CN113188423A

CN113188423A - Positioning device and detection system for detecting symmetry degree of radial hole of axial part

Info

Publication number: CN113188423A
Application number: CN202110335567.4A
Authority: CN
Inventors: 田中山; 杨晓; 杨昌群; 杨新锋; 牛道东; 陈杨军; 李育特; 杨兵
Original assignee: Xian Aerospace Propulsion Institute; China Oil and Gas Pipeline Network Corp South China Branch
Current assignee: Xian Aerospace Propulsion Institute; China Oil and Gas Pipeline Network Corp South China Branch
Priority date: 2021-03-29
Filing date: 2021-03-29
Publication date: 2021-07-30
Anticipated expiration: 2041-03-29
Also published as: CN113188423B

Abstract

The invention discloses a positioning device and a detection system for detecting symmetry of radial holes of a part for a shaft. The positioning device comprises a first positioning block, a second positioning block, two positioning pins and a pin; a plane A1 vertical to the axial direction and a side plane parallel to the axial direction are arranged on the surface of the first positioning block, a mounting hole and two positioning holes are formed in the first positioning block along the axial direction, the two positioning holes are located on two sides of the mounting hole, and the planes of the central axes of the two positioning blocks are parallel to the side plane; a bottom positioning plane B1, a positioning plane B2 and a positioning plane C are arranged on the two surfaces of the positioning block, the positioning plane B2 is perpendicular to the positioning plane C, the plane A1 is attached to the positioning plane B2, and the side plane is attached to the positioning plane C; the two positioning pins are respectively arranged in the two positioning holes, a part to be measured is arranged in the mounting hole during measurement, the pin penetrates through the radial hole to be measured to be mounted, and the two ends of the pin are attached to the positioning pins on the two sides to be positioned and fixed. The device of the invention has reliable six-point positioning and simple and accurate measurement.

Description

Positioning device and detection system for detecting symmetry degree of radial hole of axial part

Technical Field

The invention relates to a tool for measuring a radial hole of a part for a shaft, in particular to a positioning device for detecting the symmetry degree of the radial hole of the part for the shaft and a corresponding detection system.

Background

In the manufacturing and using processes of precision products, the processing requirements for each part are high, and especially the form and position size precision of key parts often determines the overall performance of the products. The measurement of the form and position size needs to be positioned accurately repeatedly, and the reference is consistent.

For example, the shaft part has the structural characteristics of radial holes and higher requirements on the position degree of the holes, and is commonly used as a small module gear transmission shaft. For the measurement of the radial hole position, an existing measuring instrument is often used: one is to adopt three-coordinate measurement, although the measurement is accurate, the equipment price is expensive, and the measurement cost is high; the other is to adopt a projector for measurement, and then a special tool with higher precision is needed to ensure that the radial hole vertical measurement platform can carry out measurement, the measurement difficulty is high, the possibility of system error is high, the measurement cost is high, and the measurement effect is not ideal.

Disclosure of Invention

In view of the defects or shortcomings of the prior art, the invention provides a positioning device for detecting symmetry of a radial hole of a part for a shaft.

Therefore, the positioning device for detecting the symmetry degree of the radial hole of the shaft part comprises:

a first positioning block, wherein a plane A1 vertical to the axial direction and a side plane parallel to the axial direction are arranged on the surface of the first positioning block; one end of the first positioning block, which is opposite to the plane A1, is provided with an installation hole which is arranged along the axial direction and two positioning holes which are arranged along the axial direction, the two positioning holes are positioned at two sides of the installation hole, and the plane where the central axes of the two positioning holes are positioned is parallel to the side plane;

the two positioning pins are respectively arranged in the two positioning holes;

the pin penetrates through the radial hole of the part to be tested to be installed when the part to be tested is axially installed in the installation hole, and two ends of the pin are attached to the two positioning pins;

and a second positioning block, wherein a second positioning block 2 is provided with a bottom positioning plane B1, a positioning plane B2 and a positioning plane C which are parallel to the bottom positioning plane on the surface, the positioning plane B2 and the positioning plane C are mutually perpendicular, the first positioning block is placed on the second positioning block, the plane A1 is attached to the positioning plane B2, and meanwhile, the side plane is attached to the positioning plane C.

Preferably, a positioning surface D is set on the inner wall of the mounting hole, the positioning surface D is located between the two positioning holes, a plane of the positioning surface D is parallel to a plane of the central axes of the two positioning holes or the side plane, and the plane of the positioning surface D is located between the plane of the central axes of the two positioning holes and the plane of the side plane.

Optionally, a recessed v-shaped groove is formed in the inner wall of the mounting hole, and the bottom surface of the v-shaped groove is the positioning surface D.

Further, a plane A2 which is opposite to and parallel to the plane A1 is further arranged on one surface of the positioning block; the plane A2 is provided with an installation hole arranged along the axial direction and two positioning holes arranged along the axial direction, and the part of the pin which leaks out of the radial hole of the part to be tested is attached to the plane A2.

