DE202018101755U1 - Arrangement of electronic components in an electric scooter - Google Patents

Abstract

Scooter, in particular scooter, comprising a handlebar (12), a running board (14) having a tread (15) for supporting a user of the scooter, a front suspension (16) for carrying at least one front wheel (20), one rear suspension ( 18) for supporting 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), a memory device (118) for storing electrical energy, in particular an accumulator, and a control device (116), in particular control electronics, for controlling the electronic auxiliary drive (24), characterized in that the roller further comprises a charger (114) for charging the memory device (118), wherein the memory means (118 ), the control device (116) and the charger (114) are arranged below the tread surface (15).

Description

The present invention relates to a scooter, in particular a scooter, with 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, a memory device for storing electrical energy, in particular an accumulator, and a control device, in particular a control electronics, for controlling the electric auxiliary drive.

Such scooters are well known in the art.

For example, the document shows WO 2011/148125 A1 a scooter having a cavity in the running board, in which a receptacle for battery cells and various components for controlling the electronic drive are arranged. In the receptacle for the battery cells several battery cells can be introduced.

Furthermore, for example, the document shows CN 203228897 U an electrically operated scooter, in the footboard an electrical storage unit and control electronics is housed. The footboard has a connection on the side for a charging cable of a charger.

Furthermore, for example, the document shows DE 10 2013 003 484 A1 an electrically operated scooter, which has an electrical energy storage device for storing electrical energy for the drive motor, which is arranged in a battery compartment under the foot platform. The scooter may further include a battery management system and a drive motor controller coupled with a display device to the handlebar. The scooter may further include an integrated charger.

Furthermore, for example, the document shows EN 10 2016 210 107 B3 an electrically powered scooter, in the footboard a rechargeable electrical energy storage is arranged. The scooter further comprises actuating means arranged on the handlebar for activating, deactivating and / or regulating the electromotive drive.

It is therefore an object of the present invention to provide an improved scooter with electric auxiliary drive, in particular improves the charging function of the scooter.

According to one aspect of the invention, the described scooter, in particular a scooter, with 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, a storage device for storing electrical energy, in particular an accumulator, and a control device, in particular a control electronics, for controlling the electric auxiliary drive. The scooter further includes a charger for charging the memory device. The storage device, the control device and the charger are arranged below a tread surface of the footboard.

So far, it was necessary for longer trips electrical components, such as an external charger or a charging cable for charging the storage device or a spare battery or replacement batteries to replace the storage device to carry separately. This is avoided in the present invention. This results in a significant gain in comfort over the known scooters for a user of the scooter, since the user does not need to provide additional storage space for these electrical components in his luggage.

Furthermore, it is advantageous if the electrical components are arranged so that the cable paths between the electronic components are as small as possible. This saves space and weight. This becomes all the more relevant, the more electronic components a scooter has and are controlled by the control device.

Electrical components of the scooter can basically be arranged in or on the handlebar. This can make the footboard thinner or place a larger battery in the footboard to increase the range.

Electrical components with a large footprint, in particular a charger or a control device, can not now easily accommodate in the handlebar without increasing the dimensions of the handlebar. As a result, the handlebar as a whole larger, especially thicker, and thus with constant stability also heavier. Overall, this results in that the center of gravity of the scooter is higher. A higher center of gravity is unfavorable in terms of driving dynamics.

It is therefore advantageous if these electronic components below the footboard are arranged because of the center of gravity is lower, whereby the driving dynamics is improved.

The object initially posed is thus fully solved.

In one embodiment of the scooter can be provided that the footboard has a thickness, wherein the footboard forms a first cavity below the tread surface, wherein the storage device, the control device, and the charger are arranged in the first cavity.

The first cavity thus surrounds the essential electrical components, in particular the charger, the control device and the storage device, and thus protects them against external influences. In addition, the wall of the first cavity also increases the weight in the lower part of the scooter, thus causing the center of gravity of the scooter to lower.

In a further embodiment of the scooter can be provided that the thickness of the footboard 2 cm to 10 cm, preferably 3 cm to 8 cm, in particular 5 cm.

The thickness of the footboard has a significant influence on the distance between the tread and the ground on which the scooter is arranged with the wheels in the driving position. For a user of the scooter is a small ground clearance to the tread of advantage because it makes it easier to get on and off and easier to push the scooter. Preferably, the ground clearance of the tread is less than 20 cm, preferably less than 15 cm. On the other hand, the thickness of the running board also determines the available space for electronic components which are arranged in the running board, in particular the size and thus also the capacity of the storage unit. The larger the capacity of the storage unit, the greater the range of the scooter. Preferably, the thickness of the footboard is 3 cm to 8 cm, in particular 5 cm.

In a further embodiment of the scooter can be provided that the scooter further comprises a charging cable, which is electrically connected to the charger.

The scooter thus has all the essential electrical components needed to load the scooter. As a result, a user of the scooter does not have to carry any additional electrical components, such as a charger or charging cable, to charge the scooter anywhere.

In a further embodiment of the scooter can be provided that the charging cable can be connected to an electrical power supply to supply the charger with electrical voltage.

This makes it possible to load the scooter anywhere where a corresponding power supply is provided. The charging cable and the charger are preferably designed so that they can be connected to a conventional power supply, which preferably provides an AC voltage of 100-240 V, by means of a corresponding connector.

