DE102013113407A1 - coordinate measuring machine - Google Patents

Abstract

The invention relates to a coordinate measuring machine with a quill and arranged on the quill probe in which between the probe and the quill, an intermediate piece is arranged, in which the intermediate piece of the quill is formed in the event of a collision, and in which the probe on the intermediate piece is detachably arranged in the event of a collision or in which a stylus or stylus combination in the event of a collision is detachably arranged on the probe.

Description

The invention relates to a coordinate measuring machine with a quill and arranged on the quill probe.

The prior art ( DE 100 30 570 A1 ) includes a coordinate measuring machine with which a method for quickly releasing a stylus from a probe is possible.

The stylus is mounted according to the prior art on the probe of the coordinate measuring machine via a precision bearing. A holding device, for example in the form of a hook pulls the stylus into a three-point bearing to allow a reproducible storage of the stylus during the measurement process. In the event of a collision, a control device detects the collision and outputs a signal for automatic release of the stylus, wherein an electrical signal is converted into a mechanical trigger pulse and the release of the stylus takes place.

The technical problem underlying the invention is to improve the device belonging to the prior art.

This technical problem is solved by a coordinate measuring machine with the features according to claim 1 or by a coordinate measuring machine with the features according to claim 2.

The coordinate measuring machine according to the invention with a sleeve and a stylus arranged on the sleeve is characterized in that between the probe and the sleeve an intermediate piece is arranged, that the intermediate piece of the sleeve in the event of a collision is detachable and that the probe on the intermediate piece in the event of a collision is detachably arranged.

This embodiment according to the invention has the advantage that the mechanical interfaces, which are advantageously monitored by sensors, deflect in the event of a collision. The coordinate measuring machine is advantageously decelerated. After a retraction from the collision, the deflected sensor interface can automatically return to its original position. According to the invention, two interfaces are provided in the coordinate measuring machine, namely on the one hand between the intermediate piece, which is arranged between quill and probe, such that the intermediate piece of the quill is made detachable in the event of a collision, and on the other by releasing the probe from the intermediate piece ,

This means that there are two detachable interfaces, so that protection of the probe in the event of a collision is provided in any case.

According to a second embodiment, the coordinate measuring machine according to the invention with a quill and a probe arranged on the quill is characterized in that an intermediate piece is arranged between the probe and the quill, that the intermediate piece is detachably formed by the quill in the event of a collision and that a stylus or a stylus combination in the event of a collision is detachably arranged on the probe. This coordinate measuring machine also has two detachable interfaces. The first interface is provided between the intermediate piece and the quill. The second detachable interface is provided between the stylus or stylus combination and the probe.

This solution according to the invention has the advantage that in the event of a collision of the stylus with a workpiece, the stylus or stylus combination can be solved by the probe and that in the case of collision of the probe with an obstacle, the intermediate piece, on which in turn the probe is arranged , is detachably formed by the quill.

In this way you get in any case a collision protection of the probe, which is advantageous because the probe is relatively expensive and expensive.

According to a further advantageous embodiment of the invention it is provided that at least one device is provided, with which a return of the intermediate piece can be carried out in a measuring position.

This means that after deflection of the intermediate piece from the measurement position and after retraction from the collision, the intermediate piece is automatically returned to the original position, that is to say in the measurement position and the coordinate measuring machine can continue with the measurement.

According to a further advantageous embodiment of the invention it is provided that the device is designed as at least one spring and / or a hook. These mechanical devices are relatively simple and inexpensive to build and at the same time are able to return the intermediate piece to the measuring position after being released from a collision.

According to a particularly preferred embodiment of the invention, a deflection force of the intermediate piece is adjustable. This can be adjusted in advance, at which deflection force in In case of a collision, the intermediate piece is released from the quill.

Another particularly advantageous embodiment of the invention provides that at least one sensor is provided for detecting the position of the intermediate piece. This makes it possible to provide a deflection signal to the control of the coordinate measuring machine, whereby the coordinate measuring machine can decelerate. After retraction from the collision, the deflected sensor interface automatically returns to its original position.

As already stated, it is advantageous that a control device receives a signal when the intermediate piece is deflected out of the measuring position so that the control device can advantageously trigger an emergency stop. Advantageously, followed by a retraction from the collision, for example, on the last covered path, and then moves the deflected sensor interface, as already described automatically back into the measurement position.

