RU2087850C1 - Device measuring linearity of axis of cylindrical holes - Google Patents

Abstract

FIELD: measurement technology, measurement of linearity (bending) of axis of cylindrical hole of long pipes of small diameter. SUBSTANCE: measurements are conducted from theoretical, i.e. ideally straight, axis of hole. Case of device is made with two self-centering supports placed at preset base distance. Each support is manufacture so that sets case of device precisely to center of hole in section where it is. In this case line connecting centers of self-centering supports is theoretical (ideal) axis of measured cylindrical hole. Converter installed in case measured deviation of actual axis of hole from ideal one. Device is also provided with telescopic handle. EFFECT: provision for accurate measurement of linearity of axis of cylindrical holes. 4 cl, 2 dwg

Description

 The invention relates to measuring technique and can be used to measure the straightness of the axis (bending) of a cylindrical bore of long pipes of small diameter, necessary in many areas of industrial production, in particular in the production of gun shafts, submersible pumps for oil and gas wells, etc.

 A device for measuring the straightness of the axis of the hole, containing two fixed supports located at a given distance, and at least one measuring transducer located between them. The reading of the converter determines the deviation from the straightness of the axis of the hole at a given distance (Tolerances and fittings. Handbook edited by Myagkova VD L. Mechanical Engineering, 1978, p. 388).

 A device is also known for measuring deviations from the straightness of cylindrical holes, comprising a housing with two radial bearings spaced along its length, a two-arm lever with a measuring tip located on one of its shoulders and in contact with the surface of the cylindrical hole, and an inductive transducer associated with the second arm of the lever (A.S. USSR N 15334291, class G 01 B 5/24, 1988).

 A disadvantage of the known devices is that the transducer readings do not determine the deviation from the straightness of the axis of the cylindrical hole, but the deviation from the straightness of its generatrix, which reduces the accuracy of the measurements.

 This invention solves the problem of increasing the accuracy of measuring the straightness of the axis of the cylindrical hole due to the fact that the measurements are made not from the generatrix of the surface of the cylindrical hole, but from the theoretical (ideal, i.e. straight) axis of this hole.

 This is achieved with the help of two self-centering supports located at the base distance. Each support is made in such a way that sets the device body exactly in the center of the hole in the section where it is located. The line connecting the centers of the supports is the theoretical axis (i.e., an ideal straight line) of the measured cylindrical hole, and the transducer installed in the housing measures the deviation of the real axis from the ideal.

 The essence of the invention lies in the fact that in the known device for measuring the straightness of the axis of cylindrical holes, comprising a housing with two radial bearings spaced along its length, a two-arm lever with a measuring tip located on one of its shoulders and in contact with the surface of the cylindrical hole, and an inductive transducer connected with the second lever arm, the supports are self-centering, and a second two-arm lever is installed in the housing, at one end of which an inductive azovatel and the other second measuring tip located diametrically opposite the first and arranged to be in contact with the surface of the cylindrical hole simultaneously with the first probe tip.

In this case, the self-centering bearings can be made in the form of rotation bodies located in the housing at an angle of 120 ^° , mounted with the possibility of radial movement of the conical sleeve axially spring-loaded, each self-centering bearing can be equipped with a pneumatic arrester made in the form of a flaccid membrane, the center of which is fixed on the cone sleeve, and the periphery on the device.

 The device may be equipped with a telescopic handle with a support belt pivotally connected to the housing, the hinge being made with a gap greater than the gap between the support belt of the handle and the surface of the cylindrical hole.

 Distinctive features of the prototype are the implementation of self-centering supports and the installation of a second two-shouldered lever in the housing, at one end of which an inductive transducer is placed, and at the other end is a measuring tip located diametrically opposite the first and installed with the possibility of contact with the surface of the cylindrical hole simultaneously with the first measuring tip.

 These design features are necessary and sufficient in all cases of constructive implementation of the device with the achievement of the above technical result (see sheet 2).

A specific embodiment of the self-centering supports may be their implementation in the form of rotation bodies located in the housing at an angle of 120 ^° , mounted with the possibility of radial movement of their conical spring-loaded conical sleeve. In addition, to reduce the force required to move and rotate in a long cylindrical hole, the self-centering support can be equipped with a pneumatic arrester made in the form of a flaccid membrane, the center of which is fixed on the conical sleeve, the periphery on the device body.

 In order to be able to measure the straightness of the axis of long cylindrical openings, the device can be equipped with a telescopic handle with a support belt pivotally connected to the housing, and in order to prevent the weight of the handle from affecting the measurement results, the handle hinge is made with a gap larger than the gap between the girdle of the handle and the surface of the cylindrical hole.

 The invention is illustrated in the drawing, where in FIG. 1 shows a device in section, in FIG. 2 a section A-A of FIG. one.

