DE102023128612A1 - Robot system for relieving robot equipment using a rope robot system - Google Patents

Abstract

In a robot system with a space robot device with at least one movable robot element and at least one actuator for moving the at least one robot element, a support device for supporting the robot device when using the space robot device on earth, with a force application element that is connected to the robot element at least at one point and applies at least one force to the robot element that at least partially compensates for the gravitational force acting on the robot element, it is provided that the support device is a cable robot system that has at least two cable elements that are connected to the force application element, wherein each cable element is connected to at least one motor that can move the respective cable element so that the direction and amount of the force that can be applied to the robot element via the force application element can be adjusted.

Description

The invention relates to a robot system according to claim 1.

Robot devices are known that are manufactured in particular for use in space. Space robot devices are designed for conditions in space. Since no gravitational forces act on the space robot device in space, a large part of the forces required due to gravity can be neglected when designing the space robot device. This means that the joints and/or actuators can be made smaller, lighter and more energy efficient.

However, the robot devices should also be operated on earth, for example to test or improve the robot devices. For this, the robot device must be supported, otherwise the joints will be placed under too much strain or the actuators will not be able to move the robot device. For this purpose, support devices exist which support the robot devices on earth. This is done, for example, with helium balloons or via planar, mobile, active or passive support tables. Helium balloons, which can have a diameter of several meters depending on the load, help to relieve the load through their buoyancy. These are mounted on the robot device at the designated points and pull the robot device upwards at this point with a constant force. Planar, mobile support tables can, for example, glide over smooth floors and support the joints of the robot device. With this method, however, the robot devices can only perform planar movements.

The object of the present invention is therefore to provide a robot system that can support the robot device in a simple manner.

The features of claim 1 serve to solve this problem.

The invention advantageously provides that a robot system is created with a robot device, preferably a space robot device, with at least one movable robot element and at least one actuator for moving the at least one robot element. Furthermore, the robot system has a support device for supporting the robot device when the robot device is used on earth, with a force application element which is connected to the robot element at least at one point and applies at least one force to the robot element which at least partially compensates for the gravitational force acting on the robot element.

It is advantageously provided that the support device is a cable robot system having at least two cable elements connected to the force application element, wherein each cable element is connected to at least one motor that can move the respective cable element so that the direction and amount of force that can be applied to the robot element via the force application element can be adjusted.

Due to the support device, which is formed from a cable robot system having at least two cable elements, each connected to at least one motor, the amount and direction of the force with which the robot element is supported can be arbitrarily adjusted.

The rope robot system can have at least three rope elements. More than at least three rope elements can also be provided. The number of rope elements determines the number of degrees of freedom in which the direction of the force can be adjusted and the design of the robot device. If the robot device has several movable robot elements, for example, several force attachment elements can also be provided on the robot elements, each of which has several rope elements connected to it. Even if only one force attachment element is provided, more than three rope elements can be provided.

A force application element in the sense of the present invention is merely an element which is connected to the at least one robot element, to which the cable elements can be connected directly or indirectly and on which the forces which are applied to the cable elements with the aid of the motors can act on the robot element.

A motor can be arranged on each of the rope elements, which can move the respective rope element.

The rope elements can be connected to a force application rope which is connected to the force application element.

In this way, the cable elements can be indirectly connected to the force application element. The force exerted on the force application element and thus on the robot element is transmitted via the force application cable to the force application element. The rope elements are preferably connected to the force application rope at the same point. In this way, the direction and magnitudes of the forces exerted via the rope elements determine the total magnitude and direction of the force acting in the force application rope.

The force application element can be rotated about two axes that are essentially orthogonal to one another. The force application element aligns itself depending on the direction in which the force is applied to the force application element via the cable elements.

At least one first sensor device can be provided which detects the respective angle of the first and/or second axis to the force application cable.

At least one second sensor device can be provided which detects the force and/or movement acting on the force application element via the force application cable. The amount of the force can thus be detected.

The first and second sensor devices can also be designed as a common sensor device which can detect both the angle of the first and second axes to the force application cable and the amount of force in the force application cable.

Furthermore, at least one third sensor device can be arranged on each rope element, which detects the force and/or movement of the respective rope element.

