EP3246077A1 - Pivot for a skateboard - Google Patents

Abstract

Pivoting device (1) for a skateboard (6), wherein the pivoting device comprises a below a skateboard deck of the skateboard attachable base part (2) and a pivoting part (3) on which a first driving axis of the skateboard can be arranged, wherein the pivoting part about a pivot axis (5) relative to the base part is pivotable and a first end (8) of a torsion spring element (7) with the base part and a second end (9) of the torsion spring element with the pivot member is at least in operative contact, wherein a value of a force and / or a pivot angle with respect to a pivoting of the pivot part relative to the base part of a value of a variable by a change in position of the first and / or the second end of the torsion spring element spring rate of the torsion spring element is dependent.

Description

The invention relates to a swiveling device for a skateboard, wherein the swiveling device comprises a base part, which can be attached below a skateboard deck of the skateboard, and a pivoting part, to which a first, preferably a front, driving axis of the skateboard can be arranged.

Such swivel devices are known from the prior art. The pivoting movement of the pivoting part is sprung according to the prior art by means of a tension or compression spring. However, such pivoting devices have the serious disadvantage that the spring rate of the built-in spring can not be set or can only be set with great difficulty in order to adjust and adjust the handling behavior of the skateboard according to the needs of the skater.

It is therefore the object of the present invention to provide a pivoting device for a skateboard, by means of which the pivoting behavior of the pivoting part relative to the base part is to be influenced by a simple and quickly performed Federratenverstellung the built-in spring.

The object is achieved according to the features of claim 1.

The object is accordingly achieved by a pivoting device for a skateboard, wherein the pivoting device a below a skateboard deck of the skateboard attachable base part and a pivot member to which a first axis of the Skateboards is arranged, comprises, wherein the pivoting part about a pivot axis relative to the base part is pivotable and a first end of a torsion spring element with the base part and a second end of the torsion spring element with the pivoting part is at least in operative contact, wherein a value of a force and / or a Pivoting angle with respect to a pivoting of the pivoting member relative to the base part of a value of a variable by a change in position of the first and / or the second end of the torsion spring element spring rate of the torsion spring element is dependent.

Alternatively or cumulatively, the spring rate of the torsion spring element can also be changed by a change of an attack point of the force on the first and / or the second end of the torsion spring element.

By changing the point of application of the force on the first and / or the second end of the torsion spring element, the corresponding engaging lever changes, which consequently changes the torque and thus also changes the spring rate of the torsion spring element.

The term "swivel angle" is to be understood here as meaning the angle which the swivel part occupies after swiveling relative to the base part. In particular, the angle between a longitudinal extent of the pivoting part and a longitudinal extent of the base part is arranged. The larger the swing angle, the farther the swing member has been pivoted relative to the base member in a circumferential direction.

The same applies to the concept of force, wherein the force is the force that is needed to pivot the pivoting member relative to the base part. If, for example, the spring rate has been increased, then more force is needed overall to deflect the pivoting part by the same angle of rotation.

The pivot axis is particularly preferably a real pivot axis. In particular, it is also conceivable that the pivoting part is mounted pivotably about at least two pivot axes, for example by means of a pivoting head, whereby a three-dimensional pivotal movement of the pivoting part is possible.

According to a particularly advantageous embodiment, the torsion spring element is arranged at least partially around the pivot axis, wherein a longitudinal extension of the torsion spring element coincides with a longitudinal extent of the pivot axis.

By such an arrangement of the torsion spring element, the space requirement can be reduced, so that overall the pivoting device can be built smaller and more compact in size.

It is according to a further embodiment preferred that the torsion spring element is a leg spring having a first and a second leg, wherein the first leg corresponds to the first end of the torsion spring element and the second leg to the second end of the torsion spring element.

In particular, a leg spring can be arranged particularly easily and simply around the pivot axis. Furthermore, a leg spring is advantageous in that the spring rate can be changed particularly simply or advantageously by changing the position of the first and second legs.

