CZ31629U1 - A device for measuring and/or calibrating the position of a body in a space - Google Patents

Description

Technical field

The invention relates to a device for measuring and / or calibrating a position of a body in a working space, including adjoining spaces, comprising at least two movable arms, one end articulated to the frame and the other end to a platform for connection to the measured or calibrated body. the device is provided with sensors for sensing the relative position of the individual members of the device.

BACKGROUND OF THE INVENTION

Positioning or calibrating a point, body, or formation in space is an important parameter in many areas of technology, such as machine tools, robots, construction, etc.

Methods of measuring or calibrating the position of a point, body or formation (these three terms will be replaced by one term, namely a body) in space is based on determining one or more distances between one or more length measurement systems and a reference element arranged on the object the angles between the lines of the measuring system-reference element to each other or to the base (frame) etc. are measured. The determination of the position of the body is then carried out by solving geometric dependencies between the measured quantities, eg triangulation or trigonometry.

The position of the point is given by three Cartesian coordinates, the position of the body is given by six coordinates (three positional and three angular) and the position of the formation can be given by different number of coordinates from one to many. For example, interconnected bodies in space are meant by the form.

In the current methods of measuring the position of an object, as many quantities as the degrees of freedom of a measured object in space, ie how many coordinates of determining the position of an object, point, body, or object, it represents in space, are measured.

Consequently, as a result of measuring multiple quantities, each with virtually a certain error, the resulting accuracy of determining the position of an object due to the sum of measurement errors is significantly less than when measuring a single distance or an angle.

Another disadvantage of this determination of the position of the object in space is the expensive preparation of measurements due to the necessity of very accurate production, calibration and adjustment of the measuring devices and consequently the lengthy preparation of the measurement itself related to the establishment of the initial measurement positions.

This disadvantage is partially eliminated when measuring the position of the object in space by simultaneously measuring the distance of the measured object from the four laser interferometers located on the base and the subsequent solution of the predetermined equations not only for determining the position of the object in space. Even here, however, it is possible to determine only the position of a point in space, not the orientation of the body, and the resulting accuracy of positioning the object is not sufficient and is lower than the accuracy of measuring the initial distances from individual laser interferometers.

Current methods of determining the position of an object are mainly based on distance measurement, most often by a laser interferometer, where the coordinates of the individual points of the surface of the measured body are determined. In addition to the relatively expensive method of such measurement, given primarily by the price of laser interferometers, it is necessary to use a relatively large number of parts of the measuring device, including individual drives for each interferometer.

For this reason, a laser tracker has been developed which, in addition to measuring distances by a laser interferometer from the reflector, also determines the angular position of its beam and determines the position of the reflector point in space from spherical coordinates. The problem with this device is that it achieves less accurate positioning of the spotlight spot in space than the accuracy of partial measurements due to the summation of measurement errors. Another disadvantage is that only three degrees of freedom of position of a point in space can be determined at a time, not six degrees of freedom of position of a body in space.

-1 CZ 31629 Ul

Another method of measurement is measurements based on optical images captured by a camera or luminous element. Their problem is less accuracy than with laser interferometer measurements and again the impossibility to simultaneously determine six degrees of freedom of body position in space.

Another known device for measuring or calibrating the position of a body in space is the use of a coordinate measuring machine. Again, his problem is the impossibility of simultaneously determining six degrees of freedom of position of the body in space. Other disadvantages are the poorly accessible working space of the coordinate measuring machine, the need to provide it with controlled drives and its large weight and dimensions.

Therefore, procedures have been developed to calibrate the position of a body in space based on the measurement of the position of pre-fabricated artifacts in space, eg in the form of precision spheres on a beam or tetrahedron. The problem is again the impossibility to simultaneously determine six degrees of freedom of position of the body in space and coverage of the entire working space.

Another known device for measuring or calibrating a position of a body in space is to use measuring arms composed of at least two slidingly connected parts. The arm is then connected at one end to the platform and the other end rotatably to the frame. The distance between the body and the center of rotation is measured and the position of the body in space is determined or calibrated on the basis of these length measurements. Similar known devices using such measuring arms use the same principle, except that the body is not moved along a circle.

