EP0870461A1 - Drive system to move a robot or vehicle on flat, sloping or curved surfaces, in particular on a glass structure - Google Patents

Abstract

The drive has a liftable driven wheel (3), which is associated with a wheeled frame (2) supporting the robot or the vehicle. The driven wheel is made of a material with a high coefficient of friction in the travel direction. The remaining wheels (4) made from a material with a lower coefficient of friction. The frame is held by a retaining cable wound around a pair of spaced cable drums (9). The sidewards movement or angular position of the frame relative to the travel direction is detected for operating the drum drives (10), under control of a position correction device.

Description

The invention relates to a drive device for Moving a robot or vehicle on flat, inclined or curved surfaces, especially one Glass construction, as well as a robot with drive device.

Recently, glass halls and built with large glass surfaces where the glass panes glass brackets of a grid construction, which are designed as an outer or inner skeleton is to be held. Such halls are often like this trained that the glass sheets starting from the Peak of the roof to the previous one Disc are inclined by a certain angle. There with such large glass surfaces, the question of Cleaning the same poses considerations employed the use of cleaning robots.

When moving a robot or a vehicle Glass surfaces have a major problem in choosing one suitable kinematics for the drive and the Direction control of the robot or vehicle. If the construction of the glass surface has elements, that can serve as guiding elements for the robot and which allow force input, e.g. B. rail systems, become these elements for getting around used. Are such constructive elements not available or unsuitable, the force must be applied done directly into the glass.

In this case, problems arise in that for locomotion of the robot, for example as Wheel trained drive element a force on the Glass that must be larger than the one hand the rolling friction resistance between the glass and the wheel plus the static and rolling friction resistance of the respective Powertrain, such as the engine, bearings and the like. On the other hand, the force applied must be smaller than the stiction between wheel and glass, otherwise slip would occur and the wheel would "go crazy". Since the amounts of the above minimum and maximum forces with low friction coefficients is very close to one another very sensitive regulation required.

In addition to getting around, one is as always type of steering, d. H. Influencing the direction of movement, required. The steering constructions known from the car are available due to the low standing space not suitable.

The invention is therefore based on the object Drive device for moving a robot or Vehicle on the surfaces in particular a glass structure to create a smooth forward movement without excessive point loads, which can cause the glass to break, ensures and a correction of the movement in the transverse direction.

This task is characterized by the features of the main claim solved.

The fact that the device according to the invention Drive wheel with a high coefficient of friction in the Direction of the wheel in the direction of travel and non-driven Wheels with a very low coefficient of friction has, with all wheels on a support frame are attached, on the one hand, a clean forward movement the component of a robot or of a vehicle supporting frame without spinning or slip and on the other hand a slight side Pushing or turning allows. With appropriate The lateral deviation and the facilities Rotation of the support frame determined and corresponding Corrections made with a control device the correction devices depending on the Size of the lateral deviation and the twist controls.

By the measures specified in the subclaims are advantageous further developments and improvements possible.

An embodiment of the invention is in the Drawing shown and is in the following Description explained in more detail. Figures 1 and 2 show perspective views of a cleaning robot, the device according to the invention having.

In the figure, a robot 1 is shown, which in Embodiment designed as a cleaning robot and that on a glass roof or a glass envelope moves a hall and the glass surface cleans according to its width. Here is the illustrated embodiment for cleaning a Grid construction suitable, which a predetermined grid Dimension forms .. The glass panes are thereby on glass mounts under the grid construction appropriate.

The cleaning robot essentially has one square support frame 2 on which the necessary Components are attached. On the support frame 2 are on free-running wheels 4 attached to all four corners, the preferably consist of a Teflon material or have a Teflon coating. It can also be a other material is chosen, it is important that it a material with a very low coefficient of friction is, which makes the robot 1 slide and easily can rotate. Furthermore, the hitneren part of the Frame 2 in the middle, for example, of an electric motor driven drive wheel 3 provided that the support frame 2 in particular on horizontal glass surfaces emotional. This drive wheel 3 is one pneumatic cylinder 5 can be lifted off the glass surface or lowerable. The drive wheel 3 consists of a Material that has a high coefficient of friction.

Because the robot in the present embodiment is designed as a cleaning robot, is in the direction of travel seen at the front on the support frame perpendicular to Moving direction attached a roller brush 6, the extends over the entire width of the support frame 2. The sides of the support frame are elongated Arms 7 arranged on which via swivel head assemblies 17 plate brushes 8 are attached. The arms 7 are retractable and extendable and are designed by an electric motor 18 driven by toothed belts.

