EP3927603A1 - Self-balancing driverless transportation vehicle - Google Patents

Abstract

The invention relates to a driverless transportation vehicle (1) for general cargo (5), comprising a chassis (2), a traction drive (20), a load-transfer means (3), which is installed on the driverless transportation vehicle (1) and has a load-transfer drive (33), and a control system (7); wherein the chassis (2) comprises at least two wheels (21) arranged on an axle (9); wherein the traction drive (23) is configured to drive the at least two wheels (21); wherein the load-transfer means (3) is configured to pick up an item of general cargo (5) and transfer the centre of mass thereof on the driverless transportation vehicle (1); wherein the control system (7) is configured to control the traction drive (23) in such a way that the transportation vehicle (1) is prevented from tilting about the axle (9) of the chassis (2), while the driverless transportation vehicle (1) balances on only the at least two wheels (21), which are arranged on the axle (9); wherein the control system (7) is additionally configured to actuate the load-transfer drive (33) in such a way that the position of the centre of mass of the item of general cargo (5) is adapted for a driving manoeuvre which is to be carried out.,

Description

description

Self-balancing driverless transport vehicle

The invention relates to the technical field of driverless transport vehicles (AGVs) for transporting piece goods and to the use of such transport vehicles for transporting, distributing and / or sorting piece goods, as well as to a sorting system which includes such transport vehicles.

For driverless transport vehicles (also called Automated Guided Vehicle, AGV), numerous and very different drive concepts are used today, depending on the application. For the application of the transport, storage, order picking and sorting of piece goods in the postal and airport environment, such as baggage, parcels and bulky goods, special challenges arise that the existing concepts cannot adequately meet.

Previous applications of AGVs also show a specific kinematic structure for a defined application in a defined domain.

These special challenges are:

Inhomogeneous shape and casing material of the piece goods, which can result in the piece goods rolling, tilting, sliding, tilting or catching;

Inhomogeneous mass distribution leads to a center of mass that does not coincide with the geometrical center of gravity, as Hesse suspects from the external shape of the piece goods;

The center of mass can also shift in an undefined manner during transport, for example if the piece goods are a package or a piece of luggage with loose contents; - It is desirable to be able to carry out travel profiles at a height, with a rough road surface, as well as inclines, slopes, helices, steps and crevices;

- A simple adaptation to the existing infrastructure is also desirable (migration).

So far, AGVs have mainly been built with more than one axle, so they are statically stabilized systems.

In order to be able to overcome uneven ground structures, different concepts are pursued:

- Statically determined three-point bearing (e.g. tricycle);

- Boogie landing gear technology (like the Mars Rover);

- sprung support wheels;

- Spring-loaded independent wheel suspension (as in the current automobile).

These concepts are based on elaborate chassis.

The challenges listed above can therefore only be met with considerable costs for the vehicle chassis itself.

Self-balancing single-axle vehicles are known from another technical field of transporting relatively fixed masses, such as people or goods, and are documented, for example, in the following links: https: // www. youtube. com / watch? v = ZhhRBUdnliI

https: // www. youtube. com / watch? v = 3Tie5-kgHlk

These links reveal self-balancing systems designed as wheelchairs based on the Segway principle, such as the NINEBOT NINO. People as well as fixed objects can be transported on these.

Such devices are not known for inhomogeneous goods with an undefined movable center of gravity and People and goods are loaded onto a suitable position of the single-axle self-balancing vehicle through human intervention.

The present invention is therefore based on the object of providing a concept with which piece goods can be transported as flexibly and economically as possible by means of an AGV.

This object is achieved by the concepts described in the independent claims.

According to the invention, a driverless transport vehicle for piece goods is presented. The driverless transport vehicle comprises a running gear, a travel drive, a load displacement means installed on the driverless transport vehicle with a load displacement drive and a control system. The chassis comprises at least two wheels arranged in an axle. The drive is designed to drive the at least two wheels. The load shifting means is designed to pick up a piece goods and to shift its center of gravity on the driverless transport vehicle. The control system is designed to regulate the travel drive in such a way that the transport vehicle is prevented from tipping around the axis of the chassis, while the driverless transport vehicle balances on only the at least two wheels arranged in the axis. The control system is also designed to control the load displacement drive in such a way that the position of the center of gravity of the piece goods is adapted for a driving maneuver to be performed.

According to one embodiment, the load displacement means is designed as a conveyor, for example as a conveyor line, conveyor belt, belt conveyor or roller conveyor. These allow a reliable and simple adjustment of the position of the center of mass of the piece goods. In particular, conveyor belts and belt conveyors allow a particularly reliable sige adjustment of the position of the center of mass of bulky piece goods.

According to one embodiment, the wheels can be driven individually. This enables high maneuverability of the driverless transport vehicle.

According to one exemplary embodiment, the chassis comprises exactly two wheels arranged on the side of the driverless transport vehicle in the axle. This results in a particularly simple construction of the driverless transport vehicle.