In particular, stepless or non-stepless position changes to the spring rate change are conceivable.

According to a further particularly preferred embodiment, the first and the second end of the torsion spring element with the base part and the pivot member are particularly easy to bring into operative contact, when the first end of the torsion spring element with at least a first Federendeneinhängung and the second end of the torsion spring element with at least one second Federendeneinhängung connectable is, wherein the first Federendeneinhängung is arranged on the base part and the second Federendeneinhängung on the pivoting part.

In particular, it is conceivable that by means of Federendeneinhängungen preferably also subsequently the spring is replaceable, since the ends of the torsion spring element with the Federendeneinhängungen can be detachably connected. However, it is also conceivable that the ends of the torsion spring element can also be permanently connected to the Federendeneinhängungen.

According to a first possible embodiment variant of the change in position of the first and / or the second end of the torsion spring element, it is conceivable that at least two first Federendeneinhängungen and at least two second Federendeneinhängungen are provided which are each formed as a recess and the first and second ends of the torsion spring element itself extend in a longitudinal direction of the torsion spring member or at an angle to the longitudinal direction and the first end engages in a first Federendeneinhängung and the second end in a second Federendeneinhängung, wherein by a transfer of the first end and / or the second end in one of the respective end corresponding spring input mounting the spring rate of the torsion spring element is variable.

This means that both the base part and the pivoting part have recesses, which may be configured, for example, as bores or the like. In particular, the recesses extend in a height direction and in particular perpendicular to a longitudinal extension of the skateboard or at an angle to the height direction and / or at an angle to the longitudinal extent of the skateboard. In particular, the longitudinal extent of the skateboard coincides with the longitudinal extent of the base part.

The torsion spring element in this case has a first and a second end, which extend in the longitudinal extent of the torsion spring element. If in this case the torsion spring element is advantageously designed as a leg spring, which has a first and a second leg, then the two legs are bent in an end region in such a way that the respective ends extend into the longitudinal extent of the torsion spring element, in the present case the leg spring. By such a configuration, the ends of the torsion spring element can be particularly easily introduced into the corresponding recesses, so that the ends engage in the recesses.

In addition, in such an embodiment of the pivoting device, the spring rate can be changed particularly easily by the first end and / or the second end of the torsion spring element, in particular the leg spring, is transferred from a recess of the base part and / or pivot part in a further recess. For example, the first end of the torsion spring element is transferred from a recess of the base part into another recess of the base part, whereby the spring rate of the torsion spring element is variable.

Alternatively or cumulatively, the second end of the torsion spring element can be correspondingly transferred from a recess of the pivoting part into another recess in the base part, whereby a change in the spring rate is likewise accompanied.

Particularly advantageously, the recesses of the base part and of the pivoting part are arranged in a circumferential direction about the pivot axis. Particularly advantageously, the recesses are arranged such that the ends of the torsion spring element are arranged at a positional adjustment of the ends on a circumferential direction of the torsion spring element, since the torsion spring ends are not changed about the pivot axis per se in position, but about a fictitious pivot axis which does not the pivot axis of the pivoting part coincides.

According to an alternative and also preferred embodiment, the first Federendeneinhängung as a first threaded sleeve and the second Federendeneinhängung as a second threaded sleeve, each with an external thread formed, wherein the first end of the torsion spring member with the first threaded sleeve and the second end of the torsion spring member with the second Threaded sleeve is operatively connected such that the ends are insertable into a corresponding interior of the associated threaded sleeve and the first threaded sleeve in at least one corresponding internal thread of the base part and the second threaded sleeve in at least one corresponding internal thread of the pivoting part can be screwed, wherein by a transfer of the first threaded sleeve the first end of the torsion spring element and / or the second threaded sleeve with the second end of the torsion spring element in one of the respective threaded sleeve corresponding further internal thread the spring rate of the torsion spring element v is changeable.

Instead of a threaded sleeve and similar elements can be used, which fulfill the same purpose.

