DE102018127921A1 - Robot and method for determining a movement space using a robot - Google Patents

Abstract

The invention relates to a robot with an additional force measuring device (5) and a method for determining a movement space (S; B) by means of a robot.

Description

The present invention relates to a robot and a method for determining a movement space available for a robot with the aid of the robot.

Different tasks can be carried out by means of robots, in particular also lightweight robots. The spectrum ranges from simple pick & place activities to machining workpieces and lifting or carrying objects to interactions with the human body, such as in surgery.

Basically, it is also known that robots, be they position-controlled industrial robots or force and / or torque-controlled manipulators, have additional force sensors or force measuring devices that are designed and set up to influence them in a corresponding manner during teaching, position control or motion control to take.

From the DE 10 2015 004 484 A1 For example, a position-controlled robot system is known in which a force sensor is provided at the end of the robot arm, which is capable of detecting an input force applied by a user at this end with the aim of thereby changing the target position of the robot arm. Corresponding information relating to the weight or the mass of an object or tool held by the robot arm must be communicated to the control of the robot system in advance so that the position control can be carried out.

Furthermore, it is from the DE 10 2015 214 170 A1 It is known to provide a force measuring device for at least one link of a multi-link robot arm which interacts with structural components of the link or adjacent links and is designed to measure a force on the link in a predetermined direction with the aim of improving the positioning accuracy of the robot.

Due to the design and its kinematics, a maximum available movement space is assigned to a robot arm or manipulator, the limits of which result from the maximum extension or range of its links in three dimensions. The robot arm can carry out the intended activities within such a movement space. Stationary obstacles within such a movement space by e.g. objects, floors, walls, etc. must be communicated to the robot system, i.e. are usually programmed, which proves to be very complex and error-prone, particularly in the case of position-controlled robot systems.

In general, various force sensors are known from the prior art for robots which are able to measure forces acting on the robot from the outside. Furthermore, it is known to determine the contact forces which occur when a robot arm comes into contact, for example by means of its end effector, with an object or a surface, via the actually measurable drive forces and / or drive torques in connection with a dynamic model, such as e.g. E.g. the DE 10 2009 058 607 A1 teaches.

However, none of the known systems is designed to further use such forces to determine the properties of a movement space provided for a robot arm, in particular as part of a human-robot collaboration.

Based on this, it is an object of the invention to provide a force evaluation device that interacts with a robot arm for a new evaluation option. Another object is to provide a simple method for determining a movement space to be provided for a robot.

This object is achieved with a robot according to claim 1 and with a method for determining a movement space for a robot according to claim 10.

In a first aspect, the invention relates to a robot with a robot arm that has at least two axes or members that are movable relative to one another and is designed to interact with an object and that has at least one sensor device for force and / or torque detection, at least a force measuring device is provided which is designed to measure a contact force which results when the robot arm comes into contact with an obstacle in response to a force exerted by a user on the obstacle by means of the robot arm.

Any obstacle, preferably a stationary object, that is within reach of the robot arm, such as the floor, walls, containers, work stations, shelves, conveyors, etc., is to be understood as an obstacle. The object need not necessarily be rigid, but can also have a certain elasticity or Have compliance, such as human tissue.

Under robot in the sense of the invention, an industrial robot or also an articulated arm robot of lightweight construction can in particular at least six successive axes of rotation can be understood. According to the invention, however, it should preferably be a robot which can be operated in a force and / or torque-controlled manner instead of merely in a position-controlled manner and is designed for human-robot collaboration.

Such lightweight robots are generally designed via the sensor device to react appropriately to various external forces, the sensor device being formed by torque sensors arranged on the joints or implemented in the drives of the joints, as a result of which torques and / or forces in several Spatial directions can be recorded or measured. Alternatively or in addition, the external forces can also be estimated on the basis of the measured motor currents of the drives at the joints of the lightweight robot. For example, indirect force control by modeling the lightweight robot as mechanical resistance (impedance control) or direct force control can be used as control concepts.

The robot is also set up to provide a resilience of the robot arm suitable for safe human-robot collaboration, if necessary, which enables manual operation by the user, i.e. The robot arm can be moved manually by the user in free space and thereby guided in a targeted manner, whereby the joints can be adjusted accordingly, possibly in dependence on predetermined stiffness parameters, and thus the limbs of the robot arm.

