EP3615395A1 - Electrically driven wheeled device - Google Patents

Abstract

The invention relates to an electrically driven wheeled device (10), in particular a smart wheel device, comprising at least one main wheel part (12) and at least one drive unit (14), in particular electric motor unit, at least part of which is disposed in the main wheel part (12). According to the invention, the electrically driven wheeled device (10) includes a sensor unit (16) provided for determining a surface roughness of a ground (18) and/or at least one frictional value within the main wheel part (12) and/or the drive unit (14).

Description

 description

Electric motor driven wheel device

State of the art

An electric motor-driven wheel device, in particular a smartwheel device, has already been proposed with at least one wheel base body and with at least one drive unit, in particular an electric motor unit, arranged at least partially in the wheel base body.

DISCLOSURE OF THE INVENTION The invention is based on an electric motor-driven wheel device, in particular a smartwheel device, with at least one wheel base body and with at least one drive unit arranged at least partially in the wheel base body, in particular an electric motor unit. It is proposed that the electric motor driven wheel device, in particular the Smartwheelvorrichtung, a sensor unit, which is intended to determine a surface roughness of a soil and / or at least one coefficient of friction within the Radgrundkörpers and / or the drive unit.

Preferably, a "smartwheel device" comprises at least a part of the components of a smartwheel, and in particular a wheel with electric drive components, preferably with sensor components and with data interface components, which leads to an imple- mentation of a smartwheel. contributing to at least one system functionality. Preferably, a control of a propulsion of the smartwheel takes place at least partially automatically, in particular as a function of at least one signal of a sensor component.

A "wheel base body" is to be understood in particular as an assembly which at least partially forms a wheel and / or at least partially encloses a wheel Blocking of movable components of the wheel device may form from an interior of the Radgrundkörpers particularly sensitive, such as dirt and / or moisture sensitive components of the electric motor driven wheel device, in particular the Smartwheelvorrichtung form a receptacle for further components of the electric motor-driven wheel device, in particular of the smartwheel device, Preferably, the drive unit of the electric motor driven wheel device, in particular the Smartwheelvorrichtung, at least partially arranged in the Radgrundkörper. In particular, an energy storage unit of the electric motor-driven wheel device, in particular the Smartwheelvorrichtung, arranged to supply at least a portion of the drive unit with particular electrical energy, at least partially in the Radgrundkörper. Alternatively, the energy storage unit may be arranged at least partially outside the Rad basic body, such as in a connection unit of the electric motor driven wheel device, in particular the Smartwheelvorrichtung. In particular, a computing unit of the electric motor-driven wheel device, in particular the smartwheel device, for controlling and / or regulating at least one function of the electric motor driven wheel device, in particular the smartwheel device, is arranged at least partially in the wheel main body. Alternatively, the arithmetic unit can be arranged at least partially outside the Radgrundkörpers. A "computing unit" is to be understood in particular as meaning a controller having a processor, a memory unit, and / or an operating, control and / or calculation program stored in the memory unit For example, the wheel base body has at least one wheel tread and / or at least one tire with at least one wheel tread. In particular, the Radgrundkörper on at least one wheel rim. Preferably, the wheel rim has at least one bearing surface for at least one tire.

The drive unit, in particular the electric motor unit, preferably comprises at least one electric motor. The electric motor is preferably formed by a DC motor, by an electrically commutated DC motor or a three-phase motor. In addition, it is conceivable that the drive unit has at least one transmission to a torque variation of at least one rotational movement of the Radgrundkörpers. In this context, a "sensor unit" is to be understood as meaning, in particular, a unit which is intended to accommodate at least one parameter, at least one environmental parameter and / or one physical characteristic, the recording being active, in particular by generating and transmitting an electrical signal In this context, a "surface roughness" should be understood to mean, in particular, height deviations of an actual boundary surface from an ideally smooth averaged reference plane. In this context, a "floor" is to be understood as meaning, in particular, a surface on which the electric motor-driven wheel device is to be operated - Press force between two bodies are understood. In particular, the sensor unit is provided for detecting a surface roughness and / or friction values counteracting a rotational movement of the wheel base body within the wheel base body, which counteract a rotational movement of the wheel base body, and / or to determine from recorded measured values. In particular, the coefficient of friction within the wheel base can be influenced by frictional connections and / or bearings of components of the wheel base and / or the drive unit. In particular, the sensor unit is provided for determining the determined surface roughness of a floor and / or at least one determined coefficient of friction within the wheel base and / or the drive unit to a computing unit of the electric motor driven Wheel device, in particular the Smartwheelvorrichtung to transmit to a control and / or regulation of at least one function, in particular to a control and / or regulation of a drive of Rad basic body, the electric motor driven wheel device. In particular, the computing unit is provided for determining the surface roughness and / or the coefficient of friction in a

