DE4300026A1 - Sensing head for coordinate measurement device - Google Patents

Abstract

The sensing head has a spatial spring system which carries a sensing pin (3) displaceable parallel wrt. itself in all three spatial directions. The spatial displacement of the sensing ball (4) is measured by sensors. The sensing pin is mounted on three corrugated tube springs (5) or similar torsionally stiff and elastically displaceable elements, whose axes do not lie in one plane. The axes of the springs lie on the surface of a cone and symmetrical to the axis of the cone.

Description

The invention relates to a probe for coordinate measuring machines for spatial probing of workpieces to be measured (3D Probe).

Known measuring 3D probes are usually designed that for the three spatial directions of the machine coordinate system Guides are provided that a parallel displacement of the Stylus and the probe ball attached to it in one Realize coordinate direction and which sensors for each Measurement of the deflection are assigned in the push button coordinates. In particular, three are orthogonal as guides series-connected straight guides used for Ensuring smooth and play-free movement preferably be executed as spring parallelograms (Parallel spring guides).

A major advantage of such a button design is that the probe coordinate system with great accuracy after the Machine coordinate system is oriented and the displacements additively overlap from three individual displacement paths.

The disadvantage of these arrangements is that they consist of many elements are composed, require a large space and one have considerable mass. In addition, the overall error, e.g. B. by three times the circular arc Parallel spring guides and their series connection, great his.

Buttons are also known in which two of the spatial Degrees of freedom as swivel movements using two crossed Pivot bearing in the sense of a cardan joint, preferably as friction-free leaf spring or cross spring joints, are executed. The disadvantage of these arrangements is that the spatial movement of the probe ball takes place on arcs, and that the translation of the button depending on the shape and the length of the stylus changes. In addition, the deflection  the probe ball in the direction of the center of the universal joint with special needs. These solutions also include a design according to DE-OS 32 15 878, in which the stylus is down, in the Z direction hanging, attached to a corrugated pipe. The disadvantages from the Swiveling of the stylus remains. The stylus but can be moved in the Z direction.

The object of the invention is a stylus with a few Elements without friction and play in the three spatial directions to run a coordinate measuring machine parallel to itself.

According to the invention the object is achieved in that the Stylus on three corrugated tube springs or similar torsionally stiff and otherwise elastically deflectable elements whose axes are not in one level is attached.

In such an arrangement, the stylus cannot be twisted or panned, only parallel to itself or in the Axis directions are shifted. Using only three Elements are the movement options of the button on three translational degrees of freedom restricted.

The corrugated tube springs can be arranged orthogonally to one another. In a preferred embodiment, the axes of the Corrugated tube springs on the surface of a cone, symmetrical to the Cone axis, which can also be the axis of the probe.

An optical system can be arranged in the cone axis. Usual interchangeability or design of the stylus provided it is possible to use the workpiece or a Touch the adjustment element optically in the Z axis.

The corrugated tube springs are preferably with a pressure medium filled and to a system for adjusting the internal pressure connected. By changing the pressure in the corrugated tube springs the button, for example after changing the Stylus with different weights, in a simple way be adjusted.  

The corrugated tube springs can be used together or separately depending of the difference between the actual and target position and the Temperature can be controlled. You can also use a hydraulic pressure medium can be damped vibrations.

In other preferred versions, each corrugated tube spring assigned a corrugated pipe, both of them via the pressure medium are interconnected. With each push of a button changes with the length also the enclosed volume of the corrugated pipes. This results in several possible uses.

The corrugated pipes can be used in a simple way to measure the Length change can be assigned. From the three ways, the Button position can be calculated. Due to the spatial separation of the Sensors and the probe can be made very small become.

Corrugated tube and associated corrugated tube spring can each refer to the enclosed pressure medium is a closed system form, which is one in the execution options closer explained mechanical adjustment results. Besides, can in such an embodiment the ductility of a corrugated pipe and thus the translational degree of freedom of the connected Corrugated tube spring can be locked in the direction of their axis. It a 2D button is created.

The invention is illustrated below using some exemplary embodiments explained in more detail. Show in the drawings

Fig. 1 shows a button according to the invention with orthogonally arranged corrugated tube springs,

Fig. 2 shows a probe according to the invention with bellows springs, the axes of which lie on a conical surface and symmetrical about the Z-axis of the sensor are distributed,

Fig. 3 shows a hydraulic circuit for connecting the bellows springs,

Fig. 4 shows a button according to Fig. 2 and an optical measuring system assigned to it.

In a first embodiment ( FIG. 1), three corrugated tube springs 5 are attached to a housing 1 . Their axes are orthogonal to each other in the X, Y, Z coordinate system of the measuring device. At the intersection of the axes, the base body 2 of a stylus 3 is connected to the corrugated tubes 5 . The stylus 3 carries a stylus ball 4 at its tip.

Each corrugated tube spring 5 can be compressed or pulled apart along its axis. Otherwise, the corrugated tube springs 5 are torsionally rigid. This means that the base body 2 can only be displaced in the direction of the X, Y, Z coordinates and cannot be rotated about one of these axes. The stylus 3 can thus only be moved parallel to itself or in its axial direction. The deflection of the probe ball 4 during probing is therefore a geometric sum of the displacement in the coordinate directions.