In the event that the cable elements are attached directly to the force application element, it could also be recorded in which direction the force acts on the cable elements in relation to the first and/or second axis of the force application element. For example, a further sensor device can be provided for this purpose or the third sensor device can be designed to also record these angles. Alternatively, the direction of the force in the cable elements could also be calculated. It can be calculated by knowing how the cables run and where on the robot element the force application element is located.

The rope elements can be redirected via deflection elements.

The deflection elements can be arranged above the space robot device.

The robotic device may be a robotic arm, in particular a space robotic arm.

The robot device can be attached to a fixed object in the room.

The motors that move the rope elements can also be attached to a fixed object in the room.

A first control device can be provided which is designed to control the motors which move the cable elements and thus to control the amount and/or direction of the force which can be applied to the robot element via the force application element.

The control device can control the force in such a way that the motors are controlled in such a way that the gravitational force acting on the robot element is at least partially compensated. This means that at least the robot device is at least partially relieved. It can also be provided that the control device is designed in such a way that the gravitational force acting on the robot element is completely compensated. The amount and direction of the force acting on the robot element and which at least partially compensates for the gravitational force acting on the robot element is determined depending on the design of the robot device. The geometries and design as well as masses of the robot elements of the robot device are known. The amount of the force is designed in such a way that at least the actuator can move the robot element. The amount of the force can be determined by calculations or tests with robot devices.

Data from the control device of the robot device can be used as input for controlling the first control device.

The robot device may be attached to a movable base, wherein a base support device is provided, wherein the base support device is a second cable robot system having at least two cable elements connected to the base, wherein each cable element is connected to at least one motor which can move the respective cable element so that the direction and amount of force which can be applied to the base is adjustable.

The base support device may comprise at least 8 ropes connected to the base, each rope element being connected to at least one motor that can move the respective rope element so that the direction and The amount of force that can be applied to the base is adjustable.

The base can have 8 corners and the rope elements can be connected to the base at each of the corners of the base.

At least one base control device may be provided which is designed to control the motors which move the cable elements of the base support device and thus to control the amount and/or direction of the force which can be applied to the base.

According to the present invention, there may further be provided a multi-robot system comprising at least two robot systems according to any one of claims 1-18, wherein the at least two robot systems are connected to at least one common movable base, wherein the common base is a movable base according to any one of claims 15 to 18.

• - zumindest einer Robotereinrichtung mit zumindest einem beweglichen Roboterelement und zumindest einem Aktuator zum Bewegen des zumindest einem Roboterelements,
• - zumindest einer Unterstützungseinrichtung zum Unterstützen der Robotereinrichtung, mit zumindest einem Kraftaufbringungselement, das an zumindest einer Stelle mit dem Roboterelement verbunden ist und zumindest eine Kraft auf das Roboterelement aufbringt, welche die auf das Roboterelement wirkende Gravitationskraft zumindest teilweise kompensiert, wobei
• - die Unterstützungseinrichtung ein Seilrobotersystem ist, das zumindest zwei Seilelemente aufweist, die mit dem Kraftaufbringungselement verbunden sind, wobei jedes Seilelement mit zumindest einem Motor verbunden ist, der das jeweilige Seilelement bewegen kann, so dass die Richtung und Betrag der Kraft, die über das Kraftaufbringungselement auf das Roboterelement aufbringbar ist, einstellbar ist,

wobei die mindestens zwei Robotersysteme mit mindestens einer gemeinsamen bewegbaren Basis verbunden sind, wobei die gemeinsame Basis eine Basis ist, bei der eine Basis-Unterstützungseinrichtung vorgesehen ist wobei die Basis-Unterstützungseinrichtung ein zweites Seilrobotersystem ist, das zumindest zwei Seilelemente aufweist, die mit der Basis verbunden sind, wobei jedes Seilelement mit zumindest einem Motor verbunden ist, der das jeweilige Seilelement bewegen kann, so dass die Richtung und Betrag der Kraft, die auf die Basis aufbringbar ist, einstellbar ist.A multi-robot system according to the present invention may comprise at least two robot systems, wherein the at least two robot systems each have at least the following features

