DE3623189C2 - - Google Patents

Description

The invention relates to a holding device with a Device platform for holding at least one metrological Axially in front of a cylindrical test specimen bore with at least approximately horizontal bore axis, for piercing measurements on the line of the Test specimen bore.

Such holding devices are used to carry out Roughness measurements using probe cutters on the cylinder running surfaces used by crankcases. The crankcase are preferably in a position for this, in which the axes of the cylinder bores are roughly horizontal are aligned. The holding devices used so far have a device platform and a bracket on which the device platform swivels and in their respective pivot position is locked. The device platform can be attached using the bracket a threaded hole for the cylinder head on the front Bolted crankcase and parallel to another  axis pivoted to the axis of the cylinder bore will. Because of these two adjustment options it is possible to narrow the location of the device platform to the conditions required for the respective measuring device adapt.

In the case of roughness measurement, the device platform serves as Support surface for a feed device, which is a telescopic extendable probe tip along a generatrix of the Cylinder bore moved. For this the device shape is like this align that they are in the tangential plane of the lowest bore line. With a previously used Holding device requires the alignment of the Device platform in the desired manner relatively large amount of time and some manual skill. So to carry out a roughness measurement on everyone Cylinder bores of a crank device the workflow screwing on the bracket, aligning the Device platform and unscrewing the bracket for every single hole must be repeated. It is also an application this holder for different crankcases with different bore diameters only conditionally possible.

The invention has for its object the handling a holding device with a device platform for metrological Simplify equipment and workflow from the attachment of the holding device to the bore housing, about the orientation of the device platform, right down to  to simplify the disassembly of the holding device and shorten in time. In addition, the holding device also universal for drilling different Bore diameter can be used without attaching the holding device for the presence of threaded holes or other movements in the area around the borehole to be instructed.

According to the invention, this object is achieved by the characterizing Features of the main claim solved. The support body the holding device is at least approximately in the horizontal bore axis aligned cylindrical Bore used, the connecting edge of the device platform also aligned approximately horizontally should be. Through the adjustment element is the one with the device platform rigidly connected storage console in their respective Swiveling position in relation to the support body can be determined, which is due to gravity the weight of the device platform of the support body supports the reveal. The support is provided here by means of a multi-point support in statically determined Way, for which at least three partly symmetrical Plane of symmetry of the support body and other part in the direction the longitudinal extension of the support body offset from one another support points arranged on the support body are present have to be. With the help of the adjustment element, the device platform can also according to the position of the bore axis in an at least approximately horizontal position to be brought. An alignment of the device platform  exactly in the tangential plane of the lowest generatrix of the The cylinder bore can be positioned accordingly the pivot axis can be achieved on the support body.

Tilted when inserting the holder at an angle the support body after settling due to the influence of gravity on the reveal and holds the holding device easily stuck in the reveal. About the The device platform can be adjusted quickly be aligned, with the holding device due of the swiveling support body also for different large holes can be used. Special mounting arrangements in the area around the hole - such as Tapped holes - are not required for this.

Appropriate embodiments of the invention can be described in the subclaims be removed. Otherwise, the following is the invention with reference to one shown in the drawings Embodiment explained in more detail. Here demonstrate

Fig. 1 a holding device in side view with inserted in a cylindrical bore support body,

Fig. 2 shows the holding device of Fig. 1 with the support body inserted into a bore of larger diameter and

Fig. 3 is a perspective view of a holding device.

A holding device 1 shown in Fig. 1 comprises a device platform 2, a bearing bracket 3, serving as an adjusting member adjusting screw 4 and a supporting body 6 used in a cylindrical bore 5, which is mounted about a pivot axis 7 pivotally to the bearing bracket 3. Support points 8 , 9 , with which the support body 6 is supported in the cylindrical specimen bore at its reveal, are designed as hemispherical rubber feet 8 , 9 . The rubber foot 9 can be adjusted in height by means of a threaded bolt 10 fastened to it and rotatable into or out of the support body 6 . The adjusting screw 4 is movably mounted on the bearing bracket 3 and on the support body 6 , an intermediate washer 11 having a dome-shaped design being arranged between the adjusting screw 4 and the bearing bracket 3 , and the adjusting screw 4 on the supporting body 6 engages in a threaded hole provided centrally on a thru axle 12 by correspondingly turning the adjusting screw 4 to pivot the support body 6 in the desired direction. For this purpose, the plug-in axle 12 is rotatably mounted with its end regions on the support body 6 . The bearing bracket 3 is provided with stop faces 13 which rest on the end face of the specimen bore 5 . In Fig. 1, the bearing surface of the device platform 2 is in the tangential plane of the lowest bore surface line 14 . By arranging the rubber feet 8 and 9 on the support body 6 according to the manner shown in FIG. 1 - that is, a rubber foot 9 on the end facing away from the device platform 2 in the apex line of the support body 6 and two rubber feet 8 on the end facing the device platform 2 , at the same height and in the lower region of the support body 6 - a secure and stable support of the support body 6 in the test specimen bore 5 can be achieved. Due to the height-adjustable rubber foot 9 , in addition to the adjusting screw 4, there is a further adjustment possibility for aligning the device platform 2 in the desired manner. Due to the design of the support points 8 , 9 as rubber feet 8 , 9 , the holding device 1 can also be used in bores which are not ideally aligned horizontally, but rather are inclined with respect to the horizontal. The rubber feet 8 and 9 are supported in a punctiform manner on the line of the test specimen bore 5 , the rubber having a high coefficient of friction ensuring good adhesion and slip resistance and thus a secure hold of the holding device 1 in the test specimen bore 5 . Comparably good results would also be achieved with support points 8 , 9 , which would be covered with a material with a high coefficient of friction. With the help of the movably mounted adjusting screw 4 , the support body 6 can be pivoted relatively sensitively and quickly about the pivot axis 7 and fixed in its respective pivot position. In order to facilitate insertion of the holding device 1 exactly in the axial direction of the test specimen bore 5 and to limit the insertion depth of the holding device 1 within the test specimen bore 5 , the bearing bracket 3 is provided with the abutment surfaces 13 which rest in the edge area of the test specimen bore 5 on the front face of the housing.