Furthermore, a cable drum is on or on the support frame 2 16 with drive motor and a hose drum 15 attached with drive motor. The cable drum 16 takes one or more electrical lines, the at least for the power supply of the serve the supporting frame 2 mounted electrical parts, as a cable while the hose drum 15 picks up a water hose. Cable and water hose are handled when moving the robot 1. The hose end of the on the hose reel 15 provided hose is with a not shown Water distribution system provided that over Water jets in the area of the roller brush 6 and the plate brushes 8 splashes.

At the rear end of the support frame 2 are two rope drums 9 arranged as far as possible after are offset outside. On the rope drums 9 are Ropes, not shown, wound up normally as safety ropes to prevent the robot from falling serve and in the process of the robot from the rope drums 9 are unwound. With curved or inclined glass surfaces, they are also used for Pulling up the robot 1. The rope drums 9 are drum drives 10 each having electric motors assigned with corresponding gear transmissions. The ropes are each across the width of the rope drums and are recorded with a given cable tension wound up or unwound. These are the respective Cable drums measuring devices 11 for measurement assigned to the cable pulling force. The drum drives and the measuring devices designed as cable pull sensors 11 are for each rope drum 9 to a control loop interconnected, over which the given cable tension can be met. These are both the drum drives 10 as well as the cable sensors 11 with a control and regulating device, not shown connected, provided on the support frame 2 can be, but also separate from that Robot 1 can be arranged, then via electrical Control lines the control and regulation signals be fed. The control and regulating device is trained as a microcomputer or as a PC and also serves to control the drive of the drive wheel 3 and the motors 18 for retracting and extending the linear arms 7 and the swivel heads 17. Die from the cable drum 16, the hose drum 15 and the cable drums 9 wound and unwound cables, Hoses and ropes have to be tightened without grinding the glass surface are stored or recorded, and in a synchronous manner, and for this purpose Control loops provided through which the tax and Control device drives the cable drum 16, the hose drum 15 and the drum drive 10 for the cable drum 9 can be regulated. The traction that on the cable of the cable drum 16 and the hose the hose drum 15 acts in each case, is over the Power of the electric drive motors of the drums 16, 15 detected. Depending on the sensor signals the cable sensors 11 and the engine performance Traction gained regulates the tax and Control device the respective drives such that Ropes, cables and hose are stored tightly, so that there is no friction on the glass surfaces.

The robot 1 also has two measuring wheels 12, near the rope drums 9, ideally directly above the entry point of the rope on the drum (However, this cannot be realized because the entry point over the width of the rope drum 9 changes). The measuring wheels 12 are likewise with the control device, not shown connected and are connected to the cable drum drives 10 and the electric drive of the drive wheel 3 trained as control loops. Via the measuring wheels 12 is, for example, by counting the revolutions of the Measuring wheels 12 determines the distance traveled. On sensors, such as distance sensors, be provided, the construction elements detect what makes another statement be met via the routes covered can, because the construction elements in predetermined Grids or dimensions are arranged. Depending on The signals of these sensors can the measuring wheels 12th be readjusted.

The support frame 2 is with lateral slide rails 13 provided, each with a pneumatic piston-cylinder arrangement 14 are retractable and retractable and those for support on external construction parts to serve. The compressed air for the pneumatic components is about a not shown, on Support frame 2 attached compressor won.

The robot 1 is a service vehicle that is not is shown assigned to the top vertex a hall is arranged and with electric drives and distance measuring devices is provided over which he is moved in the direction of the hall axis. The ropes of the cable drums 11 of the robot 1 are with the service vehicle connected just like the cable of the Cable drum and the hose of the hose drum. The power supply is on the service vehicle provided that over the cable the cable drum 9 supplies the robot 1 with the necessary voltage, and it can also be called a microcomputer or PC trained control device provided be. There is still on the service vehicle a centrifugal pump connected to the hose of the Hose reel 10 of the robot 1 and with a long one Hose that taps the irrigation system connected and the necessary pressure for the water delivers. In addition, the service vehicle shows at least one automatic pick-up device, of which the assigned robot 1 on the glass surface discontinued or taken up by the glass surface.