Preferably, at least two internal threads are provided for the pivoting part and the base part. Under an internal thread is to be understood in particular that areas of the pivoting part and the base part are provided, which have an internal thread such that the threaded sleeve is screwed into this internal thread.

The internal threads are in this case designed such that when unscrewing the Federendeneinhängungen by a simple advancing the Federendeneinhängung the Effective contact between the Federendeneinhängung and the corresponding end of the torsion spring element does not need to be solved. It is therefore advantageous if the internal threads are interconnected by at least one gap, wherein the end of the torsion spring element can move in this gap.

The threaded sleeve, which is at least in operative contact with one end of the torsion spring element, in this case has an external thread and an interior, wherein in the interior of the threaded sleeve, the respective end of the torsion spring element can be introduced.

According to a further alternative embodiment, the first and second Federendeneinhängung each have a linearly displaceable support member with a plurality of juxtaposed tooth elements, wherein the tooth elements are in operative contact with a rotatably mounted about a rotation axis rotary spindle and by means of rotation of the rotary spindle, the support member is linearly displaceable, whereby the position of the first and / or the second end is variable and thereby the spring rate of the torsion spring element.

Particularly advantageously, the linearly displaceable support member is guided safely by means of a guide in a linear displacement. Further advantageously, a locking of the rotary spindle is provided in order to exclude an undesirable spring rate setting can.

According to this embodiment, upon rotation of the rotary spindle, which preferably has a thread, which are operatively connected to the tooth elements of the support member, thereby the support member linearly shifted and correspondingly changed the position of the corresponding end of the torsion spring element and thereby changed according to the spring rate of the torsion spring element.

According to a further preferred embodiment, the first and the second Federendeneinhängung each formed by a rotation in a threaded linearly displaceable element, wherein the first and the second end of the torsion spring member are in operative contact with the element and by a displacement of the elements, the position of the first and / or second end is variable and thereby the spring rate of the torsion spring element.

As a result, the spring rate can be adjusted in a particularly simple manner by simply displacing the element or elements. A shift of the element is hereby brought about by a rotation of the element in the thread, for example, this is a screw, a threaded sleeve or the like, so that by using a screwdriver, an Allen or the like, the element can be moved.

Particularly advantageously, a corresponding end of the torsion spring element is moved by moving the corresponding element, wherein the end can be introduced into the thread. Preferably, the corresponding end has a constant position with respect to the thread until the element is brought into operative contact with the associated element and the element is moved in position by displacement of the element.

According to a particularly preferred embodiment, the pivoting part and / or the base part is connected via at least one ball bearing with the pivot axis. As a result, the pivoting of the pivoting part relative to the base part is reduced in total friction and the pivoting part also less tilted with the pivot axis, so that a trouble-free movement can be ensured.

Alternatively or cumulatively, a rolling bearing, a cylindrical roller bearing, a needle bearing, a tapered roller bearing or a roller bearing can be provided instead of the ball bearing.

According to a further preferred embodiment, a blocking device is provided, which is connectable to the base part and the pivoting part in order to prevent a pivoting movement of the pivoting part relative to the base part.

For example, the blocking device can be at least one screw connection, by means of which the base part and the pivoting part can be screwed together and whereby, correspondingly, a pivoting movement of the pivoting part relative to the base part can be prevented.

According to a further preferred embodiment, by means of a movement of the first and / or the second Federendeneinhängung along a longitudinal direction of the point of application of the force on the first and / or the second end of the torsion spring element variable, whereby the spring rate of the torsion spring element is variable.

Preferably, the first and second Federendeneinhängung each have an external thread and are each with a thread with a matching to the external thread Internal thread connectable, wherein the longitudinal direction corresponds to the longitudinal direction of the thread.

Alternatively, it is also conceivable that instead of the thread by means of at least one rail device, the first and / or the second Federendeneinhängung along a longitudinal direction of the rail device are movable to change the point of application of force to the first and / or the second end of the torsion spring element, thereby Here, too, the spring rate of the torsion spring element is variable.

