WO2019185688A1 - Folding mechanism for an electric scooter - Google Patents

Abstract

The present invention relates to a scooter, in particular a kick scooter, comprising a steering rod (12), a footboard (14), an electric auxiliary drive (24), and a pivoting device (26). The pivoting device pivotally connects the steering rod (12) and the footboard (14) such that the steering rod (12) and the footboard (14) can be pivoted relative to one another between a driving position (28) and a transporting position. The footboard (14) has a receiving device for receiving the pivoting device (26), said receiving device comprising at least one receiving element.

Description

 FOLDING MECHANISM FOR AN ELECTRICOLOR

The present invention relates to a scooter, in particular scooter, with a

 A handlebar, a footboard, a front suspension for supporting at least one front wheel, a rear suspension for supporting at least one rear wheel, an electric auxiliary drive for driving the at least one front and / or the at least one rear wheel, and a pivoting device, wherein the pivoting device the handlebar and the footboard pivotally interconnects, so that the handlebar and the footboard relative to each other between a driving position and a transport position are pivotable, and wherein the footboard has a receiving device for receiving the pivoting means with at least one receiving element. Furthermore, the present invention relates to a method for folding such a scooter.

Such scooters are already known in the art. For example, document EP 2 425 989 A1 shows a scooter which has a receiving device attached to the running board and a pivoting device connected to the handlebar. The receiving device and the pivoting device are rotatably connected to each other. The pivoting device has a round bolt and the receiving device has a plurality of complementary to the bolt ausgebil finished recesses. The bolt is disposed in the recesses to lock the pivot member and the receptacle with respect to a plurality of positions, in particular a driving position or a transport position. In this case, the bolt is biased in the direction of the receiving element. Furthermore, an actuating element is provided which cooperates with the bolt in order to move the bolt against the tension force in front of the recesses and thus to allow a free rotation between the individual positions.

Furthermore, for example, the document DE 10 2013 003 484 A1 shows a scooter, which also has a receiving element and a pivoting element, which are also connected to each other rotatable. For locking the pivoting element and the receiving element with each other, the pivoting element on a round pin and the receiving element has two complementary thereto formed recesses according to a driving position and a transport position.

Furthermore, for example, the publication CN 103228897 U shows another

 Roller, which has a pivoting device and a receiving device, which are rotatably connected with each other and can be locked in individual positions.

The well-known in the art bolts and recesses are typically made so ex works that the bolt can be arranged without play in the recesses. When driving with such a roller, in particular in the driving position, large forces act on the bolt and the recess, so that wear, in particular abrasion and deformation on bolts and the recesses, occurs. This results in that the bolt and the recesses are no longer formed exactly complementary, so that the bolt in the recesses can not be arranged without play. This leads to an increased wear, since the bolt can move or vibrate in the recess. The other is the Handlebar in the driving position no longer firmly and stably connected to the footboard, which significantly reduces the ride comfort and safety feeling for a user of the scooter.

It is therefore an object of the present invention to provide an improved scooter with electric auxiliary drive, which provides an improved folding mechanism.

According to a first aspect of the invention, a scooter, in particular scooter, with a handlebar, a running board, a front suspension for carrying least one front wheel, a rear suspension for carrying at least one rear wheel, an electric auxiliary drive for driving the at least one front and / or the at least one rear wheel, and a pivoting device provided. The pivoting device pivotally connects the handlebar and the footboard together so that the handlebar and footboard are pivotable relative to each other between a driving position and a transporting position. The treadboard has a receiving device for receiving the pivoting device with at least one receiving element. Each receiving element has a first and a second wedge-shaped recess. The pivoting device has a wedge-shaped wedge element. The wedge element is engageable in the driving position with the first wedge-shaped recess and in the transport position with the second wedge-shaped recess.

According to a second aspect of the invention, there is further provided a method of

Flaps of a scooter, in particular kick scooter, provided, the scooter a handlebar, a running board, a front suspension for supporting at least one front wheel, a rear suspension for supporting at least one rear wheel, an electric auxiliary drive for driving the at least one front and / or the at least one rear wheel, and a pivoting device, wherein the pivoting means the handlebar and the footboard pivotally interconnects, wherein the footboard has a receiving device for receiving the pivoting device having at least one receiving element, each receiving element a first and a second wedge-shaped recess having the swing Device has a wedge-shaped wedge element, the method comprising the following steps:

Arranging the handlebar and the footboard relative to each other in a driving posi tion or in a transport position, wherein the wedge member is in the driving position in engagement with the first recess and in the transport position in engagement with the second recess;

- pivoting the handlebar and the footboard relative to each other in the trans port position or in the driving position; and

- Bringing the wedge member with the first recess, when the steering rod and the footboard are arranged relative to each other in the driving position or engaging the wedge member with the second recess, when the handlebar and the footboard are arranged side by side in the transport position is ,

In this way, the pivoting device and the receiving device are connected to each other with increasing usage time and the associated wear play in the driving position. This is made possible by the fact that the wedge surfaces of the wedge and the inner surfaces of the recess provided complementary thereto are formed so that when the wear occurs, only the wedge slips further into the recess and can therefore continue to be arranged without play in the recess.

Furthermore, the wedge surfaces lie flat against the side surfaces of the recesses, which creates a surface pressure in the first recess in particular during ferry operation. As a result, the wear is significantly reduced because the forces now not punctual but surface act.

The object initially posed is therefore completely solved. In one embodiment of the scooter can be provided that the pivoting device has a receptacle for the handlebar, in which the handlebar is rotatably mounted.

The handlebar is mounted so in the pivoting device that during the

 Fährbetriebs the scooter in the driving position a steering movement of the scooter is executable. The receptacle is preferably formed as a perforation or as a tube through which the handlebar extends in the longitudinal direction.

In a further embodiment of the scooter can be provided that in the

 Transporting a longitudinal axis of the running board is substantially parallel to a longitudinal axis of the handlebar.

Characterized the scooter is folded as compact as possible in the transport position and can thereby advantageously transport. Preferably, the steering Stan ge is in the transport position on the rear wheel or the rear suspension.