Furthermore, a fixing hole communicated with the mounting hole is formed in the first positioning block along the radial direction; the fixing device also comprises a compression screw which is arranged in the fixing hole.

Further, the first positioning block is a cylinder with a part being cut along the axial direction.

Furthermore, the two axial sections of the positioning blocks are L-shaped.

The invention also provides a system for detecting the symmetry of the radial holes of the axial parts. Therefore, the detection system provided by the invention comprises a measuring tool and the positioning device, wherein a second positioning block of the positioning device is fixedly arranged, the measuring tool is fixedly arranged relative to the second positioning block, the measuring tool is used for measuring the relative variation of the maximum measurement values of the front and the back two times, the maximum measurement value of the front time is the maximum measurement value displayed when the measuring tool contacts the outer side surface of the part to be measured when the part to be measured is axially arranged in the mounting hole, and the maximum measurement value of the back time is the maximum measurement value displayed when the part to be measured rotates 180 degrees relative to the measurement of the front time.

Specifically, the measuring tool is a dial indicator.

Furthermore, the detection system also comprises a bracket, wherein the bracket is fixedly arranged relative to the second positioning block, and a movable measuring tool mounting structure is arranged on the bracket and used for mounting the measuring tool.

Has the advantages that:

the device of the invention has reliable six-point positioning, namely X, Y, Z coordinate and rotation positioning of each coordinate axis, and the measurement becomes simple and easy, and the reading is accurate.

Drawings

FIG. 1 is a schematic view showing the overall structure of the apparatus of the present invention;

FIG. 2 is a schematic structural reference diagram of the positioning block I;

FIG. 3 is a schematic top view of the positioning block I;

FIG. 4 is a cross-sectional view B-B of FIG. 3;

FIG. 5 is a cross-sectional view A-A of FIG. 3;

FIG. 6 is a schematic view of a positioning block II;

fig. 7 is a reference diagram of the actual use state of the device of the present invention.

Detailed Description

Unless otherwise specified, the terms or methods herein are understood or implemented according to the knowledge or common knowledge of one of ordinary skill in the relevant art.

The axial direction, the radial direction and the like or the azimuth terms are consistent with the corresponding directions or azimuths in the drawings, wherein the axial direction is also the extending direction of the part to be measured in the mounting hole, and the extending direction is perpendicular to the radial hole of the part to be measured; it should be noted that the directions and orientations shown in the drawings do not limit the present invention, and those skilled in the art can make modifications, rotations, adjustments, and the like based on the concept of the present invention within the protection scope of the present invention.

Example (b):

referring to fig. 1, the positioning device of the present invention includes a first positioning block 3, a second positioning block 2, two positioning pins 4 and a pin (not shown in fig. 1); wherein: a plane A131 perpendicular to the axial direction and a side plane 33 parallel to the axial direction are arranged on the surface of the first positioning block, a mounting hole 31 and two positioning holes 32 which are axially formed are arranged at one end of the first positioning block opposite to the plane A1, the two positioning holes 32 are positioned at two sides of the mounting hole 31, and planes where central axes of the two positioning blocks are positioned are parallel to the side plane 33;

a bottom positioning plane B123, a positioning plane B221 and a positioning plane C22 which are parallel to the bottom positioning plane are arranged on the surface of the second positioning block 2, the positioning plane B221 and the positioning plane C22 are perpendicular to each other, the first positioning block is placed on the second positioning block, the plane A1 is attached to the positioning plane B2, and the side plane is attached to the positioning plane C;

the two positioning pins are respectively arranged in the two positioning holes and are locally leaked; when a part to be tested is installed in the installation hole, the pin is used for penetrating through the radial hole to be tested to be installed, and two ends of the pin are attached to the positioning pins on two sides.

During measurement, referring to fig. 7, a second positioning block is horizontally arranged to form a positioning reference, and the first positioning block is arranged on the second positioning block according to the scheme; the shaft part to be measured is axially arranged in the mounting hole and attached to the surface of one side in the mounting hole, a pin is inserted into a radial hole on the shaft part, the pin and the hole form a tight fit, and the pin is attached to positioning pins on two sides so as to position and fix the shaft part to be measured;

then, a measuring tool 5 fixedly arranged at the side, such as a dial indicator, is used for contacting the surface of the part to be measured, the positioning block I is slightly slid left and right to drive the part to be measured to slide, the highest measuring point is found out, and the numerical value is recorded; in the same method, the measured piece is rotated by 180 degrees, the precision of the measured piece is measured again, and the numerical value is recorded; and comparing the two measurement data to obtain an accurate value of the symmetry of the radial hole of the part for the measured shaft. The corresponding planes or the positioning surfaces among the parts are attached, and when the first positioning block drives the tested part to slide, the position deviation cannot be caused to generate errors. In addition, the second positioning block needs to be fixed during measurement, and displacement is not allowed; meanwhile, the measuring tools such as percentage angles and positions are consistent, and the shaking or the change of the percentage table position is not allowed. In a more specific scheme, during measurement, the second positioning block can be placed on the horizontal table 1 and is matched with the first positioning block to ensure accurate positioning.

