METHOD FOR DETERMINING A MINIMUM DISTANCE BETWEEN AN OBJECT AND AN APPARATUS SURFACE, SAFETY DEVICE FOR A HANDLING APPARATUS HAVING AN APPARATUS SURFACE, AND HANDLING APPARATUS

A system and method for determining a minimum distance between an object and an apparatus surface, in particular for determining a minimum distance between an object and an apparatus surface of a handling apparatus, is described. A primary distance of the object is captured as the distance of the object by a distance sensor unit in or on the apparatus surface. A critical point which is at the primary distance from the distance sensor unit and is within a capture range of the distance sensor unit and comes closest to the apparatus surface taking into account a spatial course of the latter is also determined. A minimum distance between the critical point and the apparatus surface is determined.

The invention relates to a method for determining a minimum distance between an object and an apparatus surface, in particular for determining a minimum distance between an object and an apparatus surface of a handling apparatus.

In addition, the invention is directed towards a safety device for a handling apparatus having an apparatus surface, in particular towards a safety device for a robot having an apparatus surface.

The invention further relates to a handling apparatus, in particular a robot, having an apparatus surface and such a safety device.

Such methods, safety devices and handling apparatuses are known from the prior art. They are used in applications in which the handling apparatus and people share the same working space. This is the case e.g. in the context of human-robot cooperation. In this context it must be ensured that the people present within the working space of the handling apparatus remain safe. Moreover, collisions between the handling apparatus or components thereof and other non-human objects in the working space must be avoided.

Safety devices are used for this purpose which are configured to perform methods for determining distances between people and non-human objects. Movement of the handling apparatus is thereby slowed, stopped or completely impeded in consideration of the measured distances.

For the purpose of easier readability, people and non-human objects will be jointly referred to hereinafter as objects.

Safety devices and methods executable thereby for distance determination are known and make possible a high level of precision for distance determination but with a similarly high level of outlay. In this manner, associated handling apparatuses can be operated safely and efficiently.

The invention is applicable hereto, the object of which is to further improve methods, safety devices and handling apparatuses of the type mentioned in the introduction. In particular, a simple and reliable way to determine distances between objects should be created. It should also be possible to perform such a method with a comparatively low level of outlay. There should be no compromise in relation to operational safety.

The object is achieved by a method of the type mentioned in the introduction comprising the following steps:a) capturing a primary distance of the object by means of a first distance sensor unit positioned on or in the apparatus surface, wherein the primary distance is the distance between the object and the distance sensor unit,b) determining a critical point which is at the primary distance from the first distance sensor unit and within a capture range of the first distance sensor unit and comes closest to the apparatus surface in consideration of a 3-dimensional course of the apparatus surface, andc) determining the minimum distance between the critical point and the apparatus surface.

Such a method can be performed simply and reliably. In this context, consideration is given to the fact that distance sensor units can typically determine a distance but cannot indicate where within the associated capture range the distance is measured. This problem is solved by determining the critical point and the associated minimum distance. It is impossible for the method to determine a minimum distance which, e.g. owing to a 3-dimensional course of the apparatus surface, is greater than an actual distance. Rather, a somewhat shorter distance is output in case of doubt. The method is thus particularly safe.

The following items of information must be known for the method: course of the apparatus surface at least in the relevant range, position of the distance sensor on the apparatus surface, capture range of the distance sensor unit. This information can easily be stored on a control unit which is configured for performing the method.

It is also understood that a capture range of a distance sensor unit is always selected such that the apparatus surface does not screen it. Otherwise, the distance sensor unit would not be able to be operated with the desired reliability.

Furthermore, in the present case it is assumed that the distance sensor unit has a substantially conical capture range.

The critical point can lie on an edge of the capture range when the apparatus surface is flat or when the apparatus surface is convexly curved in the direction of the object and a radius of curvature of the apparatus surface is greater than the primary distance or when the apparatus surface is concavely curved in the direction of the object. In these cases, the position of the critical point can be determined in a particularly rapid and simple manner. As a result, the minimum distance can likewise be determined in a rapid and simple manner. Information relating to the curvature of the apparatus surface can also be stored on a control unit which is configured for performing the method.