FIG. 2 shows a housing with a test specimen bore 5 , which has a larger diameter than that shown in FIG. 1. The support body 6 of the holding device 1 is supported with the rubber feet 8 and 9 on the reveal of the test specimen bore 5 , with a steeper pivot position with respect to the bore axis. In this case, too, the contact surface of the device platform 2 lies in the tangential plane of the lowest bore surface line 14 . In order to ensure that the support surface of the device platform 2 can be pivoted at least approximately into the tangential plane of this lowermost bore surface line 14 regardless of the bore diameter, the pivot axis 7 for mounting the support body 6 should be placed between the rubber feet 8 and 9 and in this case closer to the rubber feet 8 . Likewise, the pivot axis 7 should be above the plane spanned by the rubber feet 8 and 9 .

In order to achieve an alignment of the device platform as precisely as possible in the tangential plane of the lowest bore surface line 14 , the pivot axis 7 should be approximately 10 to 25% of the distance, measured between the projection of the support points 8 , 9 , which are offset with respect to one another in the direction of the longitudinal extension of the support body 6 , on the The plane of symmetry of the support body 6 is located away from the support points 8 arranged on the end of the support body 6 facing the device platform 2 . Likewise, the pivot axis 7 should be about 4 to 10% of the distance measured in the same way between the rubber feet 8 and 9 above the plane spanned by them. The exact position of the pivot axis 7 on the support body 6 to achieve an alignment of the device platform support surface exactly in the tangential plane of the lowest bore surface line 14 can be calculated according to known trigonometric formulas and is particularly dependent on the design of the support body 6 and the desired bore diameter range , within which the holding device 1 is to be used.

Fig. 3 shows a perspective view of the device platform 2 , the bearing bracket 3 with the connection surfaces 13 , the support body 6 , the rubber feet 8 and the rubber feet 9 designed as a tandem support point, the adjusting screw 4 , the plug axis 12 , the pivot axis 7 and beyond the device platform connecting edge 15 , the display scale 16 and the line marking 17th

As can be seen from this view, the support body 6 is designed as a slotted hollow cylinder and is provided with a slot opening below between the pair of rubber feet 8 . In this way, for example, a probe tip which can be telescopically extended from a feed device can be moved freely along a bore surface line of the test specimen bore 5 . The area of the lower bore surface lines remains freely accessible. The support body can be formed from a slotted, obliquely cut tube in a simple and inexpensive manner. It would also be conceivable to obtain this desired support body shape by rolling up a triangular sheet metal part.

The configuration of the support point 9 at the free end of the support body 6 as a tandem point 9 , i.e. by the arrangement of two closely spaced rubber feet 9 on the support body 6 , makes it possible to achieve a particularly secure and stable support of the holding device 1 in the reveal of the test specimen bore 5 .

The support body 6 is provided with a display scale 16 and the bearing bracket 3 with a line marking 17 , with the aid of which, with appropriate adjustment, a particularly rapid alignment of the device platform 2 can be achieved in the desired manner. It would thus be possible to indicate on the display scale 16 the bore diameter range applicable to the holding device 1 and to use the adjusting screw 4 to set the inclination of the device platform 2 relative to the support body 6 for the respective bore diameter solely via the display scale 16 and the line marking 17 . In the case of a display scale 16 with an adjusted line marking 17 , this setting could also be made before the holding device 1 is inserted into the test specimen bore 5 .