Advantageously, the precision bearing is designed as a three-point bearing. It is also possible to provide other bearings. It is important here that a reproducible storage is provided in the detachable interfaces.

The probe can be designed as an optical and / or switching and / or measuring probe. It can also be a multi-sensor interface with a roughness or magnetic field sensor. The invention is applicable to all types of probes. It can also be used with motorized rotary swiveling or sliding units.

A particularly preferred embodiment of the invention provides that a holding force of the stylus is formed less than a holding force of the probe on the intermediate piece or a holding force of the intermediate piece on the quill. This means that in the event of a collision, the stylus is first deflected out of the measuring position, that is, out of the precision bearing. If this is not sufficient until the successful implementation of, for example, an emergency stop, the probe can then be correspondingly deflected out of the measuring position on the intermediate piece or the intermediate piece on the quill, in order in particular to protect the probe in the event of a collision.

Further features and advantages of the invention will become apparent from the accompanying drawings in which several embodiments of a coordinate measuring machine with sensor interface are shown only by way of example. In the drawing show:

1 a coordinate measuring machine in perspective view;

2 a longitudinal section through a quill with adapter and probe;

3 a modified embodiment;

4 a plan view of a three-point bearing;

5 a section along the line VV the 2 without the intermediate piece.

1 shows a coordinate measuring machine 1 with a measuring table which can be moved in X-direction 2 , A portal 3 , which is not designed to be displaceable, carries on a traverse 4 a slidable in the Y direction slide 5 , on which in turn a sleeve which can be displaced in the Z direction 6 is arranged. At the quill 6 is a probe 7 arranged. The probe 7 in turn carries a stylus 8th with a probe ball 9 ,

2 shows the quill 6 at the one intermediate piece 10 is arranged, which in turn is the probe 7 wearing. The central part of the coordinate measuring machine 1 is the probe 7 that provides the measurement information. During the measuring process, the currently inserted sensor is placed on the surface of a workpiece and thus measured in single-point or scan mode. It is also possible, as in 2 shown that the probe 7 is designed as an optical probe. In this case, no touching is measured.

The one at the quill 6 over the intermediate piece 10 arranged probe 7 can do so in the measuring volume of the coordinate measuring machine 1 be moved in all three spatial directions X, Y, Z to meet as many different measurement tasks can.

To be able to measure with as many different sensor types as possible is the probe 7 designed exchangeable.

When measuring the trajectories of the probe 7 on the workpiece (not shown) predetermined by a program created by the user. During program creation and in measuring mode as well as during manual operation, errors can occur that lead to the probe 7 collided with the workpiece.

To damage the probe 7 To avoid is a mechanical deflection device 11a . 11b between the quill 6 and the intermediate piece 10 provided, which serves as a sensor holder, with a corresponding sensor 12a . 12b for detecting collisions, their signals for braking or stopping the coordinate measuring machine 1 be used in the event of a collision.

The one at the quill 6 attached probe 7 , which as already stated, for example, can be an optical or tactile system, sits at the intermediate piece 10 , The coupling takes place for example by a precise three-point bearing 13a . 13b . 13c ,

The sensor is maintained for example by a pneumatically or by an electrically operated lock 14 , in the 2 as a hook 15 is trained. The hook 15 reaches behind a counterpart 16 and pull the probe 7 in the camps 17a . 17b . 17c , with balls 18a . 18b . 18c , The lock 14 can be designed as a pneumatically or electrically operated latch. An actuator system of locking 14 is in the intermediate piece 10 arranged. About this mechanical interface 13a . 13b . 13c become sensors, like the probe 7 reproducibly changed. An electrical or optical contact occurs when replacing the probe 7 automatically via corresponding interfaces 19 ,

The intermediate piece 10 is again via a deflectable mechanical interface 11a . 11b . 11c For example, a three-point bearing with the quill 6 connected. By the power of springs 20a . 20b . 20c be balls 21a . 21b . 21c in stock 22a . 22b . 22c pressed. In case of a collision of the probe 7 , for example with a workpiece, lifts the interface 11a . 11b . 11c and prevents excessive force on the probe 7 and the quill 6 ,

The holding force can be selected by selecting appropriate springs 20a . 20b . 20c to adjust. After retracting from the collision, the deflected interfaces return 11a . 11b . 11c back to their original position. Corresponding sensors 12a . 12b . 12c For example, switches detect the location of the mechanical interfaces 11a . 11b . 11c and, in the event of deflection, provide a signal to a controller (not shown). The control device then triggers an emergency stop of the coordinate measuring machine. After retracting from the collision, the sensors report 12a . 12b . 12c whether the interfaces 11a . 11b . 11c have returned to their seat.