In a further embodiment of the scooter can be provided that in the

 Driving position a longitudinal axis of the footboard with a longitudinal axis of the handlebar an angle of 45 ° to 120 °, preferably 60 ° to 90 °, in particular 80 °, 81 °, 82 °, 83 °, 84 °, 85 °, 86 °, 87 ° , includes.

During the ferry operation, in which the scooter is arranged in the driving position, is a

Users of the scooter on a tread of the footboard and holds with his hands the steering rod, in particular a trained or mounted on the upper end of the handlebar handlebar. In order for the user to hold the handlebar, the handlebar extends away from the footboard in the direction of the user. The handlebar can be arranged substantially perpendicular to the footboard. It is advantageous in this case if the handlebar is inclined slightly towards the user and encloses an angle of less than 90 ° with the running board, since the user can thereby grasp the handlebar more easily and has better steering control. In a further embodiment of the scooter can be provided that the

Pivoting means comprises a shaft on which each receiving element is rotatably gela Gert.

In other words, the wave tears the receiving elements and allows a

 Pivoting movement of the receiving elements about a longitudinal axis of the shaft. As a result, a pivotal connection between the handlebar and the footboard is made in a simple manner. The shaft extends in this case preferably perpendicular to a longitudinal direction of the running board.

In a further embodiment of the scooter can be provided that each of the

 Receiving elements has a bore through which the shaft extends.

The pivoting device is characterized by the shaft on each receiving element of the

 Treadboards pivotally mounted. Preferably, the bore is dimensioned such that an inner diameter of the bore corresponds to an outer diameter of the shaft. As a result, the pivoting device is mounted without play on the receiving elements and allows only a rotational movement about a longitudinal axis of the shaft.

In a further embodiment of the scooter can be provided that each of the first and second recess is radially outwardly open and widened radially outward.

Outside in this context means that each receiving element has an outer side, wherein the wedge element is disposed adjacent to the outside. The wedge member is movable along this outside. The wedge element can then penetrate into each of the recesses and be brought into abutment with the inner contour of the recess. As a result, the wedge element can be brought into engagement with the recess.

In a further embodiment of the scooter can be provided that the

Swivel device comprises a spring element, wherein the wedge member by means of Spring element in the first recess in the driving position and in the second recess in the transport position can be prestressed.

Characterized the wedge member is held both in the driving position and in the transport position, in which it is held in the corresponding recess by the biasing force in engagement. This avoids that the wedge element is inadvertently brought out of engagement with the respective recess during ferry operation or during transport of the scooter.

In a further embodiment of the scooter can be provided that the

 Furthermore, the pivoting device has a spring holder, wherein the spring element is fastened to a side of the wedge element facing the receiving device and to the spring holder.

At substantially the same distance between the spring holder and wedge member and the biasing force is substantially equal, since both components are arranged in the pivoting device. When adjusting the biasing force is generally to ensure that the wedge member is secured in the driving position and the transport position in the corresponding recesses, but also a release of the wedge member by a user of the scooter is possible to the handlebar and the footboard between the driving position and to transfer the transport position. If the pretensioning forces in the driving position and the transporting position are approximately the same, the pretensioning force can be better adapted to the aforementioned points.

In a further embodiment of the scooter can be provided that a depth of the first recess is greater than a depth of the second recess.

During the ferry operation in the driving position, larger forces act on the

Folding mechanism of a scooter as when transporting in the transport position. Accordingly, the wear of the components of the folding mechanism, in particular of the wedge element and the recesses, in the driving position is greater than in the transport position. Accordingly, it is advantageous if the driving position corresponds to The first recess is deeper than the transport position corresponding to the second recess, since the wedge member penetrates deeper with increasing wear in the first recess from as in the second recess.

In a further embodiment of the scooter can be provided that a

 Cross-sectional profile of the wedge element is formed complementary to a cross-sectional profile of the first recess and / or the second recess.

As a result, the wedge element, when it is in engagement with one of the recesses, lies flat against at least one of the side surfaces of this recess. As a result, the wear of the wedge element and the recess is reduced because forces act flat and not punctual. Furthermore, the wedge element is better secured by the areal inclusion of the wedge element in the recess, since the surface contact creates a greater stiction, which must be overcome additionally or alternatively to the biasing force of a spring, especially if the wedge element is clamped in the Ausneh determination ,

In a further embodiment of the scooter can be provided that the first

 Recess and the second recess each having two side surfaces extending from an open end to a closed end, wherein a distance of the respective side surfaces at the open end is greater than a distance of the respec gene side surfaces at the closed end.

The wedge member may then penetrate into each of the recesses and be brought into abutment with at least one of the side surfaces of the recess. As a result, the wedge element can be brought into engagement with the recess.

In a further embodiment of the scooter can be provided that the wedge element has two opposite wedge surfaces extending from a side facing away from the receiving device to a receiving device side facing the Keilele element, and wherein the distance of the wedge surfaces to each other at the Aufnah- Means facing away from the wedge element is greater than at the receiving device facing the side of the wedge member.

The wedge surfaces of the wedge element thus have the same distance profile as the

 Side surfaces of each recess on. When the wedge element is brought into engagement in one of the recesses, at least one of the wedge surfaces lies flat against the correspondingly facing side surface of the recess.

In a further embodiment of the scooter can be provided that the distance of the

 Side surfaces of the first recess at the closed end is smaller than the distance of the wedge surfaces of the wedge member on the receiving device side facing.

This ensures that the wedge element does not completely penetrate into the first recess until it comes into contact with at least one of the side surfaces of the first recess. When wear on the wedge element and / or the Ausneh tion mutually exploit, whereby the wedge element can continue to penetrate into the recess. Since the wedge element previously does not completely penetrate into the first recess, it is ensured even with onset of wear that the wedge element holds flat in the recess.

In a further embodiment of the scooter can be provided that the distance of the

 Side surfaces of each recess at the open end is greater than the distance of the wedge surfaces of the wedge member on the receiving device side facing.

This ensures that the wedge element penetrate into each recess and in

 Engagement with the respective recess can be brought.

