WO2017220407A1 - Vehicle with a chassis and a drive unit - Google Patents

Abstract

The invention relates to a vehicle (1) which has a chassis (2) with a frame (3) and multiple non-driven wheels (4) which are rotatably mounted on the chassis (3) and which are designed to support and move the chassis (2) on a track (5). The vehicle also has a drive unit (6) with drive wheels (7, 7.1, 7.2) which are designed to roll on the track (5) in a driven manner. The drive unit (6) has a first motor (M1) which drives a first drive wheel (7.1) of the drive wheels (7), and the drive unit (6) has a second motor (M2) which drives a second drive wheel (7.2) of the drive wheels (7) independently of the first drive wheel (7.1). The vehicle (1) has a rotary bearing (16, 16a, 16b) which supports the drive unit (6) on the chassis (3) and which comprises an automatically switching clutch (8, 8a, 8b) that is designed to allow a rotation of the drive unit (6) about a vertical rotational axis (D) relative to the chassis (3) in the disengaged state of the clutch and to rigidly connect the drive unit (6) to the chassis (3) in the engaged state. The invention additionally relates to a method for actuating such a vehicle (1).

Description

Vehicle with a chassis and a drive unit

The invention relates to a vehicle comprising a chassis with a chassis and several on the chassis rotatably ^¬ bar mounted, unpowered wheels, which are designed for carrying and moving the chassis on a roadway, and comprising a drive unit with drive wheels for driven rolling on the Roadway are formed. The invention also relates to a method for driving such a vehicle.

From US 2012/0041677 AI is an autonomous vehicle be ^¬ known, comprising a chassis with a chassis and two rotatably mounted on the chassis, non-drive wheels, which are designed for carrying and moving the chassis on a road, and having a drive ^¬ with two drive wheels, which are designed for driven rolling on the road.

The object of the invention is to provide a vehicle and an associated method for driving such a vehicle, in which, despite a non-omindirektionalen and non-holonomic drive unit of the vehicle, the chassis of the vehicle can be moved omnidirectionally in a simple manner.

The object of the invention is achieved by a vehicle comprising a chassis with a chassis and a plurality of rotatably mounted on the chassis, non-driven wheels, which are designed for carrying and moving the chassis on a roadway, and comprising a drive unit with drive wheels, the driven for unwinding are formed on the road, wherein the drive unit comprises a first motor which drives a first drive wheel of the on ^¬ drive wheels and the drive unit has a second Motor, which drives a second drive of the Antriebsrä ^¬ independent of the first drive wheel, and the vehicle has a drive unit on the chassis ^¬ store the pivot bearing comprising an automatically switching clutch, which is formed in its disengaged ^¬ th state a rotation of the drive unit relative to the chassis to allow a vertical axis of rotation and rigidly connect the drive unit in its engaged state with the chassis. The vehicle may be an autonomous vehicle. autonomous

Vehicles are operated without a driver, ie there is no person sitting on the vehicle, which steers the vehicle manually. Autonomous vehicles are self-propelled in this respect. Autonomous vehicles may be manually controlled by means of an on-vehicle driving control or a driving control separate from the vehicle, which communicates with the vehicle, either in an automatic operation or by remote control, and thus driven around on a roadway. The autonomous vehicle may, for example, be part of an automated guided vehicle system (FTS), a mobile robot, a service robot, or an automated rollator. The requisite degree of autonomy, which is erfor ^¬ sary for a specific Vehicle then, can be determined from the requirements of the tasks to be done in each case in particular.

The chassis is not only storage of the antriebslo ^¬ sen wheels and the drive unit, but may also comprise a support, in particular a supporting floor, are conveyed at or on the objects or persons NEN kön-. But the autonomous vehicle can be, for example ausgebil ^¬ det as the example mentioned automated walker, in which the drive unit via an automatic travel control or by manual input means, the examples For example, can be arranged on handles of the automated rollator, can be driven manually controlled. The automated walker forms according to the invention in that respect an autonomous vehicles because the person who pushes the automated walker, manual ansteu ^¬ ert and / or is supported thereon is not driven around by this and do not always modulates all automated driving operations manually, navigated anticipated and com ^¬ compensated. The drive unit has at least two drive wheels. Two drive wheels each can form pairs of drive wheels which are arranged with their drive axles, in particular in the direction of a common drive axis, on the drive unit. In that regard, two drive wheels can be rotatably mounted on a common drive axle. However, the two drive wheels of each pair of drive wheels are configured to be independently driven. This means that in each case two rotatably mounted on a common drive axle driving wheels can be driven by a respective motor and in particular in opposite directions of rotation. By the respective pair of two drive wheels can be driven in opposite directions of rotation, the entire drive unit can be automatically reoriented about a vertical center axis of the drive unit. By the respective pair of two drive wheels are driven in the same directions of rotation but with different rotational speeds, the drive unit can be moved on the road in curves. This is possible because the drive unit has a first motor which drives a first drive wheel of the drive wheels and the drive unit has a second motor which drives a second drive wheel of the drive wheels independently of the first drive wheel. By the vehicle having a drive unit on the Fahrge ^¬ alternate confirmed lead pivot bearing, which comprises an automatic switching clutch which is formed, in its decoupled state a rotation of the drive unit bezüg- lent of the chassis about a vertical axis of rotation to permit and in its engaged state, the To rigidly connect drive unit to the chassis, the vehicle, despite a non-omindirektionalen and non-holonomic drive unit of the vehicle, the chassis of the vehicle can be easily omnidirectionally moved.