The essence of the invention therefore lies in the fact that the at least one further force measuring device, which in principle can be configured in any way, is designed to measure a counterforce as a contact force, which simply results from the user using a robotic arm, for example his end effector Brings an obstacle into contact and exerts a force, however small.

The counterforce naturally depends on the amount of force exerted by the user; According to the invention, however, the first occurrence and detection of a contact force can be used in terms of control technology to recognize the position and location of an obstacle that is located in the maximum available movement space of the robot arm. Touching the object at a plurality of positions then also enables conclusions to be drawn about the two- or three-dimensional shape of the object, as will be explained in connection with the method according to the invention.

For this purpose, a robot controller is provided, which is designed to detect the contact force measured by means of the force measuring device and, moreover, the drive forces and / or drive torques of the drives in the joints between the axes or members of the drives exerted in the interaction with the object to distinguish the contact force measured by means of the force measuring device.

In particular, the robot controller is designed and set up to detect a one-, two- or three-dimensional course of a movement of the robot arm by guiding the robot arm by the user in relation to the object under contact. In other words, the user can selectively touch the object at a point with the robot arm, so that the controller recognizes that an obstacle exists with respect to a movement of the robot in the direction carried out. Such a one-dimensional contact would already be sufficient to recognize via a spatial and / or movement model correspondingly stored in the controller or via separate programming that there is a vertical wall perpendicular to the direction of movement of the robot arm and / or perpendicular to the base of the robot arm, in which this point lies.

It is also conceivable for the user to move the robot arm along the object, along a surface thereof, while maintaining contact, which does not necessarily have to be linear in order to detect the extension or extension of this surface of the object. Ultimately, such a movement of the robot arm while in contact with the object can also take place in all possible spatial directions, both in a continuous and discontinuous manner, which allows conclusions to be drawn about the outer three-dimensional shape of the object. The same applies to a room in which the walls, the floor and the ceiling form the tactile borders.

The contact force curve that arises in this way corresponds in principle to a scanning of the shape of an object or the extent or extension of a room. Since the coordinate system assigned to the robot arm is generally known in advance, the exact position, position and shape of the object can be determined relative to the position and mobility of the robot arm. This makes it possible to scan or "map" the entire movement space available to the robot arm with all its obstacles and barriers, which can be used for subsequent operations, for example when teaching the robot arm.

According to the invention, however, it is also conceivable that the robot arm is not stationary, but rather itself movable, for example one on one Robot base arranged on the mobile base, whereby two or three-dimensional structures that are larger than the nominally assigned to the robot arm due to its kinematics due to its kinematics can be traversed via the robot arm by appropriate guidance by the user.

The force measuring device can be implemented in any known version of a force sensor and in particular comprise several degrees of freedom. Force measurement in the sense of the invention also includes a torque measurement.

In one embodiment, the at least one force measuring device can be arranged on the outer housing structure of the robot arm, for example on the housing shells of a manipulator. If the robot arm has an end effector for interaction with the object, the force measuring device can be arranged on the end effector or preferably integrated into it. It is also conceivable that the robot arm, preferably at its distal end, has an input device for the user for controlling and / or programming the robot, wherein the force measuring device can be arranged on the input device or can preferably be integrated therein.

In a further embodiment according to the invention, the force measuring device can be arranged inside the housing structure of the robot arm. The arrangement of structural components inside the housing shells of a manipulator is conceivable. Preferably, the force measuring device can be integrated into the existing sensor device in the joints between axle members, whereby either additional sensors are used for this or the existing torque and / or force sensors in the joints allow an evaluation in terms of control technology via appropriate algorithms such that the robot controller can be integrated into the Position is shifted to make a clear distinction between the force exerted by the user or the exerted moment and the prevailing drive forces and / or drive moments, also in relation to an activated gravitational compensation.

• - Aktivieren eines gravitationskompensierten Zustands für den Roboterarm;
• - Führen des Roboterarms in Bezug auf ein Objekt durch einen Benutzer in einer ein-, zwei- oder dreidimensionalen Bewegungsfolge;
• - Messen einer Kontaktkraft oder eines Kontaktkraftverlaufs, die/der als Reaktion auf die durch den Benutzer bei Kontakt mit dem Objekt mittels des Roboterarms ausgeübten Kraft oder Kraftfolge resultiert; und
• - Erfassen einer ein-, zwei- oder dreidimensionalen Struktur in Bezug auf den Bewegungsraum, bei der eine Kontaktkraft oder ein Kontaktkraftverlauf gemessen wurde.