A sensor signal from a second distance sensor unit positioned on or in the apparatus surface is preferably ignored when the second distance sensor unit detects an object. Alternatively, the critical point lies outside a capture range of a second distance sensor unit positioned on or in the apparatus surface when the second distance sensor unit does not detect an object. In the latter case, it can consequently be ruled out that an object is present in the capture range of the second distance sensor unit. Therefore, an object also cannot be present in a possibly provided overlapping region of the capture ranges of the first distance sensor unit and the second distance sensor unit. Accordingly, the critical point also must lie outside of the overlapping region. In the former case, it cannot be determined whether the object captured by the second distance sensor unit is the same object as captured by the first distance sensor unit or a different object. For safety reasons, it must be assumed that these are two different objects. Accordingly, in this case, ignoring the sensor signal generated by the second distance sensor unit results in increased reliability of the first distance sensor unit. It is understood that in a following step the sensor signal from the second distance sensor unit can naturally also be evaluated. In this context, the sensor signal from the first distance sensor unit can be ignored.

If two distance sensor units are provided, a position of the captured object within the associated capture ranges can also be determined. This can be effected e.g. by virtue of the fact that both distance sensor units capture a phase of a signal reflected by the object and so an associated phase shift can be determined. The position within the capture ranges can be deduced from the phase shift.

According to one embodiment, at least two raw distances are determined in each distance sensor unit, wherein the primary distance is the shorter of the raw distances. At least two distance sensors are preferably arranged for determining the raw distances within the distance sensor unit, said sensors having detection ranges which at least partially overlap. The distance sensors used for determining the raw distances are thus redundant. As a result, reliability of the distance sensor unit encompassing same and consequently also of the method in accordance with the invention is increased.

Preferably, the detection ranges of the distance sensors for determining the raw distances overlap such that one detection range lies completely within the other. A raw distance can thus be determined by the two distance sensors in the associated overlapping region. Alternatively, the detection ranges are substantially identical. It is understood that the details relating to the detection ranges are possibly only valid outside of a certain minimum distance. Only insufficient overlapping can be present within the minimum distance owing to the geometric features. In the extreme case, the capture ranges do not overlap at all within the minimum distance.

The raw distances can be determined in accordance with a time-of-flight method by means of different sensor principles. In particular, one of the sensor principles is an electromagnetic, preferably optical, sensor principle and another of the sensor principles is an acoustic sensor principle. In this context, each time-of-flight sensor includes a transmission unit and a reception unit and an evaluation unit. The evaluation unit determines, in dependence upon the running time which a signal output by the transmission unit requires until it is detected by the reception unit, and with knowledge of a wave propagation speed in the relevant space, a sensor signal in the form of a distance value. Time-of-flight sensors thus operate in a comparatively rapid and precise manner. As a result, they are particularly well suited to be used in the context of handling apparatuses or robots. By using different sensor principles, the robustness and error tolerance when determining raw distances can be increased.

A first distance sensor can be an infrared sensor and a second sensor can be an ultrasound sensor. In this thereby ensured that virtually any object used in a typical environment of a handling apparatus, i.e. people clothed in any way and objects made from any material, can be recognised in different environmental conditions (brightness, fog, air humidity, etc.). This applies in particular in comparison with capacitive sensors which operate less reliably in particular with fluctuating moisture in the working space and when dust is present. In addition, some synthetic materials having a dielectric constant close to air cannot be easily recognised with capacitive sensors.

According to one variant, at least one of the distance sensor units has a capture range which can change during operation. In particular, the capture range changes in a time-dependent manner or in dependence upon a measured distance value. In this context, relatively narrow capture ranges which e.g. have the form of a comparatively narrow measuring cone, are useful in the case of comparatively remote objects because the direction in which these objects lie can be better estimated. In contrast, in the case of comparatively close objects, it is advantageous to provide comparatively wide capture ranges e.g. in the form of wide measuring cones, in order to minimise or eliminate gaps in capture. Changing capture ranges thus increase the capture precision as a whole. In the case of ultrasound sensors, e.g. a capture range can be changed in particularly simple manner by changing a sound frequency.