In a further embodiment of the scooter can be provided that the

Pivoting means an actuating element, in particular a lever, which is in operative connection with the wedge element, so that the wedge element from the first recess and out of the second recess can be moved out. The actuating element interacts with the wedge element such that the

Wedge element is disengaged from the respective recess and moved out. Thus, the pivoting device can be pivoted after actuation of the actuating element between the driving position and the transport position.

In a further embodiment of the scooter can be provided that the

 Pivoting means comprises a motion transmitting member, wherein the Keilele element has a recess, wherein the motion transmitting member extends through the recess, and wherein the motion transmitting member is rotatably connected to the actuating element.

A rotational movement of the actuating element about an axis on which the

 Motion transmission element and the actuating element are connected, is thus on the recess and the motion transmission element in a relative movement of the wedge member with respect to the receiving device, in particular with respect to the first and second recess transferable. By this arrangement, an operative connection between the wedge member and the actuating element for disengaging the wedge member from the respective recess is made in a simple and compact manner.

In a further embodiment of the scooter can be provided that the

 Recess extends through both wedge surfaces of the wedge element.

In this arrangement of the recess is by the rotational movement of the

 Actuator displaced the wedge member in a direction which is parallel to the direction from the narrow end of the wedge to the wide end of the wedge.

In a further embodiment of the scooter can be provided that the

Swivel device comprises a securing element which is designed such that it secures the actuating element when the wedge element is brought into engagement with the first Ausneh tion or the second recess. By means of the securing element, the actuating element can be secured in the driving position and the transport position, to ensure that during the ferry operation or the transport of the scooter, the actuating element does not accidentally triggers and brings the wedge element out of engagement with the respective recess. Only by a Entsi chern the fuse element by a user of the scooter so that the Actuate can be actuated transmission element.

In one embodiment of the method can be provided that the

 Pivoting means comprises a spring element, wherein in the step of engaging the wedge member is brought by a biasing force of the spring member into engagement with the first recess or the second recess.

It is thereby achieved that, after a pivoting between the driving position and the transport position in one of the respective positions, the wedge element is automatically brought into engagement by the biasing force of the spring element with the corresponding recess.

In a further embodiment of the method can be provided that the

 Method further comprises the step that the wedge member by means of Federele element in the first recess when the handlebar and the footboard are arranged relatively zueinan in the driving position, or in the second recess when the handlebar and the footboard relative to each other in the Transport position are arranged, is biased.

The wedge member is held in both the driving position and in the transport position by the biasing force in the corresponding recess. This avoids the fact that the wedge element is inadvertently brought out of engagement with the respective recess during ferry operation or during transport of the scooter.

In a further embodiment of the method can be provided that the

Swivel device comprises an actuating element, in particular a lever, which is in operative connection with the wedge element, wherein the method further comprises the step has that the actuating element is unlocked to allow movement of the Actuate transmission element.

By securing the actuating element, the actuating element in the

 Driving position and the transport position are held to ensure that during the ferry operation or the transport of the scooter, the actuating element does not accidentally triggers and brings the wedge element out of engagement with the respective recess. Only by the unlocking of the fuse element by a user of the scooter so that the actuator can be actuated.

In a further embodiment of the method can be provided that the

 Swivel device comprises an actuating element, in particular a lever, which is in operative connection with the wedge element, the method further comprising the step of the actuating element for moving out of the wedge element out of the first recess when the handlebar and the footboard relative to each other in the driving position are arranged, or from the second recess, when the handlebar and the footboard are arranged relative to each other in the transport position is actuated. Preferably, the actuating element is pivoted for actuation.

The actuating element cooperates with the wedge element in such a way that the

 Wedge element is disengaged from the respective recess and moved out. Thus, the pivoting device can be pivoted after actuation of the actuating element between the driving position and the transport position.

In a further embodiment of the method can be provided that the

 The method further comprises the step of securing the actuator when the wedge member is engaged with the first recess or the second recess.

By securing the actuating element, the actuating element in the

Driving position and the transport position are held to ensure that during the ferry operation or the transport of the scooter, the actuator is not unintentionally triggers and brings the wedge element out of engagement with the respective recess. Only by a release of the fuse element by a user of the scooter, so that the actuator can be actuated.

It is understood that the features mentioned above and those yet to be explained not only in the particular combination, but also in other combinations or alone, without departing from the scope of the present invention.

Embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description. Show it:

Figure 1 is an isometric view of an embodiment of a scooter, which is arranged in a driving position.

FIG. 2 shows a side view of the scooter from FIG. 1; FIG.

Fig. 3 is a side view of the scooter scooter of Figure 1, wherein the scooter is arranged in a trans port position.

FIG. 4 is an isometric view of a folding mechanism of the scooter from FIG. 1 in the driving position; FIG.

Fig. 5 is a detail view of the folding mechanism of Fig. 4;

Fig. 6a is a plan view of a wedge member of the folding mechanism of Fig. 4;

Fig. 6 is an isometric view of the wedge member of the folding mechanism of Fig. 4;

Fig. 6c is a plan view of a receiving element of the folding mechanism of Fig. 4; Fig. 7 is an isometric view of the folding mechanism of Fig. 4 in the transport position;

Fig. 8 is a detail view of the folding mechanism of Fig. 7;

Fig. 9 is an isometric view of the folding mechanism of Fig. 4 between the driving position and the transporting position;

Fig. 10 is a detail view of the folding mechanism of Fig. 9;

Fig. 1 1 is a side view of the folding mechanism of Fig. 9;

12 shows a first embodiment of a method for folding a scooter; and

Fig. 13 shows another embodiment of a method for folding a scooter.

Figs. 1 and 2 show an embodiment of a scooter 10, which in a

 Driving position 28 is arranged. The scooter 10 has a handlebar 12, a running board 14, a front suspension 16 and a rear suspension 18. The handlebar 12 has an upper and a lower end 32, 34. The footboard has a front side 36 and a rear side 38. The footboard 14 further includes a tread 15 for supporting a user of the scooter 10. The tread 15 he stretches at least partially from the front 36 to the rear 38 of the treadboard 14th

The front suspension 16 is disposed at the lower end 34 of the handlebar 12. In other words, the lower end 34 of the handlebar 12 faces the front suspension 16 and the upper end 32 of the handlebar 12 faces away from the front suspension 16. The front suspension 16 is rotatably connected to the handlebar 12. Preferably, the handlebar 12 forms the front suspension 16. The rear suspension 18 is disposed on the rear side 38 of the running board 14. In other words, the front side 36 of the running board 14 faces the front suspension 16 and the handlebar 12 and faces away from the rear suspension 18. The rear side 38 of the footboard 14 faces the rear suspension 18 and faces away from the front suspension 16 and the handlebar 12. The footboard 14 is preferably disposed substantially between the front and rear suspensions 16, 18. The footboard 14 preferably forms the rear suspension 18.