At the beginning of the cleaning process, the robot 1 from the service vehicle at the apex of the glass roof discontinued, and the driven wheel is lowered. It works against the rope drums 9 itself unwinding ropes, whereby over the control loops, through which the measured values of the draw wire sensors are processed are regulated to the specified cable tension becomes. This is done via appropriate signals, the control device to the drum drives 10 delivers. At the beginning of the procedure, the Slide rails 13 extended until they each to the Construction elements in the grid of the grid construction bump, causing the robot 1 between aligns with the grid since the non-driven ones Wheels due to the low coefficient of friction no resistance to a uniform shift represent. However, in this case there is alignment the drive wheel 3 raised. After aligning the piston-cylinder arrangements become depressurized made, and the beginning of the Procedure with the drive wheel 3 lowered is carried out.

During the forward movement of the robot by the lowered drive wheel 3 with a high coefficient of friction is initiated, it comes due to external or internal influences, for example through the constructive elements of the glass roof, through a slight inclination of the robot when positioning or alignment, etc., during the procedure to a deviation from the desired direction of travel, which after a certain driving distance through a Rotation or lateral displacement of the robot 1 must be balanced. To determine the twist of the robot 1 are sent to the control device delivered measurement results of the measuring wheels 12 used. During the mean of the measurement results of the two measuring wheels 12 information about the distance traveled Path determines the difference between the measurement results of one and the measurement results of the other Measuring wheel 12 the angular rotation of the robot, which is calculated by the control device. The Control device monitors the size of the angular rotation and returns at a certain threshold a signal to correct the twist.

The lateral displacement is done via the slide rails 13 found. If the robot moves sideways off the desired direction of travel, he bumps into the existing construction elements, and, since the Piston-cylinder assemblies 14 have been depressurized, the respective piston is slowly retracted. A proximity sensor is located in or on the piston-cylinder arrangement provided a signal to the control device releases when the piston approaches. This signal triggers the necessary correction of the side Deviation from.

When the corrections are made should, the control device sends a signal to the pneumatic drive for the drive wheel 3, whereby the latter is lifted off the glass surface. The lateral shift is by extending again the side slide rails 13 performed.

The correction of the rotation is also lifted Driving wheel performed when the robot 1 is located on an inclined glass surface. To do this the control device regulates the cable drums 9 invalid, whose associated measuring wheel 12 the lesser Amount or the smaller measurement result. For the control loop of the other rope drum 9 gives the Control device a high setpoint for the cable tension before, causing the drive 10 of this rope drum 9 is pressed until it turns of the entire robot 1 around the entry point of the stationary rope due to the "winding" of the other rope, both measured values of the measuring wheels 12 match. This corrects the twisting, and that Drive wheel can be lowered again. Of course the correction can also be done by regulating the Cable tension is carried out via both control loops will. When correcting the rotation of the robot on horizontal glass surfaces, e.g. B. at the beginning of Traversing movement, the drive wheel 3 remains in the lowered Condition, so that the support frame 2 around Drive wheel rotates as a fulcrum.

In addition, the movement is stabilized of the robot 1 in that the front, not driven wheels 4 perpendicular to the wheel axis by one small angle, in the exemplary embodiment z. B. 15 °, are rotatably mounted, the vertical axis, in Seen driving direction, arranged in front of the wheel axle is. A deflection caused by external disturbances the wheels from the direction of travel lead to a restoring moment, that the wheels 4 in the original Direction pulls.

The robot 1 is retracted when the robot is raised Drive wheel 3 only using the control loops the cable drums 9 and the measuring wheels 12 performed. When changing the direction of movement, the former front wheels 4 in the middle position with a locked pneumatic cylinder, not shown and therefore also have one for this direction of travel stabilizing effect.

In the described embodiment, the Correction of the twist via the cable tension carried out. If the space requirement is there is it is conceivable that the front wheels 4 have a steering have made a change in position can be.

The cleaning is carried out during the downward movement of the respective robot 1 on the glass surface by means of Roller brushes 6 and the side of the robot 1 by means of the plate brushes 8 performed. Between the glass suspensions the robot 1 cleans over this width with the roller brush 6. To the glass suspensions, the due to the external grid shell of the hall construction are required to be able to drive around the side arms 7 retracted and extended. The plate brushes 8 are pivoted over the swivel heads 17, which also in the hidden area behind the glass hangers can be cleaned. While the process of the robot will be the side Arms depending on the selected travel speed of the robot constantly moving in and out, to clean the entire side glass surface. However, the drive 10 of the cable drums 9 and / or the drive wheel 3 also controlled or be regulated that the robot 1 each time extending the arm 7 stops, advances and retracts stops again.