The capture range of at least one distance sensor unit can also be changed by virtue of the fact that the distance sensor unit is mounted in a movable manner and thus the capture range covers another section of the space surrounding the distance sensor unit depending upon the position within the movability of the distance sensor unit.

The object is also achieved by a safety device of the type mentioned in the introduction which includes a first distance sensor unit, which can be positioned on or in the apparatus surface, and an evaluation unit, which is coupled to the distance sensor unit in terms of signal technology and is configured to perform a method in accordance with the invention when the distance sensor unit is in the mounted state. Minimum distances of apparatus surfaces can thus be determined in a simple and reliable manner by means of the safety device. As a result, apparatuses equipped with the safety device, in particular handling apparatuses, can be operated reliably in those working spaces in which objects which are potentially at risk of colliding, and in particular also people, are present.

Moreover, the effects and advantages mentioned in relation to the method are also applicable to the safety device, and vice-versa.

Furthermore, a second distance sensor unit which can be positioned on or in the apparatus surface is coupled to the evaluation unit in terms of signal technology. The safety device can also provide those functions which have already been mentioned in conjunction with the method in accordance with the invention and are based on the use of two distance sensor units.

Preferably, the first distance sensor unit and the second distance sensor unit each comprise a capture range, wherein the capture ranges overlap outside of a predefined safety distance from the distance sensor units. This means that a space outside of the predefined safety distance is reliably illuminated by the distance sensor units. In particular, the space outside of the predefined safety distance is completely illuminated by the distance sensor units, i.e. there are no illumination gaps outside of the predefined safety distance. However, it is also possible to allow illumination gaps outside of the predefined safety distance. However, in that case the distance sensor units are configured and positioned such that the illumination gaps are non-critical in size. This means that the illumination gaps are clearly smaller than the objects to be detected by means of the distance sensor units. As a result, it is achieved that the object to be detected also cannot lie completely within the illumination gap in the least favourable case and thus is always reliably detected. For example, an illumination gap having a cross-section of a few square centimetres can be produced by three partially overlapping illumination cones of adjacent distance sensor units in space. However, this is deemed to be non-critical when people are being detected. As an analogy for the allowable illumination gaps of non-critical size, consideration can be made of a cage formed of a grid. The grid comprises openings but these are sized such that predefined objects cannot pass therethrough. In contrast thereto, illumination gaps which possibly exceed the non-critical size are also permitted within the predefined safety distance. As a whole, the region outside of the safety distance can be illuminated with a high degree of reliability and coverage. However, for this purpose only a minimum number of distance sensor units are required. The design of the safety unit is thus comparatively simple and cost-efficient.

In one embodiment, each of the distance sensor units comprises at least two distance sensors which operate in accordance with a time-of-flight method. In this context, reference can be made to the effects and advantages of the use of time-of-flight sensors which have already been explained.

A detection range of one of the distance sensors and a detection range of the other of the distance sensors can at least partially overlap. In particular, the detection ranges are substantially identical or one of the detection ranges completely encompasses the other detection range. There is thus a certain redundancy in the capture of the distances. As a result, the safety device ensures a high degree of reliability and a high level of safety.

Advantageously, the distance sensors use different sensor principles. In particular, one of the distance sensors uses an electromagnetic, preferably optical, sensor principle and another of the distance sensors uses an acoustic sensor principle. The effects and advantageous already explained in conjunction with the method in accordance with the invention are produced.

Also, in conjunction with the safety device at least one of the distance sensors uses in one of the distance sensor units can have a detection range which can change during operation. In particular, the detection range is set in a time-dependent manner or in dependence upon a measured distance value.

In addition to the ways of changing the detection range already explained in conjunction with the method in accordance with the invention, the safety device can also have in this context a shielding unit, the position of which can be adjusted. A detection range is thus changed by adjusting a position of the shielding unit. The shielding unit can be adjusted e.g. by means of piezo elements. It is understood that for the setting of a detection range, only the relative position between the shielding unit and the associated distance sensor is important. In a similar manner, a fixed shielding unit can also be provided which cooperates with a movably mounted distance sensor.