The scooter preferably has a front wheel 20, also called a front wheel, and a rear wheel 22, also called a rear wheel. The front Radaufhän supply 16 forms a holder for the front wheel 20. An axle of the front wheel 20 is supported in the bracket so that the front suspension 16 supports the front wheel 20. The rear suspension 18 forms a support for the rear wheel 22. An axle of the rear wheel 22 is supported in the bracket so that the rear suspension 18 supports the rear wheel 22.

The front wheel 20 and the rear wheel 22 preferably each have a diameter of 15 cm to 35 cm, in particular 25.4 cm, on. The footboard 14 is disposed substantially between the front wheel 20 and the rear wheel 22. The front wheel 20 and the rear wheel 22 preferably have an axis distance of 55 cm to 115 cm, in particular 85 cm.

Preferably, the scooter 10 may also include a plurality of front wheels and / or rear wheels, wherein the brackets of the front suspension 16 and the rear suspension 18 are formed so that they can carry the plurality of front wheels and / or rear wheels.

The footboard 14 of scooter 10 has a thickness which is preferably 2 cm to 10 cm, preferably 3 cm to 8 cm, in particular 5 cm. The thickness of the footboard 14 extends perpendicular to the tread surface 15 of the footboard 14. The footboard 14 has a length that extends longitudinally from the rear 38 to the front 36 of the footboard Running boards 14 extends out. The length of the footboard 14 is smaller than the axial distance in a driving position 28 of scooter roller 10. The tread surface 15 has a length which is less than or equal to the length of the footboard 14 and which preferably 30 cm to 60 cm, preferably 40 cm to 50 cm, in particular 45 cm. The footboard 14 further has a width which is preferably 10 cm to 20 cm, preferably 13 cm to 18 cm, in particular 16 cm. The width of the footboard 14 extends perpendicular to the longitudinal direction and parallel to the tread surface 15. The width of the footboard 14 is greater than or equal to a width of the tread surface 15th

The scooter 10 is arranged in the driving position 28 on a floor 31. In this case, the front wheel 20 and the rear wheel 22 are on the floor 31. The footboard 14 has a ground clearance, which corresponds to the distance of a bottom of the footboard 14 to the bottom 31 and preferably 4 cm to 15 cm, preferably 5.5 cm to 10 cm, in particular 7 cm special. This results in that the distance between the tread surface 15 and the bottom 31 is preferably 6 cm to 25 cm, preferably 8.5 cm to 18 cm, in particular 12 cm.

The scooter 10 further has an electric auxiliary drive 24. The electric

 Auxiliary drive 24 is configured to drive the front wheel 20 and / or the rear wheel 22 to drive. The electric auxiliary drive 24 is preferably arranged in the front wheel 20 and / or in the rear wheel 22. Alternatively, the auxiliary electric drive 24 may also be arranged in the front suspension 16 and / or in the rear suspension 18. In the illustrated embodiment, the auxiliary electric drive 24 is disposed in the rear wheel 22.

The scooter 10 further comprises a pivoting device 26. The

Swivel device 26 connects the handlebar 12 and the footboard 14 pivotally with each other, so that the handlebar 12 and the footboard 14 relative to each other between the driving position 28 and a transport position 30 are pivotable. The pivoting device 26 is arranged between the handlebar 12 and the footboard 14. The pivoting device 26 has on a front, the handlebar 12 side facing a receptacle 40 for the handlebar 12, in which the handlebar 12 about a longitudinal axis 42 of the handlebar 12 is rotatably mounted. The longitudinal axis 42 of the handlebar extends centrally in the handlebar 12 from the lower end 34 to the upper end 32. The receptacle 40 may preferably be formed as a continuous bore, wherein the handlebar 12 extends through the through bore.

Preferably, the handlebar 12 is lockable on the pivoting device, so that a

 Rotary movement of the handlebar 12 about the longitudinal axis 42 of the handlebar 12 in the receptacle 40 of the pivoting device 26 can be locked or lockable when the scooter 10 is disposed in the transport position 30, and can be released or is releasable when the scooter 10 in the Driving position 28 is arranged.

The pivoting device 26 is pivotally connected to the footboard 14 on the rear, the footboard 14 side facing. The rear side of the pivoting device 26 is so pivotally mounted on the front side 36 of the footboard 14, that the handlebar 12 and the footboard 14 relative to each other between the driving position 28 and a trans port position 30 are pivotable.

In Fig. 1 and 2 of the scooter 10 is shown in the driving position 28. In the driving position, the handlebar 12 and the footboard 14 are arranged relative to each other such that a longitudinal axis 44 of the footboard 14 which extends centrally in the footboard 14 from the front 36 to the rear 38 of the footboard 14, with the longitudinal axis 42 of the handlebar 12 a Angle a of 45 ° to 120 °, preferably 60 ° to 90 °, in particular 80 °, 81 °, 82 °, 83 °, 84 °, 85 °, 86 °, 87 °, includes.

Fig. 3 shows the scooter 10 of FIGS. 1 and 2, wherein the scooter in the

 Transport position 30 is arranged. In the transport position 30, the handlebar 12 and the footboard 14 are arranged relative to each other such that the longitudinal axis 44 of the footboard 14 extends substantially parallel to the longitudinal axis 42 of the handlebar 12. Preferably, the longitudinal axis 44 of the footboard 14 with the longitudinal axis 42 of the handlebar 12 includes an angle a between 0 ° and 10 °, in particular 5 °, a.