In this case, the first and / or the second end of the torsion spring element extend in a particularly advantageous manner in the longitudinal direction of the thread or of the rail device.

Further advantageous embodiments will become apparent from the dependent claims.

Fig. 1

die Schwenkvorrichtung in einer Seitenansicht;

Fig. 2A

die Schwenkvorrichtung gemäß Figur 1 in einer unverschwenkten Stellung;

Fig. 2B

die Schwenkvorrichtung gemäß Figur 2A in einer verschwenkten Stellung;

Fig. 3A

eine Ausführungsform eines Drehfederelements;

Fig. 3B

das Basisteil in einer Draufsicht;

Fig. 3C

das Schwenkteil in einer Draufsicht;

Fig. 4A

die Schwenkvorrichtung gemäß einer weiteren Ausführungsform in einer Seitenansicht;

Fig. 4B

eine perspektivische Ansicht einer Gewindehülse;

Fig. 4C

die Schwenkvorrichtung gemäß Figur 4A in einer Draufsicht;

Fig. 4D

einen Ausschnitt der Schwenkvorrichtung in einer Seitenansicht gemäß Figur 4C;

Fig. 5A

die Schwenkvorrichtung gemäß einer weiteren Ausführungsform;

Fig. 5B

die Schwenkvorrichtung gemäß Figur 5A in einer Draufsicht;

Fig. 6A

die Schwenkvorrichtung gemäß einer weiteren Ausführungsform;

Fig. 6B

eine alternative Ausführungsform der Figur 6A;

Fig. 7

die Schwenkvorrichtung mit einer Vorrichtung zum Verändern des Angriffspunktes der Kraft auf das erste und zweite Ende des Drehfederelements.

Other objects, advantages and advantages of the present invention will become apparent from the following description taken in conjunction with the drawings. Hereby show:

Fig. 1

the pivoting device in a side view;

Fig. 2A

the swivel device according to FIG. 1 in an unpivoted position;

Fig. 2B

the swivel device according to FIG. 2A in a pivoted position;

Fig. 3A

an embodiment of a torsion spring element;

Fig. 3B

the base part in a plan view;

Fig. 3C

the pivoting part in a plan view;

Fig. 4A

the pivoting device according to another embodiment in a side view;

Fig. 4B

a perspective view of a threaded sleeve;

Fig. 4C

the swivel device according to FIG. 4A in a plan view;

Fig. 4D

a section of the pivoting device in a side view according to FIG. 4C ;

Fig. 5A

the pivoting device according to another embodiment;

Fig. 5B

the swivel device according to FIG. 5A in a plan view;

Fig. 6A

the pivoting device according to another embodiment;

Fig. 6B

an alternative embodiment of the FIG. 6A ;

Fig. 7

the pivoting device with a device for varying the point of application of the force to the first and second ends of the torsion spring element.

The FIG. 1 shows a pivoting device 1 according to a preferred embodiment in a side view, but without a representation of a Federratenverstellung, which is shown in more detail in the following figures, wherein the base part 2 is disposed below a skateboard deck 6, in particular is arranged stationary. The base part 2 is in this case screwed to the deck 6 by means of the standard bore existing on skateboard decks, so that the base part 2 is arranged stationarily opposite the skateboard deck 6.

As can also be seen, a pivoting part 3 is pivotally connected by means of a pivot axis 5 with the base part 2, wherein a torsion spring element 7 is further provided to pivot a pivoting of the pivoting part 3 relative to the base part 2 and in particular recover after a successful pivoting of the pivoting part 3 with respect to the base part 2.

Furthermore, it can be seen that a first driving axle 4 is arranged on the pivoting part 3, on which driving axle 4, in particular wheels (not shown here) can be fastened. The first drive axle 4 is particularly preferably the front axle of the skateboard, seen in the longitudinal direction.

The FIGS. 2A and 2 B show in this case the pivoting device 1 in a non-pivoted position and in a pivoted position, ie in a position in which the pivoting part. 3 is not pivoted relative to the base part 2, and in a position in which the pivoting part 3 is pivoted relative to the base part 2.

