DE3722254A1 - CENTERING AND ALIGNMENT DEVICE FOR BORE MEASURING DEVICES - Google Patents

Abstract

It is the state of the art to make use for the purpose of avoiding centring errors and alignment or tilting errors of additional or integral devices on bore meters whose mode of operation corresponds to static methods which are based on different geometrical considerations. The disadvantage of these devices, which have to be sunk into the bores to be measured together with the assigned meter, is their poor suitability for measuring deep bore holes, since the control of centring and alignment is more difficult at depths. The object of the invention is therefore the improvement of the measurement of deep bore holes without centring and alignment errors. This object is achieved by means of a device which is distinguished by a meter carrier (18) which is pivoted to a retaining rod (10) in the manner of a universal joint and has two elements (24) which automatically expand radially outwards and are at the distance (b) of the bore axis. The advantage of this solution is that because the retaining rod can be of any length it is possible for the carrier of the bore meter to be brought, if necessary, up to the rear and (situated at depth) of a deep bore hole. On the way there, the two elements of the meter carrier automatically ensure, irrespective of the position of the rod on the meter carrier, that the measuring axis of the meter is centred and aligned and remains so if the error in cylindricity of the bore to be measured is not too large. <IMAGE>

Description

The invention relates to a centering and aligning device for bore measuring devices with a measurement axis to be arranged along a bore diameter in a measurement plane and perpendicular to the bore axis. - Centering is the search for the center of an ideally circular bore cut with a point on the measuring axis; Alignment is the cutting of the ideally straight bore axis with the measuring axis at a right angle. Centering and alignment errors result in measurement errors that also occur in the case of disturbances in the bore cylindricity.

There are various devices on bore gauges known, which allow centering errors and Alignment or tilting errors negligibly small hold. The operation of these devices mostly corresponds to static procedures based on different geometric considerations.

A disadvantage of the known devices is that them because they have additional or even integral parts of the bore gauges and with them in the Holes must be sunk to measure so-called deep holes (length in comparison to the diameter) are less suitable because of the depth control of centering and alignment is more difficult.

The invention is therefore based on the object Measuring deep holes without centering and Improve alignment errors.

This object is achieved by a Centering and alignment device for bore gauges, which is characterized by a gimbal on a holding bar  articulated device carrier with two radially outwards automatically resilient elements in axial bore Distance from each other.

Since the holding bar can be of any length, the Carrier of the bore gauge, if necessary, to Bring the rear end of a deep hole, the two elements of the device carrier on the way there regardless of the position of the rod on the tool carrier of even ensure that the measuring axis of the measuring device is and remains centered and aligned if the Cylindricity error of the bore to be measured is not allowed is great.

In preferred embodiments of the invention Centering and alignment device are the two elements of the device carrier is essentially the same, so that not just making the device easier than when the elements are different, but also a methodical measurement error is avoided.

In the preferred embodiments, each has Element of the device carrier three more or less point-like locations for touching the bore wall in a support plane parallel to the measuring plane. The three- Point support of the elements is outside the measuring plane particularly advantageous in the case of large cylindricity errors hole to be measured.

With one for the measurement of smaller bores (up to 80 mm) determined and more suitable first of the preferred embodiments is one in three Axial section planes of the slotted hollow body provided, which approximated in the area of the support plane circular cylindrical or annular, convex profiled Outer peripheral surface that forms three points of contact. A such element is relatively simple and accurate manufacture and allows the attachment of a sliding block  on a hollow third, which in the train one Bullet barrel sunk and guided by this can.

In the first embodiment, the hollow body profiled S-shaped outside, its concave section rooted and its convex section is free, which in the support plane has the largest outside diameter, so that despite the large spring range, the three-part Outer peripheral surface of the hollow body with the bore wall always forms approximately the same contact angle.

In the first embodiment, the free ones Sections of the two hollow bodies closer to the holding rod their rooted sections, so that the detention and Sliding friction of the hollow body on the bore wall is considerably smaller than with the reverse arrangement.

For measuring larger bores (from 80 mm) certain and more appropriate second of the preferred Each element of the device carrier has embodiments in three axial section planes each with a role linear circumference in an axial section plane, its more circular in the area of the support plane Section forms one of the three contact points; and is at least one role, preferably all three roles, with their point of contact radially resilient in the support plane stored on equipment carrier. Such an element can to offer relatively large travel, without special to be expensive.

In the second embodiment, the device carrier trained and forms as an extension of the support rod the axis of rotation of each roll of the same element the knee axis of a knee lever, the two arms of which Flanges of two flange sleeves are articulated, which are fixed or axially displaceable on the rod-shaped device carrier sit, with the movable flange sleeve axially sprung is. This element design makes the extension  the holding rod by a gimbal as I said articulated device carrier in rod form and is particularly easy.