In Figures 4 to 1 1, a folding mechanism 52 of the scooter 10 of FIG. 1 will be described in more detail. Figures 4 and 5 show the folding mechanism 52 of the scooter 10 of FIG. 1, wherein the folding mechanism 52 is arranged in the driving position 28. The Klappmecha mechanism has elements of the pivoting device 26 and the footboard 14, which cooperate so that the scooter 10 between the driving position 28 and the transport position 30 is pivotable.

The footboard 14 has for this purpose a receiving device 54. The recording device

 54 is arranged on the pivoting device facing the front side 36 of the footboard 14. The receiving device 54 has two receiving elements 56. The receiving elements 56 are arranged on the pivoting device facing the front side 36 of the footboard 14 in a direction next to each other, which is perpendicular to the longitudinal axis 44 of the footboard 14 and perpendicular to the longitudinal axis 42 of the handlebar 12. The receiving elements 56 extend substantially from an underside of the footboard 14 to the tread surface 15 of the footboard 14. The receiving elements 56 each have a bore 58. The holes 58 of the receiving elements 56 are arranged at the same height between the underside of the footboard 14 and the tread surface 15 of the footboard 14. Alternatively, only one receiving element 56 may be provided with a bore 58.

Furthermore, the pivoting device 26 forms a cavity 46 extending from one of the handlebar 12 facing the handlebar side 48 of the pivoting device 26 to the running board 14 facing footboard side 50 of the pivoting device 26 he stretches. In the cavity 46 pivot means side elements of Klappmecha mechanism 52 are arranged. The pivoting device 26 has a shaft 60 in the cavity 46. The shaft 60 extends through the cavity 46 and is perpendicular to the longitudinal axis 44 of the footboard 14 and perpendicular to the longitudinal axis 42 of the handlebar 12 is arranged. The receiving elements 56 are rotatably mounted on the shaft 60. The shaft 60 extends through the holes 58 of the receiving elements 56. By means of this rotatable mounting the handlebar 12 and the footboard 14 are pivotable relative to each other.

Furthermore, the folding mechanism 52 has elements arranged on the pivoting device side and on the side of the board, by means of which the scooter 10 is in the driving position 28 and is fixable in the transport position 30. Each receiving element 56 has for this purpose a first wedge-shaped recess 62 and a second wedge-shaped recess 64. The pivoting device 26 has a wedge element 74. The wedge element 74 is engageable in the driving position 28 with the first recess 62 and in the transport position 30 with the second recess 64 in engagement. Preferably, a cross-sectional profile of the wedge member 74 is complementary to a cross-sectional profile of each of the first and second recesses 62, 64 formed. Each of the first and second recesses 62, 64 is radially outwardly open and widens radially outward.

As long as the wedge member 74 with the first recess 62 or the second

 Recess 64 is engaged, the T retroller 10 is fixed in the driving position or the transport position. Thus, the scooter 10 between the driving position 28 and the Transportpo position 30 is pivotable, the wedge member is out of engagement with the respective Ausneh tion 62, 64 to bring.

In the embodiment illustrated in FIGS. 4 and 5, the wedge element 74 is in FIG

 Engagement with the first recess 62, so that the scooter 10 is fixed in the driving position 28. A detailed illustration of the wedge element 74 and the receiving element 56 can be taken from FIGS. 6A to 6C.

The pivoting device 26 further includes a spring element 84 and a

 Spring retainer 86 on. The spring holder is arranged in the cavity 46 on the running board side 50 of the pivoting device 26. The spring element 84 is connected to the wedge element 74 and the spring holder 86. The spring element preferably has an eye or through bore, to which one end of the spring element 84 can be attached. The other end of the spring element 84 is fastened to a side 82 of the wedge element 74 facing the receiving device 54. Preferably, the Keilele element 74 also has an eyelet 85 or bore on which the receiving device 54 facing side 82 of the wedge member 74 is arranged.

The spring element 84 is arranged so that it the wedge element in the direction of

Recording device 54 biases. Is the wedge element 74 in a recesses 62, 64th arranged, the wedge member 74 is biased by the biasing force of the spring member 84 in the engagement direction with the respective recess 62, 64. The spring element 84 and the spring holder 86 are further arranged between the two receiving elements 56.

The pivoting device 26 further comprises an actuating element 88, a

 Transmission shaft 90 and a motion transmitting member 92. The wedge member 74 further includes a recess 94.

The actuating element 88 is arranged on an outer side of the pivoting device 26. The actuating element 88 is preferably designed as a lever. The transmission shaft 90 extends through the cavity 46 of the pivoting device 26 and is arranged perpendicular to the longitudinal axis 44 of the footboard 14 and perpendicular to the longitudinal axis 42 of the handlebar 12. The transmission shaft 90 is arranged parallel to the shaft 60. The transmission shaft 90 is rotatably supported about a longitudinal axis of the transmission shaft 90 in the cavity 46 of the pivot means. The actuator 88 is disposed perpendicular to the transmission shaft 90. The Betätigungsele element 88 is rotatably connected to the transmission shaft 90. Thereby, a rotational movement of the actuating element 88 can be transmitted to the transmission shaft 90 about a longitudinal axis of the transmission shaft 90.

The motion transmitting member 92 is spoon-shaped and extends perpendicular to the transmission shaft 90 from the transmission shaft 90 away. The motion transmitting member 92 is also rotatably connected to the transmission shaft 90. Thereby, a rotational movement of the transmission shaft 90 can be transmitted to the motion transmission member 92 about a longitudinal axis of the transmission shaft 90. The motion transmitting member 92 extends through the recess 94 of the wedge member 74 therethrough. By a rotational movement of the motion transmitting member 92 about the longitudinal axis of the transmission shaft 90, the wedge member 74 is movable and displaceable in its relative position with respect to the receiving device 54. The actuating element 88 is thus operatively connected via the transmission shaft 90 and the motion transmission element 92 with the wedge element 74, so that the wedge element 74 by a rotational movement of the actuating element 88 against the biasing force of the spring element 84 of the first and the second recess 62, 64th is moved out. Conversely, when the wedge element 74 is moved into the first or the second recess 62, 64 by the biasing force of the spring element 84, the actuating element 88 is rotated.

In other words, the actuator 88 is in between an engagement position 102, in which the wedge member 74 is in engagement with one of the recesses 62, 64, and a transfer position 104, in which the wedge member 74 out of engagement with one of the recesses 62, 64 is rotatable.

