DE102017119149A1 - Method for contactless detection of relatively moving objects and sensor device - Google Patents

Abstract

The invention relates to a method and a sensor device for non-contact detection of objects (12) and / or persons. It is z. B. applicable to accident prevention in the human-robot collaboration. The method and the sensor device are based on the use of ultrasound. At least two ultrasonic transducers (2.2, 4) each generate a flattened-pear-shaped ultrasonic field within a security area to be monitored. By switching the ultrasonic transducers (2.2, 4) into an operation as ultrasonic sensors, reflections of objects (12) moving within the safety range relative to the ultrasonic transducers (2.2, 4) are detected and a distance and a relative speed are determined by the evaluation unit (2.1, 6) ,

Description

The invention relates to a method and a device for non-contact detection of relatively moving objects. The invention is applicable to protection against an accident of a human by the action of a robot, i. H. a programmable, autonomously operating machine, or the protection of a robot against penetrating into his work space objects or people.

The term robot herein describes any type of moving automatic (i.e., computer program controlled) machine that can be both stationary and mobile.

Robots are widely used in industrial production. They are available in various designs, eg. B. as a stationary installed handling device, as a programmable machine tool, as an autonomously acting transport device, etc.

As a rule, robots follow a previously programmed sequence of movements. Unpredictable events, such as B. a randomly penetrating into the working space of a robot worker, are not taken into account here. Accordingly, there is always the danger that a person will be injured by a robot or parts of the robot may be accidentally damaged.

A variety of systems and methods are already known for a secure human-robot collaboration (MRC).

The DE 202014100411 U1 describes a safety device which comprises a detection device to be worn by the worker for locating the worker. The disadvantage here is that any person who could get into the working area of the robot must first create such a detection device. If this is forgotten, the safety device can not work.

A multifunctional camera unit for coupling to a mobile robot system is incorporated in WO 2017 089 364 A1 proposed. The camera unit is designed primarily for recognition and tracking of static and dynamic objects, where it can be used both statically and mobile. However, this requires a complex computer technology for real-time image analysis, whereby the system can only recognize previously programmed scenarios.

In order to enable safe operation of an autonomously operating transport device in a workshop, it is known to equip it with laser scanners, which can monitor a horizontal area around the autonomously acting transport device, the so-called protective field (also referred to as security area below). If an obstacle, such as a person, enters the security area, a violation of the security area can be detected or detected by means of the laser scanner. In response, the autonomous transport device may stop to avoid a potential collision. Laser radiation, however, is subject to reservations due to its potential for human health harm.

Another disadvantage of optical image acquisition by means of cameras or laser scanners is that they depend on a clear view; For example, dust, rain or fog can seriously affect the function.

 The object of the invention is to provide a method and a sensor device for detection within a safety range of relatively moving objects, in particular for human-robot collaboration, wherein the method and sensor device both universally applicable and largely independent of environmental conditions always ready for use and for the People are harmless. In particular, they should reliably detect a person or objects that penetrate into the security area, so as to be able to protect the human against injury by the robot or a robot from damage.

The solution of this object is achieved by the method for detecting relatively moving objects according to claim 1 and the sensor device according to claim 6; expedient embodiments of the invention can be found in the subclaims. A particularly advantageous use of the invention is shown in claim 11.

The inventive method for the contactless detection of relatively moving objects, for example, to secure a workplace with robots, based on the use of ultrasound for non-contact scanning of the security area.

In order to build up a safety area formed in two spatial directions, that is to say largely planar, at least two ultrasound emitters, each generating a flattened-pear-shaped ultrasound field, are used. Here, each flattened-pear-shaped ultrasonic field has a first opening angle in a first plane, namely the plane of the security area, and a second opening angle in one of the first Level vertical second level up. From a superimposition of these individual ultrasonic fields of the locally limited, largely spanned in the first plane security area, ie the area to be monitored or the protective field is formed.

According to the method, by means of at least one ultrasonic sensor, which may also be constructed in a structural unit with an ultrasound emitter, an ultrasound field of the security area formed by the superimposition of the ultrasound fields generated by the individual emitters (stationary or moving objects or persons) is reflected detected, wherein this detection of a reflected ultrasonic signal is performed periodically recurring at a predetermined measurement frequency.

Since, for example, furnishings or other machines or robots can be permanently positioned within the security area, preferably only a temporal change of the ultrasound signal detected with each periodically recurring measurement is taken into account for an evaluation. The evaluation of the temporal change of the ultrasonic signal takes place, for example, by means of an evaluation unit, which is connected at least to the one or more ultrasonic sensors.

