EP1214958A2 - Vibration damping device for skis etc. - Google Patents

Abstract

The shock absorber unit (7) has two shock absorber elements consisting of a cylinder and piston rod and relatively movable in a lengthwise direction against damping resistance and positioned on the ski's upper side. One of the damper elements is fixed on the ski (1) by a thrust-piece (2); the other element is detachably connected to another thrust piece (4). A coupling part (8) cooperates with a counter-coupling part adjustable between two positions.

Description

The invention relates to a device for damping Flex movements of a ski or sliding board, with a damper unit, which two in a longitudinal direction against damping resistance damping elements which can be displaced relative to one another has and on the top of the ski or gliding board is arranged.

Such a device is described in EP 0 492 658 A1 13 and 14 are shown. The damper unit is as double-acting hydraulic piston-cylinder unit, its cylinder and housing relative to flex movements can be moved towards each other, with an adjustable Throttle that hydraulically between two from the piston chambers arranged in the cylinder, hydraulic medium flows from one chamber to the other. By corresponding adjustment of the throttle can be different Damping resistance can be set.

The object of the invention is now in a device of type specified at the beginning in addition to a setting with clear Damping of flex movements of the ski or the like also one To enable setting at which the constructively specified Flex characteristics of the ski or the like. practically completely remains unchanged.

This task is accomplished with the device specified at the beginning solved in that the one element of the damper unit on a first on the ski or the like. attached or attachable Abutment held and the other element coupled with another abutment on and off which is in the longitudinal direction away from the first abutment on the ski or the like is attached or attachable.

The invention is based on the general idea of the damper unit to arrange on and off by one Damper element mechanically decoupled from the associated abutment or can be coupled with the abutment. In order to can be on the one hand between the two abutments Switch on damping-effective adhesion by one Damper element in its coupled state with the abutment brought. On the other hand, one is also practical Non-positive connection possible by the damper unit functionally mechanically separated from the abovementioned abutment becomes.

According to a preferred embodiment of the invention the other element of the damper unit in the longitudinal direction firmly connected to a coupling part, which with a between two end positions adjustable mating coupling part of the other abutment cooperates, the coupling part in one end position of the mating coupling part in the longitudinal direction held positively relative to the other abutment and in the other end position of the mating coupling part in Is movable in the longitudinal direction.

This ensures a simple construction in principle, the damper assembly is largely arbitrary, however, according to a preferred embodiment can be trained that so-called counterflex movements of the ski where the ends of the ski or Sliding boards down relative to the bond area swing, be effectively dampened during flex movements, where the ski ends move relative to the binding area move up, not or only slightly damped.

In a particularly expedient embodiment, the counter coupling part formed as a slide, which in one End position holds a claw of the coupling part positively and releases in its other end position.

In this case, the counter coupling part is provided in particular train as a rotary valve, which the claw in his engages an end position with a part of its peripheral wall as well as in the longitudinal direction and in its other end position the claw with a recess in its peripheral wall Longitudinal direction releases.

The rotary bearing of the rotary valve can be set using a link guide take place outside the axis of rotation is so that for the claw within the peripheral wall of the A correspondingly large space is available stands.

Furthermore, it is preferably provided to design the damper in such a way that that it is only so-called Counterflex movements of the ski, i.e. Movements of the Ski ends down relative to the ski center area, dampens. For this general thought, regardless of whether the damper can be uncoupled from one of its abutments or not, protection claimed.

Otherwise, with regard to preferred features of the invention to the claims and the following explanation referred to the drawing, based on a particularly preferred Embodiment is described in more detail.

Fig. 1

einen Längsschnitt durch die erfindungsgemäße Vorrichtung,

Fig. 2

einen Querschnitt entsprechend der Schnittebene II-II in Fig. 1,

Fig. 3

eine perspektivische Ansicht des Kupplungsteiles von schräg oben,

Fig. 4

eine perspektivische Ansicht des Gegenkupplungsteiles von schräg unten und

Fig. 5

eine perspektivische Schnittdarstellung eines erfindungsgemäßen Dämpfers.