Control and / or regulation of a drive of the Radgrundkörpers at least largely compensate.

By such a configuration, a generic electric motor driven wheel device, in particular smartwheel device, can be provided with advantageous properties with regard to user support. In particular, by determining a surface roughness of a floor and / or at least one coefficient of friction within the wheel base body and / or the drive unit, an advantageously simple compensation of the disturbance variables can take place during a drive of the wheel body. In this way, it can advantageously be achieved that a user always has to spend the same force on the vehicle driven by the electric motor driven wheel device independently of a surface roughness of a floor and / or a coefficient of friction within the wheel base body and / or the drive unit.

It is further proposed that the sensor unit has at least one vibration sensor and is provided for determining the surface roughness of the floor on the basis of vibration patterns detected by the vibration sensor. In particular, the vibration sensor is at least partially disposed within the Radgrundkörpers. In particular, the vibration sensor is intended to detect vibrations of the wheel base caused by the surface roughness of the floor. In particular, the sensor unit has at least one arithmetic unit which is provided to determine the surface roughness of the soil from the vibration patterns detected by the vibration sensor, for example by means of a frequency analysis based in particular on an FFT, which is specific for different soil conditions. Alternatively or additionally, it is proposed that the sensor unit has at least one optical sensor and is provided for this purpose. hen is to determine the surface roughness of the soil based on detected by the optical sensor optical readings. In particular, the optical sensor is arranged directly on the Radgrundkörper. For example, the optical sensor as a 3D camera, a laser sensor or the like. be educated. In particular, the optical sensor is intended to optically detect the surface roughness of the soil. In particular, the sensor unit has at least one arithmetic unit, which is provided to determine the surface roughness of the ground from the optical measured values detected by the optical sensor. Alternatively or additionally, it is proposed that the sensor unit has at least one slip sensor and is provided for determining the surface roughness of the floor on the basis of FIG

 Slip sensor detected measured values. In particular, the slip sensor is provided to detect a possible rotation of the wheel base on a floor when the wheel base is subjected to a torque by the drive unit. In particular, the sensor unit has at least one computing unit which is provided for this purpose from the measured values of

 Slip sensor in conjunction with the applied torque to determine the surface roughness of the soil. This allows an advantageously simple and / or reliable determination of the surface roughness of the soil.

Furthermore, the invention proceeds from a method for operating an electromagnetically driven wheel device, in particular a smartwheel device, with at least one wheel base body and with at least one drive unit, in particular an electric motor unit, arranged at least partially in the wheel base body. It is proposed that in at least one method step, in particular in a Anlernverfahrensschritt, the Radgrundkörper is automatically applied from standstill so long with a torque from the drive unit until the Radgrundkörper performs a rotational movement, wherein the torque value is stored at the onset of rotation, wherein based on the torque, a surface roughness of a soil and / or at least one Friction within the Radgrundkörpers and / or the drive unit is determined. In particular, the wheel base body is acted upon by the drive unit from standstill for a long time until a vehicle driven by the electric motor-driven wheel device, for example a logistics vehicle, moves. As soon as the vehicle driven by the electric motor-driven wheel device moves, the drive unit is switched off and the torque value currently applied is stored. The stored torque value is used during normal operation of the electric motor driven wheel device for at least substantial compensation of surface roughness of a floor and / or at least one coefficient of friction within the wheel base and / or the drive unit. Alternatively or additionally, it is proposed that the surface roughness of the floor and / or at least one coefficient of friction within the wheel base body and / or the drive unit is determined during each rotational movement of the wheel base body caused by a user action. In this way, it can advantageously be achieved that a user always has to spend the same force on the vehicle driven by the electric motor-driven wheel device independently of a surface roughness of a floor and / or a coefficient of friction within the wheel base body and / or the drive unit during normal operation.