In the second embodiment, the movable one Flange sleeve with its hollow cylindrical section Compression coil spring on the one hand on the flange supports this sleeve and on the other hand on an adjusting ring, which sits firmly on the rod-shaped device carrier, so that for the desired preload of each bore diameter Spring is adjustable.

In the second embodiment, the measuring device is on the arranged away from the holding rod end of the device carrier. This arrangement has the particular advantage that the deepest rearmost section of the measured Hole is still reached by the measuring device without the Measurement quality would be reduced. By reverse insertion of the device carrier into the hole from its rear end the front end is grasped up to the mouth.

The invention also relates to the use of Device according to the invention for a device for measuring in particular bombarded bullets of firearms such as rifles, the measurement both in the field and in the train of the Bullet run can take place, which is one of the deep-hole drilling in question, whose Length could be of the order of 10 m. It is it is also possible to maintain the constancy or progressiveness of the To determine the twist angle of the train of a bullet barrel.

The device according to the invention can also for Devices for measuring internal profiles such as internal gears or multi-spline profiles of otherwise circular cylindrical Holes are used.  

The invention is based on the two by the following Drawing preferred shown by way of example Embodiments of the centering and Alignment device explained in detail. It shows:

FIG. 1a is a radial side view of the first embodiment shown Right broken

Fig. 1b shows a cross section along the line II in Fig. 1a through the first embodiment and

Fig. 2 is a corresponding side view of the second embodiment shown broken off on the right, two rollers per element with the associated toggle levers being pivoted apart by 60 ° into the plane of the drawing.

In the first embodiment according to FIG. Hinged 1a on a cylindrical support rod (10) by means of a universal joint (12), the axis intersection is located (14) on the rod longitudinal axis (16), a circular-cylindrical on the whole device carrier (18), whose maximum outside diameter represents the minimum diameter ( d ) of the bore ( 3 ) to be measured. In the middle of the device carrier ( 18 ) has an annular groove ( 20 ) which receives a bore measuring device, whose measuring axis lies in the radial plane recognizable by its track ( MM ) and perpendicularly intersects the longitudinal axis ( 22 ) of the device carrier, which ideally cuts the rod -Longitudinal axis ( 16 ) continues and coincides with the axis of the bore ( 3 ). The annular groove ( 20 ) divides the device carrier ( 18 ) into two halves, namely into a front half connected to the holding rod and a rear half that is free. Each half of the device carrier ( 18 ) is fitted with an element ( 24 ) that automatically springs open radially outwards, the distance between the holes ( b ) of which is adapted to the length of the hole to be measured.

Each of the two essentially identical elements ( 24 ) of the device carrier ( 18 ) has three point-like locations ( 26 ) for contacting the bore wall in a support plane parallel to the measuring plane ( MM ) (cf. the drawing plane of FIG. 1b). The element ( 24 ) is a hollow body provided with a narrow slot ( 28 ) in three axial section planes of the device carrier ( 18 ), the outer circumferential surface ( 30 ) of which, in the area of the support plane, approximately forms the three contact points ( 26 ). The three slots ( 28 ) of each element ( 24 ) are evenly distributed on the outer peripheral surface ( 30 ), so that there is a mutual distance of 120 degrees. The slots ( 28 ) of one element ( 24 ) and the slots ( 28 ) of the other element ( 24 ) are rotated by 60 degrees with respect to one another, as illustrated in FIG. 1a.

Each of the third parts of the hollow element ( 24 ) is designed like a shell and has an S-shaped profile, its concave section being rooted and its convex section being free, which in the support plane at the locations ( 26 ) of the outer peripheral surface ( 30 ) has the largest outer diameter has, which corresponds to the diameter ( D ) of the maximum measurable bore ( 5 ) when the element ( 24 ) is fully flared. - In order to make the roots ( 32 ) of the third part of the hollow element ( 24 ) formed on the device carrier ( 18 ) sufficiently flexible, a radial bore ( 34 ) is provided at the end of each slot ( 28 ) near the root, the diameter of which is by far the slot width exceeds. - The holding rod ( 10 ) remote element ( 24 ) of the device carrier ( 18 ) is in the vicinity of its exposed outer peripheral surface ( 30 ) on a third part with a sliding block ( 36 ) which fits into the train of a projectile barrel, the field of which Outer peripheral surface ( 30 ) is touched.

The outer peripheral surface ( 30 ) having free sections of the two hollow elements ( 24 ) are closer to the holding rod ( 10 ) than its rooted sections, which precede the sinking of the device carrier ( 18 ) in a bore with the diameter d to D , while the Allow the free element sections with the contact points ( 26 ) to radially sink more or less into annular recesses ( 38 ) of the device carrier ( 18 ).

In the second embodiment as the carrier (118) of a Bohrungsmeßgerätes (107) is provided an extension of a holding rod, not shown, which is hinged by means of a universal joint, also not shown, with the device carrier (118).