Vehicles can have different configurations. In robotics, differential and omnidirectional drives are particularly popular. Omnidirectional drives increase the flexibility, but also the complexity of the vehicle. Often omnidirectional drives are also we ^¬ niger efficient because more friction. In omnidirectional drives, a distinction is made between holonomic and non-holonomic drives. The former have the advantage that they can travel in any direction at any time. In many applications, however, omnidirectionality is rarely required. In most driving situations, a differential drive is sufficient; only in certain situations, for example when positioning at a workstation or maneuvering in a confined space, does the omnidirectional drive offer significant advantages.

Most of the time, only a differential drive is needed to maneuver the vehicle. The problem is that the vehicle is in a situation where ^¬ play, in a docking with a workstation that can be run overall, from which it comes out very poorly again without omni. This may be the case, for example, when the vehicle has traveled very close to a wall. Here, by means of the invention, the exis- ting (in itself non-omnidirectional and non-holonomic) drive are briefly reoriented to get out of the situation, then resume normal configuration. Thus, expensive omnidirectional drive, such as on the basis of Mecanum wheels, can be dispensed with and nevertheless an omnidirectionality of the entire vehicle can be achieved.

The weight of the chassis and a load supported thereon, if necessary, which is also referred to as platform, via passive ie non-driven support wheels GETRA ^¬ gene. In the platform, preferably in the middle, a particular circular in horizontal cross section from ^¬ savings be provided. This recess contains the actual drive unit. The drive unit has at least two independently driven on ^¬ drive wheels. In drive mode, the orientation of the drive unit relative to the platform remains the same. This allows the platform to drive straight or around bends like any diffe rent platform. If the platform will drive omnidirectional comparable, so the orientation of the drive unit is re ^¬ tively released to the platform by the inventive releasable and lockable pivot bearing. By rotating the wheels of the drive unit in opposite directions, the drive unit can change its orientation. The platform maintains its own orientation, either by the support wheels are braked by rigid outriggers are extended or simply due to the static friction of the wheels. After the new relative orientation of the drive unit is again fi xed ^¬, the platform can be comparable drive in the new direction. Both for the fixation of the relative orientation as well as for the reorientation several procedures are possible, which may be as follows, for example. In one embodiment, the drive unit can be raised for reorientation. In the upper position, the drive wheels of the drive unit touch the platform from below and the drive unit can reorient itself by driving the drive wheels in opposite directions and rolling it past the underbody of the platform. A mechanical decoupling can be done, for example, by locking one or more mandrels or elevations in a corresponding counter receptacle in the drive unit in a lower position of the drive unit. This simple Ausführungsbei ^¬ game stands for a generally positive-acting coupling ^¬ ment. However, this has the disadvantage that only certain Ori ^¬ entierungen the drive unit are possible relative to the platform, but has the advantage of low complexity and high robustness.

In another embodiment ^variant , a flat adhesion can be provided in the lower position of the drive unit. It is advantageous if one of the two surfaces is mounted vertically movable to ensure contact of the drive unit to the ground. The Fixie ^¬ tion of the orientation of the drive unit relative to the platform is achieved for example by a kind of brake on the rotary ^¬ axis. This simple embodiment stands for a generally non-positively acting clutch. To redirect this brake is released. The drive unit is then oriented by the drive wheels rotate counter-clockwise again.

The approaches described above make it possible to move the platform in different directions. The platform can also reorient itself on the basis of the differential drive about the axis of rotation of the drive unit. Due to the fact that the passive, ie unpowered wheels of the platform have to reorient themselves, for example in the case of propulsion loose steering wheels, but it can lead to a misalignment. For this reason, another approach is presented.