When a change in the detected reflected ultrasound signal occurs between two successive measurements, a distance and, from the time change of the distance, a relative speed between the ultrasound sensor and the object reflecting the ultrasound are determined. Additionally, an output signal, e.g. As an indication or warning signal can be generated.

Furthermore, an estimated collision position can be determined by means of the determined distance and the determined relative velocity, wherein in the case of an anticipated collision event an output signal, e.g. As a warning or alarm signal is generated.

Thus, the method according to the invention allows detection of movements of the ultrasonic sensor with respect to objects within the safety area. D. h., It is both a movement of the ultrasonic sensor, the z. B. is fastened to an autonomously acting transport device, in the direction of an object as well as a movement of objects, the z. B. are on a collision course with the ultrasonic sensor or the component to which the ultrasonic sensor is mounted, detected.

An advantage of the method for non-contact detection of moving objects is that the sensor components z. B. can be placed independently of the evaluation unit, where they are stationary, d. H. fixed, or can be mounted on a moving component or an autonomously acting transport device. Since the sensor components can be kept very small, there are few restrictions on their placement. In addition, the method is not based on feedback or communication of the sensors with dedicated, z. B. instructed by a human or set up at predetermined positions in the room, devices.

Furthermore, it can be provided to send one or more control commands to the robot whose security area is monitored as the output signal. The evaluation unit can accordingly be connected to a control unit of the robot and set up such that the control commands of the robot are transmitted in real time to the evaluation unit. By having these control commands, i. H. the preprogrammed trajectory of the robot or its z. As manipulator, and the received ultrasonic signals from potential collision partners are linked, the evaluation unit can transmit a modified set of control data to the control unit of the robot, so that a collision is avoidable.

In a preferred embodiment of the method, ultrasound fields having a first opening angle of 17 ° in the first plane, that is to say of the individual ultrasound emitters, are respectively emitted. H. the plane of the security area, and a second opening angle of 5 ° in the second plane perpendicular to the first plane, wherein the ultrasonic field extends to a distance of 2.5 m from the ultrasonic emitter.

The measuring frequency with which successive measurements of the reflected ultrasonic waves take place is preferably 33 Hz.

An acoustic frequency of 103 kHz has proved to be advantageous for the ultrasound.

The sensor device according to the invention for non-contact detection of objects within a security area monitored by the sensor device comprises at least two ultrasonic transducers and one evaluation unit connected to these. The evaluation unit is set up to operate the ultrasonic transducers alternately as ultrasound emitter and ultrasound sensor, i. H. periodically, the ultrasonic transducer is operated for a predetermined period of time as an ultrasonic emitter and hereafter - for a predetermined measurement period - used to measure the reflected ultrasonic signal.

The ultrasound transducers are set up and designed such that-during their operation as ultrasound emitters-a flattened-pear-shaped ultrasound field having a first opening angle in a first plane and a second opening angle in a second plane perpendicular to the first plane can be generated.

The evaluation unit has for each ultrasonic transducer on a safe output in the form of two output switching elements (also known under the English term "OSSD" - Output Signal Switching Device) on. Thus, each ultrasonic transducer two output channels are assigned, which is important for the use of the sensor device for personal protection.

The evaluation unit is furthermore set up to determine a position and relative speed of objects within the safety area based on temporal changes of an ultrasound signal detected by the ultrasound transducers during their operation as an ultrasound sensor. For example, in the event of an impending collision, an output signal, for example a warning signal that can be detected by a human being (eg visually and / or acoustically), can be generated.

In addition, the evaluation unit may have an interface for connection to a control unit connected to the robot, i. H. the robot controller, to receive from the control unit for the movement sequence of the robot generated control commands. The evaluation unit can accordingly be set up to link the received control commands with the positions and relative speeds of objects within the security area determined from the ultrasound measurements and, based thereon, to send control commands via the control unit to the robot of the workstation, e.g. B. a control signal that drives the robot in a rest position or the robot arm out of the "danger zone" out.

In particular, it may be provided to link the received sensor signals of the ultrasonic transducers and the programmed movement sequence transmitted by the robot control in such a way that an evasive movement of the robot arm is calculated, so that the movement sequence of the robot compared to the original programming is indeed temporarily changed but both the production is maintained and, for example, the person who unexpectedly gets into the original trajectory of the robot remains unhurt.

