• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A method for positioning a first movable unit (2) of a machine system (1) and a second movable unit (5) of the machine system (1) in a predeterminable relative position to each other is provided. For this purpose, the first movable unit (2) is moved by means of a first measuring system to a first position (13) within a first movement space (4). Furthermore, the second movable unit (5) is moved by means of a second measuring system (9) to a second position (14) within a second movement space. The first position (13) and the second position (14) lie within a detection range (12) of a third measuring system (11, 15.25). Finally, the first movable unit (2) and / or the second movable unit (5) are moved into said predetermined relative position by means of the third measuring system (11, 15, 25). In addition, a machine system (1) for carrying out said method is given.
    公开号:AT513697A1
    申请号:T50501/2013
    申请日:2013-08-13
    公开日:2014-06-15
    发明作者:
    申请人:Stiwa Holding Gmbh;
    IPC主号:
    专利说明:

    1
    The invention relates to a method for positioning a first movable unit of a machine system and a second movable unit of the machine system in a predetermined relative position to each other, wherein the first movable unit is moved by means of a first measuring system to a first position within a first movement space and the second movable Unit is moved by means of a second measuring system to a second position within a second movement space.
    Furthermore, the invention relates to a machine system comprising a first movable unit, which is movable by means of at least a first drive in a first movement space, a first of the first movable unit associated measuring system, with the aid of the first movable unit at an arbitrary predetermined position in the first Movement space can be positioned, a second movable unit, which is movable by means of at least a second drive in a second movement space, wherein the first movement space and the second movement space have an overlap region, and a second of the second movable unit associated with the measuring system, with the help of second movable unit can be positioned at any predetermined position in the second movement space.
    A method and a machine system of the type mentioned are basically known, for example in the form of a machine tool, whose machining head designed as a first movable unit and whose tool carriers designed as second movable units move into a tool change position. 2/35 N2012 / 21200 2
    The machining head is thereby positioned by means of a first measuring system, which includes, for example, incremental or absolute encoders on the axes of motion. The tool carriers may for example be arranged on a chain which is positioned by means of a second measuring system, which may also comprise incremental or absolute encoders. The fact that the processing robot and the tool change system are arranged on a common frame or their placement in a predetermined position to each other, can be specified by specifying a first position in the first measuring system and a second position in the second position in the second measuring system, a certain relative position of the machining head to the tool carrier to perform a tool change.
    Unfortunately, in practice, it can be seen that the position of a machining robot and a tool changing system with each other may change over time. Reasons for this are temperature-induced deformations or plastic deformation of the components involved as well as aging phenomena of the measuring systems and sensor drift. The deviations can become so strong that the tool or the machining head is damaged during a tool change or a tool change can not be performed. For this reason, such machine systems respectively their measuring systems are calibrated after setting up or during operation at regular intervals.
    "Calibration" generally refers to a measuring process for determining and documenting the deviation of a measuring device or a material measure to a reference device or a reference standard of measurement. The reference device or reference standard is also called "normal". The determined deviation is taken into account in the subsequent use of the measuring device for correcting the displayed values.
    As a result of the calibration of the first and the second measuring system, the relative position of the machining head relative to the tool carrier determined by the first and second positions coincides again with the desired relative position. 3/35 N2012 / 21200 3
    The disadvantage is that the calibration process, which makes it necessary to measure the machine system, is very complex. In addition, a certain accuracy between two calibration operations can not be guaranteed.
    Another disadvantage of the known machine system is that the entire first and second measuring system must have a relatively high accuracy, which is based on the required accuracy of the relative position to be adopted. Particularly with large tool change magazines, the measuring system necessary for the correct positioning of the tool carriers can cause considerable costs.
    In addition, the achievable accuracy of the relative position due to error addition is well below the accuracy of the first and the second measurement system. If, for example, the first measuring system has an accuracy / resolution of +/- 0.1 mm and the second measuring system has an accuracy / resolution of +/- 0.2 mm, then for the given relative position with an accuracy / resolution of +/- 0.3 mm can be achieved.
    An object of the present invention is therefore to provide an improved method and an improved machine system for positioning two movable units in a relative position to each other. In particular, calibration operations should be avoided or their spacing should at least be extended, and the accuracy / resolution of the relative position increased, wherein the accuracy / resolution of the first and / or second measurement system need not be increased or even reduced.
    The object of the invention is achieved by a method of the type mentioned, in which the first position and the second position are within a detection range of a third measuring system and the first movable unit and / or the second movable unit by means of the third measuring system in said predetermined relative position is moved / be. 4/35 N2012 / 21200 4
    The object of the invention is further achieved with a machine system of the type mentioned above, additionally comprising a third measuring system, whose detection range lies in said overlap region and which is adapted to determine a relative position between the first movable unit and the second movable unit.
    In this way, the achievable for the relative position accuracy (only) depends on the third measuring system. If, for example, the first to third measuring systems have an accuracy / resolution of +/- 0.1 mm, an accuracy / resolution of +/- 0.1 mm can be achieved for the given relative position. An error addition does not lead to a reduced accuracy / resolution of +/- 0.2 mm as in the prior art.
    In addition, it is noted that the "resolution" generally indicates the smallest displayable difference between two measured values. In contrast, "accuracy" generally indicates the difference between measured size and true size. A high resolution is therefore not necessarily an indication of high accuracy and vice versa. Generally, the accuracy can be expressed as the difference between the measured quantity and the true size or the ratio of the two (e.g., relative accuracy in percent).