In a further embodiment of the scooter can be provided that the roller has a connecting device which connects the handlebar and the footboard together, wherein the connecting device forms a second cavity, wherein the charging cable extends from the charger into the second cavity of the connecting device.

Thus, the charging cable is stowed in an advantageous manner in the scooter, without taking up unnecessary space in the footboard. As a result, there is more space in the footboard for the remaining electrical components, in particular for the storage unit. In addition, it is advantageous that the connecting device connects directly to the footboard. As a result, the cable path of the charging cable is kept as small as possible from its stowed location to the charger.

In a further embodiment of the scooter can be provided that the footboard on the side facing the connecting device has an opening through which the charging cable extends from the first cavity into the second cavity.

By means of the opening, the charging cable is led directly from the charger from the first cavity into the second cavity.

In a further embodiment of the scooter can be provided that the connecting device comprises a hinged flap element, which is designed so that the charging cable from the connecting device for loading is at least partially removed.

As a result, on the one hand, the charging cable can be safely stowed in the connecting device both during the driving operation of the scooter in the driving position and during the transport of the scooter in the transport position. On the other hand, the folding element provides access to the charging cable in a simple and compact manner.

In a further embodiment of the scooter can be provided that the Connecting device is designed as a pivoting device which connects the handlebar and the footboard pivotally with each other, so that the handlebar and the footboard are pivotable relative to each other between a driving position and a transport position.

The connecting device thus serves both for relative pivoting of the handlebar and the footboard to each other and as a storage location for the charging cable. Preferably, the pivoting device is pivotally mounted on the footboard. The charging cable is guided out of the first cavity of the footboard in the second cavity of the connecting device, that it is not tensioned by the pivoting during pivoting but is carried so that it remains in a relaxed state, and that it does not pivot with the Folding mechanism collides.

In a further embodiment of the scooter can be provided that the charger is arranged on one of the connecting device side facing the footboard.

Since the charging cable extends into the second cavity of the connecting device, it is advantageous if the charger is arranged on the side facing the connecting device of the footboard, because thus the cable path of the charging cable is kept as low as possible.

In a further embodiment of the scooter can be provided that the control device is arranged on the side facing the connecting device side of the footboard and the storage device on a side facing away from the connecting device of the footboard.

Since the storage device generally requires the most space in the footboard, it is advantageous if the control device and the charger are arranged on one side of the footboard and the storage device is arranged on an opposite side, since thus the electronic components burst in the first cavity fill the footboard as advantageous as possible.

In a further embodiment of the scooter can be provided that the charger is electrically connected to the memory device.

As a result, the charger does not have to be complexly connected to the storage device first. This simplifies loading for a user of the scooter.

In a further embodiment of the scooter can be provided that the tread has a width of 10 cm to 20 cm, preferably 13 cm to 18 cm, in particular 16 cm, wherein the tread a length of 30 cm to 60 cm, preferably 40 cm to 50 cm, in particular 45 cm.

The size of the tread affects in a decisive way, the dimensioning of the entire running board. A large tread makes it possible to provide the footboard with the smallest possible thickness, without reducing the space provided for the electrical components, such as the charger, control device and storage device. On the other hand, too wide a tread makes it difficult to manually push off or get on and off a user of the scooter and thus reduces the ride comfort. Too long a tread makes it difficult to transport the scooter. Too narrow or too short tread makes it difficult for the user to stand on the tread safely. The size of the tread depends accordingly on the needs of a user. The tread is therefore to be dimensioned so that on the one hand the ride comfort for a user of the scooter and on the other hand, the space for electrical components is maximized as possible.

In a further embodiment of the scooter it can be provided that the at least one front wheel and the at least one rear wheel are the same size, in particular wherein the at least one front wheel and the at least one rear wheel have a diameter of 10 to 35 cm, in particular 25.4 cm. Alternatively, the front wheel and the rear wheel may be formed differently in size.

The rim size depends on two factors. On the one hand, a relatively large rim size offers greater ride comfort for a user of the scooter and increases the efficiency of the electric auxiliary drive. On the other hand, a large rim increases the weight of the scooter and makes it difficult to transport the scooter, especially in a folded state. The rim therefore preferably has a rim size of 10 inches or 25.4 cm.

In a further embodiment of the scooter can be provided that the at least one front wheel and the at least one rear wheel in the driving position on a floor, with a distance between the tread and the ground 6 cm to 25 cm, preferably 8.5 cm to 18 cm, in particular 12 cm.

It is advantageous if the distance between the ground and tread surface is as small as possible, as a user can better push the scooter and the center of gravity of the scooter is lower, which is difficult by tilting the scooter. The smaller the distance between the tread and the ground becomes, the smaller the space for the electrical components, such as the charger, Control device and storage device, which are arranged below the tread surface between the tread surface and the ground. The ground clearance of the tread is thus dimensioned so that ride comfort for a user and space for electrical components are maximally possible.