• - at least one robot device with at least one movable robot element and at least one actuator for moving the at least one robot element,
• - at least one support device for supporting the robot device, with at least one force application element which is connected to the robot element at least at one point and applies at least one force to the robot element which at least partially compensates for the gravitational force acting on the robot element, wherein
• - the support device is a cable robot system having at least two cable elements connected to the force application element, each cable element being connected to at least one motor that can move the respective cable element so that the direction and amount of force that can be applied to the robot element via the force application element can be adjusted,

wherein the at least two robot systems are connected to at least one common movable base, wherein the common base is a base in which a base support device is provided, wherein the base support device is a second cable robot system having at least two cable elements connected to the base, wherein each cable element is connected to at least one motor that can move the respective cable element so that the direction and amount of force that can be applied to the base is adjustable.

In a multi-robot system, there is therefore at least one support device for each robot device and at least one base support device for the common base.

The multi-robot system may comprise an overall control device configured to coordinate the first control devices of the support devices, the control devices of the robot systems and the basic control device.

In the following, an embodiment of the present invention is explained in more detail with reference to the drawings.

• 1 das Robotersystem,
• 2 ein Ausschnitt aus 1, der das Kraftaufbringungselement zeigt,
• 3 ein Multi-Robotersystem,
• 4 eine Gesamtsteuereinrichtung eines Multi-Robotersystem.

They show schematically

• 1 the robot system,
• 2 an excerpt from 1 , which shows the force application element,
• 3 a multi-robot system,
• 4 an overall control device of a multi-robot system.

In 1 a robot system 1 is shown. The robot system 1 has a robot device 2. The robot device 2 is preferably a space robot device. The robot device 2 has at least one movable robot element 4. In the present embodiment, at least three movable robot elements 6, 4 and 8 are provided. The at least one movable robot element 4 can be moved with at least one actuator 13. In the present embodiment, an actuator 15 is provided which can move the robot element 6. Furthermore, an actuator 11 is provided which can move the robot element 8. Furthermore, joints 14, 12 and 10 are provided around which the respective robot elements 6, 4 and 8 can rotate.

In the present embodiment, the robot device 2 is preferably a robot arm. Furthermore, the robot device is preferably mounted on a spatially fixed object at the location 16. Alternatively, the robot device can also be attached to a movable base.

The robot system 1 has a support device 3 which can support the robot device 2 when using the robot device in the gravitational field of the earth. The support device 3 has at least one Force application element 30 which is connected to the at least one robot element 4 at least at one point and to which at least one force can be applied to the at least one robot element 4, which force at least partially compensates for the gravitational force or gravity acting on the one robot element 4. This means that at least a portion of the force exerted on the robot element 4 via the force application element 30 acts against the gravitational force or gravity. By applying the force and partially compensating for the gravitational force or gravity, the robot device 2 is supported. The robot device 2 should be supported at least enough that the actuators 12 and 15 can move the robot elements 6, 4 and 8.

The illustrated support device 3 is a cable robot system that has at least two cable elements, in the present embodiment four cable elements 18, 20, 22, 24, which are connected to the force application element 30. In the illustrated embodiment, four cable elements 18, 20, 22 and 24 are provided and each cable element 18, 20, 22, 24 is connected to at least one motor 38, 36, 34, 32 that can move the respective cable element 18, 20, 22, 24. By operating the respective motor 38, 36, 34, 32, for example, the respective cable element 18, 20, 22, 24 can be rolled up and the respective cable element 18, 20, 22, 24 can thus be moved. At point 48, the four cable elements 18, 20, 22, 24 are connected to a force application cable 26. The force application cable 26 is connected to a force application element 30. Thus, in the illustrated embodiment, the cable elements 18, 20, 22, 24 are indirectly connected to the force application element 30.

Depending on how strongly the individual cable elements 18, 20, 22, 24 are rolled up, a force is exerted on the force application element 30 and thus on the robot element 4. By adjusting the motors and moving the cable elements 18, 20, 22, 24, the amount and direction of the force acting on the force application element 30 and thus on at least one robot element 4 can be adjusted. The cable elements 18, 20, 22, 24 are deflected via deflection elements 41, 43, 45 and 47. The deflection elements 41, 43, 45 and 47 are preferably arranged above the robot element 4.