    The proposed measures calibration can also be avoided or their distance can be at least extended without the achievable accuracy for the relative position suffers, especially between two Kalibriervorgängen. However, a calibration process of the first and / or second measuring device may be necessary, for example, when the first and / or the second position are no longer within the measuring range of the third measuring device. A calibration of the third measuring device may be necessary if the third measuring device is no longer sufficiently accurate.
    In the proposed method and the proposed machine system, the observance of an absolute measure of the first and / or second measuring device for the achievement of a certain relative position between the first and the second movable unit actually negligible. In general, it is sufficient if the predetermined by the first and second position relative position or the final relative position reached "somewhere" in the measuring range of the third measuring system. The use of reference standards, as is the case with a calibration process, is not necessary.
    Further advantageous embodiments and modifications of the invention will become apparent from the dependent claims and from the description in conjunction with the figures.
    It is advantageous if at least one of the first movable unit associated first drive for starting the first position is coupled to the first measuring system, at least one of the second movable unit associated second drive for starting the second position is coupled to the second measuring system and the first drive and / or second drive for starting the predetermined relative position with the third measuring system is / are coupled, in particular exclusively with the third measuring system.
    Similarly, a machine system is advantageous, comprising means for coupling the first drive with the third measuring system alternatively / in addition to the first measuring system and / or the second drive with the third measuring system alternatively / in addition to the second measuring system.
    In this variant of the method, the first and the second position are therefore approached with the aid of the first and the second measuring system. From there, the predetermined relative position is approached by means of the third measuring system. For this purpose, it is possible that correction values for the first and / or second measuring system are determined with the third measuring system and the corrected first and / or second position is approached with the aid of the first and / or the second measuring system. A drive control of the machine system advantageously does not need to be modified for this purpose, since with the aid of the third measuring system only adjusted setpoint values for the first and / or second measuring system are preset to 6/35 N2012 / 21200 6. It is also conceivable that the drives of the machine system are decoupled from the first and / or second measuring system and instead coupled to the third measuring system. As a result, the position control is then carried out directly via the third measuring system. Finally, mixed forms of the two mentioned methods are possible. For example, both the values determined by the first / second measuring system and the values determined by the third measuring system can be used for the position control. Under certain circumstances, the positioning accuracy compared to a method in which only the first / second measuring system or only the third measuring system is used, can be substantially improved. As an example, it is again assumed that all measuring systems have an accuracy / resolution of +/- 0.1 mm.
    If the "scales" of the first / second measuring system and of the third measuring system are offset from one another, in particular by 0.05 mm, then the accuracy / resolution can be increased to + / by simultaneously using the measured values of the first / second measuring system and the third measuring system. - 0.05 mm can be increased.
    It is particularly advantageous if the relative position of the first movable unit to the second movable unit is measured directly by the third measuring system. As a result, the deviation of the actual relative position from the desired relative position is at most as great as the accuracy / resolution of the third measuring system. For example, if the accuracy / resolution is +/- 0.1 mm, the relative position can be determined with +/- 0.1 mm accuracy / resolution.
    But it is also advantageous if the relative position of the first movable unit to the second movable unit by measuring the position of the first movable unit to a reference point and by measuring the position of the second movable unit to this reference point by the third measuring system and by subsequent subtraction of the two Positions is determined. It is advantageous that the third measuring system can be fixedly mounted on a frame. This makes it easy to protect against dirt and damage. If necessary, a possible error addition should be taken into account. If, for example, the accuracy / resolution of the third measuring device is again +/- 0.1 mm, then the relative position can be measured with +/- 0.2 mm accuracy / Resolution to be determined.
    Moreover, it is particularly advantageous if the measured values of the first and / or second measuring system are stored when the predetermined relative position is reached as a future first and / or second position. The first and second positions are therefore not necessarily constant. Instead, the first and / or the second position is continuously readjusted, so that the relative position reached by the first and second position is successively approximated or tracked successively to the desired desired relative position or the actual relative position determined by the third measuring system. In this way it is ensured that the first and the second position can not "out" over time due to temperature-induced or plastic deformation of the components involved and aging phenomena and sensor drift of the first and / or second measuring system from the measuring range of the third measuring range. At this point, it is noted that this process is not a calibration of the first and / or second measuring device, because the achievement of a certain relative position of the first and second movable unit to each other is not necessarily to an exactly operating respectively calibrated first and second Bound measuring system. A correct relative position can also be achieved with a "wrong" first and second position.
    In the presented machine system, it is advantageous if the resolution and / or accuracy of the third measuring system is lower than that of the first and / or second measuring system. If the accuracy / resolution of the first and second measuring device is sufficient for realizing a certain accuracy / resolution of the relative position between the first and the second mobile unit, the third measuring system can without disadvantage have a lower accuracy / resolution than the first and the second measuring system. This is especially true if the third measuring system only provides correction values for the first and / or the second measuring system and approaches the final position of the first and second mobile units with the aid of the first and second measuring devices becomes. If, for example, the first measuring system has an accuracy / resolution of +/- 0.1 mm and the second measuring system has an accuracy / resolution of +/- 0.2 mm, an accuracy / resolution of +/- 0 can be achieved for the given relative position , 3 mm can be achieved if only the first and the second measuring system are used for position control. For the third measuring system, an accuracy / resolution of +/- 0.3 mm is therefore sufficient in principle in this case.