In the embodiment shown in Figures 4 and 5, the actuating element

 88 arranged in the engagement position 102.

The pivoting device 26 furthermore has at least one guide element 96.

The guide element 96 has a recess 98. The recess 98 has a first guide surface 99 'and a second guide surface 99 "which extend from a closed end to an open end and between which the wedge element 74 is arranged is constant from the closed end to the open end. The spacing of the guide surfaces 99 ', 99 "of the recess 98 is greater than or equal to a distance of the wedge surfaces 76, 78 of the wedge element 74. The guide element 96 is arranged between the two receiving elements 56. The recess 98 extends radially outward from the receiving device 54 Thus, the recess 98 provides a guide for the wedge member 74 along which the wedge member 74 is movable, and the guide direction is radial to the receiver 54. In other words, the wedge member 74 is movable along the guide direction relative to the receiver 54, so that the wedge member 74 is engageable or disengageable with either one of the recesses 62, 64. The recess 98 further has a depth corresponding to the distance from the closed end to the first one open end corresponds. The depth is at least so great that the wedge member 74 is completely disengageable.

Preferably, the pivoting device 26 has two such guide elements 96. The

 Guide elements 96 are preferably net angeord between the receiving elements 56. Preferably, the spring element 84 and the spring holder 86 are arranged between the two guide elements 96.

The pivoting device 26 furthermore has a securing element 100. The

 Securing element 100 secures the actuating element 88 when the wedge element 74 is brought into engagement with one of the first or the second recess 62, 64. The fuse element 100 is formed so that it is by a force acting perpendicular to the direction of rotation of the actuating element 88, from a secured in an unlocked state can be transferred, wherein the fuse element 100 is biased in the gesicher th state. In the locked state, the securing element 100 blocks a rotational movement of the actuating element 88. In the unlocked state, the securing element 100 releases a rotational movement of the actuating element 88. The securing element is arranged between the engagement position 102 and the transfer position 104 of the actuating element 88.

Preferably, the securing member 100 may have a locking side and an opposite sliding side, wherein the locking side perpendicular to the direction of rotation of the actuating element 88 and the sliding side transversely to the direction of rotation of the Actuate transmission element 88 extends. The actuator 88 is in the engaged position 102 on the locking side of the fuse element 100 when the fuse element 100 is in the locked state, whereby the fuse element 100 blocks the rotational movement of the actuating element 88. If the actuating element 88 is arranged in the transfer position 104, the actuating element 88 is arranged adjacent to the sliding side of the securing element 100. If the actuator 88 is moved by a rotational movement against the sliding side of the fuse element 100, slides the Actuate transmission element 88 along the sliding side and thereby transferred the fuse element 100 against the biasing force from the prestressed secure state in the unlocked state, so that the actuator 88 of the transfer position 104 is movable into the engagement position 102. If the actuating element 88 is moved into the engagement position 102, the securing element 100 is transferred from the unlocked into the secured state as soon as the actuating element 88 has reached the engagement position 102.

In the embodiment shown in Figures 4 and 5, the folding mechanism is arranged in the driving position and the wedge member 74 is in engagement with the first Ausneh determination 62. The actuator 88 is therefore secured by means of the securing element 100.

FIGS. 6A and 6B show the wedge element 74 from FIGS. 4 and 5 in one

 Side view and in an isometric view. The wedge element 74 has a first and a second wedge surface 76, 78. The wedge surfaces 76, 78 extend from a first, the receiving device 54 facing away from 80 to a second, the Aufnahmeein device 54 facing side 82. A distance of the wedge surfaces 76, 78 to each other on the first page 80 is greater than on the second side 82 of the wedge member 74. The wedge surfaces 76, 78 thus run to the receiving device 54 at an angle y aufei each other. The wedge member 74 further includes the recess 94 which extends through the two wedge surfaces 76, 78. The wedge member 74 further includes the eyelet 85 disposed on the second side 82 of the wedge member 74.

FIG. 6C shows a receiving element 56 from FIGS. 4 and 5 in a side view.

Each recess 62, 64 of the receiving element 56 has a first side surface 66 and a second side surface 68. The side surfaces 66, 68 extend from an open end 70 facing the pivoting device to a closed end 72 facing away from the pivoting device. A distance of the side surfaces 66, 68 from each other is greater at the open end 70 than at the closed end 72 Side surfaces 66, 68 thus run at an angle d to each other. Preferably, the angle d in the first recess 62 and the second recess 64 is identical. Preferably, the angle d corresponds to the angle y at which the wedge surfaces 76, 78 converge. A distance of the side surfaces 66, 68 of each recess 62, 64 is at the closed end 72 is less than or equal to a distance of the wedge surfaces 76, 78 of the wedge member 74 on the second side 82. Preferably, at least the distance of the first recess 62nd at the closed end 72 is less than a distance of the wedge surfaces 76, 78 of the wedge member 74 on the second side 82. A distance of the side surfaces 66, 68 of each recess 62, 64 is greater at the open end 70 than a distance of the wedge surfaces 76, 78th of the wedge element 74 on the second side 82.

Each of the recesses 62, 64 has a depth corresponding to the distance between the open and closed ends 70, 72. The depth of the first recess 62 is greater than the depth of the second recess 64. Alternatively, the depth of the first recess 62 may also be equal to the depth of the second recess 64.

The open ends 70 of each recess 62, 64 are spaced substantially equidistant from a center of the bore 58. Alternatively, a distance of the open end 70 of the first recess 62 to the center of the bore 58 may be greater than a distance of the open end 70 of the second recess 64 to the center of the bore 58.

The first side surface 66 of the first recess 62 faces the second recess 64, and the second side surface 68 of the first recess 62 faces away from the second recess 64. The second side surface 68 of the second recess 64 faces the first recess 62, and the first side surface 66 of the second recess 64 faces away from the first recess 62.