In a further aspect, the invention therefore relates to a method for determining a movement space for a robot with a robot arm which has at least two members which are movable relative to one another and is designed to interact with an object, and which has at least one sensor device for force and / or Has torque detection and at least one force measuring device, with the steps:

• - Activate a gravity-compensated state for the robot arm;
• - Guide the robot arm in relation to an object by a user in a one-, two- or three-dimensional movement sequence;
• - measuring a contact force or a contact force curve which results in response to the force or force sequence exerted by the user when the object comes into contact with the robot arm; and
• - Detection of a one-, two- or three-dimensional structure in relation to the movement space, in which a contact force or a contact force curve was measured.

The essence of the method according to the invention is therefore to “scan” an existing two- or three-dimensional structure by means of a robot arm, which acts as a scanning device, and by recognizing or measuring a contact force or a sequence of contact forces when scanning the objects or obstacles to generate a virtual spatial structure in the controller in the immediate vicinity of the robot, which can influence subsequent steps in teaching or operating the robot.

• - Definieren einer Zulässigkeit in Bezug auf eine zukünftige Bewegung des Roboterarms in Abhängigkeit der ein-, zwei- oder dreidimensionalen Struktur.

In a further development, the method can have the further step:

• - Define an admissibility with regard to a future movement of the robot arm depending on the one-, two- or three-dimensional structure.

In other words, by means of previously defined or still definable parameters in the control of the robot, releases or restrictions are assigned to the structures detected by the scanning process by means of the robot arm such that the robot arm knows the obstacles during subsequent operations or movements. As a result, the controller for subsequent operations already knows where, for example, virtual and / or actual walls are located within the movement space, which must not be traversed in the course of the movements subsequently to be carried out by the robot arm, or to which the robot arm may have a predefined safety distance has to be observed.

Therefore, the method according to the invention can be further configured such that threshold values are assigned to the recorded contact force or the recorded contact force curve, and operations, releases and / or restrictions are assigned to the threshold values.

It is conceivable that the object with which the robot arm comes into contact when guided by a user is not rigid, but rather yields something when a force is applied by the user, such as, for example, in the case of a human tissue or muscles. The user can therefore "scan" a body surface with the targeted application of a force via the robot arm, the system recognizing the limits of the body on the one hand by detecting the contact forces, possibly taking into account predetermined tolerance ranges, and on the other hand the applied force or force sequence by the user saves. If the position of the body does not change afterwards, the robot arm can perform independent movements by applying the stored force or sequence of forces, which can be used for therapeutic and medical measures. A robot arm configured in this way can, for. For example, then carry out independent massage applications.

However, this principle according to the invention can in principle be carried out for all methods and operations in which a robot arm, possibly together with an end effector, on the one hand has to know its spatial restrictions on the one hand and on the other hand the applicable force level. Application examples for this would be e.g. For example, simple assembly and joining work in which one of the components is stationary and rigid.

In that the robot, in particular in addition to torque and / or force measuring sensors in the joints of the robot arm, has at least one, in particular separate, force measuring device according to the invention, which can be attached anywhere within or outside the kinematic and housing structure of the robot arm a distinction is made between forces acting on the robot arm, whether these are applied artificially by a user or in the operation of an object or an environment, for example in the event of contact.

According to the configuration of the robot according to the invention with an autonomous, i.e. separate from the separate sensor device already implemented in the robot, which can be made up of the entirety of all the rotary and force sensors arranged in the joints between the links, it becomes possible for the first time to convert the external forces acting on the robot arm into a user-induced, i.e. to disassemble human power and an object-dependent contact power.

As far as the determination of a movement space available for future movements of the robot arm is concerned, two approaches can be followed in terms of control technology with the robot according to the invention.

In a first approach, the entire movement space that can be covered by the robot arm is defined as a restricted space, i.e. the space is initially classified as unsafe, in which the robot arm is not allowed to move per se, and then those areas of the movement space in which the robot arm can actually perform movements when guided by the user, until the robot arm actually has an object comes into contact, in its entirety then recorded and defined as a movement space available for these future movements of the robot arm. In other words, the spatial sections or areas available for movements of the robot arm are “activated”.

According to another alternative approach, the entire movement space that can be covered by the robot arm is defined as a movement space that is fundamentally available for future movements of the robot arm, and the areas of the movement space in which the robot arm then actually comes into contact with an object are marked as a movement limit . The range of motion is accordingly restricted by scanning several movement limits.