    It is also particularly advantageous if the resolution and / or accuracy of the third measuring system is higher than that of the first measuring system and / or the second measuring system and / or total resolution / Summengenauigkeit the first and second measuring system. In this way, the relative position can be determined with higher accuracy than would be possible with the first and second measuring system. The reason for this, in turn, is the error addition already mentioned above. If, for example, the first measuring system has an accuracy / resolution of +/- 0.1 mm and the second measuring system has an accuracy / resolution of +/- 0.2 mm, then for the given relative position an accuracy / resolution of better than + / - 0.3 mm can be achieved if the third measuring system is used for the position control and the resolution / accuracy of the third measuring system is higher than the sum resolution / sum quantity inaccuracy of the first and second measuring system, in this case better than +/- 0, 3 mm. More preferably, the resolution / accuracy of the third measuring system is higher than that of the second measuring system (ie better than +/- 0.2 mm) or even higher than that of the first measuring system (ie better than +/- 0.1 mm) , This variant is therefore particularly useful if the position control of the first and / or second movable unit using the third measuring system.
    It is furthermore particularly advantageous if the first and / or second measuring system are designed as a discontinuous measuring system and the third measuring system as a continuous measuring system.
    In a "discontinuous" measuring system, physical quantities are recorded in the form of a step function (digital). An example is a length measuring system or an angle measuring system that operates on the basis of a bar code. If the width of a stroke is known, then only the number of passes passed must be counted in order to obtain a length measurement or an angle measurement. This simply corresponds to the stroke width multiplied by the number of passes passed. By way of example, such discontinuous length measuring systems or angle measuring systems can be embodied as incremental encoders or absolute encoders. While with absolute value encoders a measured value is unique over the entire measuring range, for example by assigning a unique code, incremental encoders require an additional reference position from which the length increments can be counted.
    In contrast to "discontinuous" measuring systems, a physical variable in a "continuous" measuring system is recorded continuously, that is steplessly (analogously). Of course, a continuous acquisition of a physical quantity does not exclude a subsequent digitization of the acquired measured value, but the detection as such takes place continuously. However, the acquisition of a measured value can never be finer than permitted by physical laws, in particular quantum mechanics.
    The mentioned embodiment of the machine system now combines the advantages of both measuring systems in an advantageous form. While the first and / or second measuring system is designed as a discontinuous and thus very robust measuring system, the third measuring system is designed as a continuous and thus usually very accurate measuring system.
    In a further advantageous embodiment of the machine system, the third measuring system comprises at least one of the group Hall sensor, Wirbelstromabstandsmeßsensor, Magnetoinduktiven distance sensor, Capacitive distance sensor, Lasetriangulationssensor, Position Sensitive Device, camera distance sensor.
    Some types of distance sensors or position sensors are known from the prior art, of which some illustrative examples are counted above on 10/35 N2012 / 21200. In general, the invention is not limited to these specifically mentioned types, but can also be realized with other measuring principles.
    If a Hall sensor flows through a current and brought into a perpendicular magnetic field, it provides an output voltage that is proportional to the product of magnetic field strength and current. A Hall sensor, unlike electrodynamic sensors, provides a signal even when the magnetic field is constant. Since the field strength of a magnet decreases with increasing distance, the distance of the Hall sensor from the magnet can be determined via the field strength. The third measuring system of the machine system can thus have a Hall sensor and at least one magnet, wherein a) the Hall sensor on the first movable unit and a first magnet on the second movable unit is arranged or b) the Hall sensor at a fixed point (eg machine frame, machine foundation) is arranged, a first magnet on the first movable unit and a second magnet of the second movable unit is arranged.
    In the case a), the relative position of the first movable unit to the second mobile unit can thus be measured directly, in case b) it is determined by subtracting the two measured positions. In case b), the Hall sensor can be advantageously mounted on a stationary machine part, whereas the movable units are equipped with the little prone to interference magnets.
    An eddy current sensor comprises a resonant circuit, which often comprises a substantially inductive measuring head and a substantially capacitive acting line, and is attenuated by a metallic object. The active resonant circuit generates an alternating magnetic field whose field lines emerge from the measuring head and generates eddy currents in the metallic object, which result in negative losses. These losses are indirectly proportional to the distance of the metallic object to the measuring head. The third measuring system of the machine system may thus comprise an eddy current sensor and at least one metallic object, wherein a) the eddy current sensor is arranged on the first movable unit and a first metallic object is arranged on the second movable unit or b) the eddy current sensor is arranged at a fixed point (eg machine frame, machine foundation), a first metallic object is arranged on the first movable unit and a second metallic object is arranged on the second movable unit.
    In the case a), the relative position of the first moving unit to the second moving unit can thus again be measured directly, in case b) it is determined by subtracting the two measured positions. In case b), the eddy current sensor can be advantageously mounted on a stationary machine part, whereas the movable units are equipped with the little interference-prone metallic objects.
    Magnetoinductive distance sensors combine the evaluation of the magnetic field strength with the eddy current principle. Advantageously, thus largely linear characteristics can be achieved over a wide detection range.
    The cases a) and b) cited for the Hall sensor and the eddy current sensor can also be applied correspondingly in the magnetoinductive distance sensor.
    Capacitive sensors are based on measuring the capacitance or capacitance change of two mutually displaceable electrodes. The capacitance or capacity change is a measure of the distance between the electrodes. In general, the normal distance of the electrodes or their transverse distance (change in the effective area or the cutting area of the two electrodes) can be changed for this purpose. The third measuring system of the machine system may thus comprise a capacitive distance sensor, wherein a) a first electrode on the first movable unit and a second electrode on the second movable unit is arranged or b) a first electrode on the first movable unit, a second electrode the second movable unit and a third electrode at a fixed point (eg machine frame, machine foundation) is arranged.
    In case a), the relative position of the first movable unit to the second movable unit can thus be directly measured again, in case b) it is determined by subtracting the two measured positions.