The FIG. 2A shows the pivoting device 1 in a non-pivoted position, ie, the pivot member 3 is compared to the base part 2 in a first position in which the torsion spring element 7 is not deflected, that is not deflected by external forces acting on the spring element 7. In particular, the longitudinal direction LB of the base part 2 corresponds to the longitudinal direction of the pivoting part LS.

In addition, it can be seen that the torsion spring element 7 is designed as a leg spring and is arranged at least partially around the pivot axis 5, the longitudinal extension LF of the torsion spring element 7 corresponding to the longitudinal extent LA of the pivot axis.

The FIG. 3A shows an advantageous embodiment of the torsion spring element 7, in particular when the torsion spring element 7 is designed as a leg spring 7. As can be clearly seen, the first 8 and the second end 9 extend in the longitudinal extension LF of the torsion spring element 7.

Such a configuration of the torsion spring element 7, as in the FIG. 3A is shown particularly advantageous for the design of the base part 2 and the pivoting part 3 according to the FIGS. 3B and 3C , wherein the base part 2 in the FIG. 3B and the swivel part 3 in the FIG. 3C is shown.

As can be seen, the pivoting part 3 and the base part 2 are pivotally connected to each other by means of the pivot axis 5, wherein about the pivot axis 5 around the leg spring 7 as in the FIG. 3A is shown arranged such that the longitudinal extent LF of the leg spring 7 of the longitudinal extent LA of the pivot axis 5 corresponds.

In this case, both the base part 2 and the gift part 3 recesses 12, 12 ', 12 "and 12'", in which the first 8 and the second end 9 of the leg spring 7 can engage. If the ends 8, 9 engage in the recesses 12, 12 ", this corresponds to the neutral position of the spring 7. The spring rate of the spring 7 can be changed by engaging the first end 8 in the recess 12 'and / or the spring second end 9 in the recess 12 '"engages. In principle, the spring hardness by introducing the ends 8, 9 in a different recess different spring rates conceivable, according to the position of the ends 8, 9 in the recesses 12, 12 "or 12, 12 '" or 12', 12 "or 12 ', 12"'.

Of course, it is also conceivable that further recesses are provided, whereby the spring rate setting of the torsion spring element 7 is even more diverse and precise adjustable.

It can also be seen that the base part 2 has at least one bore 20, which are provided to connect the base part 2 with the skateboard deck 6. Likewise, the pivoting part 3 at least one bore 21, by means of which a first driving axle 4 with the pivoting part 3 is connectable. The holes 20, 21 are in particular standard holes, as known from the prior art. By means of a selection of the bores 20, 21, in particular the radius of rotation of the first axis about the pivot axis 5 and the wheelbase of the skateboard can be changed, which leads to a different driving behavior.

The FIGS. 4A and 4B as well as the Figures 4C and 4D show a further alternative embodiment of a pivoting device 1, wherein the spring rate of the torsion spring element 7 is variable.

The spring rate of the torsion spring element 7 is hereby changed as follows. The first end 8 and the second end 9 of the torsion spring element 7, here configured as a leg spring 7, are connected to a first spring end retainer 10 and a second spring end retainer 11, wherein the spring end retracts 10, 11 are formed as threaded sleeves 13. The threaded sleeves 13 are in a possible embodiment in more detail in the FIG. 4B shown.

The dashed threaded sleeves 13 describe here possible positions of the threaded sleeves 13, according to the desire of the skateboarder for the preferred spring rate, respectively for the base part 2 and the pivot part. 3

Again FIG. 4B can be seen, the threaded sleeve 13 comprises an external thread 14 and an interior 15, which preferably represents a cavity, in which an end 8, 9 can be introduced is. Further advantageously, the threaded sleeve 13 has an end 22, which represents a conclusion of the threaded sleeve 13.