Recently, a device has been developed for measuring or calibrating the position of a body in space, which removes the previous problems. It consists of a platform that is rigidly connected to the measured or calibrated body (eg machine tool spindle), it performs any movements in the working space of the body by means of its drives, the platform is simultaneously connected via three arms to the body frame, the platform and arms are equipped with sensors. mutual positions.

A disadvantage of the latter device, which removes the previous problems, is the limited working space where the position of the body in the space can be measured simultaneously in all six degrees of freedom.

The object of the present invention is a device for measuring and / or calibrating the position of the body in space, which would achieve higher accuracy of positioning of the measured object compared to known devices, the device would be simpler and lower acquisition costs and the actual measurement of relevant quantities would be simplified and and the equipment made it possible to measure in a large working space formed by the adjacent spaces.

The essence of the technical solution

The principle of a device for measuring and / or calibrating a position of a body in a space according to the present invention consists in that the movable arms are removably connected to the frame, the number of sensors for detecting relative position between the arm parts and / or between the arm parts and the frame; / or the platform and / or between the platform and the frame is greater than the number of degrees of freedom of the free platform prior to attachment to the measured or calibrated body.

The individual movable arms of the device are detachable from the frame and repositionable to a new position on the frame, wherein the number of sensors for detecting the relative position of each device member is greater than or equal to the number of degrees of freedom of the platform before mounting on the measured or calibrated body .

The advantage of the device for measuring and / or calibrating the position of the body in the space according to this technical solution is its simplification with the possibility of using the drives of the measured and / or calibrated body and reducing its acquisition costs. accuracy of measurement and / or calibration of body position in space.

Compared to the recently developed device for measuring or calibrating the position of the body in space, which eliminates the previous problems, the device according to the invention always uses at least one arm more and the arms are detachable and displaceable.

-2CZ 31629 Ul

Clarification of drawings

The attached figures show schematically a device for measuring and / or calibrating a position of a body in a space according to the present invention, wherein Fig. 1 shows one possible variant of the device, Figs. 2 to 13 show other possible variants of the device.

Examples of technical solutions

The device generally consists of a platform 2 which is rigidly attached to the body to be measured or calibrated, 3 of the arms 1, which mostly consist of the parts 9 of the arms connected by the hinges 4, and of the fixing members Π. The joints 4 are usually either rotary or spherical 12 or sliding 5. The relative position of the arm parts 9 relative to each other or to the frame 6 or to the platform 2 is sensed by sensors 7 in kinematic pairs of joints 4 or sliding guides 5 or is sensed. point-to-point positioning for sensing point-to-point positioning between individual parts of the device by means of sensors 8, eg laser interferometers, laser trackers or other optical method.

According to FIG. 1, the device consists of a frame 6 with which the movable arms 1 are pivotally connected via the arm fasteners Π_ to the frame 6. The arms 1 are rotatable about a vertical axis and a horizontal axis, generally about two rotary axes The arm 1 is articulated at the opposite end to the platform 2 by means of a hinge 4, which in this case is a spherical hinge.

12. All joints in this and other figures are designated with the same reference numeral four, if spherical, with reference numeral twelve, and if sliding, reference numeral five. Four arms 1 are connected to the platform 2 so that the movement of the platform 2 comprises six degrees of freedom. The measuring body 3 is firmly attached to the platform 2 during measurement or calibration. The apparatus further comprises sensors 7 for measuring the angular rotation of the arms 1 in both horizontal and vertical directions as well as the displacement of the arm in the sliding guide 5. In this and other figures Arrows those movements in kinematic pairs that are measured by sensors

7. These are both rotations in joints and displacements in sliding guides. The arms I may be by means of fasteners Π. of the legs 1 to the frame 6 from the frame 6 separated and displaced.