    In the distance measurement by means of laser triangulation, a laser beam is emitted to a test object, where it meets at a certain angle on a reflector and is reflected according to the law of reflection to a receiver. Based on the position at which the reflected laser beam impinges on the receiver, the distance between transmitter / receiver and DUT can be calculated. The third measuring system of the machine system may thus comprise a laser triangulation sensor and at least one reflector gate, wherein a) the transmitter and the receiver are disposed on the first movable unit and a first reflector on the second movable unit or b) the transmitter and the receiver at a fixed point (Eg machine frame, machine foundation) are arranged, a first reflector on the first movable unit and a second reflector object is arranged on the second movable unit, wherein the laser beam is guided by the transmitter via both reflectors on the receiver or c) the transmitter on the d) the receiver on the first movable unit, the transmitter at a fixed point and a first reflector on the second movable unit is arranged.
    In cases a), c) and d), the relative position of the first movable unit to the second movable unit can again be measured directly or at least the presence of a certain relative position can be detected, in case b) it is again determined by subtracting the two measured positions. The movable units can in turn be equipped with little interference-prone reflectors.
    In the above context, the use of a "Position Sensitive Device" is advantageous. A "Position Sensitive Device" (PSD) is an optical position sensor (OPS) that can measure the single or two-dimensional position of a light spot. For example, a large-area photodiode (lateral diode, "position-sensitive diode") can be used for this purpose, in which a photocurrent arises in the region of the exposure which, depending on the light position, flows off in a specific ratio over the contacts located at the edges. From the streams, the location of the exposure can be calculated one or two-dimensionally. Alternatively, the PSD may also be a CCD or CMOS camera, in particular a line camera. The "Position Sensitive Device" then corresponds to a camera distance sensor.
    In a further advantageous embodiment of the machine system, the third measuring system comprises at least one light source and at least one photosensitive element, wherein the relative position between the first movable unit and the second movable unit is determined by evaluating a shadow on the at least one photosensitive element, which by the At least one light source emitted light and the first movable unit and / or the second movable unit is caused.
    This embodiment can therefore be regarded as a special form of a "Position Sensitive Device" or "Position Sensitive Detector" (PSD).
    However, the light beam is not bundled here but deliberately emitted in a wedge shape. Without interfering objects in the light beam, the photosensitive element, which is embodied, for example, as a transversal diode, CCD or CMOS camera, is illuminated substantially uniformly or at least in a defined manner. If an object is introduced into the light beam, this causes a shadow on the photosensitive element, which provides information about the position in which the said object is in relation to the light source or the photosensitive element.
    In such a measuring system of the machine system, a) the transmitter and the receiver may be arranged on the first movable unit and a first shading object on the second movable unit, or b) the transmitter and the receiver are arranged at a fixed point (eg machine frame, machine foundation) whereas a first mounted object on the first mobile unit and a second shading object on the second mobile unit are arranged, or c) the transmitter is on the first mobile unit, the receiver is on a fixed point and a first shading object is disposed on the second movable unit, or d) the receiver is disposed on the first movable unit, the transmitter is located at a fixed point, and a first shading object is disposed on the second movable unit.
    In this embodiment, the relative position of the first movable unit to the second movable unit in all cases a) to d) measured directly or at least the presence of a certain relative position can be detected. In case b) to provide an unambiguous assignment of movable unit to the generated shadow, the shading objects may be differently shaped or have a different size. For example, if the first shading object generates a larger shadow than the first object, then the association of detected shadow with the corresponding movable unit can be determined by the size of the shadow. It is also advantageous if the first movable unit of the machine system is designed as the head of a robot and the second movable unit of the machine system as a workpiece carrier or tool carrier. This is an arrangement in which the above-mentioned problem underlying the invention frequently results and / or particularly comes to light. In particular, this is the case when, for example, moving units of different manufacturers are combined with each other. For example, a commercial industrial robot from one manufacturer can be combined with a custom workpiece or tool transport system. Positioning errors and problems due to different responsibilities are practically inevitable. By providing the third measuring system, however, these disadvantages can be overcome. Plant engineering is therefore more flexible overall. It is also favorable if several workpiece carriers or tool carriers are connected to one another in an annular manner, in particular directly connected to one another, fastened to a chain or fastened to a cable. The advantages of the presented method or of the measures presented are particularly important in this embodiment, since the chain or the rope to which the workpiece carriers or tool carriers are fastened can stretch over time. As a result, in particular, the values measured by the second measuring system no longer coincide with the original conditions, as a result of which the actual relative position between the head of the robot and a workpiece carrier / tool carrier deviates from the desired relative position without further measures. By providing the third measuring system this is no longer the case. Finally, it is favorable if the workpiece carriers or tool carriers are designed as self-propelled units, in particular as rail-bound units. Again, the advantages of the presented method or the measures presented come particularly to bear, since self-propelled units, even if they are rail-guided, are generally more difficult to position than, for example, via a serial or parallel kinematics driven moving workpiece carrier or tool carrier. By providing the third measuring system, a relative position between robot head and workpiece carrier.
    It should be noted at this point that the various embodiments of the machine system as well as the resulting advantages can be applied analogously to the method for its operation and vice versa.
    For a better understanding of the invention, this will be explained in more detail with reference to the following figures. Show it:
    1 shows a schematically illustrated machine system with a movable robot head, a movable workpiece carrier and a camera measuring system;
    Fig. 2 is an exemplary image captured by the camera measuring system; 16/35 N2012 / 21200 16
    3 shows a third measuring system in the form of a Hall sensor in combination with a magnet;
    4 shows a third measuring system in the form of a Hall sensor in combination with two magnets;
    5 shows a third measuring system based on the laser triangulation;
    Fig. 6 is a third measuring system in which a shadow on a lichtemp sensitive element for determining the relative position between the first and second movable unit is used and
    Fig. 7 as Fig. 6 only with two shading objects.