According to FIG. 4C is a plan view of a section of the pivoting device 1 is shown, wherein a plurality of internal threads 16 are shown. The internal threads 16 are presently arranged such that they extend in a radial direction of the ends or the legs 8, 9. This facilitates in particular the screwing of the threaded sleeves 13 into the respective internal thread 16. In order advantageously to connect the ends 8, 9 with the threaded sleeves 13, the respective internal threads 16 are connected to each other by means of at least one gap 23, in which gap 23 the Ends 8, 9 can move from one internal thread 16 to the next or a different internal thread 16, in particular in the Figure 4D is pictured.

The connection of the thread of the threaded sleeve 13 with the internal thread 16 can be achieved either by unscrewing or by screwing the threaded sleeve 13 in, with unscrewing is preferred.

FIG. 5A shows a further alternative embodiment of the pivoting device 1 for adjusting a spring rate of the torsion spring element 7 is shown. The spring rate adjustment in a cutout, wherein the first end 8 of the torsion spring member 7 is in operative contact with a support member 17 by an opening 24 of the support member 17, the first End 8 of the torsion spring element 7 is inserted therethrough. In a linear displacement of the support member 17, the first end 8 is changed accordingly in its position. Preferably, the first end 8 is inserted so far through the opening 24, that for any linear displacement in a direction LL, the support member 17 is in operative contact with the first end 8.

By a rotation of the rotary spindle 19, which engage with the carrier element 17 via tooth elements 18 of the support member in the thread of the rotary spindle and wherein the tooth elements 18 are complementary to the thread of the rotary spindle 19, the support member 17 is linearly displaced. In this case, a guide (not shown here) is particularly advantageous for the carrier element 17 in order to be able to displace the carrier element 17 safely and guided.

In this case, the tooth elements 18 can be configured in various ways, for example, as already mentioned, complementary to the thread of the rotary spindle 19, wherein also Tooth elements 18 are conceivable, which are rounded, tapered or polygonal design.

Advantageously, it is also conceivable to provide an additional locking device which restricts the movement of the rotary spindle 19. It is conceivable in this case a split pin, which in openings of the rotary spindle 19 can be introduced, so as to restrict the rotational movement D.

FIG. 5B shows an arrangement with an adjustment according to FIG. 5A in a top view.

The FIG. 6A shows a further embodiment of the pivoting device 1. By way of example, the first Federendeneinhängung 10 and formed by a rotation 25 in a thread 26 linearly displaceable element 27, wherein the first end 8 of the torsion spring element 7 can be brought into operative contact with the element 27 and by a displacement of the element 27, the position of the first end 8 is variable and thereby the spring rate of the torsion spring element. 7

In this case, the element 27 is displaceable by a rotation 25 along a longitudinal extent LG of the thread 26 and can be brought into operative contact with the first end 8 of the torsion spring element 7. Preferably, the first end 8 of the torsion spring element 7 as long as a constant position with respect to the thread 26 until the element 27 is brought into operative contact with the first end 8. The thread 26 may also be equipped with an internal thread and / or an external thread to change the spring rate as advantageous and space-saving.

If the first end 8 is in operative contact with the element 27 and the element 27 is further displaced so that the active contact is not released, the position of the first end 8 is changed and the spring rate of the torsion spring element 7 is changed accordingly.

It is also conceivable that the element 27 is formed such that the element 27 is always in operative contact with the first end 8. Such a configuration may FIG. 6B be removed. In this case, the element 27 comprises a hook element 28, which is arranged on the element 27, so that the element 27 is in operative contact with the first end 8 with the hook element 28. However, this thread is no longer provided, but a guide rail 29, since rotation of the element 27 can lead to undesirable effects.

For any displacement of the element 27 in this case the position of the first end 8 of the torsion spring element 7 is changed and thus the spring rate changed.

The same applies equally to the second end 9 of the torsion spring element 7.

The FIG. 7 In this case shows a further embodiment for changing the spring rate of the torsion spring element 7, wherein according to this embodiment, the Federendeneinhängungen 10, 11 are changed in position, so that the respective attacking lever of the ends 8, 9 changes and correspondingly changes the torque. By changing the torque in the present case, the spring rate of the torsion spring element 7 changes.