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

• 1 eine isometrische Ansicht einer Ausführungsform eines Tretrollers, der in einer Fahrposition angeordnet ist;
• 2 eine Seitenansicht des Tretrollers aus 1;
• 3 eine Seitenansicht des Tretrollers aus 1, wobei der Tretroller in einer Transportposition angeordnet ist;
• 4 eine isometrische Ansicht eines Klappmechanismus des Tretrollers aus 1 in der Fahrposition;
• 5 eine Detailansicht des Klappmechanismus aus 4;
• 6a eine Draufsicht auf ein Keilelement des Klappmechanismus aus 4;
• 6b eine isometrische Ansicht des Keilelement des Klappmechanismus aus 4;
• 6c eine Draufsicht auf ein Aufnahmeelement des Klappmechanismus aus 4;
• 7 eine isometrische Ansicht des Klappmechanismus aus 4 in der Transportposition;
• 8 eine Detailansicht des Klappmechanismus aus 7;
• 9 eine isometrische Ansicht des Klappmechanismus aus 4 zwischen der Fahrposition und der Transportposition;
• 10 eine Detailansicht des Klappmechanismus aus 9;
• 11 eine Seitenansicht des Klappmechanismus aus 9;
• 12 eine Draufsicht auf das Trittbrett des Tretrollers aus 1 ohne Trittfläche;
• 13 eine isometrische Ansicht des Trittbretts und der Schwenkeinrichtung des Tretrollers aus 1;
• 14 eine isometrische Ansicht des Trittbretts und der Schwenkeinrichtung des Tretrollers aus 13 mit aufgeklapptem Klappelement; und
• 15 eine isometrische Ansicht des Trittbretts und der Schwenkeinrichtung des Tretrollers aus 13 ohne Klappelement und Trittfläche.

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

• 1 an isometric view of an embodiment of a scooter, which is arranged in a driving position;
• 2 a side view of the scooter from 1 ;
• 3 a side view of the scooter from 1 wherein the scooter is arranged in a transport position;
• 4 an isometric view of a folding mechanism of scooter from 1 in the driving position;
• 5 a detailed view of the folding mechanism 4 ;
• 6a a plan view of a wedge element of the folding mechanism 4 ;
• 6b an isometric view of the wedge element of the folding mechanism 4 ;
• 6c a plan view of a receiving element of the folding mechanism 4 ;
• 7 an isometric view of the folding mechanism 4 in the transport position;
• 8th a detailed view of the folding mechanism 7 ;
• 9 an isometric view of the folding mechanism 4 between the driving position and the transport position;
• 10 a detailed view of the folding mechanism 9 ;
• 11 a side view of the folding mechanism 9 ;
• 12 a top view of the footboard of scooter from 1 without tread;
• 13 an isometric view of the running board and the pivoting device of scooter from 1 ;
• 14 an isometric view of the running board and the pivoting device of scooter from 13 with unfolded folding element; and
• 15 an isometric view of the running board and the pivoting device of scooter from 13 without folding element and tread.

The 1 and 2 show an embodiment of a scooter 10 who is in a driving position 28 is arranged. The scooter 10 has a handlebar 12 , a footboard 14, a front suspension 16 and a rear suspension 18 on. The handlebar 12 has an upper and a lower end 32 . 34 on. The footboard has a front 36 and a backside 38 on. The footboard 14 also has a tread 15 for carrying a user of the scooter 10 on. The tread 15 extends at least partially from the front 36 to the back 38 of the running board 14 ,

The front suspension 16 is at the bottom 34 the handlebar 12 arranged. In other words, the bottom end 34 the handlebar 12 the front suspension 16 facing and the upper end 32 the handlebar 12 the front suspension 16 away. The front suspension 16 is non-rotatable with the handlebar 12 connected. Preferably, the handlebar forms 12 the front suspension 16 out.

The rear suspension 18 is at the back 38 of the running board 14 arranged. In other words, the front is 36 of the running board 14 the front suspension 16 and the handlebar 12 facing and the rear suspension 18 away. The backside 38 of the running board 14 is the rear suspension 18 facing and the front suspension 16 and the handlebar 12 away. The footboard 14 is preferably disposed substantially between the front and rear suspensions 16, 18. Preferably, the footboard forms 14 the rear suspension 18 out.

The scooter preferably has a front wheel 20 which is also called front wheel, and a rear wheel 22 , which is also called rear wheel, on. The front suspension 16 forms a holder for the front wheel 20 out. An axle of the front wheel 20 is stored in the bracket so that the front suspension 16 the front wheel 20 wearing. The rear suspension 18 forms a holder for the rear wheel 22 out. An axle of the rear wheel 22 is stored in the bracket so that the rear suspension 18 the rear wheel 22 wearing.

The front wheel 20 and the rear wheel 22 each preferably have a diameter of 15 cm to 35 cm, in particular 25.4 cm, on. The footboard 14 is essentially between the front wheel 20 and the rear wheel 22 arranged. 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 also have a plurality of front wheels and / or rear wheels, wherein the brackets of the front suspension 16 and the rear suspension 18 are designed such that they can carry the multiple front wheels and / or rear wheels.