In Figures 4 and 5, the wedge member 74 of Figures 6A and 6B is brought into engagement with the first recess 62 of the respective receiving member 56 of Figure 6C. In this case, the first wedge surface 76 lies flat against the first side surface 66. The second wedge surface 78 bears flatly against the second guide surface 99 "flatly.The wedge element 74 is clamped in the driving position 28 between the first side surface 68 and the second guide surface 99". As a result, the pivoting device 26 is supported in the direction of rotation from the driving position 28 to the transport position 30 about the shaft 60 via the wedge surface 76 on the receiving device 54 of the footboard 14. Furthermore, the pivoting device 26 rests in the driving position 28 with the running board side 50 on the front side 36 of the running board 14. As a result, the pivoting device 26 is supported in the opposite direction of rotation from the transport position 30 to the driving position 28 about the shaft 60 on the running board 14.

By supporting the pivoting device 26 on the footboard 14 in both

 Turning around the shaft 60, the pivoting device 26 and the footboard 14 in the driving position 28 are connected together without play.

Alternatively, the wedge member 74 in the driving position 28 on both side surfaces

 66, 68 of the first recess 62 of the respective receiving element 56 abut surface. The wedge element 74 is supported on both side surfaces 66, 68 in both directions of rotation about the shaft 60. The pivoting device 26 is thereby also free of play in the driving position 28 on the running board 14 can be arranged.

FIGS. 7 and 8 show the same folding mechanism 52 of scooter 10 of FIG.

 1, which has been described in Figures 4 and 5, wherein the folding mechanism 52 is arranged in the transport position 30. The wedge element 74 is in engagement with the second recess 64, so that the scooter 10 is fixed in the transport position 30. The actuator 88 is disposed in the engaged position 102 and is secured by the securing member 100.

FIGS. 9 to 11 show the same folding mechanism 52 of scooter 10 of FIG.

 1, which has been described in Figures 4 and 5, wherein the folding mechanism 52 between the driving position and the transport position 30 is arranged. The wedge element 74 is thereby out of engagement with the first and second recesses 62, 64, so that the scooter 10 between the driving position 28 and the transport position 30 is pivotable. The actuating element 88 is arranged in the transfer position 104 and is not secured by the securing element 100.

Fig. 12 shows a first embodiment of a method 200 for folding a

Rollers. The scooter is designed as a scooter 10 according to the figures 1 to 11. In a first step 202 of the method 200, the handlebar 12 and the footboard 14 are arranged relative to each other in a driving position 28 or in a transport position 30, wherein the wedge member 74 in the driving position 28 in engagement with the first recess 62 and in the the transport position 30 is in engagement with the second Ausneh determination 64.

In a further step 204 of the method 200, the handlebar 12 and the

 Footboard 14 pivoted relative to each other in the transport position 30 or in the driving position 28.

In a further step 206 of the method 200, the wedge element 74 with the first

 Recess 62 engaged when the handlebar 12 and the footboard 14 are arranged relative to each other in the driving position 28.

In a further step 208 of the method 200, the wedge element 74 with the second

 Recess 64 engaged when the handlebar 12 and the footboard 14 are arranged relative to each other in the transport position 30.

FIG. 13 shows a further embodiment of a method 200 'for folding a

 Rollers. The scooter is also designed as a scooter 10 according to Figures 1 to 11. The method 200 'comprises all the steps 202, 204, 206, 208 of the method 200.

Preferably, in steps 206 and 208 of engaging, the wedge member becomes

 74 is brought by a biasing force of the spring member 84 into engagement with the first and second recesses 62, 64.

In a further step 210 of the method 200 ', the wedge member 74 by means of

Spring element 84 is biased in the first recess 62 when the handlebar 12 and the footboard 14 are arranged relative to each other in the driving position 28, or biased in the second recess 64 when the handlebar 12 and the footboard 14 are arranged relative to each other in the transport position 30 , In a further step 212 of the method 200 ', the operating member 88, when secured by the securing member 100, is released to allow movement of the operating member.

In a further step 214 of the method 200 ', the actuating element 88 becomes the

 Move out, in particular to disengage, the wedge member 74 from the first recess 62 and the second recess 64 is actuated, in particular ge pivots when the handlebar 12 and the footboard 14 relative to each other in the position Fahrpo 28 and arranged in the transport position 30 are.

In a further step 216 of the method 200 ', the actuating element 88 is secured by the securing element 100 when the wedge element 74 is brought into engagement with the first recess 62 or with the second recess 64.

Claims

claims

A scooter, in particular scooter, comprising a handlebar (12), a footboard (14), a front suspension (16) for carrying at least one front wheel (20), a rear suspension (18) for carrying at least one rear wheel (22 ), an electric auxiliary drive (24) for driving the at least one front and / or the at least one rear wheel (20, 22), and a pivoting device (26), wherein the pivoting device (26), the handlebar (12) and the The footboard (14) pivotally interconnects, so that the handlebar (12) and the footboard (14) relative to each other between a driving position (28) and a transport position (30) are pivotable, and wherein the footboard (14) has a receiving device (54) for receiving the pivoting device (26) having at least one receiving element (56), characterized in that each receiving element (56) has a first and a second wedge-shaped recess (62, 64), wherein the pivoting Einric (26) has a wedge-shaped wedge element (74), and wherein the wedge element (74) in the driving position (28) with the first wedge-shaped recess (62) and in the transport position (30) with the second wedge-shaped recess (64) in Intervention can be brought.

2. Roller according to claim 1, characterized in that the pivoting device (26) has a receptacle (40) for the steering rod (12), in which the handlebar (12) is rotatably mounted.

3. Roller according to claim 1 or 2, characterized in that in the transport position (30) a longitudinal axis (44) of the running board (14) extends substantially parallel to a longitudinal axis (42) of the handlebar (12).

4. Roller according to one of claims 1 to 3, characterized in that in the driving position (28) has a longitudinal axis (44) of the footboard (14) having a longitudinal axis (42) the handlebar (12) an angle a of 45 ° to 120 °, preferably 60 ° to 90 °, in particular 80 °, 81 °, 82 °, 83 °, 84 °, 85 °, 86 °, 87 °, includes.

5. Roller according to one of claims 1 to 4, characterized in that the pivoting device (26) has a shaft (60) on which each receiving element (56) is rotatably mounted.

6. Roller according to claim 5, characterized in that each receiving element (56) has a bore (58) through which the shaft (60) extends.