A device for measuring the straightness of the axis of a cylindrical hole contains a housing 1 on which two self-centering bearings 2 are located at a base distance L. Each support 2 consists of three balls 3 located at an angle of 120 ^o in the channels of the housing 1. Balls 3 are supported on a conical sleeve 4. The sleeve 4 is installed in the housing 1 and is pressed against the balls by a spring 5. The balls 3 are selected of the same diameter, and the sleeve 4 is installed in the housing 1 on a sliding fit without clearance. Thus, when the housing 1 is inserted into the measured cylindrical hole 6 and the balls 3 are pressed against its surface by springs 5, the axis of the housing 1 exactly coincides with the ideal axis of the measured cylindrical hole. In the middle of the housing 1 between the supports 2 there are two L-shaped arms 7 and 8. At one end of each arm 7 and 8, measuring tips 9 and 10 are equipped with diamond. The other ends of the levers 7 and 8 are in contact with the inductive transducers 11 and 12. The measuring force is created by the force of the inductive transducers 11 and 12 and the spring 13 located between the levers 7 and 8.

 Since the measurement scheme with two transducers provides straightforwardness calculation by the formula (AB) / 2, the levers 7 and 8 can be made with a shoulder ratio of 1/2 (with a gear ratio of 1/2), which eliminates division in the electronic unit.

 To measure the straightness of the axis of long cylindrical holes, the device is equipped with a telescopic folding handle 14, consisting of several tubular parts 15 and 16, sliding onto each other. The number of parts and their length are selected depending on the measured length of the cylindrical hole 6. The movable upper tubular part 16 is fixed to the stationary lower tubular part 15 using a nut 17 and a sleeve 18 with a collet end 19. So that the weight of the handle does not affect the measurement results , the housing 1 of the device is connected to the handle 14 by means of a rotary spherical hinge 20. The hinge 20 is made with a gap S1 greater than the gap S2 between the support belt 21 of the handle 14 and the measured cylindrical hole 6. Thus, when measured The measuring device is not affected by the weight of the handle 14.

 Inductive converters 11 and 12 are connected to an electronic unit (not shown in the drawing) having an analog or digital indicating device. The output signals of the transducers 11 and 12 are algebraically summed according to the formula AB or (AB) / 2 (depending on the design of the measuring device). The reading device of the electronic unit shows the deviation from the rectilinear axis of the cylindrical hole 6 at a length equal to the distance L between the supports 2.

 To reduce the force required to move and rotate the device in a long cylindrical hole 6, the self-centering supports 2 are provided with pneumatic arresters 21. Each arrestor 21 consists of a flaccid membrane 22, the center of which is fixed to the end face of the sleeve 4, and the periphery is fixed to the housing 1. Between the membrane 22 and the housing 1 forms a chamber into which compressed air is supplied and under the action of the membrane 22, the sleeve 4 is displaced, releasing the balls 3, which makes it easy to move and rotate the device inside the cylindrical hole 6.

 The measurement is as follows.

 The device using the telescopic handle 14 is inserted into the cylindrical hole 6 and is pushed inward with a small effort. Balls 3 of the bearings are pushed into the channels of the housing 1, pushing the tapered sleeve 4. When both supports 2 of the device enter the cylindrical hole 6 and are pressed to its surface by springs 5, the housing 1 will occupy the correct position exactly along the ideal axis of the cylindrical hole 6. In this case, the measuring tips 9 and 10 are in contact with the surface of the cylindrical hole 6. The output signals of the inductive converters 11 and 12 enter the electronic unit (not shown in the drawing), are summed in it according to the formula (AB) / 2 and appear on the block scale until anija corresponding to a deviation from straightness of the axis of cylindrical hole 6. With the handle device 14 is gradually advanced along the axis of the cylindrical bore 6 and is rotated around its axis. At the same time, the readings of the electronic unit at various positions of the device in the cylindrical hole 6 are noted. The largest of these readings is the largest deviation from the straightness of the axis of the cylindrical hole 6.

Claims (4)

 1. A device for measuring the straightness of the axis of cylindrical holes, comprising a housing with two radial bearings spaced along its length, a two-arm lever with a measuring tip located on one of its shoulders and in contact with the surface of the cylindrical hole, and an inductive transducer associated with the second arm of the lever, as well as a second measuring tip, characterized in that the supports are self-centering, and the device is equipped with a second two-arm lever mounted in the housing and placed at one of its ends, a second inductive transducer, and at the other end of the second two-shouldered lever, a second measuring tip is placed diametrically opposite to the first and installed with the possibility of contact with the surface of the cylindrical hole simultaneously with the first measuring tip. 2. The device according to claim 1, characterized in that each self-centering support is made in the form of rotation bodies located in the housing at an angle of 120 ^o , mounted with the possibility of radial movement of the conical sleeve spring-loaded in the axial direction.  3. The device according to claim 1, characterized in that each self-centering support is equipped with a pneumatic arrester, made in the form of a flaccid membrane, the center of which is mounted on a conical sleeve, and the periphery on the device body.  4. The device according to claim 1, characterized in that it is equipped with a telescopic handle with a support belt, pivotally connected to the housing.

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