The footboard 14 of the 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 running board 14 extends perpendicular to the tread 15 of the running board 14 , The footboard 14 has a length extending longitudinally from the rear 38 to the front 36 of the running board 14 extends. The length of the running board 14 is smaller than the axis distance in a driving position 28 of the scooter 10 , The tread 15 has a length that is less than or equal to the length of the running board 14 and is preferably 30 cm to 60 cm, preferably 40 cm to 50 cm, in particular 45 cm. The footboard 14 furthermore 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 running board 14 extends perpendicular to the longitudinal direction and parallel to the tread surface 15 , The width of the running board 14 is greater than or equal to a width of the tread 15 ,

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

The scooter 10 also has an electric auxiliary drive 24 on. The electric auxiliary drive 24 is designed to be the front wheel 20 and / or the rear wheel 22 drive. The electric auxiliary drive 24 is preferably in the front wheel 20 and / or in the rear wheel 22 arranged. Alternatively, the electric auxiliary drive 24 also in the front suspension 16 and / or in the rear suspension 18 be arranged. In the illustrated embodiment, the electric auxiliary drive 24 in the rear wheel 22 arranged.

The scooter 10 further includes a pivoting device 26 on. The pivoting device 26 connects the handlebar 12 and the running board 14 pivotable with each other, leaving the handlebar 12 and the running board 14 relative to each other between the driving position 28 and a transport position 30 are pivotable. The pivoting device 26 is between the handlebars 12 and the running board 14 arranged. The pivoting device 26 points to a front, the handlebar 12 facing side a shot 40 for the handlebar 12 on, in the handlebar 12 around a longitudinal axis 42 the handlebar 12 is rotatably mounted. The longitudinal axis 42 The handlebar runs centrally in the handlebar 12 from the lower end 34 to the upper end 32 , The recording 40 may preferably be formed as a through hole, wherein the handlebar 12 extends through the through hole.

Preferably, the handlebar 12 at the pivoting device 26 Lockable, allowing a rotational movement of the handlebar 12 around the longitudinal axis 42 the handlebar 12 in the recording 40 the pivoting device 26 can be locked or lockable when the scooter 10 in the transport position 30 is arranged, and can be released or is releasable when the scooter 10 in the driving position 28 is arranged.

The pivoting device 26 is on the back, the running board 14 facing side with the footboard 14 pivotally connected. The rear side of the pivoting device 26 is so schenkbar on the front 36 of the running board 14 stored that the handlebar 12 and the footboard 14 relative to each other between the driving position 28 and a transport position 30 are pivotable.

In 1 and 2 is the scooter 10 in the driving position 28 shown. In the driving position are handlebar 12 and the running board 14 arranged relative to one another such that a longitudinal axis 44 of the running board 14 in the middle of the running board 14 from the front 36 to the back 38 of the running board 14 runs, with the longitudinal axis 42 the handlebar 12 an angle α of 45 ° to 120 °, preferably 60 ° to 90 °, in particular 80 °, 81 °, 82 °, 83 °, 84 °, 85 °, 86 °, 87 °.

3 shows the scooter 10 from the 1 and 2 , where the scooter in the transport position 30 is arranged. In the transport position 30 are the handlebar 12 and the running board 14 arranged so relative to each other that the longitudinal axis 44 of the running board 14 substantially parallel to the longitudinal axis 42 the handlebar 12 runs. Preferably, the longitudinal axis closes 44 of the running board 14 with the longitudinal axis 42 the handlebar 12 an angle α between 0 ° and 10 °, in particular 5 °, a.

In the 4 to 11 becomes a folding mechanism 52 of the scooter 10 out 1 describe in more detail.

The 4 and 5 show the folding mechanism 52 of the scooter 10 out 1 , where the folding mechanism 52 in the driving position 28 is arranged. The folding mechanism has elements of the pivoting device 26 and the running board 14 on that interact so that the scooter 10 between the driving position 28 and the transport position 30 is pivotable.

The footboard 14 has a recording device 54 on. The receiving device 54 is at the pivoting device facing front 36 of the running board 14 arranged. The recording device 54 has two receiving elements 56 on. The recording elements 56 are on the front of the pivoting device facing 36 of the running board 14 arranged side by side in a direction perpendicular to the longitudinal axis 44 of the running board 14 and perpendicular to the longitudinal axis 42 the handlebar 12 runs. The recording elements 56 essentially extend from a bottom of the running board 14 up to the tread 15 of the running board 14 , The recording elements 56 each have a hole 58 on. The holes 58 the receiving elements 56 are at the same height between the underside of the running board 14 and the tread 15 of the running board 14 arranged. Alternatively, only one receiving element 56 with a hole 58 be provided.

Furthermore, the pivoting device forms 26 a cavity 46 off, extending from one of the handlebars 12 facing handlebar side 48 the pivoting device 26 to a footboard 14 facing footboard side 50 the pivoting device 26 extends. In the cavity 46 are pivoting device-side elements of the folding mechanism 52 arranged. The pivoting device 26 points in the cavity 46 a wave 60 on. The wave 60 extends through the cavity 46 and is perpendicular to the longitudinal axis 44 of the running board 14 and perpendicular to the longitudinal axis 42 the handlebar 12 arranged. The recording elements 56 are on the wave 60 rotatably mounted. The wave 60 extends through the holes 58 the receiving elements 56 , By means of this rotatable bearing are the handlebar 12 and the running board 14 pivotable relative to each other.