Each element (124) of the device carrier (118) has, according to Fig. 2 in three Axialschnittebenen each thereof a roller (150) with a linear extent on in an axial section plane, which in the area of a support plane of the support plane of the other element (124) to has axial distance b , circular arc-shaped section forms one of three contact points ( 126 ), at each of which one of the three rollers ( 150 ) touches the wall of the bore to be measured with the diameter d to D.

All three rollers ( 150 ) of each element ( 124 ) of the device carrier ( 118 ) are resiliently mounted radially in the support plane on the device carrier with their contact points ( 126 ). For this purpose, the axis of rotation ( 152 ) of each roller ( 150 ) forms the knee axis of a toggle lever ( 154 ), the two arms of approximately the same length of which are articulated on the flanges of two flange sleeves ( 156 and 158 ), which are fixed or axially displaceable on the rod-shaped device carrier ( 118 ) sit, the movable flange sleeve ( 158 ) being axially sprung. For this purpose, the movable flange sleeve ( 158 ) carries with its hollow cylindrical section a compression coil spring ( 160 ), which is supported on the one hand on the flange of this sleeve and on the other hand on an adjusting ring ( 162 ) which is firmly seated on the device carrier ( 118 ), specifically on front end of the element ( 124 ). The arrangement of the two elements ( 124 ) is thus such that the flange sleeves ( 156 ) which are stuck on the device carrier ( 118 ) precede when they are sunk into the bore to be measured.

The measuring device ( 107 ) is arranged on the rear end of the device carrier ( 118 ), which is removed from the holding rod, and borders on the fixed flange sleeve ( 156 ) of the rear element ( 124 ), which is located on the left in FIG. 2 where the radial measuring plane ( MM ) can be recognized by their trace.

Claims (11)

1. Centering and alignment device for bore measuring devices with a along a bore diameter in a measuring plane ( MM ) and perpendicular to the bore axis ( 22 ) to be arranged measuring axis, characterized by a cardanically articulated on a holding rod ( 10 ) device carrier ( 18 ) with two radially outwards automatically spring elements ( 24 ) at an axial distance ( b ) from each other ( Fig. 1). 2. Device according to claim 1, characterized in that the two elements ( 24 ) of the device carrier ( 18 ) are substantially the same ( Fig. 1). 3. Device according to claim 1 or 2, characterized in that each element ( 24 ) of the device carrier ( 18 ) has three point-like points ( 26 ) for contacting the bore wall in a support plane parallel to the measuring plane ( MM ) ( Fig. 1). 4. Device according to claim 3, characterized in that as an element ( 24 ) in three axial sectional planes of the device carrier ( 18 ) slotted hollow body is provided, the approximately circular cylindrical or annular, convex profiled outer peripheral surface ( 30 ) in the region of the support plane, the three contact points ( 26 ) forms ( Fig. 1). 5. Device according to claim 4, characterized in that the hollow body ( 24 ) is profiled on the outside in an S-shape, its concave portion being rooted ( 32 ) and its convex portion being free, which has the largest outer diameter ( d to D ) in the support plane. has ( Fig. 1). 6. Device according to claim 5, characterized in that the free sections of the two hollow bodies ( 24 ) are closer to the holding rod ( 10 ) than their rooted ( 32 ) sections ( Fig. 1). 7. Device according to claim 3, characterized in that the element ( 124 ) of the device carrier ( 118 ) in three axial sectional planes thereof each have a roller ( 150 ) with a linear circumference in an axial sectional plane, the circular arc-shaped section in the region of the support plane one of the three contact points ( 126 ) forms; and that at least one roller ( 150 ), preferably all three rollers ( 150 ), with their point of contact ( 126 ) is mounted radially in the support plane on the device carrier ( 118 ) ( FIG. 2). 8. Device according to claim 7, characterized in that the device carrier ( 118 ) is designed as an extension of the holding rod and the axis of rotation ( 152 ) of each roller ( 150 ) of one and the same element ( 124 ) forms the knee axis of a toggle lever ( 154 ), the two arms ( .1, .2 ) are articulated on the flanges of two flange sleeves ( 156 and 158 ), which are seated firmly or axially displaceably on the rod-shaped device carrier ( 118 ), the movable flange sleeve ( 158 ) being axially spring-loaded ( Fig. 2). 9. Device according to claim 8, characterized in that the movable flange sleeve (158) with its hollow cylindrical portion (160), carries a compression coil spring on the one hand is supported on the flange of said sleeve (158) and on the other hand on a collar (162) which sits firmly on the rod-shaped device carrier ( 118 ) ( Fig. 2). 10. Device according to one of claims 1 to 9, characterized in that the measuring device ( 107 ) is to be arranged at the end of the device carrier ( 118 ) remote from the holding rod ( Fig. 2). 11. Use of the device according to one of the claims 1 to 10 for a device for measuring in particular fired projectile barrels of firearms.