A lifting device, which may have a rod, can be arranged on the drive unit and can be moved up and down by the drive unit. In a specific exemplary embodiment may be attached to the lower end of a stand, so that the drive unit can stand out from the ground. At the top of a plate is attached. Between this plate and the bottom of the platform springs are mounted whose strength is chosen so that they are not nen ^¬ worth compressed by the weight of the drive unit. The upper plate is rotatably mounted in Ver ^¬ ratio to the rod. Is the rod in the upper or middle position, a rotation relative to the platform is prevented, for example, because in the upper position, a mandrel of the platform in the rod inserted or the brake mechanism described above. In the lowermost position, the rotation of the rod relative to the drive unit is fi xed ^¬. Again, the two described approaches are relevant. In the travel position of the platform, the rod is in the uppermost position from the perspective of the drive unit. The base thus has no contact with the ground and the on ^¬ drive unit has contact with the ground. If the integrated Antriebsein ^¬ are reoriented, the rod moves to the medium-re position. As a result, the drive unit lifts itself and their drive wheels lose contact with the ground and come into contact with the subfloor of the platform. The orientation of the drive unit is changed as described. If the platform as a whole to be reoriented, the rod is moved to the lowest position. As a result, the springs are compressed and the platform as a whole angeho ^¬ ben. At the same time the rotation of the rod is prevented relative to the drive unit. Now, the orientation of the platform by an opposite rotation of the drive wheels the drive unit to be changed. If the platform is equipped with passive wheels that can not be reoriented, there are no negative effects due to the reorientation of the passive wheels and the direction of travel of the platform is always defined. However, no lateral travel can be realized. Of course, rotatable, passive rollers can be used.

The coupling may be a form-locking coupling which is designed to connect the drive unit rigidly to the chassis only in a limited number of predetermined different rotational angle positions from drive unit to chassis.

The interlocking coupling may be, for example, a claw clutch ^¬ or a toothed coupling. In a simple embodiment, the positive coupling can already be formed by a mere projection, such as a pin or pin, which engages in a receptacle, such as a Zapfenauf ^¬ measure or a hole when the coupling is eingekup ^¬ pelt and from the recording, the pin receptacle or the hole is removed when the clutch is disengaged. The number of predetermined different angular positions can be evenly distributed over 360 degrees. Thus, for example, four different Drehwinkelstel ^¬ lungs be provided, which are arranged offset by 90 degrees to each other. Alternatively, for example, eight different rotational angle positions can be provided, which are arranged offset by 45 degrees to each other. It can also be provided twelve different angular positions, which are offset by 30 degrees to each other. A disengagement of the positive coupling can be done automatically by the drive unit is raised automatically controlled and directly by the lifting movement of the drive unit form-fitting Clutch is disengaged, in particular the respective ge ^¬ mutual engagement elements of the positive clutch to separate from each other. An engagement of the positive clutch can be done automatically in that the drive unit is lowered automatically actuated and un ^¬ indirectly the positive clutch is engaged by the lowering movement of the drive unit, interlocking in particular the respective mutual engaging elements of the formschlüssi ^¬ gen clutch. The clutch may be a non-positive clutch, which is designed to connect the drive unit in any Drehwin ^¬ kelstellungen from drive unit to chassis with the chassis.

The non-positive coupling may be a friction clutch, such as a multi-plate clutch. The kraftschlüssi ^¬ ge coupling, one or more friction plates or friction linings so far, in particular in type of brake pads have, which frictionally bear in an engaged state at particular me ^¬-metallic intermediate fins or spacers. A force-fit coupling has the advantage that the drive unit in any rotational angular positions of the drive unit to the chassis to the chassis can be ver ^¬ prevented.

A disengagement of the frictional coupling can be effected in that the drive unit is raised automatically activated and immediately the force-fit coupling is coupled from ^¬ by the Hebebe ^¬ movement of the drive unit, in particular the respective mutual friction linings, brake pads, clutch disks and / or intermediate automatically rings of non-positive coupling separate from each other. An engagement of the non-positive coupling can be carried out automatically by the fact that the drive unit automa- driven table is lowered and directly by the lowering movement of the drive unit, the frictional Kupp ^¬ ment is engaged, in particular the respective gegen ^¬ side friction linings, brake pads, intermediate plates and / or intermediate rings of the non-positive coupling abut each other, ie pressed against each other.

The vehicle can accordingly a first lifting device aufwei ^¬ sen, which is designed to automatically raise or the drive unit relative to the chassis lower, such that the drive wheels of the drive unit are in a lowered by the lifting state of the drive unit with the track in contact and in a lifted by the lifting device state of the drive unit are freely rotatable or are in contact with an underbody of the chassis. In the raised state, the chassis or the entire vehicle may then be moved manually if necessary.

The first lifting device can thus be designed to automatically effect a disengagement of the clutch by the drive unit is raised automatically and the clutch is disengaged directly by the lifting movement of the lifting device, and automatically cause clutch engagement by the drive unit automatically ^¬ table is driven lowered and the coupling is engaged directly by the lowering movement of the lifting device.