According to one embodiment, the load shifting means is designed to shift the center of gravity of the piece goods on the driverless transport vehicle in the direction of travel and against the direction of travel. This allows particularly effective possibilities of adapting the position of the center of mass of the piece goods for different driving maneuvers.

Self-balancing single-axle AGVs (SFTF) show advantages when it comes to sorting general cargo:

- costs

-> minimum number of drive elements

-> very simple kinematic structure of the chassis

-> no lifts required in the sorting system layout

- Gradeability

-> maximum throughput over several levels

- Driving over obstacles

-> Steps, hall steps, uneven road surfaces and dirt, grating levels and steps, convex, concave and angled roads, ramps ... - Acceleration of load carriers and loads attached with high legs

-> Loading of high trolleys without steel structure for the AGV (see GrayOrange, Geek + and AIC)

Disadvantages or problems of this SFTF solution are:

- In the event of a system shutdown, an emergency stop or a failure of the energy system, the SFTF threatens to tip over;

- Inclination of the conveyor technology when dropping the goods by balancing around the dynamic overall center of gravity;

- High energy-guzzling control dynamics due to the relative instability in the dynamic pick-up and delivery of piece goods when loading or unloading at the end point (see FIGS. 20 and 21).

According to one embodiment, the driverless transport vehicle comprises a safety system for supporting the SFTF in the event of a system shutdown, an emergency stop or a failure of the energy system. Particularly when driving on uphill or downhill stretches, special precautions are desirable so that the vehicles come to a safe standstill within the legally prescribed framework for in-house sorting systems (Machinery Directive).

According to one embodiment, this includes driverless

Transport vehicle additionally has a support wheel system or a stand system which is designed to ensure a stable position of the driverless transport vehicle when the control system is switched off. This allows the driverless transport vehicle to remain stable even when the control system is switched off. In addition, the support wheel or stand system can also ensure additional stability for demanding driving maneuvers and processes, such as loading the transport vehicle.

According to an exemplary embodiment, the control system is designed to retract and / or extend the support wheel or stand system for the driving maneuver to be performed. This allows a greater variety of possible driving maneuvers that can be carried out by the driverless transport vehicle.

According to one embodiment, the support wheel system is designed and arranged to allow the transport vehicle to be steered in any direction on a driving surface in an extended state. As a result, the maneuverability of the driverless transport vehicle is not impaired by the support wheel system even when it is extended.

According to one embodiment, the support wheel system is designed and arranged to be extended by gravity or with the aid of a spring. This means that no further mechanism or drive is required to extend the support wheel system.

According to one embodiment, driverless transport vehicle comprises at least one controllable ratchet or at least one force-regulated brake which is arranged in a joint of the support wheel system and designed to prevent the support wheel system from jumping back in an extended state and one or more wheels of the support wheel system in position on the ground. This ensures that the driverless transport vehicle is supported on the ground.

According to one exemplary embodiment, the support wheel system comprises a front support wheel system and a rear support wheel system, each of which is designed and arranged to support the transport vehicle in the direction of travel at the front and rear, adapted to an existing incline of the roadway in an extended state. As a result, the driverless transport vehicle can be supported on the roadway despite the many unevenness and variable gradient angles of the roadway.

According to one embodiment, the driverless transport vehicle comprises at least one controllable ratchet or force-regulated brake in each case at least one wheel support and is designed to release the wheel support and to lock it again in a position above the road when the driverless transport vehicle is tilted.

According to one exemplary embodiment, the transport vehicle is designed to implement a force required to extend the support wheel system or the stand system purely mechanically and not by actively driven actuators designed exclusively for this purpose. This allows a simplified construction of the transport vehicle.

According to an exemplary embodiment, the control system is also designed to control the load displacement drive in such a way that the position of the center of gravity of the piece goods is individually adapted to the maneuver to be performed for different driving maneuvers.

According to one embodiment, the transport vehicle includes different kinematic and control-related driving states.

According to one embodiment, the control system can be deactivated when the support wheel system is extended. As a result, the energy consumption required to balance the driverless transport vehicle can be reduced.

According to an exemplary embodiment, when the support wheel system is extended, the drive, the control system, is designed to control the drive in a non-balancing mode.

According to an exemplary embodiment, when the support wheel system is extended, the drive, the control system, is designed to control the drive as a differential drive control.

According to one embodiment, the load displacement means is designed and arranged, the piece goods from the Drop the transport vehicle. This allows a further automation of logistical processes combined with a simple construction.

According to one exemplary embodiment, the driving maneuver comprises driving up an incline and the control system is designed to control the load shifting drive for driving up the incline in such a way that the position of the center of mass of the item is moved in or against the direction of travel. This makes it possible to keep the piece goods in a horizontal position despite driving up the slope or at least to adjust the position of the center of gravity of the piece goods so that the piece goods are stored in a less inclined position on the load displacement means than is the case with a unmatched position would be the case. When driving uphill, the control system can be designed, for example, to control the load displacement drive for driving up the incline in such a way that the position of the center of gravity of the piece goods is shifted in the direction of travel or that the position of the center of mass of the piece goods is forward in the direction of travel the axis is positioned. For downhill travel, for example, the control system can be designed to control the load shifting drive so that the position of the center of gravity of the piece goods is shifted against the direction of travel or that the position of the center of mass of the piece goods is positioned behind the axis.