    By way of introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, wherein the disclosures contained in the entire description can be mutatis mutandis to the same parts with the same reference numerals or component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and are to be transferred to the new situation mutatis mutandis when a change in position. Furthermore, individual features or combinations of features from the illustrated and described different embodiments may represent for themselves, inventive or inventive solutions. All statements on ranges of values in the description of the present invention should be understood to include any and all sub-ranges thereof, e.g. is the statement 1 to 10 to be understood that all sub-areas, starting from the lower limit 1 and the upper limit 10 are included, ie. all subregions begin with a lower limit of 1 or greater and end at an upper limit of 10 or less, e.g. 1 to 1.7, or 3.2 to 8.1 or 5.5 to 10. 17/35 N2012 / 21200 17
    1 shows a schematically represented machine system 1 with a first movable unit, which in this example is designed as the head 2 of a robot 3. The head 2, which is equipped here with a gripper, is movable by means of at least one first drive in a first, here hemispherical movement space 4. With the aid of a first, the first movable unit 3 associated measuring system, the first movable unit 2 can be positioned in a known manner at any predetermined position in the first movement space 4. Specifically, in the case of the robot 3 designed as a multi-axis industrial robot, the first measuring system comprises a plurality of incremental or absolute encoders which measure the angles of the individual arm segments relative to one another. Thus, the position of the head 2 can be determined.
    Furthermore, the machine system 1 comprises a second movable unit, which in this example is designed as a workpiece carrier 5. Several workpiece carriers 5 are annularly connected to each other via a chain 6 and run on two rails arranged elevated 7. The workpiece carrier 5 are movable by means of a second drive 8 in a second, here annularly shaped movement space. With the aid of a second, the second movable unit 5 associated measuring system, which is formed in this example as a rotary encoder 9, the second movable unit 5 can be positioned at any predetermined position in the second movement space. On one of the workpiece carrier 5, a workpiece 10 is arranged in this example.
    In addition, the machine system 1 comprises a third measuring system 11 whose detection area 12 lies in an overlapping area of the first movement space 4 and the second movement space and which is adapted to a relative position between the first movable unit (robot head) 2 and the second movable unit (workpiece carrier ) 5. The third measuring system is designed as a camera measuring system 11 in this example
    FIG. 2 shows an exemplary image acquired by the camera measuring system 11. Therein, the robot head 2 can be seen, whose first reference point arranged in the gripper lies at a first position 13. Furthermore, the workpiece carrier 5 with 18/35 N2012 / 21200 18 can be seen on the workpiece 10 arranged thereon. A second reference point arranged on the workpiece carrier 5 lies at a second position 14.
    Starting from the second reference point, the reference relative position of the first reference point is shown in dashed lines. If possible, the robot head 2 and the workpiece carrier 5 are thus brought into the relative position shown in dashed lines to each other. For this purpose, the robot head 2 can be moved slightly to the bottom right. Alternatively, of course, it is also conceivable that the robot head 2 are moved only down and the workpiece carrier 5 to the left. Any combinations are conceivable here. When the predetermined relative position is reached, the robot head 2 executes predefined work on the workpiece 10.
    Thus, the method for positioning a first movable unit (robot head) 2 of a machine system 1 and a second movable unit (workpiece carrier) 5 of the machine system 1 in a predeterminable relative position to one another comprises the steps:
    Moving the robot head 2 to a first position 13 within a first movement space 4 by means of a first measuring system,
    Moving the workpiece carrier 5 to a second position 14 within a second movement space by means of a second measuring system 9, wherein the first position 13 and the second position 14 within a detection range 12 of a third measuring system (camera) are 11 and
    Moving the robot head 2 and / or the workpiece carrier 5 by means of the camera measuring system 11 in said predetermined relative position.
    There are several options for this. For example, the first drives of the robot 3 for starting the first position 13 can be coupled to the first measuring system, the second drive 8 for starting the second position 14 are coupled to the second measuring system 9 and the first drives and / or the second drive 8 for Approaching the predetermined relative position can be coupled to the camera measuring system 11, in particular exclusively with the camera measuring system 11.
    The machine system 1 comprises means for coupling 19/35 N2012 / 21200 19 of the first drives with the camera measuring system 11 alternatively / in addition to the first measuring system and / or the second drive 8 with the camera measuring system 11 alternatively / in addition to the second measuring system ,
    On the one hand, it is now possible for correction values for the first measuring system and / or second measuring system 9 to be determined with the camera measuring system 11 and for the corrected first position 13 and / or second position 14 with the aid of the first measuring system and / or the second measuring system 9 is approached. A drive control of the machine system advantageously does not need to be modified for this purpose, since with the aid of the camera measuring system 11 only adjusted nominal values for the first measuring system and / or second measuring system 9 are predetermined. In general, the resolution and / or accuracy of the camera-measuring system 11 may be less than that of the first measuring system and / or second measuring system 9, since the robot head 2 and the workpiece carrier 5 are not positioned more accurately than the sum resolution / Summengenauigkeit the first measuring system and / or second measuring system 9 allow. If, for example, the first measuring system has an accuracy / resolution of +/- 0.1 mm and the second measuring system 9 has an accuracy / resolution of +/- 0.2 mm, an accuracy / resolution of +/- can be set for the given relative position. 0.3 mm can be achieved. For the camera measuring system 11, an accuracy / resolution of +/- 0.3 mm is therefore sufficient in principle in this case.