The distance sensor unit can additionally be selectively deactivatable. This is particularly advantageous when distance sensor units are positioned on an apparatus surface such that in most postures of the associated apparatus, in particular a handling apparatus, the distance sensor unit would capture part of the apparatus surface or of the handling apparatus.

Moreover, the object is achieved by a handling apparatus, in particular a robot, of the type mentioned in the introduction, which comprises a safety device in accordance with the invention, wherein at least a first distance sensor unit of the safety device is positioned in or on the apparatus surface. Therefore, distances between objects and the apparatus surface can be reliably captured. As a result, the handling apparatus can be operated in a safe and reliable manner in a working space in which both people and/or non-human objects potentially at risk of colliding are present.

The handling apparatus or the robot thus carries the distance sensor units required for safeguarding. This is also referred to as apparatus-centric or robot-centric safeguarding.

Moreover, the effects and advantages mentioned in conjunction with the method in accordance with the invention and/or the safety device in accordance with the invention are also applicable to the handling apparatus in accordance with the invention, and vice-versa.

The handling apparatus can operate in a distance-controlled operating mode if only objects outside of a predefined safety distance are captured by means of the safety device. Alternatively, the handling apparatus can operate in a force-controlled operating mode or stop when objects are captured within the safety distance. In this context, the force-controlled operating mode is associated with a reduction in the working or travel speed of the handling apparatus, and so if there is contact between the handling apparatus and a person, the contact force is so low that no injuries can occur. Alternatively, the handling apparatus stops. It thus no longer moves. Only when objects are no longer captured in the safety distance can a decision be made as to the restarting of the movement. In this manner, high operational safety is also ensured.

In addition to the predefined safety distance, a predefined threshold distance can also be provided. This is greater than the predefined safety distance, i.e. lies in a region outside same. The handling apparatus can be configured such that, for particular operating parameters in dependence upon whether an object is detected within the predefined threshold distance or outside of the predefined threshold distance, different limit values can be applied. For example, outside of the predefined threshold distance a first, preferably high maximum travel speed is allowed, wherein within the predefined threshold distance, but outside of the safety distance, a second, reduced maximum travel speed is allowed. It is understood that a plurality of such threshold distances can also be defined. In this manner, the handling apparatus can be operated in an efficient whilst safe manner.

In this context, it is also advantageous to set the safety distance and/or the threshold distance in a speed-dependent manner. A variable of the safety distance is directed to the so-called stopping distance, i.e. the distance the handling apparatus still travels after the emergency shut-off switch is actuated before it comes to a standstill. This stopping distance must be shorter than the safety distance. Otherwise, an undesired collision may occur.

The handling apparatus can also be equipped with a direction recognition unit. It can thus be recognised whether the handling apparatus is moving towards or away from a captured object. For this purpose, the minimum distances captured by means of the distance sensor units can be evaluated in combination with movement data of the handling apparatus.

For the case that objects at risk of colliding are always positioned in the working space of the handling apparatus and/or close to a working space limit, the handling apparatus can furthermore be programmed such that it always works in the force-controlled mode in the region of these objects. This can be effected by specific programming or by a learning run. The purpose of such a functionality resides in the fact that people who were previously hidden by such objects can enter the capture range of the distance sensor units behind such objects. The concealing object can also be parts of the handling apparatus itself.

As already mentioned, the handling apparatus is in particular a robot. This is designed e.g. as a hinged arm robot, gantry robot, delta robot or hexapod robot. A hinged arm robot can be a bent arm robot, a dual arm robot or a so-called SCARA robot.

The invention will be explained hereinafter with the aid of various exemplified embodiments which are illustrated in the attached drawings. In the drawing:

FIG.1shows a handling apparatus10which in the illustrated embodiment is designed as a bent arm robot.

The handling apparatus10comprises a base12, a first arm14, a second arm16and a gripper18.

The first arm14is connected to the base12and to the second arm16in an articulated manner. On its side opposite the first arm14, the second arm16is coupled to the gripper18in an articulated manner.

The handling apparatus10comprises a plurality of apparatus surfaces12a,14a,16a,18a.