In an embodiment variant in which the drive wheels are freely rotatable in a state of the drive unit raised by the lifting device, the drive unit can be reoriented by a separate automatically controlled motor. However, if the drive unit is raised so that the drive wheels with an underbody of the Chassis are in contact, then a separate motor can be omitted and the drive unit can be reoriented by the Antriebsradpaare respectively driven in opposite directions and roll on the underbody of the chassis. Since the chassis is stationary, the drive unit is um ^¬ oriented.

The vehicle can be constructed and arranged to engage the clutch in egg ^¬ nem lowered by the lifting state of the drive unit, so that the drive unit rigidly in its lowered position with the

Chassis is connected and disengage in a raised by the lifting device state of the drive unit, the clutch, so that an automatic rotation of the drive ^¬ unit with respect to the chassis about a vertical axis of rotation is possible, in the event that the drive wheels are freely rotatable by a separate drive of the vehicle which rotates the drive unit or, in the case where the drive wheels are in contact with the underbody of the chassis, by driving the drive wheels. The separate drive can, for example, act on a Hubstan ^¬ ge of the first lifting device.

The vehicle may have a second lifting device with a stand which can be moved from ^¬ , wherein the lifting device is designed to automatically extend the stand against the road or retract from the road, such that in an extended state of the base, the chassis is raised and the non-drive wheels of the landing gear are lifted from the road and in a retracted state of the base, the chassis is lowered, such that the non-powered wheels of the chassis are in contact with the road. If the chassis is lifted by the second lifting device and the stand, so that the non-driven wheels of the undercarriage are lifted off the roadway, the drive ^¬ unit on the stand is rigidly against the stand-up, that the roadway is supported, so that by driving the drive wheels, which are supported against the underbody of the chassis and roll there, the chassis is reoriented. In one embodiment variant, in which the drive wheels are freely rotatable in a state of the chassis lifted by the second lifting device, the chassis can also be reoriented by a separate automatically controlled motor.

The first lifting device and the second lifting device may also be embodied as a single, common lifting device, which may then have three states in this respect, i. can position at three different altitudes. The extent common lifting device can then be moved in particular by means of a single drive.

The first lifting device and the second lifting device can have a common lifting rod, which supports the base and the vehicle has a first clutch which, in its engaged state, rigidly connects the chassis to the lifting rod and, in its disengaged state, rotates the chassis with respect to Lifting rod around a vertical axis of rotation permits and the vehicle has a second Kupp ^¬ ment that connects the drive unit rigidly connected to the lifting rod in its engaged state and in its disengaged state allows rotation of the drive unit bezüg ^¬ Lich the lifting rod about a vertical axis of rotation. In general, the vehicle may have a control device, which is designed to drive the drive wheels of the drive unit, the first clutch, the second clutch, the first Hubvor- direction and / or the second lifting device to control automatically. The vehicle can in particular have a tax advantage ^¬ device which is adapted automatically to actuate the drive wheels of the drive unit, the first clutch, the second clutch, the first lifting device and / or the second lifting device and that in one of the procedures described below.

The object according to the invention is therefore also achieved by a method for driving a vehicle according to one or more of the described embodiments, characterized by the steps: automatically driven driving of the vehicle by driving the drive wheels of the drive unit in a first relative orientation of the drive unit with respect to the chassis in egg ^¬ nem engaged state of the clutch,

Disengaging the clutch,

Reorienting the drive unit relative to the chassis from their first relative Orientie ^¬ tion relative to the chassis in a second re lative ^¬ orientation relative to the chassis by automatically driving the first drive ^¬ wheel and the second drive wheel in each case against ^¬ ent directions of rotation in the disengaged

Condition of the clutch,

Engaging the clutch, automatically driving the vehicle by driving the drive wheels of the drive unit in the second relative orientation of the drive; drive unit with respect to the chassis in the ^¬ coupled state of the clutch.

The reorientation of the drive unit with respect to the Fahrge ^¬ stells from their first relative orientation with respect to the chassis takes place in a second relative orientation with respect to the chassis, which differs from the first relati ^¬ ven orientation, by automatically Antrei ^¬ ben the first drive wheel and the second drive wheel in opposite directions of rotation in the disengaged state of the clutch.

An automatically driven driving of the vehicle may be performed by a control device of the vehicle, wherein the control device controls motors which are connected for driving with the drive wheels of the drive unit. In addition, engagement and disengagement of the clutch may be accomplished by the controller actuating an automatic actuator of the clutch that actuates the clutch for engagement and disengagement.