In the FIG. 7 Here, only the corresponding components are shown schematically in order to ensure a better clarity of the figure. The first end 8 is connected to the base part 2 and the second end 9 is connected to the pivoting part 3.

For this purpose, the pivoting device comprises two threads 26 whose longitudinal directions LG are located on a common straight line. The spring end fittings 10, 11 have an external thread 14 which is in operative contact with the thread 26 by means of a mating internal thread 16. By rotation of the Federendeneinhängungen 10, 11, the Federendeneinhängungen each move along the longitudinal direction LG, so that in this way the point of application 30 of the force is changed.

How further from the FIG. 7 it can be seen, it is in the Federendeneinhängungen 10, 11 advantageously threaded sleeves 13, through which the first and / or the second end 8, 9 are passed and so can be brought into operative contact with the threaded sleeve 13.

All disclosed in the application documents features are claimed as essential to the invention, provided they are new individually or in combination over the prior art.

LIST OF REFERENCE NUMBERS

1

swivel device

2

base

3

swiveling part

4

first driving axis

5

swivel axis

6

skateboard

7

Torsion spring element

8th

first end of the torsion spring element

9

second end of the torsion spring element

10

first spring-end suspension

11

second spring-end suspension

12

recess

13

threaded sleeve

14

external thread

15

Inside of the threaded sleeve

16

inner thread

17

support part

18

tooth element

19

spindle

20

Hole deck

21

Drilling the first axle

22

End of threaded sleeve

23

gap

24

opening

25

rotation

26

thread

27

element

28

hook element

29

guide rail

30

Point of attack of the force

LA

Longitudinal extension of pivot axis

LB

Longitudinal direction of the base part

LS

Longitudinal direction of the pivoting part

LL

Linear displacement direction

LF

Longitudinal extension of the torsion spring element

LG

Longitudinal thread

Claims (15)