The brushes 6,8 are placed over the hose of the Hose reel 15 supplied water. The roller brush 6 faces the center of the roller brush bristles that get longer because of their own weight of the robot 1 the glass panes easily bend, and there can be an even contact pressure the bristles on the glass are guaranteed.

In the above embodiment, a cleaning robot described.

The explained device for moving a robot can also be used with other robots, such as an inspection robot or generally a processing robot, be used. The latter can, for example Work such as painting, sandblasting, grinding, etc. perform on facades. According to the type of use are then cable drum and hose drum with Corresponding cables and hoses are provided, whereby any fluid or also in the hoses Colors for painting or the like can flow.

Claims (16)

Drive device for moving a robot or vehicle on flat, inclined or curved surfaces or facades, in particular a glass structure,
marked by a support frame (2) provided with wheels (3, 4) which is part of the robot (1) or vehicle, at least one wheel being designed as a drive wheel (3) which can be lifted off, at least two cable drums (9) with drum drive (10) which are arranged at a distance from one another and which hold holding cables for holding the supporting frame, a device (13, 14, 12) for determining the lateral deviation and / or the rotation of the support frame (2) with respect to the linear forward movement, a device (13, 14) for correcting the lateral deviation and / or a device (9, 10, 11) for correcting the rotation, and a control and regulating device which controls the correction devices depending on the size of the lateral deviation and / or the rotation. Drive device according to claim 1, characterized characterized in that the lowerable drive wheel (3) a high coefficient of friction and the other wheels (4) have a low coefficient of friction exhibit. Device according to claim 1 or 2, characterized in that that the facility for ascertaining the lateral deviation and / or twist at least two spaced apart Has measuring units (12) with the control and regulating device are connected and capture the distance traveled, where the control and regulating device the difference between each of the distance measuring units (12) distance traveled determined and dependent of the difference the device for correction controls the twist. Device according to one of claims 1 to 3, characterized in that the device for Correction of the rotation of the drum drives (10) of the two rope drums (9) and associated with them Measuring units (11) for measuring the Cable tension, each together with the Control and regulating device a control loop form for the cable tension, includes, and that the control loops to correct the rotation Cable tension at least one cable drum (9) regulate such that the measuring units are the same Deliver values. Device according to one of claims 1 to 4, characterized in that the displacement measuring units are designed as measuring wheels. Device according to one of claims 1 to 5, characterized in that the device for Correction of the lateral deviation on the side the support frame (2) arranged extendable and retractable Has pressing elements (13), which external construction elements of the glass construction pull the trigger. Apparatus according to claim 6, characterized in that the push elements as pneumatic driven slide rails (13) formed are. Apparatus according to claim 6 or claim 7, characterized in that the pressing elements (13) with pneumatic piston-cylinder arrangements (14) are connected and that the facility to determine the lateral deviation on the Piston-cylinder assemblies (14) attached Has sensors for detecting the piston stroke. Robot with a drive device after one of claims 1 to 8. Robot according to claim 9 with a hose receiving hose reel (10) and at least one receiving an electrical line Cable drum (9) attached to the support frame (2) are. Robot according to claim 9 or claim 10, characterized characterized that the control and regulating device the drives of the hose reel (10), the cable drum (9) and / or the cable drums (11) regulates depending on the tractive force. Robot according to one of claims 9 to 11, characterized characterized in that hose reel (10), Cable drum (9) and / or rope drum (11) in such a way be regulated synchronously that the unwound Hose, the unwound electrical Line and / or the unwound rope taut placed on the glass structure without loops will. Robot according to one of claims 9 to 12, characterized characterized in that at least one vertical roller-shaped arranged in the direction of travel Cleaning element (3) on the support frame (2) is attached, the hose of the Hose reel (10) with a distribution system for supplying water to the area of the roller-shaped Cleaning element (3) is connected. Robot according to claim 13, characterized in that with external construction elements the glass surface construction on the support frame (2) cleaning elements that can be moved in and out laterally (7) are arranged by the Control and regulating device can be controlled. Use of a robot according to one of the claims 9 to 14 as a cleaning robot. Use of a robot according to one of the claims 9 to 12 as an inspection robot or as Machining robot.

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