During the scanning of the objects, it can be provided that information relating to a contact of the robot arm with an object is transmitted to the user, preferably audiovisually or haptically via an input device, contact force ranges which, for example, indicating whether the force applied by the user is too high or too low when in contact with the object.

It becomes clear that by providing at least one further force measuring device and a corresponding evaluation control, the application spectrum of a human-robot collaboration can be expanded, in particular for such robots. A user can use the robot arm itself as a means for “scanning” a work or movement space available for it, without the need for complex programming.

• 1 schematisch einen Roboter gemäß der Erfindung;
• 2a bis 2c eine Bewegungsfolge beim Führen eines Roboterarms zur Bestimmung eines Bewegungsraums für diesen in einer ersten Ausführungsform des erfindungsgemäßen Verfahrens; und
• 3a bis 3c eine Bewegungsfolge beim Führen eines Roboterarms zur Bestimmung eines Bewegungsraums für diesen in einer zweiten Ausführungsform des erfindungsgemäßen Verfahrens.

Further advantages and features of the present invention result from the description of the exemplary embodiments illustrated with reference to the accompanying drawings. Show it:

• 1 schematically a robot according to the invention;
• 2a to 2c a sequence of movements when guiding a robotic arm for determination a movement space for this in a first embodiment of the method according to the invention; and
• 3a to 3c a sequence of movements when guiding a robot arm to determine a movement space for this in a second embodiment of the method according to the invention.

In the 1 to 3c the principle of the invention is shown schematically.

A 7-axis articulated arm robot has a robot arm 1 consisting of several links 2nd and an input device at its distal end 3rd on the opposite a gripping mechanism 4th with which the robot is provided 1 can grab an object.

The robot 1 is with a controller 6 provided, which cooperates with a sensor device (not shown), which consists of the total of all force and / or torque sensors in the drives in the joints between the individual links 2nd composed and the a compliance control of the robot arm 1 enables.

According to the invention, the robot arm has 1 at least one other force measuring device 5 any configuration on that at any point on the robot arm 1 can be attached internally or externally (shown here by way of example in connection with the input device 3rd ).

The robotic arm 1 In its gravity-compensated mode, it can be freely moved by a user (hand).

The 2a to 2c show a first sequence of movements in a first embodiment of the method according to the invention, wherein only the front limbs 2nd and the input device 3rd with the gripper 4th are shown.

Starting from a basic position of the robot, how the 2a shows the total available movement space into a movement space S which is permissible for a movement, ie safe, and a blocked, ie insecure movement space B (dotted) in which there is an object 7 is located, which is to be regarded as an obstacle in the exemplary embodiment shown.

Now the user moves the manipulator to the right on the object 7 until the gripper 4th with the object 7 comes into contact, the controller of the robot system recognizes the occurrence of a contact force F _K that the object is in the appropriate place 7 and there is an obstacle. The measure of contact force F _K In the simplest case, since the robot is operated in its gravity-compensated mode, it corresponds to the operating force manually exerted by the user in the course of the movement F _H .

During the movement, the safe area S changes, so to speak dynamically, in relation to the unsafe area B .

In the 2c is shown as an example of how the user touches the distal end of the robot arm 1 first vertically along the object 7 moved upwards and then again horizontally to the right over the surface of the object 7 has moved, wherein the controller has recorded the contact forces or contact force profiles that occur. The vertical contact force F _K corresponds to the manual actuation force F _H which, however, can be very small, but due to the sensitivity of the force measuring device 5 can be recognized.

In this way, both the position and the three-dimensional shape of the object 7 can be localized or stored, with the available movement space S spreading further, while the area considered unsafe B further reduced.

The sequence of figures 3a to 3c shows an example of a second embodiment of the method according to the invention.

In this case, a maximum of the movement space S available to the robot is assumed, which is initially classified as accessible or safe. In this there is still an object representing an obstacle 7 .

In the 3a is shown the beginning of the "mapping" at which a user manipulates 1 opposite a floor 8th touches down and thereby a mostly vertical manual force F _H exercises. Since the robot is moved in a gravity-compensated state, the force measuring device recognizes it 5 in response to this, an appropriately dimensioned contact force F _K .

Of course, while driving along the floor (or surfaces of any object) in a linear, two-dimensional direction, the user practices like that 3b shows, inclined or horizontal force components. This can also be done by the force measuring device 5 appropriately recorded, since this is preferably designed in relation to forces in all three spatial directions and in relation to moments in all three directions of rotation, and are taken into account by an appropriately designed evaluation logic.