According to one embodiment, the driving maneuver includes a braking maneuver and the control system is designed to control the load shifting drive for the braking maneuver in such a way that the position of the center of gravity of the piece goods is shifted against the direction of travel. This allows for a shorter braking distance, because otherwise during the braking maneuver, the inertia of the cargo and the upper part of the transport vehicle would cause the transport vehicle to lean forward, which in turn is compensated for by an acceleration of the drive. would have to be done so that the transport vehicle does not tip forward.

According to one exemplary embodiment, the driving maneuver comprises a starting or acceleration maneuver and the control system is designed to control the load shifting drive for the starting or acceleration maneuver in such a way that the position of the center of gravity of the piece goods is shifted in the direction of travel. This allows faster starting and acceleration maneuvers, since otherwise the driverless transport vehicle has to be set in a position inclined in the direction of travel by a short acceleration against the intended direction of travel so that the transport vehicle can then be accelerated in the direction of travel again without it tilts.

According to one embodiment, the control system 7 is designed to control the load shifting drive 33 and / or the travel drive 23 so that a receiving surface of the load shifting means on which the piece goods 5 rests assumes an intended angle of inclination or comes to lie horizontally.

According to one embodiment, the control system is also designed to control the load displacement drive so that the position of the center of gravity of the piece goods is adapted for the maneuver to be performed, while the driverless transport vehicle only uses the at least two in the axle arranged wheels balanced. This allows a greater variety of possible driving maneuvers that can be carried out by the driverless transport vehicle.

According to the invention, a sorting system is also presented. The sorting system comprises a sorting area, a sorting logic and a plurality of driverless transport vehicles according to one of the embodiments described above. The sorting area comprises at least one loading area and sorting destinations. The loading area is designed to load the driverless transport vehicles with piece goods. The sorting logic is designed to guide a transport vehicle loaded with piece goods to a sorting destination assigned to the piece goods.

The invention also relates to the use of a driverless transport vehicle according to one of the embodiments described above for transporting, distributing and / or sorting piece goods, in particular for transporting, distributing and / or sorting pieces of luggage or packages.

The invention is explained in more detail below using the figures, for example. Show:

Figures 1-3 perspective views of a driverless

Transport vehicle according to an embodiment of the invention;

FIG. 4 shows a perspective view of a driverless transport vehicle according to a further exemplary embodiment of the invention;

FIG. 5 is a schematic side view of the transport vehicle shown in FIGS. 1-3 while it is balancing on two wheels arranged in the axle;

Figure 6 is a schematic side view of the transport vehicle shown in Figures 1-3 while it is being automatically loaded;

Figure 7 is a schematic side view of the transport vehicle shown in Figures 1-3 while it is accelerating;

Figure 8 is a schematic side view of the transport vehicle shown in Figures 1-3 while it is traveling straight ahead; Figure 9 is a schematic side view of the transport vehicle shown in Figures 1-3 while it is traveling up a slope;

FIG. 10 shows a schematic side view of the transport vehicle shown in FIGS. 1-3 while it is traveling down an incline;

FIG. 11 shows a schematic side view of the transport vehicle shown in FIGS. 1-3, during a braking maneuver;

FIG. 12 shows a sorting system according to an exemplary embodiment of the invention;

FIG. 13 shows a schematic side view of a driverless transport vehicle according to an embodiment of the invention with an extendable support wheel system on a horizontal track;

FIG. 14 shows a schematic side view of the driverless transport vehicle from FIG. 13 on a concave roadway;

FIG. 15 shows a schematic side view of the driverless transport vehicle from FIG. 13 on a roadway with a gradient or an increase;

FIG. 16 shows a schematic side view of the driverless transport vehicle from FIG. 13 on a convex roadway;

FIGS. 17 and 18 are perspective views of the driverless transport vehicle from FIG. 13;

FIG. 19 shows a perspective view of a variant of a driverless transport vehicle according to an embodiment of the invention; FIGS. 20 and 21 variants of sorting systems according to embodiments of the invention;

FIG. 22 shows a perspective view of a further variant of a driverless transport vehicle according to an embodiment of the invention.

Figures 1-3 show perspective views of a driverless transport vehicle 1 according to an embodiment of the invention. Figures 5-11 show side views of the driverless transport vehicle 1 during different maneuvers. The driverless transport vehicle 1 can be used, for example, for transporting, distributing and / or sorting piece goods, for example for distributing and / or sorting pieces of luggage or packages.