    It is also conceivable that the first drives and / or the second drive 8 of the machine system 1 are decoupled from the first measuring system and / or second measuring system 9 and instead coupled to the camera measuring system 11. The resolution and / or accuracy of the camera measuring system 11 is then advantageously higher than that of the first measuring system and / or the second measuring system 9 and / or sum resolution / Summengenauigkeit the first measuring system and second Measuring system 9. The achievable accuracy / resolution of the relative position depends in this case only on the accuracy / resolution of the camera measuring system 11. With the above values for the first measuring 20/35 N2012 / 21200 20
    System and / or the second measuring system 9, the accuracy / resolution of the camera measuring system 11 is preferably better than +/- 0.3 mm. More preferably, the resolution / accuracy of the camera measuring system 11 is higher than that of the second measuring system 9 (ie better than +/- 0.2 mm) or even higher than that of the first measuring system (ie better than +/- 0, 1 mm).
    Finally, mixed forms of the two mentioned methods are possible. For example, both the values determined by the first / second measuring system 9 and the values determined by the camera measuring system 11 can be used for the position regulation. Under certain circumstances, the positioning accuracy can be substantially improved compared to a method in which only the first / second measuring system 9 or only the camera measuring system 11 is used. As an example, it is again assumed that all measuring systems have an accuracy / resolution of +/- 0.1 mm. If the "scales" of the first / second measuring system 9 and the camera measuring system 11 are offset from each other, in particular by 0.05 mm, then the accuracy / resolution can be achieved by simultaneously using the measured values of the first / second measuring system 9 and the camera measuring system 11 increased to +/- 0.05 mm.
    In general, the relative position of the robot head 2 to the workpiece carrier 5 can be measured directly by the camera measuring system 11, as shown in FIG. 2. As a result, the deviation of the actual relative position from the desired relative position is at most as great as the accuracy / resolution of the camera measuring system 11. If the accuracy / resolution is, for example, +/- 0.1 mm, then the relative position can be +/- 0.1 mm accuracy / resolution can be determined.
    However, the relative position of the robot head 2 to the workpiece carrier 5 can also be determined by measuring the position of the robot head 2 to a reference point and by measuring the position of the workpiece carrier 5 to this reference point and by subsequent subtraction of the two positions. In FIG. 2, for example, a reference point remote from the robot head 2 and the workpiece carrier 5 could be used for this purpose. 21/35 N2012 / 21200 21
    In an advantageous embodiment, the measured values of the first and / or second measuring system 8 are stored on reaching the predetermined relative position as a future first and / or second position. In a new positioning operation, the first position 13, which is approached by the robot head 2, and the second position, which is approached by the workpiece carrier 5, thus already in the predetermined relative position to each other or at least largely correspond. A repositioning by the camera measuring system 11 will therefore be no longer or only to a small extent necessary. Furthermore, in this way it is ensured that the first position 13 and the second position 14 do not over time due to temperature-induced or plastic deformation of the components involved and aging phenomena and sensor drift of the first measuring system and / or second measuring system 9 from the measuring range or detection range 12 of the camera measuring system 11 "out" can.
    FIG. 3 now shows an example in which the third measuring system comprises a Hall sensor 15 which is mounted on the head 2 of the robot 3. On the workpiece carrier 5, a magnet 16 is arranged. With the help of the Hall sensor 15, the relative position to the magnet 16 and thus the relative position between robot head 2 and workpiece carrier 5 can now be measured directly in a conventional manner.
    4, the machine system 1 comprises a fixedly mounted Hall sensor 15, and a magnet 16 mounted on the workpiece carrier 5 and a magnet 17 mounted on the robot head 2. By subtracting the positions of the magnets 16 and 17 measured by the Hall sensor 15 the relative position between the magnets 16 and 17 and thus the relative position between robot head 2 and workpiece carrier 5 can be determined.
    In a similar manner as shown in Figures 3 and 4, other sensors can be used, such as Wirbelstromabstandsmeßsensoren, magnetoinductive distance sensors and capacitive distance sensor. In a Wirbelstromabstandsmeßsensor example, the measuring head takes the place of the Hall sensor 15 and a metallic object to be detected at the point 22/35 N2012 / 21200 22 of the magnet 16 or at the location of the magnet 17. In a capacitive distance sensor corresponding electrodes to the corresponding Components of the machine system 1 are provided.
    5 shows a variant of the machine system 1 in which the relative position between robot head 2 and workpiece carrier 5 is determined by means of laser triangulation. For this purpose, a laser transceiver module 18 is arranged on the robot head, with which a laser beam 19 is directed onto a reflector 20 mounted on the workpiece carrier 5. By evaluating the position of the received at the laser transceiver module 18 laser beam 19 can in turn be closed to the relative position between the robot head 2 and workpiece carrier 5.
    6 shows a further variant for determining the relative position between robot head 2 and workpiece carrier 5. For this purpose, the third measuring system comprises a light source 21, which is mounted on the robot head 2, and an elongate photosensitive element 22, which is mounted stationary. The photosensitive element 22 may be formed, for example, as a transversal diode, CCD or CMOS camera. The relative position between the robot head 2 and the workpiece carrier 5 is determined in this example by evaluating the shadow 23 on the photosensitive element 22, which is caused by the light emitted by the light source 21 and a first shadowing object 24 formed on the workpiece carrier 5 as a bolt. By providing a plurality of transversely aligned light sources 21 and light-sensitive elements 22, the relative position between robot head 2 and workpiece carrier 5 can also be determined in several dimensions. Of course, the same also applies if a photosensitive element 22 which can be evaluated in a multidimensional manner is used. For example, the shadowing object 24 may have a tip or a hole whose position on such a photosensitive element 22 may also be detected in two dimensions.