The folding mechanism 52 also has elements on the side of the swivel device and on the side of the footboard, through which the scooter can pass 10 in the driving position 28 and in the transport position 30 can be fixed. Each receiving element 56 has for this purpose a first wedge-shaped recess 62 and a second wedge-shaped recess 64 on. The pivoting device 26 has a wedge element 74 on. The wedge element 74 is in the driving position 28 with the first recess 62 and in the transport position 30 with the second recess 64 engageable. Preferably, this is a cross-sectional profile of the wedge element 74 complementary to a cross-sectional profile of each of the first and second recesses 62 . 64 educated. Each of the first and second recesses 62 , 64 is radially outwardly open and widens radially outward.

As long as the wedge element 74 with the first recess 62 or the second recess 64 is engaged, is the scooter 10 fixed in the driving position or the transport position. So the scooter 10 between the driving position 28 and the transport position 30 is pivotable, the wedge element is disengaged from the respective recess 62 . 64 bring to.

In the in the 4 and 5 illustrated embodiment is the wedge element 74 in engagement with the first recess 62 so the scooter 10 in the driving position 28 is fixed. A detailed illustration of the wedge element 74 and the receiving element 56 is the 6A to 6C refer to.

The pivoting device 26 further includes a spring element 84 and a spring holder 86 on. The spring retainer is in the cavity 46 on the running board side 50 of the pivoting device 26 arranged. The spring element 84 is with the wedge member 74 and the spring holder 86 connected. The spring element preferably has an eyelet or throughbore, at one end of the spring element 84 can be attached. The other end of the spring element 84 is at one of the receiving device 54 facing side 82 of the wedge element 74 attached. Preferably, the wedge member 74 also an eyelet 85 or puncture on, at the receiving device 54 facing side 82 of the wedge element 74 is arranged.

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

The pivoting device 26 further includes an actuator 88 , a transmission wave 90 and a motion transmitting member 92 on. The wedge member 74 further includes a recess 94 on.

The actuator 88 is on an outside of the pivoting device 26 arranged. The actuator 88 is preferably designed as a lever. The transmission wave 90 extends through the cavity 46 the pivoting device 26 and is perpendicular to the longitudinal axis 44 of the running board 14 and perpendicular to the longitudinal axis 42 the handlebar 12 arranged. The transmission wave 90 is parallel to the wave 60 arranged. The transmission wave 90 is rotatable about a longitudinal axis of the transmission shaft 90 in the cavity 46 the pivoting device stored. The actuator 88 is perpendicular to the transmission shaft 90 arranged. The actuator 88 is non-rotatable with the transmission shaft 90 connected. This allows a rotational movement of the actuating element 88 about a longitudinal axis of the transmission shaft 90 on the transmission shaft 90 be transmitted.

The motion transmission element 92 is spoon-shaped and extends perpendicular to the transmission shaft 90 from the transmission shaft 90 path. The motion transmission element 92 is also non-rotatable with the transmission shaft 90 connected. This can cause a rotational movement of the transmission shaft 90 about a longitudinal axis of the transmission shaft 90 on the motion transmission element 92 be transmitted. The motion transmission element 92 extends through the recess 94 of the wedge element 74 therethrough. By a rotational movement of the motion transmission element 92 around the longitudinal axis of the transmission shaft 90 is the wedge element 74 in its relative position with respect to the receiving device 54 movable and displaceable.

The actuator 88 thus stands over the transmission wave 90 and the motion transmitting member 92 with the wedge element 74 Operative connection, so that the wedge element 74 by a rotational movement of the actuating element 88 against the biasing force of the spring element 84 from the first and from the second recess 62, 64 is moved out. Conversely, if the wedge element 74 by the biasing force of the spring element 84 in the first or the second recess 62 . 64 is moved in, the actuating element 88 turned.

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

In the in the 4 and 5 illustrated embodiment, the actuating element 88 is in the engaged position 102 arranged.

The pivoting device 26 furthermore has at least one guide element 96 on. The guide element 96 has a recess 98 on. 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. A distance of the guide surfaces 99 ' . 99 " the recess 98 is constant from the closed end to the open end. The distance between the guide surfaces 99 ' . 99 " 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 between the two recording elements 56 arranged. The recess 98 extends radially outward from the receiving device 54 path. The recess 98 thus represents the wedge element 74 a guide ready along the wedge element 74 is movable. The guide direction is radially to the receiving device 54 , In other words, the wedge element 74 along the guide direction relative to the receiving device 54 movable, so that the wedge element 74 either with one of the recesses 62 . 64 engageable or disengageable. The recess 98 Further, it has a depth corresponding to the distance from the closed end to the open end. The depth is at least so great that the wedge element 74 completely disengaged.

Preferably, the pivoting device 26 two such guide elements 96 , The guide elements 96 are preferably between the receiving elements 56 arranged. Preferably, the spring element 84 and the spring holder 86 between the two guide elements 96 arranged.

The pivoting device 26 further includes a fuse element 100 on. The fuse element 100 secures the actuator 88 if the wedge element 74 in engagement with one of the first or the second recess 62 . 64 brought is. The fuse element 100 is designed so that it by a force perpendicular to the direction of rotation of the actuator 88 acts, from a secured to an unlocked state is feasible, the fuse element 100 is biased in the secured state. In the locked state, the securing element 100 blocks a rotational movement of the actuating element 88 , In the unlocked state gives the fuse element 100 a rotational movement of the actuating element 88 free. The securing element is between the engagement position 102 and the transfer position 104 of the actuator 88 arranged.