Pivoting device (1) for a skateboard (6), wherein the pivoting device (1) can be attached below a skateboard deck of the skateboard base part (2) and a pivoting part (3) to which a first driving axis (4) of the skateboard can be arranged , wherein the pivoting part (3) is pivotable relative to the base part (2) about at least one pivot axis (5) and has a first end (8) of a torsion spring element (7) with the base part (2) and a second end (9). the torsion spring element (7) is at least in operative contact with the pivoting part (3),
characterized in that
a value of a force and / or a pivoting angle with respect to a pivoting of the pivoting part (3) relative to the base part (2) from a value of one of a change in position of the first (8) and / or the second end (9) of the torsion spring element (7 ) and / or by a change of a point of application (30) of the force on the first (8) and / or the second end (9) of the torsion spring element (7) variable spring rate of the torsion spring element (7) is dependent. Pivoting device (1) according to claim 1,
characterized in that
the torsion spring element (7) is arranged at least partially around the pivot axis (5) and a longitudinal extent (LF) of the torsion spring element (7) coincides with a longitudinal extension (LA) of the pivot axis (5). Pivoting device (1) according to claim 1 or 2,
characterized in that
the torsion spring element (7) is a leg spring having a first and a second leg, wherein the first leg corresponds to the first end (8) and the second leg corresponds to the second end (9). Pivoting device (1) according to one of claims 1 to 3,
characterized in that
the pivot axis (5) at an angle to the longitudinal extent (LB) of the base part (2), in particular an angle in the range of 40 ° -120 °, more preferably 40 ° -90 ° and particularly preferably 60 ° -80 °. Pivoting device (1) according to one of claims 1 to 4,
characterized in that
the first end (8) of the torsion spring element (7) with at least one first Federendeneinhängung (10) and the second end (8) of the torsion spring element (7) with at least one second Federendeneinhängung (11) are connectable, wherein the first Federendeneinhängung (10) the base part (2) and the second Federendeneinhängung (11) with the pivoting part (3) is operatively connected. Pivoting device (1) according to claim 5,
characterized in that
at least two first Federendeneinhängungen (10) and at least two second Federendeneinhängungen (11) are provided which are each formed as a recess (12) and the first (8) and second end (9) of the torsion spring element (7) in a longitudinal direction ( LF) of the torsion spring element (7) or extending at an angle relative to the longitudinal direction (LF) of the torsion spring element (7) and the first end (8) in a first Federendeneinhängung (10) and the second end (9) in a second Federendeneinhängung ( 11), wherein by a transfer of the first end (8) and / or the second end (9) in a respective end (8, 9) corresponding further Federendeneinhängung (10, 11), the spring rate of the torsion spring element (7) is variable , Pivoting device (1) according to claim 5,
characterized in that
the first spring end retainer (10) is formed as a first threaded sleeve (13) and the second spring end retainer (11) is formed as a second threaded sleeve (13), each with an external thread (14), the first end (8) of the torsion spring element (7 ) with the first threaded sleeve (13) and the second end (9) of the torsion spring element (7) with the second threaded sleeve (13) is operatively operable such that the ends (8, 9) in a corresponding interior (15) of the associated threaded sleeve ( 13) can be introduced and the first threaded sleeve (13) in at least one corresponding internal thread (16) of the base part (2) and the second threaded sleeve (13) in at least a corresponding internal thread (16) of the pivoting part (3) are screwed, wherein by a transfer of the first threaded sleeve (13) with the first end (8) of the torsion spring element (7) and / or the second threaded sleeve (13) with the second end ( 9) of the torsion spring element (7) in one of the respective threaded sleeve (13) corresponding further internal thread (16), the spring rate of the torsion spring element (7) is variable. Pivoting device (1) according to claim 5,
characterized in that
the first (10) and the second Federendeneinhängung (11) each have a linearly displaceable support member (17) with a plurality of juxtaposed tooth elements (18), wherein the tooth elements (18) with a rotatably mounted about a rotation axis rotary spindle (19) are in operative contact and by means of a rotation of the rotary spindle (19), the carrier part (17) is linearly displaceable, whereby the position of the first (8) and / or the second end (9) is variable and thereby the spring rate of the torsion spring element (7). Pivoting device (1) according to claim 5,
characterized in that
the first (10) and the second spring-end retainer (11) are each formed with a linearly displaceable element (27) by rotation in a thread (25), wherein the first (8) and the second end (9) of the torsion spring element (7) are in operative contact with the element (27) and by a displacement of the elements (27), the position of the first (8) and / or second end (9) is variable and thereby the spring rate of the torsion spring element (7). Pivoting device (1) according to one of the preceding claims,
characterized in that
the pivoting part (3) and / or the base part (2) is connected to the pivot axis (5) via at least one ball bearing. Pivoting device (1) according to one of the preceding claims,
characterized in that
a blocking device is provided, which is connectable to the base part (2) and the pivoting part (3) in order to prevent a pivoting movement of the pivoting part (3) relative to the base part (2). Pivoting device (1) according to one of claims 5 to 9,
characterized in that
by means of a movement of the first (10) and / or the second Federendeneinhängung (11) along a longitudinal direction of the application point (30) of the force on the first (8) and / or the second end (9) of the torsion spring element (7) is variable, whereby the spring rate of the torsion spring element (7) is variable. Pivoting device (1) according to claim 12,
characterized in that
the first (10) and the second spring-end attachment (11) each have an external thread (14) and are each connectable with a thread (26) to an internal thread (16) which matches the external thread (14) and the first (10) and / or the second Federendeneinhängung (11) along the longitudinal direction (LG) of the thread (26) are movable. Pivoting device (1) according to claim 12,
characterized in that
by means of at least one rail device, the first (10) and / or the second Federendeneinhängung (11) along a longitudinal direction of the rail device are movable. Pivoting device (1) according to claim 14,
characterized in that
the rail device comprises a blocking device, by means of which locking device, the movement of the first and / or the second Federendeneinhängung is blocked.

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