The driverless transport vehicle 1 comprises a single-axle running gear 2, a travel drive 23, a load displacement means 3 installed on the driverless transport vehicle 1 with a load displacement drive 33 and a control system

7th

The load shifting means 3 is designed to receive a piece goods 5 and to shift its center of gravity 55 on the driverless transport vehicle 1 at right angles to the axis 9, in the direction of travel and against the direction of travel. For this purpose, the load displacement means 3 is designed as a conveyor belt and the load displacement drive 33 is designed to drive the load displacement means.

The chassis 2 comprises two individually drivable wheels 21 arranged in an axle 9. The travel drive 23 is designed to drive the at least two wheels 21 individually.

The control system 7 is designed to control the travel drive 23 in such a way that the transport vehicle 1 is prevented from tipping about the axis 9 of the chassis 2, while the driverless transport vehicle 1 only operates on the at least two in the Axis 9 arranged wheels 21 is balanced, so while the driverless transport vehicle 1 with only the at least two wheels 21 arranged in the axis 9 is touching a roadway 8 or some other surface.

The control system 7 is also designed to control the load displacement drive 33 in such a way that the position of the center of gravity 55 of the piece goods 5 is adapted for a driving maneuver to be carried out, while the driverless transport vehicle 1 only uses the at least two in the axle 9 arranged wheels 21 are balanced, that is, while the driverless transport vehicle 1 is touching a roadway 8 with only the at least two wheels 21 arranged in the axle 9.

FIGS. 5-11 illustrate how the position of the center of mass 55 of the piece goods 5 is adapted for a driving maneuver to be performed.

FIG. 5 shows the driverless transport vehicle 1 loaded with the piece goods 5 during a driving maneuver in which the transport vehicle 1 rests in a balancing manner at one point, that is to say has no speed. The position of the center of mass 55 of the piece goods 5 is adjusted by the load displacement means 3 in such a way that the total center of gravity of the transport vehicle 1 and the piece goods 5 comes to lie vertically above the axis 9. It is not necessary for this position to be calculated; it is sufficient for the control system 7 to independently set this position of the piece goods by means of negative feedback, for example by minimizing the corrections of the travel drive 23 necessary for balancing as a control variable.

In order to balance the transport vehicle 1 in the unloaded state, that is to say without the piece goods 5, the control system 7 will regulate the travel drive 23 such that the center of gravity 15 of the unloaded transport vehicle 1 is balanced vertically above the axis 9. In order to balance the transport vehicle 1 in the loaded state, i.e. with the piece goods 5, the control System 7 regulate the travel drive 23 in such a way that the common center of gravity 35 of the transport vehicle 1 and the piece goods 5 is balanced vertically above the axis 9.

In the exemplary embodiment shown in FIG. 5, the mass distribution of the transport vehicle 1 is assumed to be essentially symmetrical, whereby a particularly suitable adapted position of the center of gravity 55 of the piece goods 5 for the driving maneuver to be carried out, i.e. for the stationary balancing, is in the middle of the transport vehicle. This also results in an essentially horizontal position of the load displacement means 3 configured as a belt conveyor, thus a horizontal position of the storage of the piece goods 5.

However, numerous other embodiments are possible, including those of transport vehicles with non-symmetrical mass distribution, in which the asymmetry is compensated for by adapting the control variables of control system 7, in particular by controlling travel drive 23 and / or load shifting drive 33.

FIG. 6 shows how the transport vehicle 1 is automatically loaded with the piece goods 5 by a stationary conveyor device 50. The transport vehicle 1 is positioned adjacent to the stationary conveyor device 50 in such a way that it can convey the piece goods 5 onto the transport vehicle 1.

As can be seen in FIG. 6, the transport vehicle 1 additionally comprises a support wheel system 40 which is designed to ensure that the driverless transport vehicle 1 is in a stable position when the control system 7 is switched off. The support wheel system can be retracted and extended and is extended when the transport vehicle is being loaded, as shown in FIG. 6, in order to absorb lever forces that can be applied far outside the transport vehicle during loading. As an alternative to this, the support wheel system 40 or a stand system can also be retracted or completely absent, with the transport vehicle 1 tipping about the axis 9 of the chassis 2 by a regulation of the Travel drive 23 is prevented and the transport vehicle 1 is already balanced on the chassis 2 during the loading process, that is to say on only the two wheels 21 arranged in the axle 9.

In the process shown in FIG. 6, the transport vehicle 1 is positioned such that it is loaded with the piece goods 5 from the rear by the belt conveyor 3. As an alternative to this, the transport vehicle 1 can also position itself adjacent to the conveying device 50 in such a way that it is loaded with the piece goods 5 from the side. In other exemplary embodiments, the transport vehicle 1 can thus also be loaded from the side.

In addition or as an alternative to the load shifting means 3, the transport vehicle 1 can also comprise further conveying means which can also move the piece goods 5, for example, transversely to the direction of travel of the transport vehicle 1 or parallel to the axis 9. For example, in one variant, instead of the belt conveyor 3, the transport vehicle 1 can include a corner transfer device that allows the piece goods to be conveyed in the direction of travel of the transport vehicle and perpendicular to it, that is to say sideways on the support surface of the transport vehicle 1.