According to Fig. 2, the four arms 1 are similarly connected to the platform 2, as seen in Fig. 1, wherein the joints 4 are pivotable both on the vertical axis and on the horizontal axis, in connection with the platform they are spherical 12, and The sliding guides 5 are displaced in the individual arms i in this exemplary embodiment. The sliding guides 5 need not generally lie in one plane, but may lie in a plane. different planes of the frame 6.

According to FIG. 3, the individual arms 1 are mounted over the attachment members 11 of the arms 1 to the frame 6 in a manner similar to FIG. 1, except that the sliding guide in the arms 1 is replaced by a hinged joint 10. All arms 1 can be separated from the frame 6 by means of the attachment members H of the arms 1 to the frame 6 and displaced. All of the above embodiments allow the remaining three arms to fully determine the position of the platform 2 in the space in six degrees of freedom after disconnecting any one arm.

According to FIG. 4, the device consists only of two arms 1 which are connected to the platform 2 by a rotary joint 4 provided with a rotary sensor 7 and having a total of six rotary joints 4 provided with rotary sensors 7, 1 with the frame 6 and with the platform 2. The arms 1 are fixed to the frame 6 via fastening members 11 to the frame 6 and by means of which they can be detached and moved from the frame 6. Each of the two arms 1 has six joints 4 with rotary sensors 7 and fully determines the position of the platform 2 relative to the frame 6. Therefore, each of them can be detached and repositioned from the frame and the other during this displacement determines the position of the platform 2. and allow self-calibration. This is the smallest number of arms for implementing the device.

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According to FIG. 5, the device consists of three arms 1, which are connected to the platform 2 again by a rotary joint 4 provided with a rotary sensor 7 and having a total of six rotary joints 4 provided with rotary sensors 7 connecting the arm members 9 and the arms 1 to the frame 6 and to the platform 2 The arms 1 are attached to the frame 6 via fastening members 11 and by means of which they can be detached and displaced. Each of the three arms has six hinges 4 with rotary sensors 7 and fully determines the position of the platform 2 relative to the frame 6. Therefore, each of them can be detached and repositioned from the frame 6, and the remaining during this displacement determine the position of the platform 2. and allow self-calibration. In this embodiment, up to two arms 1 can be moved simultaneously.

According to Fig. 6, the device uses two different types of arms i. One arm 1 has six rotary joints 4 provided with rotary sensors 7 and connecting the members 9 of the arm 1 and the arm 1 to the frame 6 and the platform 2 and connected to the platform 2 by the rotary joints 4 provided with the rotary 3, three rotary joints 4 provided with sensors 7 are mounted over the fasteners 11 to the frame 6, and at the same time they are articulated at the opposite end to the platform 2 by means of a spherical joint 12. If it is from the frame 6, the arm 1 with six rotary joints 4 is disconnected, then the position of the platform 2 is determined by the three remaining arms I. If one or more arms 1 with three rotary joints 4 provided with sensors 7 are detached from the frame 6, The arm 1 with six rotary joints 4 provided with sensors 7 can be detached from the frame 6 alone. The arms 1 with three rotary joints 4 provided with sensors 7 can also be detached from the frame 6 at the same time.

According to FIG. 7, the device uses a plurality, in the present case, six arms 1 identical to that of FIG. 3.

In Fig. 8, the device of Fig. 3 is shown in a phase where one arm 16 of the arms 1 is detached and moved with the detachment member Π detached. arms 16 to frame 6.

In Fig. 9 the device is similar to that of Fig. 3, but all the arms 1 are realized here by arms with six rotary joints 4 provided with rotary sensors 7 and one spherical joint 12 not provided with sensors 7. These arms 1 are connected to the platform 2 by spherical joints 12. This device is an example of a device with arms 1 which, in the stationary platform 2, can carry out further movements, but these are measured by the rotary sensors 7 in the rotary joints 4.

All of the above embodiments allow platform 2 to move in six degrees of freedom simultaneously.