Preferably, the securing element 100 a blocking side and an opposite one Sliding side, wherein the locking side perpendicular to the direction of rotation of the actuating element 88 and the sliding side transverse to the direction of rotation of the actuating element 88 extends. The actuator 88 is in the engaged position 102 on the blocking side of the securing element 100 when the fuse element 100 in the secured state, causing the fuse element 100 the rotational movement of the actuating element 88 blocked. Is the actuator 88 in the transfer position 104 arranged, is the actuating element 88 adjacent to the sliding side of the securing element 100 arranged. Will the actuator 88 by a rotational movement against the sliding side of the securing element 100 moves, slides the actuator 88 along the sliding side and thereby transferred the securing element 100 against the biasing force from the prestressed secured state in the unlocked state, so that the actuating element 88 from the transfer position 104 to the engaged position 102 is movable. Will the actuator 88 in the engaged position 102 moves, the fuse element becomes 100 transferred from the unlocked to the secured state as soon as the actuator 88 the engaged position 102 has reached.

In the in the 4 and 5 illustrated embodiment, the folding mechanism is arranged in the driving position and the wedge element 74 is in engagement with the first recess 62 , The actuator 88 is therefore by means of the fuse element 100 secured.

The 6A and 6B show the wedge element 74 from the 4 and 5 in a side view and in an isometric view. The wedge element 74 has a first and a second wedge surface 76 . 78 on. The wedge surfaces 76 . 78 extend from a first, the receiving device 54 opposite side 80 to a second, the receiving device 54 facing side 82 , A distance from the wedge surfaces 76 . 78 each other is on the first page 80 bigger than on the second page 82 of the wedge element 74 , The wedge surfaces 76 . 78 thus run to the recording device 54 at an angle γ towards each other. The wedge element 74 also has the recess 94 on, extending through the two wedge surfaces 76 . 78 extends. The wedge element 74 also has the eyelet 85 on the second side 82 of the wedge element 74 is arranged.

The 6C shows a receiving element 56 from the 4 and 5 in a side view. Every recess 62 . 64 of the receiving element 56 has a first side surface 66 and a second side surface 68 on. The side surfaces 66 . 68 extend from an open, the pivoting end facing 70 to a closed, the pivoting end facing away 72 , A distance of the side surfaces 66 . 68 each other is at the open end 70 larger than at the closed end 72 , The side surfaces 66 . 68 thus converge towards each other at an angle δ. Preferably, the angle δ at the first recess 62 and the second recess 64 identical. Preferably, the angle δ corresponds to the angle γ, below which the wedge surfaces 76 . 78 to run towards each other.

A distance of the side surfaces 66 . 68 every recess 62 . 64 is at the closed end 72 less than or equal to a distance of the wedge surfaces 76 . 78 of the wedge element 74 on the second page 82 , Preferably, at least the distance of the first recess 62 at the closed end 72 smaller than a distance of the wedge surfaces 76 . 78 of the wedge element 74 on the second page 82 , A distance of the side surfaces 66 . 68 every recess 62 . 64 is at the open end 70 greater than a distance of the wedge surfaces 76 . 78 of the wedge element 74 on the second page 82 ,

Each of the recesses 62 . 64 has a depth equal to the distance between the open and closed ends 70 . 72 equivalent. 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 also equal to the depth of the second recess 64 be.

The open ends 70 every recess 62 . 64 are essentially equidistant from a center of the hole 58 spaced. Alternatively, a distance of the open end 70 the first recess 62 to the middle of the hole 58 greater than a distance of the open end 70 the second recess 64 to the middle of the hole 58 be.

The first side surface 66 the first recess 62 is the second recess 64 facing and the second side surface 68 the first recess 62 is the second recess 64 away. The second side surface 68 the second recess 64 is the first recess 62 facing and the first side surface 66 the second recess 64 is the first recess 62 away.

In the 4 and 5 is the wedge element 74 from the 6A and 6B in engagement with the first recess 62 of the respective receiving element 56 out 6C brought. This is the first wedge surface 76 flat on the first side surface 66 at. The second wedge surface 78 lies flat on the second guide surface 99 " flat on. The wedge member 74 is in the driving position 28 between the first side surface 68 and the second guide surface 99 " clamped. As a result, the pivoting device 26 in the direction of rotation from the driving position 28 to the transport position 30 around the shaft 60 over the wedge surface 76 at the receiving device 54 of the running board 14 supported.

Furthermore, the pivoting device is located 26 in the driving position 28 with the footboard side 50 at the front 36 of the running board 14 at. This is the pivoting device 26 in the opposite direction of rotation from the transport position 30 to the driving position 28 around the shaft 60 on the running board 14 supported.

By supporting the pivoting device 26 on the running board 14 in both directions around the shaft 60 are the pivoting device 26 and the running board 14 in the driving position 28 connected without play.

Alternatively, the wedge element 74 also in the driving position 28 on both side surfaces 66, 68 of the first recess 62 of the respective receiving element 56 lie flat. The wedge element 74 is on both sides 66 . 68 in both directions around the shaft 60 supported. The pivoting device 26 is thus also backlash in the driving position 28 on the running board 14 arranged.