FIG. 7 shows a starting maneuver or acceleration maneuver of the transport vehicle 1 after it has been loaded with the piece goods 5 as shown in FIG. The load shifting means 3 is controlled in such a way that the position of the center of gravity 55 of the piece goods 5 is shifted in the direction of travel until the driverless transport vehicle 1 tilts forward, that is, in an intended travel direction r of the transport vehicle 1. The common center of mass 35 of the transport vehicle 1 and the piece goods 5 then lies in front of the axle 9 in the direction of travel, as can be seen from the dashed lines A and B. In order to prevent the transport vehicle 1 from tipping over completely, the transport vehicle 1 accelerates in the intended direction of travel r by the control system 7 driving the drive 23 and optionally also regulates the load displacement drive in such a way that the vehicle is accelerated in this inclined position up to an intended speed v and balances during the acceleration a. Such a maneuver has several advantages over a conventional, single-axle, regulated transport vehicle:

The transport vehicle 1 does not first need to accelerate against the intended direction of travel r in order to bring about the inclination desired for travel in the intended direction of travel r. This enables more efficient approach;

- Such an acceleration contrary to the intended

The direction of travel r would not or hardly be possible in the situation shown in FIG. 6, since the transport vehicle for loading should be as close as possible to the stationary conveying device 50;

During the entire acceleration process, the inclination of the surface of the belt conveyor 3 can be regulated by the control system 7 in such a way that it counteracts the inertia of the piece goods and thus counteracts possible slipping on the belt conveyor against the intended travel direction r , and thereby prevents the piece goods from falling down on the rear of the transport vehicle 1.

The support wheel system 40 is retracted during the acceleration maneuver.

FIG. 8 shows a driving maneuver when driving straight ahead. The control system 7 controls the load displacement drive 33 in such a way that the position of the center of gravity 55 of the piece goods 5 causes a somewhat less pronounced inclination in the direction of travel than in the acceleration maneuver illustrated with reference to FIG. When traveling straight ahead at essentially constant speed, a total center of gravity 35 of the transport vehicle 1 and piece goods 5 lying somewhat in front of the axis 9 in the direction of travel r is desired, as this is conditional As a result of the air resistance and friction losses in the wheels 21, the travel drive 21 is still intended to give a torque to the wheels 21. In FIG. 8, this offset of the common center of mass 35 and axis 9 is made visible by the dashed lines A and C.

FIG. 9 shows the transport vehicle 1 which, as a driving maneuver, is driving up an incline in an upward direction. The control system 7 is designed to control the load displacement drive 33 so that the position of the center of gravity of the piece goods 5 is shifted in the direction of travel, or that the total center of gravity 35 of the piece goods 5 and the transport vehicle 1 in the direction of travel in front of the axis 9 is, as can be seen by the dashed lines A and D. According to a preferred embodiment, the position of the piece good 5 can be set such that the piece good 5 rests horizontally on a receiving surface of the load displacement means 3.

FIG. 10 shows the transport vehicle 1 which, as a driving maneuver, is driving down an incline in a downward direction. The control system 7 is designed to control the load displacement drive 33 in such a way that the position of the center of gravity 55 of the item 5 is shifted against the direction of travel, or that the total center of gravity 35 of the item 5 and the transport vehicle 1 lies behind the axle 9 as seen in the direction of travel, as can be seen from the dashed lines A and E. According to a preferred embodiment, the position of the piece goods 5 can be set in such a way that the piece goods rests horizontally on a receiving surface of the load displacement means 3.

FIG. 11 shows a braking maneuver of the transport vehicle 1 loaded with the piece goods 5. The load shifting means 3 is activated in such a way that the position of the center of gravity 55 of the piece goods 5 is shifted against the direction of travel so that the driverless transport vehicle moves 1 to the rear, i.e. against the direction of travel r of the transport stuff 1 tends. The common center of mass 35 of the transport vehicle 1 and the piece goods 5 then lies behind the axis 9, viewed in the direction of travel r, as can be seen from the dashed lines A and F. In order to prevent the transport vehicle 1 from tipping over completely, the transport vehicle 1 brakes in that the control system 7 controls one vehicle brake and optionally also the load displacement drive 33 so that the vehicle 1 is braked to a specified speed in this inclined position and during the braking process, which is represented by the negative acceleration -a acting on the wheel 21 at this point in time, balanced. Such a driving maneuver has several advantages over a conventional single-axle controlled transport vehicle:

The transport vehicle 1 does not first need to accelerate in the direction of travel r in order to bring about the inclination desired for the braking maneuver. This shortens the braking distance;

- During the entire braking process, the inclination of the surface of the belt conveyor 3 can be controlled by the control system 7 in such a way that it counteracts the inertia of the piece goods 5 and thus counteracts any possible slipping on the belt conveyor in the direction of travel r, and thus a possible fall of the Parcel 5 prevents the front of the transport vehicle 1.