    FIG. 7 now shows an embodiment of the machine system 1 which is very similar to the machine system 1 shown in FIG. In contrast, however, the light source 21 is arranged stationary, and on the robot head 2 is 23/35 N2012 / 21200 23 a second shading object 25. By evaluating the shadow of the objects 24 and 25, in turn, the relative position of the robot head 2 to the workpiece carrier be determined. Advantageously, the sensitive measuring system can be arranged in a protected position, the robot head 2 and the workpiece carrier 5, however, are equipped with the relatively insensitive shading objects 24 and 25.
    In order to provide an unambiguous assignment of movable unit 2, 5 to the generated shadow 23, the shading objects 24 and 25 may be shaped differently or have a different size. If, for example, the first shading object 24 generates a larger shadow 23 than the second shading object 25, then the association of the detected shadow 23 with the corresponding movable unit 2, 5 can be determined by the size of the shadow 23. Of course, it is also conceivable that the movement of a shading object 24, 25 is used for the said assignment. If, for example, the robot head 2 is moved, but the workpiece carrier 5 is not, then the moved shadow 23 is assigned to the robot head 2, while the stationary one is assigned to the workpiece carrier 5
    Alternatively to the embodiments shown in FIGS. 6 and 7, the light source 21 may be disposed on the robot head 2, the photosensitive member 22 may be disposed at a fixed point, and a first shading object 24 may be disposed on the workpiece carrier 5, or the photosensitive member 22 is on the robot head 2 , the light source 21 at a fixed point and a first shading object 24 on the workpiece carrier 5.
    Of course, the roles of the robot head 2 and the workpiece carrier 5 may also be reversed in the above examples.
    It is also advantageous if the first and / or second measuring system 9 are designed as a discontinuous measuring system and the third measuring system 11, 15..25 as a continuous measuring system. 24/35 N2012 / 21200 24
    In a "discontinuous" measuring system, physical quantities in the form of a step function (digital) are detected, as is the case for example with the first measuring system of the robot 3 and the rotary encoder 9. In contrast to "discontinuous" measuring systems, a physical variable in a "continuous" measuring system is recorded continuously, that is steplessly (analogously).
    For example, the Hall sensor 15, an eddy current distance measuring sensor, a magnetoinductive distance sensor, a capacitive distance sensor, the laser triangulation sensor 18, and the photosensitive member 22 may continuously adjust the relative position between the robot head 2 and the workpiece carrier 5. This is also possible with the camera 11, provided it is designed as an analogue camera. CMOS and CCD cameras, on the other hand, are part of the discontinuous systems because of the discrete pixels.
    The advantages of both measuring systems can be combined by the first and / or second measuring system 9 is designed as a discontinuous and thus very robust measuring system, the third measuring system 11,15..25 as a continuous and thus usually very accurate measuring system.
    In the foregoing examples, the second movable unit was formed as a workpiece carrier 5. Of course, the second movable unit may also have a different design and be designed, for example, as a tool carrier. In this case, a milling spindle can be arranged on the head 2 of the robot 3, for example, and the tool carriers connected to one another in a ring form a tool magazine for the robot 3.
    Furthermore, the workpiece carrier 5 need not be connected to each other via a chain. Instead, for example, these can also be connected via a rope or even directly to each other. In a further embodiment, the workpiece carriers 5 can also be designed as self-propelled units and travel, for example, on the rails 7 or even freely on a running surface. 25/35 N2012 / 21200 25
    Of course, the robot 3 does not have to have the illustrated construction. Instead, this can be constructed, for example, as a gantry robot or, for example, have a parallel-kinematic drive instead of the illustrated serial-kinematic drive.
    The embodiments show possible embodiments of a machine system 1 according to the invention, it being noted at this point that the invention is not limited to the specifically illustrated embodiments thereof, but rather various combinations of the individual embodiments are possible with each other and this variation possibility due to the teaching of technical action by objective invention in the skill of those skilled in this technical field. So are all conceivable embodiments, which are possible by combinations of individual details of the illustrated and described embodiment variant, includes the scope of protection.
    In particular, it is noted that the illustrated machine systems 1 may in reality also comprise more or fewer components than illustrated.
    For the sake of order, it should finally be pointed out that the machine systems 1, as well as their components, have been shown in part to be less accurate and / or enlarged and / or reduced in size for a better understanding of their structure.
    The task underlying the independent inventive solutions can be taken from the description. 26/35 N2012 / 21200
    LIST OF REFERENCE NUMBERS
    Machine system first moving unit (robot head) Robot first moving room second moving unit (workpiece carrier)
    Chain rails second drive second measuring system (rotary encoder) workpiece third measuring system (camera) detection area third measuring system first position second position Hall sensor
    magnet
    magnet
    Laser transmitter / receiver module
    laser beam
    reflector
    Light source photosensitive element shadow first shading object second shading object 27/35 N2012 / 21200
    权利要求:
    Claims (15)
    [1]
    1. A method for positioning a first movable unit (2) of a machine system (1) and a second movable unit (5) of the machine system (1) in a predeterminable relative position to each other, comprising the steps of: moving the first movable unit (2) to a first position (13) within a first movement space (4) by means of a first measuring system, moving the second moving unit (5) to a second position (14) within a second movement space by means of a second measuring system (9) in that the first position (13) and the second position (14) lie within a detection area (12) of a third measuring system (11, 15, 25) and the first mobile unit (2) and / or the second mobile unit (5 ) is moved by means of the third measuring system (11,15..25) in said predetermined relative position / are.