The triggerable by the evaluation unit in response to the monitoring of the security area actions z. B. to the control unit, the output of a warning signal, the reduction of the robot speed up to the stop -. B. as a function of the distance human-robot - and a rescheduling of the travel of the robot.

The advantage of the sensor device is its insensitivity to dust, moisture, paint mist, extraneous light and vibration, since the ultrasound waves thereof remain largely unimpaired. Furthermore, a situation-dependent reaction of the robot is made possible by the sensor device, wherein when the robot controller, i. H. the planned robot movement sequence, a predictive accident prevention is possible even without interrupting the production process. For this purpose, no further requirements are placed on the people interacting with the robot, in particular, no "marking" of the human being (for example by a device to be guided with it) must take place for recognition by the system.

In a particularly advantageous manner, the sensor device for an approach detection for both speed and distance monitoring after ISO / TS 15066 designed, wherein the evaluation unit is preferably programmable such that permanently arranged in the detection region of the sensor objects, for. B. permanently installed components or machines can be faded out, ie z. B. a standing in the security area system component of the robot or a pillar in space reflected ultrasonic signals are ignored.

Furthermore, the invention can be configured in such a way that the two ultrasound transducer two output switching elements (OSSD) of the evaluation unit are two secure pnp semiconductor outputs which are both short-circuit proof and monitored by an appropriate switching electronics for a cross-circuit between the two separately led semiconductor outputs.

According to one embodiment, the evaluation unit additionally has, for each of the ultrasonic transducers, a separate signaling output for warning fields, which can be embodied in a structural unit with the safe output.

It can also be provided that the evaluation unit is set up by the ultrasonic sensors from a predetermined, z. B. static, environment of the security area recorded ultrasonic signal as a base signal in a memory area of the evaluation, so that temporal changes of the ultrasonic signal can be determined as the difference to this base signal (so-called "teach-in function"). In this case, it can also be provided that a plurality of images of the security area can be stored as a respective one base signal, the evaluation unit including the acquired ultrasound image This plurality of base signals compares to produce an output signal only when deviating from all base signals, that is, when the measured signal does not correspond to any of the stored base signals. In particular, it can be provided that movements of stationarily arranged in the security area machine tools are ignored, as long as they can not cause a collision in normal operation.

Advantageously, the sensor device according to the invention can be used to secure the surface, which detects a large-area two-dimensional or large-area three-dimensional area around a robot, and / or as a robot arm protection component that only detects the near area around the robot arm - eg. B. in the form of tool protection, which monitors the environment of moving from the manipulator device of the robot tool - are used.

The tool guard, for example, includes two ultrasonic transducers that detect a working space area of a few centimeters around the tool of the robot or parts of the robot. This tool protection can z. B. monitor the directly by a gripping tool of the robot (eg., When opening and closing the gripper) claimed space by means of ultrasound. As soon as the ultrasonic waves are reflected by an object (or body part) penetrating into the monitored space, the sensor device generates an output signal z. B. to the control unit of the robot.

The invention will be explained in more detail with reference to an embodiment, wherein the same or similar features are provided with the same reference numerals. These show in a schematic representation of the

1 a stationary robot with manipulator device;

2 an autonomous transport device;

3 : the outlines of an ultrasound field; and

4 a sensor device.

On the moving arm parts 1 of the robot 10 is the ultrasound-based tool protection 2 applied. Here the tool protection covers 2 the evaluation unit 2.1 and the two, with this evaluation unit 2.1 connected ultrasonic transducer 2.2 that close the area around the tool 5 cover.

Furthermore, the robot 10 equipped with an ultrasonic room sensor for surface protection. The ultrasonic room sensor includes the two ultrasonic transducers 4 and the evaluation unit connected to these 6 , The two ultrasonic transducers 4 each generate a narrow, pear-shaped ultrasonic field at a distance of up to 2.5 m in front of the robot 10 ,

In 2 is the autonomous transport device 9 shown with a sensor device for non-contact detection of lying in the direction of travel obstacles 12 Is provided. The sensor device comprises the two ultrasonic transducers 4 and the evaluation unit connected to these 6 ,

3 shows the flattened-pear-shaped formation of the ultrasonic field generated by an ultrasonic transducer. Here is the outline 7 of the ultrasonic field in the plane of the security area significantly wider - here the maximum width is 800 mm - than the outline 8th of the ultrasonic field perpendicular to the plane of the security area, the maximum width of which is 320 mm. The range of the ultrasonic transducer, ie the length of the ultrasonic field is in this example at about 2 m.