The following applies to all driving maneuvers shown in the figures: In order to adapt the position of the center of gravity 55 of the piece goods 5 for a driving maneuver to be carried out, it is not necessary to calculate this position;

FIG. 4 shows a driverless transport vehicle 101 according to a further exemplary embodiment of the invention, in which the load shifting means 3 is placed lower and in which the center of gravity of the transport vehicle 101 is low lies. This makes it possible to keep the transport vehicle more easily balanced on the wheels 21. The transport vehicle 101 also has side walls.

FIG. 12 shows a sorting system 100 which comprises a sorting area 104, a sorting logic 103 and a plurality of driverless transport vehicles 1. The sorting area 104 comprises at least one loading area 105 and sorting destinations 108. The loading area 105 is designed to load the driverless transport vehicles 1 with piece goods. The sorting logic 103 is designed to guide a transport vehicle 1 loaded with a piece goods 5 to a sorting destination 108 assigned to the piece goods 5 and to cause the transport vehicle 1 to deliver the piece goods to the sorting destination assigned to the piece goods.

By using only one axis, a balancing active tilting stability system (inverse single pendulum, Segway principle) and a transfer technology that shifts the center of gravity (inverse double pendulum), further exemplary embodiments of the invention also enable a high degree of mobility, since the transport vehicle is on the place can turn, a free navigation and a free route optimization. In addition, a high speed bandwidth is possible, for example from 1 m / s to 10 m / s. High-speed connections can also be used. Embodiments of the invention also allow a high level of independent climbing ability and a high degree of independence from uneven ground, which can be advantageous in particular in airport halls, aprons and parcel centers.

Due to the mechanical simplicity of the vehicle, the costs can be reduced considerably compared to known current AGV designs. The transport vehicle can be used as a self-balancing 1-axle cross conveyor AGV for inhomogeneous

Be carried out piece goods. Embodiments of the invention are based on the combination of an actively self-balancing 1-axle vehicle (Segway (inverse single pendulum)) and a conveyor system that actively shifts the load center of gravity. The associated kinematic, control-technical and physical relationships for such a combination are known from the problem of the "inverse double pendulum".

Single pendulum: https: // www. youtube. com / watch? v = 6diEXY6JVPM double pendulum: https: // www. youtube. com / watch? v = ew-yP6uZbrU

Embodiments of such combinations allow a simple and flexible transport of piece goods with a Segway principle, which would otherwise only be realizable with great restrictions and cumbersome.

FIG. 13 shows a schematic side view of two identical driverless transport vehicles 1 according to an embodiment of the invention with an extendable support wheel system 40 on a horizontal track. The support wheel system comprises a front support wheel system 41 and a rear support wheel system 42, which are attached to the transport vehicle 1 at the front and rear as seen in the direction of travel. The driverless transport vehicle 1 shown on the left in FIG. 13 has retracted the support wheel system 40 and is balancing with the help of the control system 7 on the chassis 2. The driverless transport vehicle 1 shown on the right in FIG. 13 has extended the support wheel system 40 and needs it therefore no regulation so as not to tip over. With the support wheel system 40 extended, the transport vehicle 1 can be parked. With the support wheel system 40 extended, the transport vehicle 1 can be parked but also transport piece goods with reduced energy consumption, since in this case the energy required for regulating the balancing can be saved. This can be particularly useful for overcoming longer, less demanding stretches, for example stretches without steps. To start up and move the transport vehicle 1, the active ribs can automatically and passively raise the support legs 41, 42 and fix them in the end position reached, for example by means of a ratchet. The transport vehicle 1 can be stabilized again by reversing the ratchets.

The control system 7 can be designed and adapted, when the transport vehicle 1 stops, the support wheels 41,

42 by releasing and reversing the ratchet function to let fall onto the roadway and to lock it there so that the transport vehicle 1 is stabilized in the respective position in every climbing situation. This is illustrated in Figures 14-16.

FIG. 14 shows two identical transport vehicles 1 from FIG. 13 on a concave roadway. The transport vehicle 1 on the right was stabilized by the extended support wheel systems 41, 42.

FIG. 15 shows two identical transport vehicles 1 from FIG. 13 on a roadway with an uphill / downhill gradient. The transport vehicle 1 on the left was extended by the

Support wheel systems 41, 42 stabilized.

FIG. 16 shows two identical transport vehicles 1 from FIG. 13 on a convex roadway. The transport vehicle 1 on the right was stabilized by the extended support wheel systems 41, 42.

FIG. 17 shows a perspective view of a transport vehicle 1 shown in FIG. 13, both support wheel systems 41, 42 being extended and supporting the transport vehicle 1 on the roadway. In this mode, the control system 7 can be inactive.

Figure 18 shows a perspective view of a variant of the transport vehicle from Figure 17, in which both support wheel Systems 41, 42 are retracted and therefore do not touch the road. The transport vehicle 1 balances with the aid of the control system 7.