By guiding the robot arm horizontally 1 over the area of the floor 8th its extension is recorded until the end effector 4th with the object 7 comes into contact, thus again the position of the object 7 can be determined in space.

As with the 2c the user guides the distal end of the robot arm 1 then continue on the object 7 vertically up and then horizontally to the right to get the three-dimensional shape of the object 7 to scan ( 3c ).

The difference from the first embodiment of the method according to the invention lies in the fact that the movement space S initially classified as safe gradually over an expansion of the range limits B (dotted) is limited when scanning, always the contact force F _K within a contact force curve of the manual actuation force F _H within an operating force curve in all spatial directions.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102015004484 A1 [0004]
• DE 102015214170 A1 [0005]
• DE 102009058607 A1 [0007]

Claims (15)

Robot with a robot arm (1) which has at least two members (2) which are movable relative to one another and is designed to interact with an object and which has at least one sensor device for force and / or torque detection, characterized by at least one force measuring device (5 ) which is designed to measure a contact force (F _K ) which, when the robot arm (1) comes into contact with an object (7; 8) as a reaction of a user to the object (7; 8) by means of the robot arm (1 ) exerted force (F _H ) results. Robot after Claim 1 , in which a controller (6) is provided which is designed to detect the contact force (F _K ) measured by means of the force measuring device (5). Robot after Claim 2 , in which the controller (6) is further configured to carry out a one-, two- or three-dimensional course of a movement of the robot arm (1) by guiding the robot arm (1) by the user in relation to the object (7; 8) Contact. Robot according to one of the Claims 1 to 3rd , in which the force measuring device is arranged on the outer housing structure of the robot arm. Robot according to one of the Claims 1 to 3rd , in which the robot arm (1) has an end effector (4) for interaction with the object (7; 8), and in which the force measuring device (5) is arranged on the end effector (4) or is integrated therein. Robot according to one of the Claims 1 to 3rd , in which the robot arm (1) has an input device (3) for the user to control and / or program the robot, and in which the force measuring device (5) is arranged on the input device (3) or is integrated therein. Robot according to one of the Claims 1 to 3rd , in which the force measuring device (5) is arranged inside the housing structure of the robot arm (1). Robot after Claim 7 , in which the force measuring device (5) is integrated in the sensor device. Robot according to one of the Claims 1 to 8th , in which the force measuring device (5) is designed to measure a force and / or a moment in relation to several axes and thus degrees of freedom. Method for determining a movement space (S) for a robot with a robot arm (1) which has at least two members (2) which are movable relative to one another and is designed to interact with an object, and which has at least one sensor device for force and / or Has torque detection and at least one force measuring device (5), with the steps: - activating a gravitationally compensated state for the robot arm (1); - Guide the robot arm (1) in relation to an object (7; 8) by a user in a one-, two- or three-dimensional movement sequence; - Measuring a contact force (F _K ) or a contact force curve which results in response to the force (F _H ) or force sequence exerted by the user when in contact with the object (7; 8) by means of the robot arm (1); and - Detection of a one-, two- or three-dimensional structure (S; B), in which a contact force (F _K ) or a contact force curve is measured. Procedure according to Claim 10 , comprising the further step: - defining an admissibility with regard to a future movement of the robot arm (1) depending on the one-, two- or three-dimensional structure (S; B). Procedure according to Claim 10 or 11 , in which threshold values are assigned to the contact force (F _K ) or the contact force curve, and in which operations, releases and / or restrictions are assigned to the threshold values. Procedure according to Claim 10 , 11 or 12th , in which the entire movement space which can be covered by the robot arm (1) is defined as a restricted space (B), and the areas (S) of the movement space in which the robot arm can carry out movements until the robot arm (1) has an object ( 7; 8) comes into contact when a movement space (S) available for future movements of the robot arm (1) is detected. Procedure according to Claim 10 , 11 or 12th , in which the entire movement space that can be covered by the robot arm (1) is defined as a movement space (S) available for future movements of the robot arm (1), and the areas (B) of the movement space in which the robot arm (1) is connected with a Object (7; 8) comes into contact as a movement limit (B) is detected. Procedure according to one of the Claims 10 to 14 , in which information relating to contact of the robot arm (1) with an object (7; 8) is transmitted to the user, preferably via an input device (3).

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