The reorientation of the drive unit relative to the chassis from their first relative orientation with respect to the chassis in a second relative orientation with respect to the chassis can be carried out by the control device of the vehicle which drives the motors for turning on ^¬ drive the first drive wheel and the second drive wheel are formed in opposite directions of rotation in the disengaged state of the clutch.

The automatically driven driving of the vehicle may be performed by the control device of the vehicle by driving the drive wheels of the drive unit by means of the motors in the engaged state of the clutch. The method may have the additional steps of:

- raising of the drive unit, such that the at ^¬ drive wheels are lifted off the roadway and the driving wheels are kept with an underbody of the chassis in rolling contact,

- reorienting of the drive unit relative to the chassis from their first relative Orientie ^¬ tion relative to the chassis in a second re ^¬ lative orientation relative to the chassis by automatically driving the first drive ^¬ wheel and the second drive wheel in each case ent ^¬ against directions of rotation in the disengaged state of the clutch ,

The lifting of the drive unit can be done by driving a first lifting device by means of the control device, such that by automatically raising or extending the first lifting the drive wheels are lifted off the road in such a way that the drive wheels get into abrollendem contact with an underbody of the chassis.

Alternatively or additionally, the method may have the additional further steps:

- Lifting the drive unit and the chassis

by automatically extending a base of the vehicle against the road, such that both the drive wheels of the drive unit and the non-powered wheels of the landing gear are lifted off the road, Reorienting the chassis with respect to the drive unit from its first relative orientation with respect to the drive unit to a second relative orientation with respect to the drive unit by automatically driving the first drive wheel and the second drive wheel in respectively opposite directions of rotation, the drive wheels of the drive unit being connected to an underbody of the chassis the landing gear in rolling contact are held off, and the drive unit to the chassis connecting first rotational bearing is disengaged and the on ^¬ drive unit connecting with the base two ^¬ tes pivot bearing is engaged. In one particular, further embodiment variant, the suspension can also be alone, that are first lowered again without the An ^¬ drive unit and an original relative orientation of the chassis and drive unit to be restored before the drive unit is lowered concluded. The vehicle can then start in the new direction.

The lifting of the drive unit and the chassis, he can ^¬ follow by driving a second lifting device by means of the control device, such that automatically by driving a stand of the vehicle against the road by means of the second lifting device, both the drive wheels of the drive unit and the non-drive wheels lift the landing gear off the road.

Various embodiments of the invention are illustrated in the accompanying schematic drawings by way of example. Concrete features of these embodiments can be found regardless of the specific context in which they are used. are considered, if appropriate, individually or in other than the combinations shown, represent general features of the invention.

1 is a schematic sectional view of the side of an exemplary autonomous vehicle according to the invention with a chassis and a drive unit, FIG. 2 is a schematic representation of the autonomous vehicle according to FIG. 1 from below with the drive unit in a first orientation with respect to the chassis 3 shows a schematic representation of the side of the au ^¬ tonomen vehicle with a raised drive unit,

4 is a schematic representation of the autonomous vehicle according to FIG. 1 from below with the drive unit in a second orientation with respect to the chassis of the running gear,

5a shows a schematic representation of the autonomous vehicle according to FIG. 1 in a first embodiment with a form-locking coupling,

5b is a schematic representation of the autonomous vehicle of FIG. 1 in a second embodiment with a non-positive coupling,

Fig. 6 is a schematic representation of a modified

Embodiment of the autonomous vehicle according to FIG. 1, with a base, which is shown in a raised state, wherein the drive unit is lowered from ^¬ , Fig. 7 is a schematic representation of the modified embodiment of the autonomous vehicle of FIG. 1, with the base, in a raised state is shown, wherein the drive unit is raised, and

Fig. 8 is a schematic representation of the modified embodiment of the autonomous vehicle of FIG. 1, with the base, which is shown in a lowered state, so that both the drive unit and the chassis is raised.

Fig. 1 shows an autonomous vehicle 1 comprising a chassis 2 with a chassis 3 and a plurality of rotatably mounted on the Fahr- part rotatably mounted, non-driving wheels 4, which are designed to carry and method of the chassis 2 on a roadway 5.

The autonomous vehicle 1 has a drive unit 6 with on ^¬ drive wheels 7, which are designed for driven rolling on the roadway 5.

The drive unit 6 has a first motor M1, which drives a first drive wheel 7.1 of the drive wheels 7. The drive unit 6 also has a second motor M2, which drives a second drive wheel 7.2 of the drive wheels 7 independently of the first drive wheel 7.1.

The autonomous vehicle 1 has a drive unit 6 on the chassis 3 overlapping pivot bearing 16, which a automatically switching clutch 8 comprises, which is configured in its disengaged state (Fig. 3) rotation of the drive unit 6 relative to the chassis 3 about a ver ^¬ Tikale axis of rotation to permit and in its engaged state (FIG. 1), the drive unit 6 rigidly connected to the Fahrge ^¬ stell 3.