It shows

Fig. 1

a longitudinal section through the device according to the invention,

Fig. 2

2 shows a cross section corresponding to the section plane II-II in FIG. 1,

Fig. 3

a perspective view of the coupling part obliquely from above,

Fig. 4

a perspective view of the mating coupling part from obliquely below and

Fig. 5

a perspective sectional view of a damper according to the invention.

1 is shown on a section Ski 1 is a first, essentially plate-shaped abutment part 2 arranged lying on the top of the ski. The The abutment part 2 is fixed on the ski 1 by means of a likewise substantially plate-shaped holding part 3, which is the right end of the abutment part 2 in FIG. 1 encompasses and with a toothing form-fitting in a counter toothing engages on abutment part 2. The holding part 3 is attached to the ski 1 with screws, not shown.

In the longitudinal direction of the ski from the holding part 3 is on the other Another abutment part 4 at the end of the abutment part 2 arranged, which is attached to the ski 1 with screws 5. In the abutment part 4, which, like the abutment part 2 and the holding part 3 is made of plastic, is made of metal existing sliding guide 6 embedded, cf. Fig. 2. This sliding guide 6 engages with C-shaped in cross section Wheels facing each other with their concave sides are, correspondingly shaped longitudinal edges of the abutment part 2, which changes when the ski flexes Ski longitudinal direction relative to the sliding guide 6 and the abutment part 4 moves. This is due to the fact that the abutment part 4 vertically away from the neutral bending zone the ski 1 arranged and in the longitudinal direction in a larger Distance from the sliding guide 6 by means of the holding part 3 is recorded.

Within a corresponding one extending in the longitudinal direction of the ski Recess of the abutment part 2 is a cylinder designed as a piston-cylinder unit hydraulic Damper 7 arranged under jamming or latching. The Piston rod of the damper 7 is with a coupling part 8 - see. also Fig. 3 - connected, which is in a corresponding Longitudinal channel on the underside of the abutment part 2 extends and under a molded on the abutment part 4 Guide plate 9 - cf. Fig. 1 - passes.

The coupling part 8 acts with a counter-coupling part 10 together, which in the manner shown below as Rotary valve designed and around a vertical pivot axis S - cf. Fig. 1 - is rotatably supported on the abutment part 4.

The elements for the rotary mounting of the mating coupling part 10 are arranged at a distance from the pivot axis S and include essentially one molded onto the abutment part 4 and in Fig. 1 visible arcuate web 11, which in a 4 clearly recognizable groove 12 on the underside of the mating coupling part 10 engages with play in the direction of the arc, i.e. the groove 12 forms a guide link for the web 11, such that the mating coupling part 10 between two End positions can be rotated. In addition, the counter coupling part engages 10 the guide plate 9 of the abutment part 4 with a radially outwardly projecting edge 13.

In the area of the pivot axis S is on the underside of the counter coupling part 10 a region radially outwards open recess 14 formed, in the corresponding Rotary position of the mating coupling part 10 Claw-shaped end 15 of the coupling part 8 remote from the damper can be inserted. By turning the Counter-coupling part 10 can be a locking piece molded thereon 16 in a bolt recess 17 next to the claw-shaped End 15 of the coupling part 8 are inserted. In this position, which is shown in Fig. 1, are Coupling part 8 and the mating coupling part 10 with each other coupled, i.e. the claw-shaped end 15 of the coupling part 8 is inside the recess 14 of the mating coupling part 10 held in the longitudinal direction of the ski, with the result that the piston rod of the damper 7 when flexing the Skis 1 is moved relative to the cylinder of the damper 7 and the damper 7 accordingly one of the flex movements counteracting damping resistance generated.