10 to 12, another alternative embodiment of a device for measuring and / or calibrating a position of a body in space is shown. In FIG. 10, several embodiments of the arms 1 are shown. One arm 1 is articulated to both the frame 6 and the platform 2, and the individual parts 9 of the arms 1 are also articulated together. with the platform 2 by means of sliding guides 5, and a sliding guide 5 is also arranged between the two parts of the arm 1, in particular here between the first and second parts away from the frame 6. The two parts of this arm 1 are connected together by a hinge. parallel parts 9 connected to each other by joints 4, in which a part of them is measured by sensors 7.

FIG. 11 shows one arm 1 between the frame 6 and the platform 2 consisting of a plurality of parts 9 connected to each other by means of joints 4, in which a part 7 of them is measured by sensors 7, between the individual parts of the device, here in particular one sensor 8 for detecting the relative position of the points between the frame 6 and the first part of the arm i, the second sensor 8 for detecting the mutual position of the points between the second and fourth part of the arm i a part of the arm 1 and the platform 2 and two other sensors 8 for sensing the relative position of the points between the fixing member 1T on the frame 6 and the platform 2. Any joint 4 of the arm 1 can be replaced by a sliding guide 5 and vice versa each sliding guide 5 can be replaced by a joint 4. Another arm is divided into a plurality of parallel portions 9 as in Fig. 10.

Fig. 12 shows a device for measuring and / or calibrating the position of the body in space, which in addition to the two arms as in Fig. 10 also realizes only the optical measurement of the relative position of points between the arm attachment member 11 to the frame 6 and the platform 2. the arms are replaced by optical measurement of the relative position of the points between the attachment member 11 of the arm I of the frame 6 and the platform 2. Possible measurement methods are the measurement of the relative position of the points 13

-4- 31629 U1 by measuring the impact of a laser beam on a photosensitive element (eg, a CCD or PSD element), measuring the relative position of points 14 by measuring a laser tracker (e.g. a laser tracker or laser tracer), measuring the relative position of points 15 by measuring the distortion of a reference image element of an optical camera.

Figure 13 is an illustrative example of the construction of the device shown in Figure 3.

All the devices described are intended for measuring and / or calibrating the position of the body in space. The different arrangements of the arms 1 are important in terms of the different mobility of the device, i.e. the size of the working space of the device. Another second aspect is the resulting accuracy of measuring and / or calibrating the position of the body in space. In addition to the arrangement of the arms 1 and their dimensions, it is influenced primarily by the number and location of the sensors 7 and 8 in the device.

The arms 1 connected to the platform 2, which does not move, and fixed via the arm fixing member 11 immovably (firmly) to the frame 6, may be immovable or movable. This is given by the number of degrees of freedom of these arms connected between the stationary platform 2 and the frame 6. This number of degrees of freedom is determined by the number of kinematic pairs in arm 1. If the number of degrees of freedom of these kinematic pairs in arm is equal to prior to attachment to the measured or calibrated body 3, then the arm 1 is subsequently fixed between the stationary platform 2 and the frame 6 stationary. If the number of degrees of freedom of these kinematic pairs in the arm i is greater than the number of degrees of freedom of the free platform 2 prior to attachment to the measured or calibrated body 3, then the arm I is subsequently movable. This number of degrees of freedom must not be less, then platform 2 would have limited mobility and the device would not function. The mobility of the arm I is usually given by the additional joint 4 in the arm compared to the minimum number required for equality the number of degrees of freedom of arm I and the number of degrees of freedom of the free platform 2. The position of arm I must be clearly determined by measurements in sensors 7 and / or 8. of joints 4 in the arm greater than this minimum number, then these additional joints 4 must comprise additional sensors 7 and / or 8.

As can be seen in all embodiments, the sensors 7 sense individual length or angular displacements between the individual portions 9 of the arms 1 and adjacent parts or generally any two portions 9 of the leg 1 or between the portions 9 of the leg I and the frame 6 or between portions 9 of the leg I. the platform 2 or between the platform 2 and the frame 6, while the point-to-point sensors 8 detect the distances between any points of the device or the angular rotation of the line of these points. The sensors 8 may be realized by means of a distance and tilt measurement system using the measurement of the intersection points of laser beams with photosensitive elements 13, by a distance and tilt measurement system using the distortion of the reference element image by optical cameras 15, laser interferometers as laser trackers or laser trackers) 14 etc.