The autonomous vehicle 1 has a first lifting device 11, which is designed to automatically raise the drive unit 6 relative to the chassis 3 (FIG. 3) or to lower it (FIG. 1), such that the drive wheels 7, 7.1, 7.2 Drive unit 6 in a lowered by the lifting device 11 state (Fig. 1) of the drive unit 6 with the carriageway 5 are in contact and in a raised by the first hub ^¬ device 11 state (Fig. 3) of the drive unit 6 with an underbody 10 of the chassis 3 are in contact.

As shown in Fig. 1, the autonomous vehicle 1 is formed from ^¬ and arranged to engage in a lowered by the lifting device 11 state of the drive unit 6, the coupling 8, so that the drive unit 6 rigid in their abge ^¬ lowered state with the chassis 3 connected is.

As shown in Fig. 3, the autonomous vehicle 1 is formed from ^¬ and adapted to disengage in a raised by the lifting device 11 state of the drive unit 6, the coupling 8, so that an automatic rotation of the drive ^¬ unit 6 relative to the chassis 3 by a vertical axis of rotation D is possible.

As shown in FIG. 3, the drive wheels 7, 7.1, 7.2 are in contact with the underbody 10 of the chassis 3, so that an automatic rotation of the drive unit 6 with respect to the chassis 3 about the vertical axis of rotation D. is possible by the drive wheels 7.1, 7.2 are driven in opposite directions, as shown in Fig. 4.

The autonomous vehicle 1 has a control device 13, which is designed to control the drive wheels 7, 7.1, 7.2 of the drive unit 6, the clutch 8 and the first lifting device 11 automatically.

The method for driving the autonomous vehicle 1 can be performed by automatically driven driving of the autonomous vehicle 1 by driving the drive wheels 7, 7.1, 7.2 of the drive unit 6 in a first relative orientation (Fig. 2) of the drive unit 6 with respect to the Fahrge ^¬ stells 3 in an engaged state of the clutch 8. then, a disengagement of the clutch 8. Subsequently, takes place, as indicated in Fig. 3, a reorienting of the arrival drive unit 6 relative to the chassis 3 from their ers ^¬ th relative orientation (Fig. 2) with respect of the chassis 3 in a second relative orientation (Fig. 4) be ^¬ delay of the chassis 3 by automatically driving the first drive wheel 7.1 and the second drive wheel 7.2 in opposite directions of rotation in the disengaged

Condition of the clutch 8, as indicated by the arrows. An ^¬ closing a connection of the clutch 8 is carried Thereafter, the autonomous vehicle 1 again be driven automatically driven by driving the drive wheels 7, 7.1, 7.2 of the drive unit 6 in the second relative Orientie ^¬ tion (Fig. 4) of the drive unit 6 with respect to of the Fahrge ^¬ stells 3 in the engaged state of the clutch. 8

The drive unit 6 is raised in such a way that the drive wheels 7, 7.1, 7.2 are lifted off the roadway 5 and the drive wheels 7, 7.1, 7.2 are held in rolling contact with the underbody 10 of the chassis 3, as shown in FIG Fig. 3 is shown. The reorientation of the Drive unit 6 with respect to the chassis 3 from its first relative orientation with respect to the chassis 3 in a second relative orientation with respect to Fahrge ^¬ stells 3 by automatically driving the first drive wheel 7.1 and the second drive wheel 7.2 in opposite directions of rotation in the disengaged state of the clutch eighth

According to a first embodiment variant of FIG. 5 a, the coupling 8 can be a form-locking coupling 8 a which is designed to rigidly connect the drive unit 6 to the chassis 3 exclusively in a limited number of predetermined different rotational angle positions from the drive unit 6 to the chassis 3. If the drive ^¬ unit 6, as indicated by the arrow, raised, the positive clutch 8a is disengaged. In the un ^¬ direct position of the drive unit 6, the positive coupling 8a is engaged.

According to a second variant embodiment of Figure a frictional clutch can. 5b, the clutch 8 to be 8b, which is excluded is to connect the drive unit 6 in any rotational angular ^¬ assortments of drive unit 6 to the chassis 3 to the chassis. If the drive unit 6, as indicated by the arrow, raised, the force- ^locking clutch 8 b is disengaged. In the lower position of the drive unit 6, the force-locking coupling 8b is engaged.