In Fig. 2, the axes of the three corrugated tube springs 5 lie on a conical jacket and intersect in the tip. They are distributed symmetrically around the axis of the stylus 3 , which also forms the cone axis. In the top view, two corrugated pipe axes enclose an angle of 120 °. Three stops 8 and 9 are arranged between the housing 1 and the base body 2 . They protect the button against impermissible loads. The elements 8 and 9 could also be inductive, capacitive or optical position sensors. Such position transducers would have to have a greater radial play than usual. In the embodiment according to FIG. 2, the path is measured in a different way.

In an extension of the corrugated tube springs 5 , three corrugated tubes 6 are fastened on the other side of the housing 1 . Corrugated tube 6 and corrugated tube spring 5 are filled with hydraulic oil, with no connection to the outside. The movements of the probe ball 4 lead to changes in the length of the corrugated tube 6 and can be detected with a displacement sensor 7 . The path of the probe ball 4 can be mathematically clearly calculated from the measured paths of the three corrugated tubes 6 .

With a mechanical adjusting device 15 , not shown, a force can be applied to each corrugated tube 6 via a spring 16 . The corrugated tube 6 is preloaded and an internal pressure in the closed hydraulic system - corrugated tube spring 5 and corrugated tube 6 - is thereby set. The position of the probe ball in the room can be adjusted by changing the force. A regulated electric actuator can be connected to the adjustment device, so that, for example, automatic adjustment of the button position when changing the stylus or / and depending on temperature changes is possible.

In Fig. 3, the corrugated tube springs 5 are connected or connectable via three-way cocks 11 on the one hand to the ring line 17 and on the other hand to a hydraulic system 12 , which has been shown simply as a vessel. In the situation shown, the corrugated tubes 5 are connected to the system 12 . The stylus can move, as previously described.

If you turn one of the three-way cocks 11 so that there is no hydraulic connection of the associated corrugated pipe 5 to the outside, ie the corrugated pipe 5 is neither connected to the ring line 17 nor to the system 12 , the base body 2 can be in the axial direction of the blocked corrugated pipe 5 can no longer be moved. The 3D button becomes a 2D button. Is z. B. in Fig. 1 the corrugated tube 5 lying in the Z direction, the base body 2 can only move in the X and Y directions.

When the corrugated pipes 5 are connected to the system 12 , the internal pressure in all three corrugated pipes can be changed simultaneously or individually, depending on the equipment of this system. The setting options that this gives have already been mentioned.

In Fig. 4 the corrugated tube springs 5 are arranged as in Fig. 2. The conical arrangement offers the possibility of arranging an optical measuring system 13 in the cone axis. For optical probing, the stylus 3 can be removed or swiveled to the side. The two base bodies 2 and 14 have corresponding centerings, so that a very precise adjustment of the optical axis and zero position of the probe ball is possible.

Claims (10)

1. Probe for coordinate measuring machines with a spatial spring system that carries a stylus that can be moved parallel to itself in all three spatial directions and sensors for recording the spatial displacement of the probe ball, characterized in that the stylus ( 3 ) on three corrugated tube springs ( 5 ) or similar torsionally rigid and otherwise elastically deflectable elements, whose axes are not in one plane, is attached. 2. Probe according to claim 1, characterized in that the axes of the corrugated tube springs ( 5 ) on the surface of a cone, symmetrical to the cone axis. 3. Probe according to claim 2, characterized in that an optical measuring system ( 13 ) is arranged in the cone axis. 4. Probe according to claim 1, characterized in that the corrugated tube springs ( 5 ) filled with a pressure medium ( 10 ) and connected to a system for adjusting the internal pressure and / or for vibration damping. 5. Probe according to claim 4, characterized in that the corrugated tube springs ( 5 ) is connected to a pressure medium system with an adjustability of the pressure depending on the difference between the actual and zero position of the probe ball and / or the temperature. 6. Probe according to claim 4, characterized in that each corrugated tube spring ( 5 ) is assigned a corrugated tube ( 6 ) or a similarly elastic, stretchable working cylinder, and the corrugated tube springs ( 5 ) with their associated corrugated tubes ( 6 ) are connected to each other via the pressure medium are. 7. Probe according to claim 4 and 6, characterized in that the corrugated tubes ( 6 ) via three-way cocks ( 11 ) and connected lines with each other and / and with a pressure medium system ( 12 ) can be connected. 8. Probe according to claim 6, characterized in that each corrugated tube spring ( 5 ) with the associated corrugated tube ( 6 ) form a closed system with respect to the pressure medium enclosed by both and each corrugated tube ( 6 ) via a spring ( 16 ) a mechanical adjusting device assigned to change its volume. 9. Probe according to claim 7, characterized in that with the mechanical adjustment device is an electric one Actuator is connected. 10. Probe according to claim 6, characterized in that each corrugated tube ( 6 ) is assigned a displacement sensor ( 7 ).