Claims (16)

1. Holding device with a device platform for holding at least one measuring device axially in front of a cylindrical test specimen bore with at least approximately horizontal bore axis for carrying out measurements on the reveal of the test specimen bore, characterized in that the holding device ( 1 ) has a bearing bracket ( 3 ) which is outside the test specimen bore ( 5 ) is rigidly connected to the device platform and carries a support body ( 6 ) within the test specimen bore ( 5 ), the support body ( 6 ) being pivotable about a pivot axis ( 7 ) lying parallel to the connecting edge ( 15 ) of the device platform ( 2 ) is mounted on the bearing bracket ( 3 ) in such a way that the support body ( 6 ) can be swiveled and can be locked in its respective swivel position by means of a movable adjusting member ( 4 ) which engages with it on its pivot axis ( 7 ) from the bearing bracket ( 3 ) the support body ( 6 ) under the influence of gravity on the holding device Seal ( 1 ) in the test specimen bore ( 5 ) at its reveal by means of a statically determined multi-point support with at least three support points ( 8 , 9 ), which on the one hand symmetrical to the axis of symmetry of the support body ( 6 ) and on the other hand in the direction of the longitudinal extension of the support body ( 6 ) are arranged offset from one another on the support body ( 6 ). 2. Holding device according to claim 1, characterized in that at least one support point ( 9 ) on the device platform ( 2 ) facing away from the end of the support body ( 6 ) is arranged, this support point ( 9 ) in the inserted state of the holding device ( 1 ) is supported in the test specimen bore ( 5 ) in the area of the upper surface line of the test specimen bore ( 5 ) and that two further support points ( 8 ) are arranged on the end of the support body ( 6 ) facing the device platform ( 2 ), these support points ( 8 ) both in a plane perpendicular to the axis of symmetry of the support body ( 6 ) and at the same distance from this plane of symmetry on two opposite surface lines in the lower region of the support body ( 6 ). 3. Holding device according to claim 2, characterized in that the on the device platform ( 2 ) facing away from the upper end of the support body ( 6 ) arranged support point ( 9 ) as a tandem point ( 9 ) with two symmetrical to the plane of symmetry of the support body ( 6 ) lying adjacent Individual points ( 9 ) is formed. 4. Holding device according to claim 2 or 3, characterized in that the distance of the on the device platform ( 2 ) facing away from the support body ( 6 ) arranged support point ( 9 ) with respect to the support body ( 6 ) is adjustable. 5. Holding device according to one of the preceding claims, characterized in that the support points ( 8 , 9 ) are coated with a material having a high coefficient of friction or are formed from such a material. 6. Holding device according to one of claims 1 to 5, characterized in that the support points ( 8 , 9 ) by the support body ( 6 ) attachable and at least in the contact area spherically shaped feet ( 8 , 9 ) are formed. 7. Holding device according to one of the preceding claims, characterized in that the support body ( 6 ) is designed as a slotted hollow cylinder and can be inserted with the slot opening down into the test specimen bore ( 5 ). 8. Holding device according to claim 7, characterized in that the support body ( 6 ) is formed by a slotted, obliquely cut piece of pipe. 9. Holding device according to one of the preceding claims, characterized in that the bearing bracket ( 3 ) or the device platform ( 2 ) on its end face of the test specimen bore ( 5 ) facing surface has at least two attachment points or attachment surfaces ( 13 ), which in the inserted state Hold the holding device ( 1 ) in the test specimen bore ( 5 ) on both sides of the vertical plane of symmetry of the device platform ( 2 ) at the edge area of the test specimen bore ( 5 ). 10. Holding device according to one of claims 2 to 9, characterized in that the pivot axis ( 7 ) for mounting the support body ( 6 ) between the in the direction of the longitudinal extension of the support body ( 6 ) staggered support points ( 8 , 9 ) is arranged. 11. Holding device according to claim 10, characterized in that the pivot axis ( 7 ) is in the vicinity of the support points ( 8 ) which are arranged on the end of the support body ( 6 ) facing the device platform ( 2 ). 12. Holding device according to claim 10 or 11, characterized in that the pivot axis ( 7 ) about 10 to 25% of the distance, measured between the projection of the support points ( 8 , 9 ) arranged offset to one another in the direction of the longitudinal extension of the support body ( 6 ) the plane of symmetry of the support body ( 6 ) is located away from the support points ( 8 ) arranged on the end of the support body ( 6 ) facing the device platform ( 2 ). 13. Holding device according to one of claims 2 to 12, characterized in that the pivot axis ( 7 ) of the support body ( 6 ) lies above the plane spanned by the support points ( 8 , 9 ). 14. Holding device according to claim 13, characterized in that the pivot axis ( 7 ) about four to ten% of the distance, measured between the projection of the support points ( 8 , 9 ) arranged offset to one another in the direction of the longitudinal extent of the support body ( 6 ) on the plane of symmetry of the support body ( 6 ), lies above the plane spanned by the support points ( 8 , 9 ). 15. Holding device according to one of the preceding claims, characterized in that the adjusting member ( 4 ) is designed as a movable, from the bearing bracket ( 3 ) on the support body ( 6 ) pivotally engaging adjusting screw ( 4 ). 16. Holding device according to one of the preceding claims, characterized in that the bearing bracket ( 3 ) or the support body ( 6 ) with a display scale ( 16 ) and the other part are provided with a next to the display scale ( 16 ) arranged marking ( 17 ) .