    [2]
    2. The method according to claim 1, characterized in that at least one of the first movable unit (2) associated first drive for starting the first position (13) is coupled to the first measuring system, at least one of the second movable unit (5) associated second drive (8) for starting the second position (14) with the second measuring system (9) is coupled and the first drive and / or second drive (9) for starting the predetermined relative position with the third measuring system (11, 15.25) coupled will be. 28/35 N2012 / 21200 2
    [3]
    3. The method according to claim 1 or 2, characterized in that the relative position of the first movable unit (2) to the second movable unit (5) by the third measuring system (11,15..25) is measured directly.
    [4]
    4. The method according to claim 1 or 2, characterized in that the relative position of the first movable unit (2) to the second movable unit (5) by measuring the position of the first movable unit (2) to a reference point and by measuring the position of the second movable unit (5) is determined to this reference point by the third measuring system (11,15..25) and by subsequent subtraction of the two positions.
    [5]
    5. The method according to any one of claims 1 to 4, characterized in that the measured values of the first and / or second measuring system (9) when reaching the predetermined relative position as a future first and / or second position (13, 14) are stored.
    [6]
    6. Machine system (1), comprising a first movable unit (2) which is movable by means of at least a first drive in a first movement space (4), a first of the first movable unit (2) associated measuring system, with the aid of the first movable unit (2) can be positioned at any predeterminable position in the first movement space (4), a second movable unit (5) which is movable by means of at least one second drive (8) in a second movement space, wherein the first Movement space (4) and the second movement space have an overlap region, a second of the second movable unit (5) associated measuring system (9), by means of which the second movable unit (5) can be positioned at any predetermined position in the second movement space, characterized by a third measuring system (11, 15. 25) whose detection area (12) lies in the said overlapping area and which is ei is arranged to determine a relative position between the first movable unit (2) and the second movable unit (5).
    [7]
    7. Machine system (1) according to claim 6, characterized by means for coupling the first drive with the third measuring system (11,15..25) alterna tively / in addition to the first measuring system and / or the second drive (9) with the third Measuring system (11, 15, 25) alternatively / in addition to the second measuring system (9).
    [8]
    8. Machine system (1) according to claim 6 or 7, characterized in that the resolution and / or accuracy of the third measuring system (11,15..25) is lower than that of the first and / or second measuring system (9).
    [9]
    9. Machine system (1) according to claim 6 or 7, characterized in that the resolution and / or accuracy of the third measuring system (11,15..25) is higher than that of the first measuring system and / or the second measuring system (9) and / or total resolution / Summengenauigkeit the first and second measuring system (9).
    [10]
    10. Machine system (1) according to any one of claims 6 to 9, characterized in that the first and / or second measuring system (9) as a discontinuous measuring system and the third measuring system (11,15..25) are designed as a continuous measuring system.
    [11]
    11. Machine system (1) according to one of claims 6 to 10, characterized in that the third measuring system (11,15..25) at least one of the group Hall sensor (15), Wirbelstromabstandsmeßsensor, Magnetoinduktiven distance sensor, capacitive distance sensor, laser triangulation sensor (18 ), Position Sensitive Device, Camera Distance Sensor. 30/35 N2012 / 21200 4
    [12]
    12. Machine system (1) according to any one of claims 6 to 11, characterized in that the third measuring system (11,15..25) comprises at least one light source (21) and at least one photosensitive element (22), wherein the relative position between the first movable unit (2) and the second movable unit (5) by evaluating a shadow (23) on the at least one photosensitive element (22) determined by the at least one light source (21) emitted light and the first movable Unit (2) and / or the second movable unit (5) is caused.
    [13]
    13. Machine system (1) according to one of claims 6 to 12, that the first movable unit as a head (2) of a robot (3) and the second movable unit as a workpiece carrier (5) or tool carrier are formed.
    [14]
    14. Machine system (1) according to any one of claims 6 to 13, characterized in that a plurality of workpiece carrier (5) or tool carrier are annularly connected to each other, in particular directly connected to each other, attached to a chain (6) or attached to a rope.
    [15]
    15. Machine system (1) according to one of claims 6 to 13, characterized in that the workpiece carriers (5) or tool carriers are designed as self-propelled units. 31/35 N2012 / 21200
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    同族专利:
    公开号 | 公开日
    HK1212294A1|2016-06-10|
    AT513697B1|2014-09-15|
    WO2014071434A1|2014-05-15|
    US20150286211A1|2015-10-08|
    EP2917000A1|2015-09-16|
    CN104918755A|2015-09-16|
    CN104918755B|2017-08-08|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    AT505012012A|AT513564A1|2012-11-08|2012-11-08|Transport system and method for the transport of parts by means of parts carrier of a production plant|
    ATA50501/2013A|AT513697B1|2012-11-08|2013-08-13|Method and machine system for positioning two movable units in a relative position to each other|ATA50501/2013A| AT513697B1|2012-11-08|2013-08-13|Method and machine system for positioning two movable units in a relative position to each other|
    CN201380068670.0A| CN104918755B|2012-11-08|2013-11-07|For by two movable units method mutually positioning in relative position and machine system|
    EP13815678.1A| EP2917000A1|2012-11-08|2013-11-07|Method and machine system for positioning two movable units in a relative position to each other|
    PCT/AT2013/050213| WO2014071434A1|2012-11-08|2013-11-07|Method and machine system for positioning two movable units in a relative position to each other|
    US14/441,358| US20150286211A1|2012-11-08|2013-11-07|Method and machine system for positioning two movable units in a relative position to each other|
    HK16100202.6A| HK1212294A1|2012-11-08|2016-01-08|Method and machine system for positioning two movable units in a relative position to each other|
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