On the other hand, when the mating coupling part 10 in its other end position is rotated, the locking piece 16 of the counter-coupling part occurs 10 completely from the bolt recess 17 of the Coupling part 8 out, so that the claw-shaped end 15th the coupling part 8 is released and the coupling part 8 and the mating coupling part 10 are uncoupled from one another. If there is now flex movement of the ski 1, it will Coupling part 8 during the first flex movement with insertion the piston rod moved into the cylinder of the damper 7. However, the coupling part 8 is then moved Position by the resistance of the damper 7 more or less held, with the result that the damper 7 at does not perform any lifting movements and accordingly remains ineffective.

So that in turn a locking of the claw-shaped End 15 of the coupling part 8 in the mating coupling part 10 is possible, even if the claw-shaped End 15 a position outside the recess 14 of the mating coupling part 10 occupies, there is a ramp on the locking piece 16 18 formed with a counter ramp 19 on the claw-shaped End 15 of the coupling part 8 interacts and that claw-shaped end 15 with a corresponding rotation of the counter-coupling part 10 slides into the recess 14.

Instead of or in addition, it can also be provided that the piston rod of the damper 7 weak in the push-out direction is biased so that it from one in the cylinder crawl out of the damper 7 inserted position examined. This can ensure that the claw-shaped End 15 after a certain delay time again Position in the recess 14 of the mating coupling part 10 assumes and accordingly a rotary adjustment of the counter coupling part 10 with insertion of the locking piece 16 in the bolt recess 17 is made possible.

The rotational end positions of the mating coupling part 10 are as locking positions formed, in which, not shown, to the abutment part 4 molded locking elements with locking recesses 20 cooperate on the mating coupling part 10.

The top of the left end region in FIG. 1 of the abutment part 4 and the top of the holding part 3 are used for Inclusion of toe-side or heel-side shoe holder assemblies 21 a ski binding. These shoe holder assemblies 21 are indicated by dashed lines in FIG. 1. The invention Device for damping flex movements of a Skis or the like also takes on the function of a stand or Spacer plate for ski binding.

5 now shows a particularly preferred embodiment of the damper 7. This is a piston-cylinder unit with a cylinder 22 and a piston 23 displaceable therein formed with a piston rod 24 arranged on one side.

The cylinder 22 has a multiply stepped cylinder bore 25 which is at the right in Fig. 5 end of the cylinder 22 into a filling bore coaxial with the cylinder bore 25 26 continues, which is formed in one piece on the cylinder 22 Bottom 27 arranged and through a in the filling hole 26 pressed ball 28 is closed.

Within the portion of the cylinder bore adjacent to floor 27 25, which has a slightly smaller diameter than the central portion provided for the piston 23 Has cylinder bore 25 is a compressible foam body 29 with closed porous, gas-filled cell structure and a filling bore 26 which continues coaxially and completely penetrating the foam body 29 Axial bore held by an interference fit.

The foam body 29 can consist, for example, of cellular rubber or silicone foam with a density of approximately 0.5 g / cm ³ .

Between the outer periphery of the piston 23 and the inner periphery of the central portion of the cylinder bore receiving the piston 23 25 at least one throttle gap 30 is formed, over which the cylinder bore parts in front of and behind the piston 23 communicate with each other. There is also a piston 23 arranged axially stepped bore 31, with respect to the Diameter larger section arranged on the piston rod side is such that the opening cross-section is partially covered by a ring step 32 on the piston rod 24 becomes. Within the section of the stepped bore 31 with a larger diameter is one in the example shown spherical closing body 33 arranged with which the conical Ring step 34 of the step bore 31 in the manner of a valve seat cooperates, that is, the closing body 33, whose diameter is smaller than the diameter of the Closing body 33 receiving part of the stepped bore 31, and the ring stage 34 form a check valve, which opens at a pressure drop in the direction of the piston rod 24 and closes at the opposite pressure drop.