FIG. 19 shows a variant of a transport vehicle 1 with a load displacement means 3 which can move piece goods 5 transversely to the direction of travel of the transport vehicle 1 in a perspective view.

FIG. 20 shows a variant of a concept of a sorting system 100 which extends over two parallel sorting levels arranged vertically one above the other. The sorting system 100 comprises a helical roadway over which the transport vehicles 1 can drive from one of the sorting levels to the other sorting level. The sorting system also includes a helical chute, via which the transport vehicles can drop piece goods 5 from the upper of the two sorting levels to the lower level and transfer them there to a further transport vehicle 1.

FIG. 21 shows a perspective view of a further variant of a concept of a sorting system in a perspective view. In this variant, the chutes and the lanes connecting the sorting planes arranged one above the other are not helical, but straight.

FIG. 22 shows a variant of the transport vehicle 1 shown in FIG. 20 in a perspective view with a load displacement means 3 arranged in an elevated position.

Further embodiments result from the following features:

The support wheels 40, 41, 42 are designed as "omniwheels" or trailing wheels, ie in the extended state the SFTF can continue to control any direction in the plane. - The support wheels 40, 41, 42 are extended if necessary by gravity or with the aid of springs.

A controllable ratchet in the joint prevents the support wheel systems 40, 41, 42 from jumping back and holds them in position on the ground.

- Separate ratchets for the front wheel 41 and rear wheel 42 make it possible to adapt to any climbing angle that the transport vehicle 1 is currently driving over.

- An active reversal of the ratchet gives the wheel supports 40,

41 free and locks it again in a position above the road surface when the SFTF is tilted (balancing mode).

- The force required for supporting is achieved purely mechanically and not by actively driven actuators.

- Instead of a ratchet, a force-controlled brake can also be used here.

The support wheel systems 40, 41, 42 can include a passive locking of the support wheels after gravity or spring release in any position and driving situation of the transport vehicle 1, so that the SFTF is prevented from tipping over.

The support wheel systems 40, 41, 42 can include passive self-resetting of the support wheels when the transport vehicle 1 starts up by tilting the SFTF after the ratchet function has been reversed.

- Position measurement (tilt angle of the SFTF).

- Lane measurement in front of and behind the transport vehicle 1.

- Active, proportionally controlled actuators, drives and control circuits for the support wheels on the front and rear of the transport vehicle 1. The transport vehicle 1 has functional and stable support wheels that are designed as omniwheels or trailing wheels, ie in the extended state the transport vehicle 1 can steer in any direction in the plane and thus imitates a classic driverless transport vehicle.

- If necessary, the support wheels are actively extended by actuators or passively by gravity or with the aid of springs.

For this purpose, a hybrid control actively switches over from the balancing control to a simple and known differential drive control if the balancing driving style is not necessary or disadvantageous.

The control system 7 is designed and adapted to switch from a self-balancing system to a differential drive system (tank drive) and back, depending on the driving order, transport order and road situation in a driverless vehicle based on a driverless transport vehicle

Transport system or piece goods sorting system.

The driverless transport vehicle 1 can comprise a hybrid structure of the drive and chassis kinematics and the control technology.

At least the solutions of the transport vehicle, the sorting system and their uses based on claims 13-18, 20-23 also function without the feature according to which the control system must also be designed to control the load displacement drive so that the position the center of mass of the piece goods is adapted for a driving maneuver to be carried out.

Claims

Claims

1. Driverless transport vehicle (1) for piece goods (5), comprising a chassis (2), a drive (23), a load displacement means (3) installed on the driverless transport vehicle (1) with a load displacement drive (33) and a control system (7);

wherein the chassis (2) comprises at least two wheels (21) arranged in an axle (9);

wherein the travel drive (23) is configured to drive the at least two wheels (21);

wherein the load shifting means (3) is designed to receive a piece goods (5) and to shift its center of gravity (55) on the driverless transport vehicle (1); wherein the control system (7) is designed to control the drive (23) in such a way that the transport vehicle (1) is prevented from tipping about the axis (9) of the chassis (2) while the driverless transport vehicle (1 ) balanced on only the at least two wheels (21) arranged in the axle (9);

wherein the control system (7) is also designed to control the load displacement drive (33) in such a way that the position of the center of gravity (55) of the piece goods (5) is adapted for a driving maneuver to be performed.

2. Driverless transport vehicle (1) according to claim 1, wherein the load displacement means (3) is designed as a conveyor, for example as a conveyor line, conveyor belt, belt conveyor or roller conveyor.

3. Driverless transport vehicle (1) according to one of the preceding claims, wherein the wheels (21) can be driven individually.

4. Driverless transport vehicle (1) according to one of the preceding claims, wherein the chassis (2) comprises exactly two wheels (21) arranged on the side of the driverless transport vehicle in the axis.

5. Driverless transport vehicle (1) according to one of the preceding claims, wherein the load shifting means (3) is designed to move the center of gravity of the piece goods (5) on the driverless transport vehicle (1) in the direction of travel and against the direction of travel.