The emergency stop signal also enables the mechanical interface 14 , with the probe 7 in his seat 13a . 13b . 13c is held, slightly relieve. This reduces the force on the probe 7 , He remains over the hook 15 in the interface 13a . 13b . 13c hang.

The in 2 shown probe 7 is thus over two interfaces 13a . 13b . 13c such as 11a . 11b . 11c at the quill 6 deflectably mounted, so that in case of a collision a double protection for the probe 7 consists.

As already stated, the bearings are 11a . 11b . 11c . 13a . 13b . 13c about three-point bearings, which are arranged rotationally symmetrically in bearing plates. The same applies to the springs 20a . 20b . 20c of which advantageously also at least three springs are provided arranged rotationally symmetrical to the quill.

A sensor 19 measures the correct position of the probe 7

3 shows a further embodiment in which the same parts are provided with the same reference numerals.

At the quill 6 is again an intermediate piece 10 arranged, which via the mechanical interface 11a . 11b ( 11c not shown) in the event of a collision detachable at the quill 6 is arranged. At the intermediate piece 10 is the probe 7 via a dovetail guide shown only schematically 23 replaceable fastened. That means the probe 7 can be exchanged for another sensor. the interface 23 in the manner of a dovetail guide is not deflected in the event of a collision.

At the probe 7 is a stylus 8th replaceable fastened. The stylus 8th carries the feeler ball 9 , The stylus 8th is with a base plate 24 , on the balls 25a . 25b . 25c are arranged in warehouses 26a . 26b . 26c arranged. The holding force is by means of a hook 27 on which a force is above the spring 28 in the direction of arrow A, pulled upwards. This will be a catch 29 who is at the base plate 24 is fixed, pulled in the direction of arrow A and the base plate 24 with the stylus 8th and the bearing balls 25a . 25b . 25c becomes reproducible in the bearings 26a . 26b . 26c drawn.

In the event of a collision, that is, when the stylus 8th collides with a workpiece, the stylus 8th with the base plate 24 from the camps 26a . 26b . 26c be deflected. A control device (not shown) detects via sensors (also not shown) that a deflection of the bearings 26a . 26b . 26c has taken place and causes an emergency stop the coordinate measuring machine 1 , If the deflection is too large or the probe 7 itself can collide with an obstacle, the probe can 7 with the intermediate piece 10 from storage 11a . 11b . 11c , as in 2 described, also be deflected.

The holding forces of the springs 20a . 20b . 20c and 28 are advantageously set such that the first of the stylus 8th from storage 25a . 25b . 25c . 26a . 26b . 26c is deflected and then the probe 7 with the intermediate piece 10 from storage 11a . 11b . 11c ,

After retracting from the collision, the deflected interfaces return 11a . 11b . 11c . 25a . 25b . 25c . 26a . 26b . 26c automatically return to its original position. Corresponding sensors or switches can be the location of the mechanical interfaces 11a . 11b . 25a . 25b . 26a . 26b detect.

4 shows an example of a three-point bearing with bearings 17a . 17b . 17c , Camps 17a . 17b . 17c can each consist of two cylindrical pins 30 consist. There is also the possibility that only contact surfaces are provided. Put the balls 25a . 25b . 25c to the cylinders 30 or V-bearing, there are exactly two bearing points in each bearing, so that a reproducible storage is available.

In 4 is beyond the hook 14 shown.

Warehousing 11a . 11b . 11c is rotationally symmetrical to the quill in the same shape 6 built up.

5 shows a housing 31 in which the storage 22a . 22b . 22c for the intermediate piece 10 (not shown) is arranged. In the case 31 is a bearing flange 32 arranged, in turn, the bearings 22a . 22b . 22c with the cylinders 30 are arranged. The housing 31 as well as the bearing flange 32 have a recess 33 for receiving the intermediate piece 10 (not shown on).