The sensor device for non-contact detection of objects shows 4 in detail. The two ultrasonic transducers 4 are using the shielded special cable 3 to the two safe outputs 11 the evaluation unit 6 connected.

LIST OF REFERENCE NUMBERS

1

moving arm part of the robot

2

tool protection

2.1

evaluation

2.2

ultrasound transducer

3

special cables

4

ultrasound transducer

5

Tool

6

evaluation

7

Outline of the ultrasonic field in the fuse plane

8th

Outline of the ultrasonic field perpendicular to the fuse plane

9

autonomously acting transport device

10

robot

11

safe exit

12

Obstacle / object

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely 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.

Cited patent literature

• DE 202014100411 U1 [0006]
• WO 2017089364 A1 [0007]

Cited non-patent literature

• ISO / TS 15066 [0032]

Claims (11)

A method for non-contact detection of relatively moving objects, characterized in that - by means of at least two ultrasonic emitters, each generating a flattened-pear-shaped ultrasonic field with a first opening angle in a first plane and a second opening angle in a plane perpendicular to the first plane second plane, a constructed from the superposition of these ultrasound fields, locally limited security area is established; By means of at least one ultrasonic sensor having a predetermined measuring frequency one of objects ( 12 ) detected within the security area reflected ultrasonic signal; - by means of an evaluation unit ( 2.1 . 6 ) a temporal change of the detected by the at least one ultrasonic sensor ultrasonic signal is determined; and in the case of a change in the ultrasonic signal, a distance and a relative speed with respect to the object ( 12 ) is determined; and - an output signal is generated. A method according to claim 1, characterized in that the from the evaluation unit ( 2.1 . 6 ) output signal generated in response to a change in the ultrasonic signal as a function of a distance and / or relative speed between the object ( 12 ) and the at least one ultrasonic sensor is generated. Method according to one of the preceding claims, characterized in that the first opening angle is 17 ° and the second opening angle is 5 °. Method according to one of the preceding claims, characterized in that measurements for detecting the change of the ultrasonic signal are carried out with a measuring frequency of 33 Hz. Method according to one of the preceding claims, characterized in that ultrasound is used with a sound frequency of 103 kHz. Sensor device for non-contact detection of objects ( 12 ) within a security area monitored by the sensor device, in particular according to the method according to one of claims 1 to 5, characterized in that - the sensor device at least two ultrasonic transducers ( 2.2 . 4 ) and an evaluation unit ( 2.1 . 6 ); - wherein by means of each ultrasonic transducer ( 2.2 . 4 ) in each case a flattened-pear-shaped ultrasonic field with a first opening angle in a first plane and a second opening angle in a plane perpendicular to the first plane second plane can be generated; - the evaluation unit ( 2.1 . 6 ) for each ultrasonic transducer ( 2.2 . 4 ) has a safe output in the form of two output switching elements; - wherein the evaluation unit ( 2.1 . 6 ), the ultrasonic transducers ( 2.2 . 4 ) operate alternately as an ultrasound emitter and as an ultrasound sensor and, based on temporal changes of an ultrasound signal detected by the ultrasound sensors, a distance and a relative speed in relation to the object reflecting the ultrasound ( 12 ) and to generate an output signal. Sensor device according to claim 6, characterized in that the evaluation unit ( 2.1 . 6 ), the ultrasonic transducers ( 2.2 . 4 ) with a switching frequency of 33 Hz switch from an operation as an ultrasonic emitter to an operation as an ultrasonic sensor. Sensor device according to one of claims 6 to 7, characterized in that the per ultrasonic transducer ( 2.2 . 4 ) two output switching elements of the evaluation unit ( 2.1 . 6 ) are two secure pnp semiconductor outputs that are short circuit proof and short circuit protected. Sensor device according to one of claims 6 to 8, characterized in that the evaluation unit ( 2.1 . 6 ) additionally one of the number of ultrasonic transducers ( 2.2 . 4 ) comprises corresponding number of signaling outputs for warning fields. Sensor device according to one of claims 6 to 9, characterized in that the evaluation unit ( 2.1 . 6 ) is set up, the ultrasonic signal detected by the ultrasonic sensors from a static environment as the base signal in a memory area of the evaluation unit ( 2.1 . 6 ).  Use of the sensor device according to one of claims 6 to 10 for securing the surface of a robot.

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