An essential feature of the device according to the invention is the condition that the number of sensors for sensing the relative position of the individual members of the device at all movable arms connected to the shop is greater than the number of degrees of freedom of the free platform before mounting on the measured or calibrated body. Furthermore, it is essential that the number of measured quantities after disconnection of any one movable arm is at least equal to the number of degrees of freedom of the free platform prior to attachment to the measured or calibrated body.

Usually the number of degrees of freedom of the device is equal to the number of degrees of freedom of the platform, but there may be cases where the number of degrees of freedom of the device is greater than the number of degrees of freedom of the platform. which fully determine the position of the arms I and the position of the spherical joints 12 of the arm connection to the platform 2, but the arms 1 can move even with the stationary platform 2, and FIG. .

Another essential feature associated with the method of measuring or calibrating a body in space is the measurement of the relative length and angle relationships of the individual parts of the device as it moves over a substantial part of the working, respectively. manipulation space of the measured or calibrated body, while the measured quantities of all sensors, which the

-5GB 31629 Ul Redundancy Compliance. Preferably, at least one of the sensors is a sensor for sensing the relative angular position of some of the two device members.

When using the above-described device for measuring or calibrating a body in space, hereinafter referred to as the examined (manipulated) body, it is also possible to use this device, which is not itself calibrated. The device itself is calibrated either prior to its use for measuring and / or calibrating the sample and / or is self-calibrated in conjunction with the measurement and / or calibration of the sample.

Multiple arms may be disconnected and moved at the same time, provided the remaining arms attached to the frame provide a number of measured quantities that is at least equal to the number of degrees of freedom of the free platform prior to attachment to the measured or calibrated body.

The arms may be provided with an additional hinge that allows the arm to move without changing the position of the platform. Then it is necessary that the position of the arm is clearly determined by the measured quantities.

The kinematic structure of the at least one movable arm of the device makes it possible to determine more than one degree of object freedom in space at the same time. This is necessary to create a situation where the number of measured quantities is at least one higher than the number of degrees of freedom of the free platform before mounting on the measured or calibrated body. This is usually ensured by making two length and / or angle measurements on the arms of the device.

The method of measuring and / or calibrating the test specimen, including the aforementioned self-calibration of the device, proceeds as follows:

1. The arms and the device are attached to a frame 6, such as a workbench of a production machine, and the platform 2 of the device is rigidly connected to the body to be examined 3, such as a spindle or gripper of the production machine,

2. The production machine then uses its drives to perform a variable movement with the body to be examined

3. eg with a spindle or gripper, over most of the working area. By a variable movement is meant a movement in which the platform with the attached body 3 moves in a substantial part of the working space, which allows obtaining a broadly based system of equations for positioning and / or calibration of the examined body 3 while simultaneously measuring all sensor sensors 7, 8 devices. In this movement, the measured quantities are scored at a number of at least one greater than the number of degrees of freedom of the free platform 2 prior to attachment to the measured or calibrated body 3.

3. On the basis of all measured quantities from a predetermined set of equations describing the coupling conditions of the measuring device, the position of the measuring device relative to the production machine and the relative position of the fixing members 11 of the moving arms 7 of the measuring device to the frame 6 are determined. its position and design parameters such as arm lengths, distance between axes of rotary joints, angles of rotary joints etc.

4. After this self-calibration of the device, the investigated body 3, for example a production machine connected to the device platform 2, performs again a variable movement with the spindle or gripper through most of the work space by means of its drives. During this movement, the measured quantities are again taken in a number of at least one greater than the number of degrees of freedom of the free platform 2 before being fixed to the measured or calibrated body 3.