In a further embodiment according to FIGS. 6 to 8, the autonomous vehicle 1 can have a second lifting device 12 with an extendable stand 14, wherein the second lifting device 12 is designed to extend the stand 14 automatically against the roadway 5 (FIG. 8). or from the roadway 5 (FIG. 6, FIG. 7), in such a way that in an extended state (FIG. 8) of the base 14, the chassis 2 is raised and the non-driven wheels 4 of the chassis 2 are lifted off the roadway 5. In a retracted state of the stand 14, the vehicle can work 2 to be lowered (Fig. 6), such that both the non-driven wheels 4 of the chassis 2 and the drive ^¬ wheels 7, 7.1, 7.2 of the drive unit 6 in contact with the Roadway 5 are.

In general, the first lifting device 11 and the second lifting device 12 can have a common lifting rod 15, which supports the base 14 and the autonomous vehicle 1 have a first clutch 8.1 which, in its engaged state (FIGS. 6 and 7), the chassis 3 connects rigidly with the lifting rod 15 and in its disengaged state (Fig. 8), a rotation of the chassis 3 with respect to the

Lifting rod 15 allows for a vertical axis of rotation. The mous ^¬ me vehicle 1 also has a second clutch 8.2, which in its engaged state (FIG. 6, FIG. 8) connects the drive unit rigidly connected to the lifting rod 15 and in its disengaged state (Fig. 7) a rotation of the drive unit 6 with respect to the lifting rod 15 about the vertical axis of rotation D permits. Accordingly, the first lifting device 11 and the second lifting device 12 may also be formed as a single, common lifting device, which then may have three states so far, ie, can position at three different alt ^¬ heights. The extent common lifting device can then be moved in particular by means of a single drive.

As indicated in Fig. 8, a lifting of the drive unit 6 is carried out and a lifting of the chassis 2 by automatic ^¬ ULTRASONIC extension of the base 14 of the autonomous vehicle 1 against the road surface 5, such that both the drive wheels 7, 7.1, 7.2 of the drive unit 6 and the unpowered wheels 4 of the chassis 2 are lifted off the roadway 5.

A reorientation of the chassis 2 relative to the drive unit 6 from its first relative orientation with respect to the drive unit 6 in a second relative orientation with respect to the drive unit 6 is effected by automatically driving the first drive wheel 7.1 and the second drive wheel 7.2, analogous to FIG. 2 and FIG. in each entge ^¬ gengesetzten directions of rotation, wherein the drive wheels 7, 7.1, 7.2 of the drive unit 6 with the lower floor 10 of Fahrge ^¬ stells 3 of the chassis 2 are kept in rolling contact Here, the drive unit 6 with the Fahrge ^¬ stell 3 connecting pivot bearing 16a disengaged and the drive unit 6 with the base 14 connecting second pivot bearing 16b engaged.

Claims

Vehicle having a chassis

(2) with a ^chassis (3) and several on the chassis

(3) rotatably mounted, non-drive wheels

(4), which are designed to carry and move the chassis (2) on a roadway (5), and having a drive unit

(6) with drive wheels (7, 7.1, 7.2) for powered rolling on the road

(5) are designed, characterized in that the drive unit

(6) has a first motor (Ml) which drives a first drive wheel (7.1) of the drive wheels (7) and the drive unit (6) ^has a second motor (M2) which has a second drive wheel (7.2) of the drive ^¬ wheels (7) drives independently of the first drive wheel (7.1), and the vehicle (1) is the drive unit

(6) has a pivot bearing (16, 16a, 16b) mounted on the chassis (3), which includes an automatically ^switching clutch (8, 8a, 8b) which is designed to rotate the drive unit (6) in its disengaged state ) with respect to the chassis (3) in order to allow a vertical axis of rotation (D) and to rigidly connect the drive unit (6) to the chassis (3) in its engaged state.

Vehicle according to claim 1, characterized in that the clutch (8) is a positive clutch (8a), which is designed to move the drive unit (6) ^from the drive unit (6) to the chassis (3) in a limited number of predetermined different rotational angle positions ) to be rigidly connected to the chassis (3). Vehicle according to claim 1, characterized in that the clutch (8) is a non-positive clutch (8b), which is designed to connect the drive unit (6) to the chassis (3) in any rotational angle positions from the drive unit (6) to the chassis (3). ^connect .

Vehicle according to one of claims 1 to 3, ^{characterized} in that the vehicle (1) has a first ^lifting device (11) which is designed to ^{automatically} drive the ^drive unit (6) with respect to the chassis (3). to raise or lower in such a way that the drive wheels (7,

7.1, 7.2) of the drive unit (6) are in contact with the roadway (5) in a state of the drive unit (6) lowered by the lifting device (11) and are free in a state of the drive unit (6) raised by the lifting device (11). are rotatable or are in contact with an underbody (10) of the chassis (3).