Furthermore, it is proposed that in at least one method step, in particular in a Anlernverfahrensschritt, the Radgrundkörper is automatically offset in a forward and / or backward movement and during the movement of the Radgrundkörpers a surface roughness of a soil and / or at least one coefficient of friction within the Radgrundkörpers and / or the drive unit is determined. In particular, the electric motor-driven wheel device can be arranged on the vehicle by means of a rail extending parallel to a main movement direction of a vehicle driven by the electric motor-driven wheel device. In particular, a forward and / or backward movement takes place during the method step exclusively within the scope of the extension of the rail. In this way, a movement of the driven by the electric motor driven wheel device vehicle in determining a surface roughness of a Floor and / or at least one coefficient of friction within the Radgrundkörpers and / or the drive unit can be advantageously avoided.

In addition, it is proposed that in at least one method step, a surface roughness of a bottom and / or at least a coefficient of friction within the

Radgrundkörpers and / or the drive unit is calculated and / or determined on the basis of defined conditions. In particular, the surface roughness of the floor and / or the coefficient of friction within the wheel base body and / or the drive unit can be calculated on the basis of defined conditions by means of formulas and / or determined by means of lookup tables. As a result, an advantageously simple and / or rapid determination of a surface roughness of a floor and / or at least one coefficient of friction within the wheel base body and / or the drive unit for defined conditions can take place. In particular, additional measurements may advantageously be omitted.

In addition, a vehicle with an electric motor driven wheel device, in particular a Smartwheelvorrichtung, proposed.

The electric motor driven wheel device according to the invention, in particular the smartwheel device, the method according to the invention and / or the vehicle according to the invention should / should not be limited to the application and embodiment described above. In particular, the electric motor-driven wheel device according to the invention, in particular the smartwheel device, the method and / or the vehicle according to the invention, can fulfill a function described here by a number deviating from a number of individual elements, components and units and / or method steps mentioned herein exhibit.

drawing

Further advantages emerge from the following description of the drawing. In the drawing, an embodiment of the invention is shown. The drawing, the description and the claims contain numerous features in combination with tion. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

Show it:

Fig. 1 shows a vehicle with an electric motor driven wheel device in a schematic representation and

Fig. 2 is a schematic view of a section through the electric motor driven wheel device with a sensor unit.

Description of the embodiment

1 shows a perspective view of a vehicle 26 with four electric motor driven wheel devices 10 and with a transport plate 28. The electric motor driven wheel devices 10 are arranged on an underside of the transport plate 28. The electromotive wheel devices 10 are each formed as a smartwheel. Each electric motor-driven wheel device 10 each has a wheel base body 12.

The wheel base body 12 has a wheel rim 30. The wheel rim 30 forms a contact surface for a tread 32. The tread 32 is formed here of a solid material. However, it is also conceivable in this context that the tread 32 forms a pneumatic tire. The tread 32 is at least partially formed of a rubber material. The tread 32 is formed in particular changeable. The tread 32 is permanently rotatably connected to the wheel rim 30 at least in one operating state. The tread 32 has a wheel tread 34. The wheel rim 30 at least partially forms a radial, cylindrical boundary of the wheel base 12. Alternatively, the wheel rim 30 and the tread 32 may be integrally formed and / or the wheel rim 30 directly have a wheel tread 34.

The wheel base 12 has a first Raddeckelwandung 36 and a second Raddeckelwandung 38 (see Fig. 2). The Raddeckelwandungen 36, 38 at least partially form a lateral, axial boundary of the Radgrundkörpers 12th out. The wheel rim 30 is integrally connected to the two Raddeckelwandungen 36, 38, in particular welded. The wheel rim 30 may in particular be laser-welded or friction-welded to the two wheel cover walls 36, 38. The wheel rim 30 may alternatively or additionally be brazed, cold-soldered and / or glued to the two wheel cover walls 36, 38. It is in this

Context, however, also conceivable that the wheel rim 30 is positively connected to the two Raddeckelwandungen 36, 38, in particular via at least one screw, at least one rivet, at least one bolt, at least one toothing. Furthermore, it is conceivable that the wheel rim 30 is non-positively connected to the two Raddeckelwandungen 36, 38, in particular via a pressure. The wheel base 12 has a first Radachsbolzen 40 and a second Radachsbolzen 42 (see Fig. 2). The Raddeckelwandungen 36, 38 each have an opening 44 (see Fig .. 2). The opening 44 forms a receptacle for at least one of the Radachsbolzen 40, 42.