6. Driverless transport vehicle (1) according to one of the preceding claims, additionally comprising a support wheel system (40) or a stand system (40) which is designed to ensure a stable position of the driverless transport vehicle (1) when the control system (7) is switched off .

7. Driverless transport vehicle (1) according to claim 6, wherein the control system (7) is designed to retract and / or extend the support wheel system (40) or stand system (40) for the driving maneuver to be performed.

8. Driverless transport vehicle (1) according to one of the preceding claims, wherein the driving maneuver comprises driving on an incline and the control system (7) is designed to control the load shifting drive (33) for driving on the incline, that the position of the center of mass of the piece goods (5) is shifted in or against the direction of travel.

9. Driverless transport vehicle (1) according to one of the preceding claims, wherein the driving maneuver comprises a braking maneuver and the control system (7) is designed to control the load displacement drive (33) for the braking maneuver so that the position of the center of gravity of the piece - Guts (5) is shifted against the direction of travel.

10. Driverless transport vehicle (1) according to one of the preceding claims, wherein the driving maneuver comprises a starting or acceleration maneuver and the control system (7) is designed to control the load displacement drive (33) for the starting or acceleration maneuver so that the position of the center of gravity of the piece goods (5) is shifted in the direction of travel.

11. Driverless transport vehicle (1) according to one of the preceding claims, wherein the control system (7) is designed to regulate the load displacement drive (33) and / or the travel drive (23) so that a receiving surface of the load displacement means opens which the piece goods (5) lies on top, assumes an intended angle of inclination or comes to lie horizontally.

12. Driverless transport vehicle (1) according to one of the preceding claims, wherein the control system (7) is also designed to control the load displacement drive (33) so that the position of the center of gravity of the

General cargo (5) is adapted for the driving maneuver to be performed, while the driverless transport vehicle (1) balances on only the at least two wheels (21) arranged in the axle (9).

13. Driverless transport vehicle (1) according to one of claims 6-12, the support wheel system (40) being designed and arranged to allow the transport vehicle (1) to be steered in any direction on a driving surface in an extended state .

14. Driverless transport vehicle (1) according to one of claims 6-13, the support wheel system (40) being designed and arranged to be extended by gravity or with the aid of springs.

15. Driverless transport vehicle (1) according to claim 14, comprising at least one controllable ratchet or force-regulated brake, which is arranged and designed in a joint of the support wheel system (40) to allow the support wheel system (40) to spring back in an extended state and to keep one or more wheels of the support wheel system (40) in position on the ground.

16. Driverless transport vehicle (1) according to one of claims 6-15, wherein the support wheel system (40) comprises a front support wheel system (41) and a rear support wheel system (42) which are designed and arranged in an extended state to support the transport vehicle (1) at the front and rear in the direction of travel, adapted to an existing incline of the roadway.

17. Driverless transport vehicle (1) according to one of claims 15 or 16, the at least one controllable ratchet or force-regulated brake each comprising at least one wheel support and being designed to release the wheel support and to release it when the driverless one is tilted To lock the transport vehicle (1) again in a position above the roadway.

18. Driverless transport vehicle (1) according to one of claims 6-17, the transport vehicle being designed to implement a force required to extend the support wheel system (40) or the stand system (40) purely mechanically.

19. Driverless transport vehicle (1) according to one of the preceding claims,

wherein the control system (7) is also designed to control the load displacement drive (33) in such a way that the position of the center of gravity (55) of the piece goods (5) is individually adapted to the maneuver to be performed for different driving maneuvers.

20. Driverless transport vehicle (1) according to one of claims 6-19, characterized in that the control system (7) can be deactivated when the support wheel system is extended.

21. Driverless transport vehicle (1) according to one of the claims 6-20, characterized in that when an When the support wheel system is driven, the travel drive (23), the control system is designed to control the travel drive (23) in a non-balancing mode. 22. Driverless transport vehicle (1) according to one of claims 6-21, characterized in that when the support wheel system (40) is extended, the drive (23) is designed as the control system, the drive (23) as a differential to control differential drive control.

23. Driverless transport vehicle (1) according to one of the preceding claims,

wherein the load shifting means (3) is designed and arranged to throw the piece goods (5) from the transport vehicle (1).

24. Sorting system (100) comprising a sorting area

(104), a sorting logic (103) and a plurality of driverless transport vehicles (1) according to one of the preceding claims;

wherein the sorting area (104) has at least one loading area

(105) and sort destinations (108);

The loading area (105) is designed to load the driverless transport vehicles (1) with piece goods;

The sorting logic (103) is designed to guide a transport vehicle (1) loaded with piece goods (5) to a sorting destination (108) assigned to the piece goods (5).

25. Use of a driverless transport vehicle (1) according to one of claims 1 to 23 for transporting, distributing and / or sorting piece goods.

26. Use of a driverless transport vehicle according to one of claims 1 to 23 for transporting, distributing and / or sorting pieces of luggage or packages.