Vehicle according to claim 4, characterized in that the vehicle (1) is designed and set up to engage the clutch (8) when the drive unit (6) is ^lowered by the lifting device (11), so that the drive unit (6) in its ^lowered state, it is rigidly ^connected to the chassis (3) and in a state of the drive unit (6) that is raised by the lifting device (11), the ^clutch (8) is to be disengaged, so that the drive unit (8) ^rotates automatically Drive unit (6) with respect to the chassis (3) about a vertical axis of rotation (D) is possible, in the event that the drive wheels (7) are freely rotatable by a separate drive of the vehicle (1), which drives the drive unit (6). rotates, or in the event that the drive wheels (7, 7.1, 7.2) are connected to the undercarriage the (10) of the chassis (3) are in contact by driving the drive wheels (7, 7.1, 7.2).

Vehicle according to one of claims 4 or 5, characterized in that the vehicle (1) has a second lifting device (12) with an extendable base (14), the second lifting device (12) being ^designed to form the base (14 ) automatically extend against the roadway (5) or retract from the roadway (5), such that when the base (14) is in an extended state, the chassis (2) is raised and the non-drive wheels (4) of the chassis (2) are off the road (5) are lifted and the chassis is in a retracted state of the base (14).

(2) is lowered in such a way that the unpowered ^wheels (4) of the chassis (2) come into contact with the road

(5) stand.

Vehicle according to one of claims 4 to 6, characterized in that the first lifting device (11) and the second lifting device (12) have a common one

Have a lifting rod (15) which carries the base (14) and the vehicle (1) ^has a first coupling (8a) which, in its engaged state, rigidly connects the chassis (3) to the lifting rod (15) and in In its disengaged state, the chassis (3) can be rotated with respect to the lifting rod (15) about a vertical axis of rotation (D) and the vehicle (1) has a second clutch (8b) which, in its ^engaged state, controls the drive unit ( 6) rigidly connects to the lifting rod (15) and in its disengaged state allows the drive unit (6) to rotate relative to the lifting rod (15) about a vertical axis of rotation (D). Vehicle according to one of claims 1 to 7, having a control device (13) which is designed to drive the drive wheels (7, 7.1, 7.2) of the drive unit (6), the first clutch (8, 8a), the second clutch (8, 8b), to automatically control the first lifting device (11) and/or the second lifting device (12).

Method for controlling a vehicle (1) according to one of claims 1 to 8, characterized by

Steps :

- automatically driven driving of the vehicle (1) by driving the drive wheels (7, 7.1, 7.2) of the drive unit (6) in a first relative orientation of the drive unit (6) with respect to the chassis (3) in an engaged state of the clutch (8) ,

— disengaging the clutch (8),

- Reorienting the drive unit (6) with respect to the chassis (3) from its first relative orientation with respect to the chassis (3) into a second relative orientation with respect to the chassis (3) by automatically driving the first drive wheel (7.1) and the second drive wheel (7.2 ) in opposite directions of rotation when the clutch ( 8 ) is disengaged,

— engaging the clutch (8),

- automatically driven driving of the vehicle (1) by driving the drive wheels (7, 7.1, 7.2) of the drive unit (6) in the second relative orientation of the drive unit (6) with respect to the Chassis (3) when the clutch (8) is engaged.

Method according to claim 9, characterized by the steps:

- Raising the drive unit (6) in such a way that the drive wheels (7, 7.1, 7.2) are lifted off the road (5) and the drive wheels (7, 7.1, 7.2) are in contact with an underbody (10) of the chassis (3). are held in rolling contact,

- Reorienting the drive unit (6) with respect to the chassis (3) from its first relative orientation with respect to the chassis (3) into a second relative orientation with respect to the chassis (3) by automatically driving the first drive wheel (7.1) and the second drive wheel (7.2 ) in opposite directions of rotation when the clutch ( 8 ) is disengaged.

Method according to claim 9 or 10, characterized by the steps:

- Raising the drive unit (6) and the chassis (2) by automatically extending a base (14) of the vehicle (1) against the road (5), such that both the drive wheels (7, 7.1, 7.2) of the drive unit (6 ) as well as the ^unpowered wheels (4) of the chassis (2) are lifted off the road (5),

— Reorienting the chassis (2) with respect to the drive unit (6) from its first relative orientation with respect to the drive unit (6) into a ne second relative orientation with respect to the drive unit (6) by automatically driving the first drive wheel (7.1) and the second ^drive wheel (7.2) in opposite directions of rotation, the drive wheels (7, 7.1, 7.2) of the drive unit (6) having a Underbody (10) of the chassis (3) of the chassis (2) are kept in ^rolling contact, and a first pivot bearing (16, 16a) ^connecting the drive unit (6) to the chassis (3) is disengaged and a Drive unit (6) is ^coupled to the second pivot bearing (16, 16b) connecting the base (14).