The electric motor driven wheel device 10 has a connection unit 48 to a releasable connection of the Radgrundkörpers 12 with an external unit. The connection unit 48 has a connection element 50. The attachment element 50 forms a type of protective cover which partially encloses the wheel base body 12. The connection unit 48 connects the

Radachkörper 12 with the underside of the transport plate 28. The Radachsbolzen 40, 42 connect the connection unit 48 with the Radgrundkörper 12. The Radachsbolzen 40, 42 are rotatably connected to the connection element 50. Alternatively, it is conceivable that at least one of the Radachsbolzen 40, 42 rotationally fixed to at least one of Raddeckelwandungen 36, 38 is connected.

FIG. 2 shows a schematic drawing of a frontal section through an electric motor-driven wheel device 10 along a rotation axis 52. During a movement of the vehicle 26, the wheel base body 12 rotates about the rotation axis 52. The rotation axis 52 runs through the centers of gravity of the wheel

Radach bolts 40, 42.

The Radgrundkörper 12 has two bearings 54, 56. The bearings 54, 56 are disposed in recesses 58 within the openings 44. The recesses 58 extend radially to the axis of rotation 52 and extend over a whole Circumference. The bearings 54, 56 are sealed against ingress of dirt and / or moisture. The bearings 54, 56 serve for a rotatable mounting of the wheel base body 12 on the connecting element 50. The electric motor driven wheel device 10 has a drive unit

14 on. The drive unit 14 has an electric motor 60. The electric motor 60 has a motor shaft 62. The drive unit 14 has a gear 64. The motor shaft 62 forms a drive input of the transmission 64. The drive unit 14 is arranged in the Radgrundkörper 12.

The electric motor driven wheel device 10 has a computing unit 66. The electric motor-driven wheel device 10 has an energy storage unit 68. The energy storage unit 68 is provided for storing electrical energy. The energy storage unit 68 is provided for a supply of the drive unit 14 with electrical energy. The energy storage unit 68 comprises a lithium-based accumulator.

The drive unit 14 has a fixation not shown in detail on at least one of the Radachsbolzen 40, 42. The at least one Radachsbolzen 40, 42 is shaped so that it secures all standing parts of the drive unit 14 against rotation.

The electric motor-driven wheel device 10 has a sensor unit 16, which is provided to determine a surface roughness of a bottom 18 and / or at least one coefficient of friction within the wheel base body 12 and / or the drive unit 14. The sensor unit 16 has at least one

Vibration sensor 20 and is intended to determine the surface roughness of the bottom 18 on the basis of detected by the vibration sensor 20 vibration patterns. Alternatively or additionally, the sensor unit 16 has at least one optical sensor 22 and is provided for determining the surface roughness of the bottom 18 on the basis of optical signals detected by the optical sensor 22

To determine measured values. Alternatively or additionally, the sensor unit 16 has at least one slip sensor 24 and is provided to determine the surface roughness of the bottom 18 on the basis of measured values detected by the slip sensor 24. In particular, the sensor unit 16 has at least one arithmetic unit, not shown, which is provided from the through Measured by the sensors 20, 22, 24 measured values to determine the surface roughness of the bottom 18 and / or a coefficient of friction within the Radgrundkörpers 12 and / or the drive unit 14. The sensor unit 16 is provided to transmit the determined surface roughness of a bottom 18 and / or at least one determined coefficient of friction within the Radgrundkörpers 12 and / or the drive unit 14 to the computing unit 66 of the electric motor driven wheel device 10. The arithmetic unit 66 is provided to at least largely compensate the surface roughness and / or the coefficient of friction in a control and / or regulation of a drive of the wheel base 12.