At least one second sensor device 28 can be provided which measures the amount of force acting in the force application cable and thus corresponds to the amount of force acting on the robot element 4. Additionally or alternatively, sensor devices 42, 44, 40 and 46 can also be provided which measure the forces in the cable elements 18, 20, 22 and 24. The total force which can be measured with the second sensor device 28 can also alternatively be calculated with the aid of the forces measured by the third sensor devices 42, 44, 40 and 46.

In an alternative embodiment, the force application cable 26 can be omitted and the cable elements 18, 20, 22 and 24 can be connected directly to the force application element 30.

The invention is also not limited to four cable elements 18, 20, 22 and 24, but can also be implemented with more or fewer cable elements. However, at least two cable elements should be provided so that the direction and amount of force can be changed.

In 2 is an excerpt from the 1 , in which the force application element 30 is shown in more detail. The force application element 30 is rotatable on two axes 50, 52 that are essentially orthogonal to one another. Depending on where the robot element 4 is located and depending on how the motors 38, 36, 34, 32 were actuated and thus the cable elements 18, 20, 22, 24 were moved, the force application cable 26 has a different position to the robot element 4. The force application element 30 aligns itself depending on this.

The force application element 30 is thus moved passively, depending on the position of the cable elements and the robot element 4. The first axis 50 of the force application element 30 is preferably arranged coaxially to the axis of the robot element 4. At least one first sensor device 100, 102 can be provided, which detects the respective angle of the first and second axis 50, 52 to the force application cable 26. In the present case, two first sensor devices 100, 102 are provided, which detect the respective angles. This makes it possible to determine the position of the force application cable 26 in relation to the robot element 4 in order to determine in which direction the applied force acts on the robot element 4.

3 shows a multi-robot system 100 according to the invention. The multi-robot system 100 has at least two robot systems 1, 1'.

The at least two robot systems 1, 1' are each similar to the robot system 1 as in 1 . In 3 Two robot systems 1, 1' are shown. The respective robot systems 1, 1' each have a robot device 2, 2'. The robot devices 2, 2' each have at least one movable robot element 4, 4'.

For example, just like with robot system 1, 1 For example, at least three movable robot elements 6, 4 and 8 can be provided. However, these are in 3 not shown in detail. Also, just like with 1 the at least one movable robot element 4,4' can be moved with at least one actuator 13. The actuator is in 3 not shown in detail. Just like with 1 An actuator 15 can also be provided which can move the robot element 6, an actuator 13 can be provided which can move the robot element 4, 4' and an actuator 11 can be provided which can move the robot element 8. These actuators are also in 3 not shown in detail. Furthermore, just as in 1 , joints 14, 12 and 10 are provided around which the respective robot elements 6, 4 and 8 can rotate. These joints are also in 3 not shown in detail.

In the present embodiment, the robot devices 2 are preferably robot arms. Furthermore, the robot devices can also be attached to a common movable base 200. How the movable base can be moved is described in more detail below.

The robot systems 1, 1' each have a support device 3, 3' that can support the robot device 2 when the robot device is used in the gravitational field of the earth. The support devices 3, 3' each have at least one force application element 30, 30' that is connected at least one point to the respective at least one robot element 4, 4' and to which at least one force can be applied to the respective at least one robot element 4, 4' that at least partially compensates for the gravitational force or gravity acting on the one robot element 4. This means that at least a portion of the force exerted on the respective robot element 4, 4' via the respective force application element 30, 30' acts against the gravitational force or gravity. The respective robot device 2, 2' is supported by applying the force and partially compensating for the gravitational force or gravity. The respective robot devices 2,2' should be supported at least to such an extent that at least one of the respective robot elements 4, 4' can be moved.

The illustrated support devices 3, 3' are each a first cable robot system, which each has at least two cable elements, in the present embodiment four cable elements 18, 20, 22, 24 or 18', 20', 22', 24', which are connected to the respective force application element 30, 30'.

In the illustrated embodiment, four cable elements 18, 20, 22 and 24 or 18', 20', 22', 24' are provided and each cable element 18, 20, 22, 24 or 18', 20', 22', 24' is connected to at least one motor 38, 36, 34, 32 or 38', 36', 34', 32', which can move the respective cable element 18, 20, 22, 24 or 18', 20', 22', 24'. By operating the respective motor 38, 36, 34, 32 or 38', 36', 34', 32', for example, the respective cable element 18, 20, 22, 24 can be rolled up and thus the respective cable element 18, 20, 22, 24 or 18', 20', 22', 24' can be moved.