LIST OF REFERENCE NUMBERS

1

coordinate measuring machine

2

measuring table

3

portal

4

traverse

5

carriage

6

Pinole

7

probe

8th

feeler

9

probe ball

10

connecting piece

11a

mechanical deflection device

11b

mechanical deflection device

11c

mechanical deflection device

12a

sensor

12b

sensor

12c

sensor

13a

Three-point mounting

13b

Three-point mounting

13c

Three-point mounting

14

lock

15

hook

16

counterpart

17a

camp

17b

camp

17c

camp

18a

Bullet

18b

Bullet

18c

Bullet

19

sensor

20a

feather

20b

feather

20c

feather

21a

Bullet

21b

Bullet

21c

Bullet

22a

camp

22b

camp

22c

camp

23

dovetail guide

24

baseplate

25a

Bullet

25b

Bullet

26

Lagerflansch

26a

camp

26b

camp

26c

camp

27

hook

28

feather

29

hook

30

Cylinder / abutment surfaces

31

casing

32

Lagerflansch

33

Recess for intermediate piece 10

A

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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 10030570 A1 [0002]

Claims (14)

Coordinate measuring machine with a quill and a stylus arranged on the quill, characterized in that - between the probe ( 7 ) and the quill ( 6 ) an intermediate piece ( 10 ) is arranged, that the intermediate piece ( 10 ) of the quill ( 6 ) is detachably formed in the event of a collision, and - that the probe ( 7 ) at the intermediate piece ( 10 ) Is arranged detachably in the event of a collision. Coordinate measuring machine with a quill and a stylus arranged on the quill, characterized in that - between the probe ( 7 ) and the quill ( 6 ) an intermediate piece ( 10 ) is arranged, that the intermediate piece ( 10 ) of the quill ( 6 ) is detachably formed in the event of a collision, and - that a stylus ( 8th ) or a stylus combination in the event of a collision detachable on the probe ( 7 ) is arranged. Coordinate measuring machine according to claim 1 or 2, characterized in that between the quill ( 6 ) and the intermediate piece ( 10 ) a precision bearing which can be detached in the event of a collision ( 11a . 11b . 11c ) is provided. Coordinate measuring machine according to one of claims 1 to 3, characterized in that at least one device ( 20a . 20b . 20c ) is provided, with a return of the intermediate piece ( 10 ) is feasible in a measurement position. Coordinate measuring machine according to claim 4, characterized in that the device ( 20a . 20b . 20c ) is formed as at least one spring and / or a hook. Coordinate measuring machine according to one of the preceding claims, characterized in that a deflection force of the intermediate piece ( 10 ) is adjustable. Coordinate measuring machine according to one of the preceding claims, characterized in that at least one sensor ( 12a . 12b . 12c ) for detecting the position of the intermediate piece ( 10 ) is provided. Coordinate measuring machine according to one of the preceding claims, characterized in that the coordinate measuring machine ( 1 ) has a control device, and that the control device as a in deflection of the intermediate piece ( 10 ) is formed from a measurement position a signal receiving control device. Coordinate measuring machine according to one of the preceding claims, characterized in that the control device is formed in the event of collision detection as a triggering an emergency stop control device. Coordinate measuring machine according to one of the preceding claims, characterized in that at least one device for loosening the sensor interface ( 11a . 11b . 11c ) is provided. Coordinate measuring machine according to claim 3, characterized in that the precision bearing ( 11a . 11b . 11c . 13a . 13b . 13c ) is designed as a three-point bearing. Coordinate measuring machine according to one of the preceding claims, characterized in that the probe head ( 7 ) as an optical and / or switching and / or measuring probe ( 7 ) is trained. Coordinate measuring machine according to one of the preceding claims, characterized in that the probe head ( 7 ) with a motor-adjustable rotary-swivel and / or displacement unit as an optical and / or switching and / or measuring probe ( 7 ) is trained. Coordinate measuring machine according to one of the preceding claims, characterized in that a holding force of the stylus ( 8th ) is formed smaller than a holding force of the probe ( 7 ) at the intermediate piece ( 10 ) or a holding force of the intermediate piece ( 10 ) at the quill ( 6 ).

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