5. Based on the measured redundant quantities, the position of the sample 3 or its calibration is determined from a predetermined set of equations describing the coupling conditions of the measuring device.

6. If it is necessary to perform measurements in another part of the working space of the production machine, which is outside the working space of the measuring device with respect to the momentary position of the attached arms I to the frame 6, move all arms gradually to the new position to measure. This is done by detaching one arm I from the frame 6, moving it to a new position and attaching it to the frame 6. In this displacement, the number of measured variables when moving the platform 2 with the measured or calibrated body 3 after disconnecting one of the movable arms At least equal to the number of degrees of freedom of the free platform 2 prior to mounting on the measured or calibrated body 3. After attaching the displaced arm I to the frame 6, it is self-calibrated according to steps 2 and 3 above. Then, if necessary, move the next arm 1 and self-calibrate. The arms 1 can thus be moved repeatedly.

7. After the necessary number of (eg all) arms has been gradually moved to such a position that it is already possible to measure in another part of the production machine working space, which is now included in the working space of the measuring device in the new position given With the arms I to the frame 6, the required measurement of the position of the manufacturing machine is carried out according to the steps of 4 and 5.

If the device for measuring and / or calibrating the position of the body in space is itself calibrated before it is used for measuring or calibrating the test body 3, the measuring and / or calibration of the test body 3 itself is carried out from point 4 above, i.e. The device 3, such as a production machine, or its spindle or gripper, connected to the device platform 2 by means of its drives, again performs a variable movement with the device platform 2 over most of its working space. During this movement, the measured quantities are again taken at least by one greater than the number of degrees of freedom of the free platform 2 before being attached to the measured or calibrated body 3. Based on the measured redundant quantities, a predetermined set of equations describing the coupling conditions of the measuring device is determined body 3 or its calibration.

Claims (5)

A device for measuring and / or calibrating a position of a body in a space, comprising at least two movable arms which are connected at one end to a frame and the other end to a platform intended to be connected to the measured or calibrated body. positions of individual members of the device, characterized in that the movable arms (1) are removably connected to the frame (6), the number of sensors (7 and / or 8) for detecting relative position between the individual parts of the arm (1) and / or between the individual parts the arm (1) and the frame (6) and / or platform (2) and / or between the platform (2) and the frame (6) is greater than the number of degrees of freedom of the free platform (2) before mounting on the measured or calibrated body. Device for measuring and / or calibrating a position of a body in a space according to claim 1, characterized in that the individual movable arms (1) of the device are detachable from the frame and moved to a new position on the frame (6), or 8) for sensing the relative position of the individual members of the device, when the at least one movable arm (1) is disconnected, is greater than or at least equal to the number of degrees of freedom of the free platform (2) before mounting on the measured or calibrated body. Device for measuring and / or calibrating a position of a body in a space according to one of the preceding claims, characterized in that at least one arm (1) is articulated to the frame (6) and the platform (2) in a non-sliding manner. articulated or articulated together. Device for measuring and / or calibrating a position of a body in a space according to one of the preceding claims, characterized in that at least one arm (1) is articulated to the frame (6) and the platform (2), the connecting joint (s) to the frame (1). 6) or the platform (2) is / are mounted in the frame (6) or platform (2) slidingly, the arm (1) being formed by one or more parts articulated or slidably connected to each other. Device for measuring and / or calibrating a position of a body in a space according to one of the preceding claims, characterized in that the arms (1) are provided with additional hinges (4) to enable their movement in the stationary platform (2). -7EN 31629 Ul Device for measuring and / or calibrating a position of a body in a space according to one of the preceding claims, characterized in that the arm (1) connected to the frame (6) and to the platform (2) is connected to the measured and / or calibrated body ( 3), has joints (4) equipped with sensors (7) and / or (8) · Device for measuring and / or calibrating a position of a body in a space according to one of the preceding claims, characterized in that it comprises at least two movable arms (1), wherein at least one of the other arms (1) is replaced by an optical sensor (8) for measuring the relative position of the points between the arm attachment member (11) to the frame (6) and the platform (2).