimensionally stable support tube ( 23 ) formed on the mantle of the cylinder ( 2 ) is supported and guided. The guide is tilt-proof and as push fit ( 25 ) educated. On the other hand, the support tube ( 23 ) with the out of the cylinder ( 2 ) projecting piston rod ( 6 ) via a connection ( 26 ) rigidly connected. This connection is stable even in case of overload, so that the pulse-like forces introduced by the piston rod ( 6 ) on the support tube ( 23 ) be transmitted. The support tube ( 23 ) has a thickness-reinforced bottom ( 24 ), which absorbs the forces acting and leads to the support tube shell. The support tube ( 23 ) surrounds the piston rod ( 6 ) with a radial distance and acts as a kink protection. In this embodiment of the crash element ( 11 ), the dimensional stability of the adjusting element ( 1 ) ensured even in case of overload and a cancel or otherwise undesirable deformation or destruction of the adjusting element ( 1 ) prevented. As a result, even in case of overload, no danger to a passenger from the adjustment ( 1 ) go out.

Modifications of the embodiments described are possible in various ways. The features of the different variants can be interchanged or combined with each other. In particular, an adjusting element ( 1 ) several crash elements ( 11 ) have the same or different types. On one in 5 indicated blocking mechanism ( 10 ) can be omitted. An adjusting element ( 1 ) can also be modified in terms of its function and design training. It can be filled with another fluid, in particular a liquid, eg oil, or a combination of a gas and a liquid. It can be designed as a shock absorber. Furthermore, a separating piston may be present. A bypass for a fluid transfer can in the piston rod ( 6 ) and / or in the piston ( 5 ) can be arranged. Alternatively, an arrangement on the cylinder bottom area in conjunction with an inner chamber located behind it is possible. The cylinder ( 2 ) can also be designed as a double cylinder or in another suitable manner. The fluidic adjustment element ( 1 ) can also be used in other areas, except for backrest adjustments.

LIST OF REFERENCE NUMBERS

1

 Adjustment element hydropneumatic, gas spring

2

 Cylinder, pressure tube

3

 bulkhead

4

 ground

5

 piston

6

 piston rod

7

 Axis, cylinder axis

8th

 inner chamber

9

 inner chamber

10

 blocking mechanism

11

 crash element

12

 deformation element

13

 Buffer, pressure pad

14

 opening closure

15

 support piston

16

 outer cylinder

17

 Connection, locking connection

18

 Locking element, ring

19

 Sliding surface at an angle

20

 partition wall

21

 accommodation space

22

 overflow

23

 support tube

24

 ground

25

 Leadership, fit

26

 Connection, thread

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3151070 A1 [0003]
• DE 19727931 A1 [0004]
• EP 0473955 A2 [0004]
• DE 102009025142 A1 [0005]
• DE 1284692 A [0006]
• DE 19809389 C1 [0007]

Claims (19)

Fluidic, in particular hydropneumatic adjusting element which comprises a cylinder filled with a fluid ( 2 ) with an extendable piston rod ( 6 ) and a piston ( 5 ), characterized in that the adjusting element ( 1 ) a crash element ( 11 ), which absorbs externally acting forces in case of overload and the other components of the adjusting element ( 1 ), in particular the extended piston rod ( 6 ) protects. Adjusting element according to claim 1, characterized in that the crash element provided for the overload case and the adjusting element ( 1 ) is designed and dimensioned to the forces and loads occurring during normal operation. Adjusting element according to claim 1 or 2, characterized in that the crash element ( 11 ) as a deformation element ( 12 ) is formed, which provides in case of overload deformation path for receiving power. Adjusting element according to claim 1, 2 or 3, characterized in that the deformation element ( 12 ) has a load threshold matched to the overload case, wherein the deformation element ( 12 ) is dimensionally stable under loads below the threshold. Adjusting element according to one of the preceding claims, characterized in that the deformation element ( 12 ) collapsed at loads above the threshold. Adjusting element according to one of the preceding claims, characterized in that the deformation element ( 12 ) has a deformation gradient in the loading direction. Adjusting element according to one of the preceding claims, characterized in that the deformation element ( 12 ) has a deformation strength which increases in the direction of loading. Adjusting element according to one of the preceding claims, characterized in that the deformation element ( 12 ) consists of a technical foam, in particular a plastic and / or light metal foam. Adjusting element according to one of the preceding claims, characterized in that the technical foam has a density gradient, in particular a foam density increasing in the direction of load effect. Adjusting element according to one of the preceding claims, characterized in that the deformation element ( 12 ) as a buffer ( 13 ) or as an opening closure ( 14 ) is trained. Adjusting element according to one of the preceding claims, characterized in that the deformation element ( 12 ) in the cylinder ( 2 ) is arranged. Adjusting element according to one of the preceding claims, characterized in that the deformation element ( 12 ) in the cylinder ( 2 ) at the bottom area behind a support piston ( 15 ) is arranged. Adjusting element according to one of the preceding claims, characterized in that the deformation element ( 12 ) behind the cylinder ( 2 ) in an outer cylinder ( 16 ) is arranged, which the cylinder ( 2 ) surrounds the back. Adjusting element according to one of the preceding claims, characterized in that the outer cylinder ( 16 ) with the cylinder ( 2 ) by a resilient in load action connection ( 17 ), in particular latching connection, is connected. Adjusting element according to one of the preceding claims, characterized in that the deformation element ( 12 ) in an overflow opening ( 22 ) a partition wall ( 20 ) of the cylinder ( 2 ) to a recording room ( 21 ) is arranged for the fluid. Adjusting element according to one of the preceding claims, characterized in that the receiving space ( 21 ) in the bottom area of the cylinder ( 2 ) or in a surrounding outer cylinder ( 16 ) is arranged. Adjusting element according to claim 1, characterized in that the crash element ( 11 ) as a dimensionally stable support tube ( 23 ) is formed, which with the piston rod ( 6 ) via a connection ( 26 ) is rigidly connected and on the cylinder ( 2 ) with a push fit ( 25 ) is guided tip over. Adjusting element according to claim 17, characterized in that the support tube ( 23 ) a reinforced floor ( 24 ) and a stable connection ( 26 ), which withstand the external forces acting in case of overload. Adjusting element according to one of the preceding claims, characterized in that the adjusting element ( 1 ) an actuatable locking mechanism ( 10 ) having.

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