At the left end of the cylinder in FIG. 5 22 is a guide bush 35, e.g. from Delrin 100, for the Piston rod arranged. This bush 35 is axially between an inner cone on the cylinder 22 and a disc-shaped Soil 36 held by a flanged or with the bottom 36 pressed front edge of the cylinder 22 held becomes. The guide bush 35 is on the outside by an O-ring opposite the cylinder 22 and inside by a grooved ring the piston rod 24 sealed.

Piston 23 and piston rod 24 are in the example shown connected to each other in that the piston 23 with a centric axial bore on a threaded extension 37 of Piston rod 24 pushed on and by means of a thread extension 37 unscrewed nut 38 against the ring step 32 of the piston rod 24 is tensioned.

During manufacture, the damper 7 is completely prefabricated, however, without pressing the ball 28 into the filling bore 26. Before the subsequent filling, the piston rod 5 pulled out to the left so that the piston 23 reached its end position on the packing 35. Now the cylinder 22 through the filling bore 26 with hydraulic Medium filled. This filling can if necessary with overpressure. Then the filling bore 26 closed by means of the ball 28.

If the piston rod is now moved to the right in FIG. 5, the foam body 29 is increasingly elastically compressed, since the piston rod penetrating into the cylinder 22 24 Hydraulic medium displaced. The foam body 29 forms So a "volume buffer" through which the hydraulic medium kept bubble-free in the cylinder 22 and, if necessary is also kept under constant overpressure, independently on the temperature of the hydraulic medium. By the compressed foam body 29 is on the piston rod 24 a hydraulic restoring force exerted on the piston rod 24 with the piston 23 in Fig. 5 to the left in or tries to push almost to the left end position.

During the pressure stroke of piston 23 and piston rod 24, in FIG. 5 if this is the direction of movement to the right, it takes from Closing body 33 and the annular step 34 of the stepped bore 31 formed check valve its open position, so that the pressure stroke only a low hydrodynamic resistance counteracts. On the other hand, in the train stroke, this closes from the closing body 33 and the ring stage 32 check valve formed, so that those separated from each other by the piston 23 in the cylinder 22 Cylinder chambers only over the throttle gap or the throttle gap 30 between the outer circumference of the piston 23 and Communicate inner circumference of the cylinder 22 and a correspondingly high hydrodynamic resistance during the pull stroke occurs.

As a result, the pressure stroke becomes weak and the pull stroke pronounced or strongly damped.

If the damper 7 is arranged according to FIG. 1 and coupling part 8 and mating coupling part 10 with each other are coupled, piston 23 and piston rod 24 lead relatively to cylinder 22 during flex movements of the ski when the Move the ski ends upwards relative to the binding area, weakly damped pressure strokes. In contrast, counterflex movements occur of the ski when the ski ends are relative Move down to the binding area of the ski, heavily damped Lifting steps.

If the damper 7 is filled with hydraulic medium under excess pressure will, the foam body 29 in all positions the piston 23 and the piston rod 24 more or less compressed, i.e. the hydraulic medium is constantly under Overpressure. Accordingly, the seal package 35 constantly pressurized. This is beneficial because the sealing elements are always hydraulic on adjacent surfaces of the piston rod 24 or the cylinder 22 are pressed down and remain sealed.

Claims (19)