7. Roller according to one of claims 1 to 6, characterized in that each of the first and second recess (62, 64) is radially outwardly open and widened radially outward.

8. Roller according to one of claims 1 to 7, characterized in that the pivoting device (26) further comprises a spring element (84), wherein the wedge element (74) by means of the spring element (84) in the first recess (62) in the Driving position (28) and in the second recess (64) in the transport position (30) is prestressed.

9. Roller according to claim 8, characterized in that the pivoting device (26) further comprises a spring holder (86), wherein the spring element (84) on one of the receiving device (54) facing side (82) of the wedge element (74) and attached to the spring retainer (86).

10. Roller according to one of claims 1 to 9, characterized in that a depth of the first recess (62) is greater than a depth of the second recess (64).

1 1. Roller according to one of claims 1 to 10, characterized in that a cross-sectional profile of the wedge element (74) complementary to a cross-sectional profile the first recess (62) and / or the second recess (64) is formed.

12. Roller according to one of claims 1 to 10, characterized in that the first recess (62) and the second recess (64) each have two Seitenflä- Chen (66, 68), which extends from an open end (70) a closed end (72) extend, wherein a distance of the respective side surfaces (66, 68) at the open end (70) is greater than a distance of the respective side surfaces (66, 68) at the closed end (72 ).

13. Roller according to claim 12, characterized in that the wedge element (74) has two opposite wedge surfaces (76, 78) facing away from the receiving device (54) side (80) to one of the receiving device (54) Side (82) of the wedge element (74) extend, and wherein the distance of the wedge surfaces (76, 78) to each other on the side facing away from the receiving device (54) side (80) of the wedge member (74) greater than that of the receiving device (54) facing side (82) of the wedge member (74).

14. Roller according to one of claims 13, characterized in that the distance of the side surfaces (66, 68) of the first recess (62) at the closed end (72) is smaller than the distance of the wedge surfaces (76, 78) of the wedge element ( 74) on the receiving device (54) facing side (82).

15. Roller according to claim 13 or 14, characterized in that the distance of the side surfaces (66, 68) of each recess (62, 64) at the open end (70) is greater than the distance of the wedge surfaces (76, 78) of the wedge element (74) on the side facing the receiving device (54) (82).

16. Roller according to one of claims 1 to 15, characterized in that the pivoting device (26) further comprises an actuating element (88), in particular a lever, which is in operative connection with the wedge element (74), so in that the wedge element (74) can be moved out of the first recess (62) and out of the second recess (64).

17. Roller according to claim 16, characterized in that the pivoting device (26) further comprises a motion transmission element (92), wherein the wedge element (74) further comprises a recess (94), wherein the movement transmission element (92) through the recess (94) extends, and wherein the motion transmitting member (92) is rotatably connected to the actuating member (88).

Roller according to one of claims 13 to 15 and according to claim 17, characterized in that the recess (94) extends through both wedge surfaces (76, 78) of the wedge element (74).

19. Roller according to one of claims 16 to 18, characterized in that the pivoting device (26) further comprises a securing element (100) which is designed such that it secures the actuating element (88) when the ke element (74 ) is brought into engagement with the first recess (62) or the second recess (64).

20. Method (200, 200 ') for folding a scooter, in particular a scooter, wherein the scooter comprises a handlebar (12), a running board (14), a front suspension (16) for carrying at least one front wheel (20), a rear one Wheel suspension (18) for carrying at least one rear wheel (22), an electric auxiliary drive (24) for driving the at least one front and / or the at least one rear wheel (20, 22), and a pivoting device (26) wherein the pivoting device (26) pivotably connects the handlebar (12) and the running board (14), wherein the running board (14) has a receiving device (54) for receiving the pivoting device (26) with at least one receiving element (56) each receiving element (56) having a first and a second wedge-shaped recess (62, 64), wherein the pivoting direction (26) has a wedge-shaped wedge element (74), wherein the method (200, 200 ') comprises the following steps:

Arranging (202) the handlebar (12) and the footboard (14) relative to each other in a driving position (28) or in a transporting position (30) where the wedge element (74) engages the driving position (28) first recess (62) and in the transport position (30) in engagement with the second recess (28);

Pivoting (204) the handlebar (12) and the footboard (14) relative to each other in the transport position (28) or in the driving position (30); and engaging (206) the wedge member (74) with the first recess (62) when the handlebar (12) and the footboard (14) are disposed relative to each other in the driving position (28) or engaging (208) of the wedge member (74) with the second recess (64) when the handlebar (12) and the footboard (14) are arranged relative to each other in the transport position (30).

21. The method according to claim 20, characterized in that the pivoting device (26) further comprises a spring element (84), wherein in the steps of engaging (206, 208) the wedge element (74) by a biasing force of the spring element (84) is brought into engagement with the first recess (62) or the second recess (64).

22. The method according to claim 21, characterized in that the method (200, 200 ') further comprises the step:

Biasing (210) the wedge element (74) by means of the spring element (84) in the first recess (62) when the handlebar (12) and the footboard (14) are arranged relative to each other in the driving position (28), or in the second recess (64) when the handlebar (12) and the footboard (14) relative to each other in the transport position (30) are arranged.

23. The method according to any one of claims 20 to 22, characterized in that the pivoting device (26) further comprises an actuating element (88), in particular a lever which is in operative connection with the wedge element (74), where in the method ( 200, 200 ') further comprises the step of:

Releasing (212) the actuator (88) to permit movement of the actuator (88).

24. The method according to any one of claims 20 to 23, characterized in that the pivoting device () 26 further comprises an actuating element (88), in particular a lever which is in operative connection with the wedge element (74), wherein the Method (200, 200 ') further comprises the step of:

Actuating (214), in particular pivoting, the actuating element (88) for moving the wedge element (74) out of the first recess (62) when the steering rod (12) and the running board (14) are arranged relative to one another in the driving position (28) , or from the second recess (64), when the handlebar (12) and the footboard (14) are arranged relative to each other in the transport position (30).

25. The method according to claim 24, characterized in that the method (200, 200 ') further comprises the step:

Securing (216) the actuator (88) when the wedge member (74) is engaged with the first recess (62) or the second recess (64).