In a more specific scheme, as shown in fig. 1, the measuring tool 5 is fixedly mounted beside the positioning device through a bracket 6, and a movable measuring tool mounting structure is arranged on the bracket, so that the angle and position of the measuring tool can be conveniently adjusted during measurement.

In some embodiments, a surface of the positioning block is provided with a plane a2 opposite to and parallel to the plane a1, the plane a2 is provided with a mounting hole and two positioning holes, and the leaking part of the pin is attached to the plane a2 during measurement, so that the pin can be positioned more accurately during measurement.

In some schemes, in order to better realize the positioning effect, the inner wall of the mounting hole is provided with a positioning surface D, the positioning surface D is positioned between two positioning controls, meanwhile, the plane where the positioning surface D is positioned is parallel to the side plane 33 or the plane where the central axes of the two positioning holes are positioned, and the plane where the positioning surface D is positioned between the plane where the side plane is positioned and the plane where the central axes of the two positioning holes are positioned. In a specific scheme, as shown in fig. 2, a concave V-shaped groove can be arranged in the mounting hole, and the geometric bottom surface of the V-shaped groove is a positioning surface D. When the part to be measured is mounted in the mounting hole, especially when the aperture of the mounting hole is large, the part to be measured can be positioned by being attached to the positioning surface.

In a further embodiment, especially when the diameter of the mounting hole is too large, the component to be tested in the mounting hole needs to be fixed, correspondingly, a fixing hole 36 is formed in the side wall of the first positioning block in the radial direction (i.e. perpendicular to the axial direction), and when the component to be tested is mounted in the mounting hole, the component is fixed by mounting the compression screw 7 in the positioning hole 36.

In some specific embodiments, the positioning block one 3 has a cylindrical shape with a part being cut off along the axial direction, as shown in fig. 2, and the surfaces of the corresponding portions are a plane a1, a plane a2 and a side plane, respectively. The cross section of the second positioning block 2 is L-shaped, and the corresponding surfaces are a positioning plane B and a positioning plane C.

The radial holes shown in the table 1 are measured by adopting the measuring system of the invention, the requirement of the symmetry degree of each radial hole relative to the axis and the measured data are recorded as the following table 1, the two-time indication values in the table are respectively the numerical values read on the dial indicator, and the two-time indication value is the test indication value after the one-time indication test azimuth is rotated by 180 degrees.

TABLE 1

Although only a few specific embodiments of this patent have been disclosed, this design is not so limited and all changes that would occur to one skilled in the art are intended to be embraced therein.

Claims

1. The utility model provides a radial pore symmetry of spare part for axle detects and uses positioner which characterized in that includes:

2. The positioning device for detecting the symmetry of a radial hole of a shaft component according to claim 1, wherein the inner wall of the mounting hole is provided with a positioning surface D, the positioning surface D is positioned between the two positioning holes, and the plane of the positioning surface D is parallel to the plane of the central axes of the two positioning holes or the side plane, and the plane of the positioning surface D is positioned between the plane of the central axes of the two positioning holes and the plane of the side plane.

3. The positioning device for detecting the symmetry of a radial hole of a shaft component according to claim 1, wherein a recessed v-shaped groove is formed in the inner wall of the mounting hole, and the bottom surface of the v-shaped groove is the positioning surface D.

4. The positioning device for detecting the symmetry of a radial hole of a shaft component according to claim 1, wherein a surface of the positioning block is further provided with a plane a2 opposite to and parallel to the plane a 1; the plane A2 is provided with an installation hole arranged along the axial direction and two positioning holes arranged along the axial direction, and the part of the pin which leaks out of the radial hole of the part to be tested is attached to the plane A2.

5. The positioning device for detecting the symmetry of the radial hole of the shaft component as claimed in claim 1, wherein a fixing hole communicated with the mounting hole is radially formed in the first positioning block; the fixing device also comprises a compression screw which is arranged in the fixing hole.

6. The positioning device for detecting the symmetry of a radial hole of a shaft component according to claim 1, wherein the first positioning block is a cylinder partially cut in the axial direction.

7. The positioning device for detecting symmetry of a radial hole of a shaft component according to claim 1, wherein the two axial sections of the positioning blocks are L-shaped.

8. The system is characterized by comprising a measuring tool and a positioning device as claimed in any one of claims 1 to 7, wherein a second positioning block of the positioning device is fixedly arranged, the measuring tool is fixedly arranged relative to the second positioning block, the measuring tool is used for measuring the relative variation of the maximum measurement values of the former time and the latter time, the maximum measurement value is displayed when the measuring tool contacts the outer side surface of the part to be measured when the part to be measured is axially installed in the installation hole, and the maximum measurement value is displayed when the part to be measured rotates 180 degrees relative to the former time.

9. The axial component part radial hole symmetry detection system of claim 8, wherein the measurement tool is a dial gauge.

10. The system for detecting the symmetry of a radial hole of a shaft component as claimed in claim 8, further comprising a bracket fixedly disposed with respect to the second positioning block, wherein the bracket is provided with a movable measuring tool mounting structure for mounting the measuring tool.