Device for damping flex movements of a ski (1) or the like., With a damper unit (7), which two in a longitudinal direction against damping resistance relative to each other movable damper elements (cylinder, piston rod) has and the like on the top of the ski. disposed is, the one element on a first firmly on the ski or the like. attached or attachable abutment (2) held and the other element with another abutment (4) is coupled and uncoupled, which in Longitudinal direction away from the first abutment on the ski or the like. is attached or attachable. Device according to claim 1,
characterized in that the other element is fixedly connected in the longitudinal direction to a coupling part (8) which interacts with a mating coupling part (10) of the other abutment (4) which can be adjusted between two end positions, the coupling part (8) in one end position of the mating coupling part (10) in the longitudinal direction relative to the other abutment (4) positively held and in the other end position of the mating coupling part (10) is movable in the longitudinal direction. Device according to claim 2,
characterized in that the counter-coupling part (10) is designed as a slide which, in one end position, holds a claw (15) of the coupling part (8) in a form-fitting manner and releases it in its end position. Device according to claim 3,
characterized in that the counter-coupling part (10) is designed as a rotary slide valve which engages behind the claw (15) in its one end position with a part (16) on its peripheral wall and holds it in the longitudinal direction and in its other end position the claw (15) with a Releases recess in its circumferential wall in the longitudinal direction. Device according to one of claims 1 to 4,
characterized in that the two abutments (2, 4) or the like are at a large distance from the ski (1) in comparison to the longitudinal extent of the damper unit (7). are held in the longitudinal direction. Device according to one of claims 1 to 5,
characterized in that the parts (2, 4) forming the abutments are slidably guided in the longitudinal direction. Device according to one of claims 1 to 6,
characterized in that the coupling part (8) is guided in a slide-like manner on at least one abutment part (2). Device according to one of claims 1 to 7,
characterized in that the one abutment part (2) adjustable in the longitudinal direction firmly on the ski (1) or the like. arranged or attachable holding part (3) is held. Device according to claim 8,
characterized in that the holding part (3) and the one abutment part (2) together form a base for receiving a ski binding with heel-side and toe-side shoe holder assemblies (21). Device according to one of claims 1 to 9,
characterized in that the damper unit (7) is weakly preloaded and tries to crawl into its one state in which the coupling part (8) and the counter-coupling part (10) can be coupled to one another. Device according to one of claims 1 to 10,
characterized in that the damper (7) designed as a piston-cylinder unit is held with its cylinder in a form-fitting or non-positive manner in a recess in one abutment part (2). Device according to one of claims 2 to 11,
characterized in that the end positions of the mating coupling part (10) can be locked. Device according to one of claims 1 to 12,
characterized in that a hydraulic damper (7), preferably with a gel or paste-like hydraulic medium, is provided. Device for damping flex movements of a ski (1) or sliding board, with a damper unit (7) which has two damper elements (cylinder, piston rod) which can be displaced relative to one another in a longitudinal direction against damping resistance and on the top of the ski or the like. is arranged, the one element on a first fixed to the ski or the like. attached or attachable abutment (2) held and the other element with another abutment (4) coupled and uncoupled or is constantly held on this further abutment, which in the longitudinal direction away from the first abutment on the ski or the like. is attached or attachable, in particular according to one of claims 1 to 13,
characterized in that the damper (7) dampens counterflex or rearflex movements of the ski (1) or sliding board exclusively or more intensely. Device according to claim 14,
characterized in that the damper (7) designed as a piston-cylinder unit has a piston rod (24) arranged on one side on the piston (23) and a compressible foam body (29) arranged in the cylinder, which is compressed during the pressure stroke of the piston rod and during the pulling stroke the piston rod expands elastically. Device according to claim 14 or 15,
characterized in that a throttle gap (30) or a throttle opening is formed or arranged between the outer circumference of the piston (23) and the inner circumference of the cylinder (22). Device according to one of claims 14 to 16,
characterized in that at least one check valve (32, 33) opening in the direction of the piston rod (24) is arranged in the piston (23). Device according to claim 17,
characterized in that the check valve (32, 33) is formed with a stepped bore (31) axially penetrating the piston (23) and a valve body (33) arranged in the part of the stepped bore which is further in diameter and which is located between the annular step acting as a valve seat ( 32) of the stepped bore and an edge (32) which is arranged on the outlet opening of the check valve and somewhat covers the outlet opening and is caught in a cage-like manner on the piston rod (24). Device according to one of claims 14 to 18,
characterized in that in the cylinder base (27) on the side of the cylinder (22) facing away from the piston rod (24) a filling opening (26) is arranged coaxially with an axial channel in the foam body (29) adjacent to this base.

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