Like in 1 could also be a force application cable 26, as in 1 be provided, via which the cable elements 18, 20, 22, 24 or 18', 20', 22', 24' can also be indirectly connected to a force application element 30. However, the cable elements 18, 20, 22, 24 or 18', 20', 22', 24' can also be connected directly to the force application element 30 with the respective robot element 4, 4', as shown.

Depending on how strongly the individual cable elements 18, 20, 22, 24 or 18', 20', 22', 24' are rolled up by the respective motor 38, 36, 34, 32 or 38', 36', 34', 32', a force is exerted on the respective force application element 30, 30' and thus on the robot element 4, 4'. By adjusting the motors 38, 36, 34, 32 or 38', 36', 34', 32' and moving the cable elements 18, 20, 22, 24 or 18', 20', 22', 24', the amount and direction of the force acting on the respective force application element 30, 30' and thus on at least one respective robot element 4, 4' can be adjusted. The cable elements 18, 20, 22, 24 or 18', 20', 22', 24 'are deflected via respective deflection elements 41, 43, 45 and 47 or 41', 43', 45', 47'. The respective deflection elements 41, 43, 45 and 47 or 41', 43', 45', 47' are preferably arranged above the respective robot element 4, 4'.

Like in 1 As described, a second sensor device 28 can also be provided, which measures the amount of force acting in the force application cable and thus corresponds to the amount of force acting on the robot element 4. Additionally or alternatively, just as in 1 described sensor devices 42, 44, 40 and 46 are provided, which measure the forces in the cable elements 18, 20, 22 and 24 or 18', 20', 22', 24'. The total force that can be measured with the second sensor device 28 can also alternatively be calculated with the help of third sensor devices 42, 44, 40 and 46 measured forces. The sensor devices 28, 42, 44, 40 and 46 are in 3 not shown. These can be designed in the same way as in 1 was described

The invention is also not limited to four cable elements 18, 20, 22 and 24 or 18', 20', 22', 24' per support device 3, 3', but can also be implemented with more or fewer cable elements. However, at least two cable elements should be provided so that the direction and amount of force can be changed.

The respective force application element 30, 30' can be designed as in 2 presented and with regard to 2 was described in more detail.

The at least two robot systems 1,1' are in 3 connected to at least one common movable base 200, wherein the common base 200 is a base in which a base support device 300 is provided, wherein the base support device 300 is a second cable robot system having at least two, preferably eight cable elements 118, 120, 122, 124, 128, 130, 132, 134, which are connected to the base, wherein each cable element 118, 120, 122, 124, 128, 130, 132, 134 is connected to at least one motor 102, 104, 106, 108, 110, 112, 114, 116, which drives the respective cable element 118, 120, 122, 124, 128, 130, 132, 134 can move so that the direction and amount of force that can be applied to the base can be adjusted.

The Base 200 can therefore be moved freely in the room.

The base support device 300 can, as shown in the present embodiment, have at least 8 cable elements that are connected to the base 200, wherein each cable element 118, 120, 122, 124, 128, 130, 132, 134 is connected to at least one motor 102, 104, 106, 108, 110, 112, 114, 116, which can move the respective cable element 118, 120, 122, 124, 128, 130, 132, 134, so that the direction and amount of force that can be applied to the base 200 can be adjusted as desired.

The base 200 can, as shown in the illustrated embodiment, have 8 corners and the cable elements 118, 120, 122, 124, 128, 130, 132, 134 can each be connected to the base 200 at the corners of the base 200.

At least one base control device 600 of the base support device 300 can be provided, which is designed to control the motors 102, 104, 106, 108, 110, 112, 114, 116, which move the cable elements 118, 120, 122, 124, 128, 130, 132, 134 of the base support device 300 and thus to control the amount and/or direction of the force that can be applied to the base.