More precisely, the base12is delimited by the apparatus surface12a. The first arm14comprises the apparatus surface14aand the second arm16comprises the apparatus surface16a. The gripper18comprises further apparatus surfaces18a, of which only one is provided with a reference sign by way of example.

The handling apparatus10can be operated in a working space20in which objects22are provided which are additionally positioned such that the handling apparatus10or parts thereof may collide with them.

Specifically, such objects22are provided in the illustrated embodiment in the form of a person24, in the form of a comparatively small block26and in the form of a comparatively large block28.

In order to be able to operate the handling apparatus10in such a working space20safely, i.e. so as to exclude undesired collisions between the objects22, it is equipped with a safety device30.

The safety device30comprises a plurality of distance sensor units32, each positioned on one of the apparatus surfaces12a,14a,16a,18aand of which only some are provided with a reference numeral inFIG.1.

Furthermore, the safety device30comprises an evaluation unit34. All of the distance sensor units32are coupled to the evaluation unit34in terms of signal technology.

In the embodiment illustrated inFIG.1, a total of eleven distance sensor units32can be seen.

Each of the distance sensor units32has a capture range36which is substantially conical in the illustrated embodiment. Limits of the capture range36are shown in the direct environment of the associated distance sensor unit32, in each case by two thin lines. For improved clarity, again, only some of the capture ranges36are provided with a reference sign inFIG.1.

The capture ranges36can at least partially overlap, as is shown in particular inFIGS.2and3, which each show exemplified components38of the handling apparatus10with associated distance sensor units32and their associated capture ranges36.

The capture ranges36of the distance sensor units32thus form, at least in selected regions of the handling apparatus10, a type of sleeve around the handling apparatus10, within which objects22are detected and distances between the objects22and the apparatus surfaces12a,14a,16a,18acan be determined.

As can be seen in particular inFIG.4, the distance sensor units32are arranged such that the associated capture ranges36overlap only outside of a predefined safety distance S.

It is thereby ensured that objects22can be reliably captured outside of the safety distance S.

However, this also means that it is accepted that capture gaps occur within the safety distance S, i.e. inFIG.4between the apparatus surface16aand the circle representing the safety distance S.

However, with such an arrangement of the distance sensor units32an overall reliable monitoring, via sensors, of the working space20can be achieved with a manageable number of distance sensor units32. In other words, such an arrangement provides a good compromise between the outlay, in particular financial outlay, for the distance sensor units32and the coverage of the working space20by the capture ranges36.

The handling apparatus10can, in this configuration, always be operated in a safe and reliable manner despite the accepted capture gaps.

This is due to the fact that the handling apparatus10can be operated in two different operating modes.

It operates in a distance-controlled operating mode when the safety device30, more specifically the distance sensor units32, merely captures objects22outside of the predefined safety distance S.

InFIG.4, by way of example an object22is shown outside of the safety distance S.

As soon as an object is captured in the safety distance S, i.e. as soon as inFIG.4the object22touches the circular line representing the safety distance S, the handling apparatus10moves into a force-controlled operating mode.

In such an operating mode, a travel speed of the handling apparatus10is reduced so much that in particular a collision with the person24does not result in injuries.

Alternatively, the handling apparatus10can be stopped for as long as the object22is captured in the safety distance S.

In order to further increase the operational safety of the handling apparatus10, each distance sensor unit32is also equipped with two distance sensors32a,32b(seeFIG.4in conjunction withFIG.1).

All of the distance sensors32a,32boperate in accordance with the so-called time-of-flight method, i.e. each of the distance sensors comprises a transmission unit which is not illustrated in more detail and transmits a sensor signal, and an associated reception unit which can capture a signal possibly reflected by an object22within the capture range36. Using the time required for the sensor signal from the time of transmission to the time of capture thereof, and a signal propagation speed within the medium provided in the working space20, e.g. air, a distance can be thus calculated.

The distance sensors32a,32bof a distance sensor unit32are arranged such that the detection ranges of the distance sensors32a,32bare substantially identical. A detection range of the distance sensor32thus substantially corresponds to the capture range36. The same applies for the detection range of the distance sensor32b.