The 7 and 8th show the same folding mechanism 52 of the scooter 10 out 1 in the 4 and 5 has been described, the folding mechanism 52 in the transport position 30 is arranged. The wedge element 74 is in engagement with the second recess 64 so the scooter 10 in the transport position 30 is fixed. The actuator 88 is in the engaged position 102 arranged and is through the fuse element 100 secured.

The 9 to 11 show the same folding mechanism 52 of the scooter 10 out 1 in the 4 and 5 has been described, the folding mechanism 52 between the driving position and the transport position 30 is arranged. The wedge element 74 is disengaged from the first and second recesses 62 . 64 so the scooter 10 between the driving position 28 and the transport position 30 is pivotable. The actuator 88 is in the transfer position 104 arranged and is through the fuse element 100 not safe.

The 12 to 15 show an embodiment of the scooter 10 out 1 , the electrical components for operating the scooter 10 and the electric auxiliary drive 24 having. The scooter 10 has a memory device as electrical components 118 for storing electrical energy, a charger 114 for loading the storage device 118 , a first control device 116 for controlling the electric auxiliary drive 24 on. Preferably, the scooter further comprises a second control device 117 to control a charger 114 on. Alternatively, the scooter 10 also have only one control device, which is the first control device 116 and the second control device 117 formed. The first control device 116 and the second control device 117 are preferably designed as control electronics. The storage device 118 is preferably designed as an accumulator.

Alternatively, the first control device 116 for controlling the electric auxiliary drive 24 and for controlling a charger 114 be educated. In this case, the control device 117 be designed as an additional module for providing additional functions. As an additional function, for example, a rollersharing control can be provided.

The footboard 14 has a first footboard page 113 and a second running board side 115 on, which are arranged opposite to each other. The first footboard page 113 and the second footboard side 115 extend from the front 36 to the back 38 of the running board 14 and from the tread 15 to one of the tread 15 opposite underside of the footboard 14 , The direction from the back 38 extends to the front side 36, corresponds to a longitudinal direction. The direction from the first running board side 113 to the second running board side 115 runs, corresponds to a transverse direction.

The footboard 14 of the scooter 10 forms in this embodiment below the tread 15 a cavity 112 out. The cavity 112 has a length extending in the longitudinal direction, a width extending in the transverse direction, and a height extending from the underside of the footboard 14 to the tread 15 the footboard extends. A wall of the cavity 112 preferably has a thickness of 0.2 cm to 1 cm, in particular 0.5 cm. The first control device 116 , the second control device 117 , the storage device 118 and the charger 114 are in the cavity 112 of the running board 14 arranged. The height of the cavity 112 is preferably 1 cm to 9 cm, in particular 4 cm. The width of the cavity 112 is preferably 8 cm to 19 cm, in particular 15 cm. The length of the cavity 112 is preferably 29 cm to 59 cm, in particular 44 cm.

The 12 shows the footboard 14 of the scooter 10 out 1 in a plan view without tread 15 , The storage device 118 is at the back 38 of the running board 14 arranged. The storage device 118 extends transversely from the first footboard side 113 to the second footboard side 115 , The first control device 116 is at the front 36 of the running board 14 and at the first Footboard page 113 arranged. The charger 114 is at the front 36 of the running board 14 and on the second footboard side 115 arranged. The second storage device 117 is at the first footboard side between the first controller 116 and the storage device 118 arranged. The storage device 118 extends parallel to the longitudinal direction from the rear side 38 up to the charger 114 and the second storage device 117 , The storage device 118 extends in the longitudinal direction over half the length of the cavity 112 , The charger 114 extends parallel to the longitudinal direction of the front 36 to the storage device 118 , The first control device 116 extends parallel to the longitudinal direction of the front 36 to the second control device 117 ,

In an alternative embodiment, the arrangements of the first control device 116 and the second control device 117 be reversed.

The charger 114 is preferably with the storage device 118 for loading the storage device 118 and with the second control device 117 to control the charger 114 electrically connected. Preferably, the control device 116 for controlling the electric auxiliary drive 24 and the storage device 118 for providing electrical energy with the electric auxiliary drive 24 electrically connected.

The 13 shows the swiveling device 26 and the running board 14 in an isometric view. The pivoting device 26 further includes a hinged element 120 on top of the handlebar 12 opposite side and the footboard 14 facing side of the pivoting device 26 is arranged hinged. The folding element closes in the closed state, the cavity 46 the pivoting device 26 , The folding element 120 is on the shaft 60 the pivoting device 26 rotatably mounted. This allows the folding element 120 by turning around the shaft 60 in the direction of the running board 14 unfolded and closed against this direction. The folding element 120 is preferably at least partially between the receiving elements 56 arranged. In 13 is the folding element 120 arranged in the folded state.

The 14 shows the representation of the pivoting device 26 and the running board 14 out 13 , wherein the folding element 120 is arranged in the unfolded state. Preferably, the flap element lies 120 in the unfolded state at least partially on the tread 15 of the running board 14 on.

In the cavity 46 the pivoting device 26 is a charging cable 122 arranged. The charging cable 122 is in the cavity 46 the pivoting device 26 arranged such that it is at least partially removable for loading. By opening or opening the folding element 120 can be a user of the scooter 10 on the charging cable 122 access and at least partially remove. The charging cable 122 is designed such that it can be connected to an electrical power supply to the charger 114 with electrical AC voltage of preferably 100 V to 240 V, in particular 220 V to supply. The charging cable 122 has for this purpose preferably at one end a plug for connection to a corresponding socket of the electrical power supply.