The multi-robot system 100 can, as in 4 shown, have an overall control device 500 which is designed to coordinate the first control devices 610, 620 of the support devices 3. 3', the control devices 710, 720 of the robot systems and the base control device 600 of the base support device 300 as well as the control device 700 of the base.

The first control devices 610, 620 of the support devices 3. 3' control the support devices 3. 3'. The control devices 710, 720 of the robot systems control the actuators of the robot systems 1, 1' to move the robot elements. The control device 700 of the base controls the base.

Data from the control devices 710, 720 of the robot systems and/or the control device 700 of the base 200 can each be used as input variables for controlling the first control devices 610, 620, the support devices 3. 3' and/or the base control device 600 of the base support device 300.

Claims (20)

Robot system, with a robot device, in particular a space robot device, with at least one movable robot element and at least one actuator for moving the at least one robot element, a support device for supporting the robot device when using the space robot device on earth, with at least one force application element which is connected to the robot element at least at one point and applies at least one force to the robot element which at least partially compensates for the gravitational force acting on the robot element, characterized in that the support device is a cable robot system which has at least two cable elements which are connected to the force application element, wherein each cable element is connected to at least one motor which can move the respective cable element so that the direction and amount of the force which can be applied to the robot element via the force application element can be adjusted. Robot system according to Claim 1 , characterized in that the rope robot system has at least three rope elements. Robot system according to Claim 1 or 2 , characterized in that on each rope ment a motor is arranged which can move the respective rope element. Robot system according to one of the Claims 1 until 3 , characterized in that the rope elements are connected to a force application rope which is connected to the force application element. Robot system according to one of the Claims 1 until 4 , characterized in that the force application element is rotatable about two axes which are substantially orthogonal to one another. Robot system according to one of the Claims 1 until 5 , characterized in that at least one first sensor device is provided which detects the respective angle of the first and/or second axis to the force application cable. Robot system according to Claim 6 , characterized in that at least one second sensor device is provided which detects the force and/or movement of the force application cable. Robot system according to one of the Claims 1 until 7 , characterized in that at least one third sensor device is arranged on each rope element, which detects the force and/or movement of the respective rope element. Robot system according to one of the Claims 1 until 8th , characterized in that the rope elements are deflected via deflection elements, wherein the deflection elements are preferably arranged above the robot device. Robot system according to one of the Claims 1 until 9 , characterized in that the robot device, in particular space robot device, is a space robot arm. Robot system according to one of the Claims 1 until 10 , characterized in that a first control device is provided which is designed to control the motors which move the cable elements and thus to control the amount and/or the direction of the force which can be applied to the robot element via the force application element. Robot system according to Claim 11 , characterized in that the force can be controlled by means of the first control device such that the motors are controlled such that the gravitational force acting on the robot element is at least partially, preferably substantially completely, compensated. Robot system according to Claim 12 , characterized in that data from a control device of the robot device are used as input variables for controlling the first control device. Robot system according to one of the Claims 1 until 13 , characterized in that the robot device, in particular space robot device, is attached to an object fixed in space. Robot system according to one of the Claims 1 until 14 , characterized in that the robot device is attached to a movable base, wherein a base support device is provided, wherein the base support device is a second cable robot system having at least two cable elements connected to the base, wherein each cable element is connected to at least one motor which can move the respective cable element so that the direction and amount of force which can be applied to the base is adjustable. Robot system according to Claim 15 , characterized in that the base support device comprises at least 8 cables connected to the base, each cable element being connected to at least one motor which can move the respective cable element so that the direction and amount of force which can be applied to the base is adjustable. Robot system according to one of the Claim 16 , characterized in that the base has 8 corners and the rope elements are each connected to the base at the corners of the base. Robot system according to one of the Claim 15 until 17 , characterized in that at least one base control device is provided which is designed to control the motors which move the cable elements of the base support device and thus to control the amount and/or direction of the force which can be applied to the base. Multi-robot system with at least two robot systems according to one of the Claims 1 until 18 , wherein the at least two robot systems are connected to at least one common movable base, wherein the common base is a movable base according to one of the Claims 15 until 18 is. Multi-robot system according to Claim 19 , characterized in that an overall control device is provided which is designed to control the first control devices of the support devices, the control devices of the robot systems and the base control device (600) of the base support device (300) as well as the control device (700) of the base.

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