Furthermore, distance sensors32a,32bwhich operate according to different sensor principles are always used within a distance sensor unit32. In the illustrated embodiments, the distance sensor32ais an infrared sensor and the distance sensor32bis an ultrasound sensor.

Within the safety device30, all of the distances measured by the distance sensors32a,32bare communicated to the evaluation unit34.

The evaluation unit34is configured, with respect to each of the apparatus surfaces12a,14a,16a,18aand each of the distance sensor units32, to perform a method for determining a minimum distance between a detected object22and the apparatus surface12a,14a,16a,18a.

The distance values determined by the distance sensors32a,32bare used in this method as input parameters and are processed as raw distances.

Using the raw distances, initially a primary distance P is determined.

The primary distance P corresponds to the shorter of the two raw distances determined by the distance sensors32a,32b.

Such a primary distance P is shown inFIGS.5and6.

In other words, it is now thus known that an object22to be detected is located within the capture range36of the evaluating distance sensor unit32and is at a primary distance P from the distance sensor unit32.

However, depending upon the course of the associated apparatus surface12a,14a,16a,18ain space, this primary distance P is not necessarily a minimum distance between the object22and the apparatus surface12a,14a,16a,18a.

In this context,FIG.5shows an example in which the apparatus surface12a,14a,16a,18ais substantially flat.

Another example of a course of the apparatus surface16ais shown inFIG.6. In this case, the apparatus surface16ais convexly curved.

A critical point K must subsequently be determined, said point lying at the primary distance P from the relevant distance sensor unit32and within the associated capture range36, but comes closest to the apparatus surface12a,14a,16a,18ain consideration of the 3-dimensional course thereof.

Since, in the embodiment ofFIG.5, the apparatus surface is flat, this critical point K lies on an edge of the capture range36of the distance sensor unit32. For illustrative purposes, the object22is shown in an associated position in dashed lines. It can also be stated that the object22is shifted or projected theoretically into the critical point K for determining the minimum distance.

In the embodiment ofFIG.6, the critical point K does not lie on an edge of the capture range36of the considered distance sensor unit32.

This is due to the fact that the apparatus surface16ais convexly curved in the direction of the object22and a radius of curvature of the apparatus surface16ais shorter than the distance P.

In a subsequent step, the minimum distance M between the critical point K and the apparatus surface12a,14a,16a,18ais determined. This minimum distance M is used for operating the handling apparatus10which thus always operates with a distance value which ensures safe operation.

In this context, individual distance sensor units32can also be deactivated or the signals generated thereby can be ignored.

This will be explained with reference toFIGS.5and6.

In a case in which inFIG.5the distance sensor unit32illustrated on the left and also the distance sensor unit32illustrated on the right are active, then using the sensor values generated thereby a differentiation cannot be made as to whether the distance sensor unit32illustrated on the left also captures the object22, the minimum distance of which is to be determined, or whether the distance sensor unit32illustrated on the left captures another object denoted by22′ inFIG.5.

In the example ofFIG.5, the distance sensor unit32illustrated on the left captures both objects22,22′.

In such a case, i.e. in a case in which a distance sensor unit32adjacent to the distance sensor unit32to be evaluated also captures an object, initially the adjacent distance sensor unit32, i.e. the distance sensor unit32illustrated on the left inFIG.5, must be deactivated or the signals generated thereby must be ignored. Only then can the object22be reliably recognised and an associated minimum distance M be determined.

In a subsequent step, the distance sensor unit32illustrated on the right inFIG.5is deactivated or the signals generated thereby are ignored. In this manner, by using each of the distance sensor units32a reliable minimum distance M can be calculated and used for operating the handling apparatus10.

In the case ofFIG.5, the distance sensor units32are evaluated successively.

Only in the case illustrated inFIG.6, in which the adjacent distance sensor unit32in the counter-clockwise direction does not capture any object22at all, can and should the signals from this distance sensor unit32be evaluated substantially simultaneously.