In a method for operating an electric motor-driven wheel device 10, in particular in a learning phase, in at least one method step, the Radgrundkörper 12 automatically applied from standstill with a torque from the drive unit 14 until the Radgrundkörper 12 performs a rotational movement, wherein the torque value is stored at the onset of rotational movement and based on the torque on a surface roughness of a bottom 18 and / or at least one coefficient of friction within the Radgrundkörpers 12 and / or the drive unit 14 is closed. Preferably, in at least one method step, the wheel base body 12 is automatically moved in a forward and / or backward movement and during the movement of the Radgrundkörpers 12 a surface roughness of a bottom 18 and / or at least one coefficient of friction within the Radgrundkörpers 12 and / or the drive unit 14 determined. Alternatively or additionally, the surface roughness of the bottom 18 and / or at least one coefficient of friction within the wheel base 12 and / or the drive unit 14 is determined for each rotational movement of the wheel base 12 caused by a user action. Alternatively, the surface roughness of the bottom 18 and / or at least one coefficient of friction within the wheel base 12 and / or the drive unit 14 can be determined once and stored as a fixed value. Alternatively or additionally, in at least one method step, a surface roughness of a bottom 18 and / or at least one coefficient of friction within the wheel base 12 and / or the drive unit 14 is calculated and / or determined on the basis of defined conditions. In particular, the surface roughness of the bottom 18 and / or the coefficient of friction within the wheel base 12 and / or the drive unit 14 based on defined conditions, for example, for defined floor coverings and / or for defined drive unit components, are calculated using formulas and / or determined using lookup tables.

Claims

Claims 1. An electromotively driven wheel device, in particular a Smartwheel device, with at least one wheel base body (12) and with at least one drive unit (14), at least partially arranged in the wheel base body (12), in particular an electric motor unit, characterized by a sensor unit (16) connected thereto is provided, a surface roughness of a bottom (18) and / or to determine at least one coefficient of friction within the Radgrundkörpers (12) and / or the drive unit (14).

Electromotive driven wheel device according to claim 1, characterized in that the sensor unit (16) has at least one vibration sensor (20) and is provided to determine the surface roughness of the bottom (18) based on by the vibration sensor (20) detected vibration patterns. 3. Electromotive driven wheel device according to claim 1 or 2, characterized in that the sensor unit (16) has at least one optical sensor (22) and is provided, the surface roughness of the bottom (18) by means of the optical sensor (22) detected to determine optical measurements.

Electromotive driven wheel device according to one of the preceding claims, characterized in that the sensor unit (16) has at least one slip sensor (24) and is provided to the surface roughness of the bottom (18) based on by

Slip sensor (24) detected measured values. Method for operating an electric motor-driven wheel device (10), in particular smartwheel device, in particular according to one of the preceding claims, with at least one wheel base body (12) and with at least one at least partially in the Radgrundkörper (12) arranged drive unit (14), in particular electric motor unit characterized characterized in that in at least one method step, the Radgrundkörper (12) automatically from standstill with a torque from the drive unit (14) is applied until the Radgrundkörper (12) performs a rotational movement, wherein the torque value is stored at the onset of rotation and Based on the torque on a surface roughness of a bottom (18) and / or at least one coefficient of friction within the Radgrundkörpers (12) and / or the drive unit (14) is closed.

A method according to claim 5, characterized in that in at least one method step, the Radgrundkörper (12) is automatically offset in a forward and / or backward movement and during the movement of Rad basic body (12) has a surface roughness of a bottom (18) and / or at least one Friction within the Radgrundkörpers (12) and / or the drive unit (14) is determined.

Method according to the preamble of claim 5, in particular according to claim 5 or 6, characterized in that in at least one method step, a surface roughness of a bottom (18) and / or at least one coefficient of friction within the Radgrundkörpers (12) and / or the drive unit (14) calculated and / or determined on the basis of defined conditions.

Method according to the preamble of claim 5, in particular according to one of claims 5 to 7, characterized in that at each of a user action caused rotational movement of Rad basic body (12) the surface roughness of the bottom (18) and / or at least one coefficient of friction within the Radgrundkörpers ( 12) and / or the drive unit (14) is determined.

9. vehicle with an electric motor driven wheel device (10), in particular smartwheel device, according to one of claims 1 to 4.