The 15 shows the representation of the pivoting device 26 and the running board 14 from the 13 and 14 without tread 15 and folding element 120 , The charging cable 122 is with the charger 114 electrically connected. The footboard 14 has a first and a second opening on the front side 36 124 . 126 on. The charging cable 122 extends through the first opening 124 from the cavity 46 the pivoting device 26 in the cavity 112 of the running board 14 , One in the cavity 112 arranged end of the charging cable 122 is with the charger 114 electrically connected. In other words, the charging cable extends 122 from the charger 114 through the first opening 124 from the cavity 112 of the running board 14 in the cavity 46 the pivoting device 26 and is arranged there partially removable.

Preferably, through the second opening 126 or additionally through the opening 124 one or more additional cables are routed to connect the controller to other electrical components, for example, in or on the handlebar 12 are arranged. As a further electrical component, for example, a controller may be provided for adjusting the speed.

The first and second openings 124 . 126 are between the recording elements 56 arranged. Preferably, much of the charging cable is 122 in the cavity 46 the pivoting device 26 between the folding mechanism 52 and the recording 40 arranged. Preferably, in the cavity 46 the pivoting device 26 between one of the receiving elements 56 on one side and the spring holder 86 , the spring element 84 and the motion transmitting member 92 on the other side a component-free passage in the folding mechanism 52 provided by the charging cable 122 through the folding mechanism 52 extends through. This can be the scooter 10 between the driving position 28 and the transport position 30 be transferred without the charging cable 122 gets damaged because it is in contact with components of the folding mechanism 52 comes.

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• WO 2011/148125 A1 [0003]
• CN 203228897 U [0004]
• DE 102013003484 A1 [0005]
• DE 102016210107 B3 [0006]

Claims (15)

Scooter, in particular scooter, with a handlebar (12), a running board (14) with a step (15) for supporting a user of the scooter, a front suspension (16) for carrying at least one front wheel (20), one rear suspension ( 18) for supporting 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), a memory device (118) for storing electrical energy, in particular an accumulator, and a control device (116), in particular control electronics, for controlling the electronic auxiliary drive (24), characterized in that the roller further comprises a charger (114) for charging the memory device (118), wherein the memory device (118 ), the control device (116) and the charger (114) are arranged below the tread surface (15). Scooter after Claim 1 characterized in that the footboard (14) has a thickness, the footboard (14) forming a first cavity (112) below the tread (15), the storage means (118), the controller (116), and the charger (114) are arranged in the first cavity (112). Scooter after Claim 2 , characterized in that the thickness of the footboard (14) is 2 cm to 10 cm, preferably 3 cm to 8 cm, in particular 5 cm. Scooter after one of the Claims 1 to 3 characterized in that the roller further comprises a charging cable (122) electrically connected to the charger (114). Scooter after Claim 4 , characterized in that the charging cable (122) is connectable to an electrical power supply to supply the charger (114) with electrical voltage. Scooter after Claim 4 or 5 characterized in that the scooter has connecting means connecting the handlebar (12) and the footboard (14), the connecting means forming a second cavity (46), the charging cable (122) extending from the charger (114). into the second cavity (46) of the connector. Scooter after Claim 6 , characterized in that the footboard (14) on the side facing the connecting device (36) has an opening (124) through which the charging cable (114) from the first cavity (112) in the second cavity (46). Scooter after Claim 6 or 7 , characterized in that the connecting device has a hinged folding element (120), which is formed so that the charging cable (114) from the connecting device for loading is at least partially removable. Scooter after Claim 5 to 8th characterized in that the connecting means is formed as a pivoting means (26) pivotally interconnecting the handlebar (12) and the footboard (14) such that the handlebar (12) and the footboard (14) are relatively between a riding position (28) and a transport position (30) are pivotable. Scooter after one of the Claims 1 to 9 , characterized in that the charger (114) on one of the connecting device facing side (36) of the running board (14) is arranged. Scooter after Claim 10 , characterized in that the control device (116) on the side facing the connecting device (36) of the footboard (14) and the memory device (118) on a side facing away from the connecting means (38) of the footboard (14) are arranged. Scooter after one of the Claims 1 to 11 , characterized in that the charger (114) is electrically connected to the memory device (118). Scooter after one of the Claims 1 to 12 , characterized in that the tread surface (15) has a width of 10 cm to 20 cm, preferably 13 cm to 18 cm, in particular 16 cm, wherein the tread surface (15) has a length of 30 cm to 60 cm, preferably 40 cm to 50 cm, in particular 45 cm. Scooter after one of the Claims 1 to 13 , characterized in that the at least one front wheel (20) and the at least one rear wheel (22) are the same size, in particular wherein the at least one front wheel (20) and the at least one rear wheel (22) has a diameter of 10 cm to 35 cm, in particular 25.4 cm. Scooter after one of the Claims 1 to 14 , characterized in that the at least one front wheel (20) and the at least one rear wheel (22) in the driving position on a floor (31) stand up, wherein a distance between the tread surface (15) and the bottom (31) 6 cm up to 25 cm, preferably 8 cm to 18 cm, in particular 12 cm.

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