In this case, it is absolutely impossible for the object22, the minimum distance M of which is to be determined, to be located within the capture range of the adjacent sensor unit32. Therefore, the object22must also lie outside of an overlapping region of the capture ranges of the two adjacent distance sensor units32. InFIG.6, the overlapping region is emphasised with hatching. The object22can thus be located more precisely than in a case in which merely a single distance sensor unit32is available.

In addition, a distance sensor unit32must be able to be selectively deactivated if the handling apparatus10assumes a posture in which the relevant distance sensor unit32would merely capture components of the handling apparatus10.

In one variant, one or more distance sensors32cwhich have an adjustable detection range can also be used within a distance sensor unit32. This will be explained with reference toFIG.7.

The distance sensor32cshown inFIG.7comprises a shielding device40which is displaceably mounted.

In the configuration ofFIG.7(a), the shielding device40is in a retracted position and so a conical detection range having the cone angle W1is produced.

In the configuration ofFIG.7(b), the shielding device40is in an extended position. Owing to the resulting shielding effect, a conical capture range is produced having a cone angle W2which is clearly smaller than the cone angle W1.

Such distance sensors32care advantageously operated in a configuration corresponding toFIG.7(b), i.e. with a comparatively narrow detection range, if it is merely a matter of capturing objects22at a comparatively far distance away from the handling apparatus10. In this manner, it is easier to resolve the position of the object22relative to the handling apparatus10.

In contrast, the configuration ofFIG.7(a)is preferably used when objects22in close proximity are to be detected. In this manner, complete coverage of the environment of the relevant component of the handling apparatus10is produced, in particular in close proximity. In other words, in this manner a safety distance S (seeFIG.4) can be kept relatively short.

In the evaluation unit34, the previously described distances detected by means of the distance sensor units32, in particular the determined minimum distances M are always processed in connection with a movement direction of the handling apparatus10.

The latter information is made available in this context by a control unit, not illustrated in more detail, of the handling apparatus10. This control unit is specifically configured to control or regulate movements of the handling apparatus10.

Therefore, by means of the evaluation unit34distances can be captured in relation to a current movement direction of the handling apparatus10. It can thus be determined whether a detected distance lies at the front or rear in a movement direction of the handling apparatus10. In other words, it is established whether the handling apparatus10is moving towards or away from the detected object22.

It is understood that distances to the rear in the movement direction are clearly less critical for the operation of the handling apparatus10in terms of safety than distances to the front in the movement direction.

If for example the gripper18of the handling apparatus10moves in the illustration ofFIG.1in the direction R, then the position of the person24is considered substantially to be non-critical. As a result, a travel speed of the handling apparatus10does not need to be restricted owing to the person24.

In the illustrated configuration, only the objects26,28are thus to be considered when adjusting the travel speed.

The evaluation unit34is furthermore configured to store information regarding objects22located within the working space20and to classify these objects22.

This is particularly important for those objects22which are arranged within the working space20such that capture ranges36can be concealed or limited by distance sensor units32(seeFIG.8). For such objects, the situation may arise that another object, in particular a moving object, emerges so-to-speak from the shadows and thus directly enters the proximity of the handling apparatus10, without this approach being able to be captured by means of the distance sensor units32.

This is of particular importance if a person24can appear from behind such an object at least partially concealing a capture range36.

The handling apparatus must thus be always operated in the environment of such objects with such a reduced travel speed that it can still stop in good time when an object22or the person24appears. Alternatively, it must be operated in the force-controlled mode in the environment of such objects.

Storing and classifying information relating to such critical objects22on the evaluation unit34can be effected e.g. within the scope of a learning run.

FIG.9shows a variant of the safety device30.

The distance sensor unit32is arranged to be movable on the apparatus surface16a.

As indicated by the two arrows, the distance sensor unit32can be moved along a rail42.

In this manner, a single distance sensor unit32can detect objects in a comparatively large space.

It is understood that the safety device30can also comprise a plurality of such movable distance sensor units32.

The movement range of the distance sensor unit32can be selected in an application-specific manner. Contrary to that shown inFIG.9, in this context a substantially annularly circumferential rail42can also be provided so that the distance sensor unit32can be moved over the entire circumference of the arm16.