KR20010090018A - Portable apparatus for adjusting shaft center between two shafts - Google Patents

Abstract

The present invention relates to a shaft core matching device, and more particularly to a device that can accurately and easily match the shaft center between two different shafts.

In order to achieve the above object, the present invention includes a reference pin having one end attached to the end of the reference axis; A dial gauge holder having a hollow cylinder and having one reference hole inserted therein; A plurality of dial gauges attached along the circumferential direction outside the dial gauge holder; One end is attached to the end of the subordinate shaft and the other end provides a portable interaxial shaft matching device including a subordinate pin is inserted into the other inlet of the dial gauge holder.

Description

Portable apparatus for adjusting shaft center between two shafts}

The present invention relates to a shaft core matching device, and more particularly to a device that can accurately and easily match the shaft center between two different shafts.

In the mechanical field industry, it is common to connect the rotary shafts of two different devices for power connection between machines or to test the performance of the machine.In this case, if the parallelism and concentricity between the axes connected to each other do not coincide, Loss, breakage of machinery, and increased error in experimental results.

For example, in the case of an engine performance and endurance test, a dynamometer is used for the engine performance and endurance test, in which case the power transmission shaft is connected between the engine and the dynamometer firmly fixed to the floor. You will be tested. At this time, the agreement between the shaft center between the dynamometer and the engine, i.e., the concentricity and parallelism between the two shafts, determines the safety and reliability of the test. If the test is run out of the prescribed shaft center, it may cause the damage of the power transmission shaft and the damage of the dynamometer.

However, in the conventional case, the concentricity and parallelism are adjusted by using a dial gauge while moving the engine-side fixed support leg in the power system room. The difficulty in this case is that the concentricity and the factor of parallelism are correlated so that the parallelism is adjusted after measuring the concentricity, and the concentricity is out of order. The repetition continues.

This takes a considerable amount of time to achieve a defined degree of agreement (about 15 hours for a 15-year career and about a day for a year-long experience), resulting in the building, equipment, and storage of a very expensive power system. There is a problem that causes waste such as input work. In other words, the engine room should always be tested, but it takes a lot of time to set up. In addition, since the setting work based on the skill of the operator only, there is a problem in terms of management. In other words, it is difficult to set a standard time and require its compliance.

Referring to the problems of the prior art based on the accompanying drawings as follows.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the conventional shaft shaft matching device between both axes.

Conventional parallel matching device between both shafts is provided with a parallel gauge check dial gauge 13 on the reference shaft 100 so that the end of the parallel gauge check gauge gauge 13 is in contact with the end surface of the subordinate shaft 200. When the reference shaft 100 is rotated, the parallel gauge check gauge 13 also rotates at the same time, and thus the end of the parallel gauge check gauge 13 is the end of the subordinate shaft 200. A circular trajectory is drawn on the subsection.

After installing the parallel gauge check dial gauge 13 on the reference axis 100 and installing the measuring device in the cross-sectional direction of the subordinate axis 200, the parallel axis error component between both axes is observed by rotating the reference axis 100. It can be seen. If there is no parallelism error between the reference axis 100 and the slave axis 200, the trajectory drawn by the end of the parallel gauge check gauge 13 will be in the shape of a garden. However, if there is a parallelism error between the reference axis 100 and the subordinate axis 200, the trajectory drawn by the end of the parallel gauge check gauge 13 cannot be the shape of the garden and the egg shape eccentric in one direction Will be.

However, the conventional parallelism matching device between two axes should know the error value of the four directions of up, down, left, and right, but when looking down, it is inconvenient, such as having to lean over and turn your head upside down.

In the conventional biaxial concentricity matching device, the concentricity check dial gauge 14 is installed on the reference shaft 100 and the end of the concentricity check dial gauge 14 is in contact with the peripheral surface of the subordinate shaft 200. When the reference shaft 100 rotates, the concentric check dial gauge 14 also rotates at the same time, so that the end of the concentric check dial gauge 14 is the peripheral surface of the subordinate shaft 200. A circular rotation trajectory is drawn in.

When the dial gauge 14 for the concentricity check 14 is installed on the reference axis 100 and the measuring device is installed in the circumferential direction of the subordinate axis 200, the concentricity error component between the two axes is rotated when the reference axis 100 is rotated. It can be seen. If there is no concentricity error between the reference axis 100 and the subordinate axis 200, the trajectory of the end of the dial gauge 14 for the concentricity check will be the shape of the garden. However, if there is a concentricity error between the reference axis 100 and the subordinate axis 200, the trajectory drawn by the end of the concentric check dial gauge 14 cannot be in the shape of a garden and an oval eccentric in one direction Will be.

However, the conventional biaxial concentricity matching device also needs to know the error value of the four directions, usually up, down, left and right, but still has the inconvenience of having to lean back and upside down.

In addition, when using the conventional two-axis axial coincidence device, both concentricity and parallelism are not sensed in real time, it is inconvenient to record the distorted amount by four directions by hand, and the concentricity and parallelism can be simultaneously matched. Since there is no relationship between the concentricity and parallelism alternately to work to be repeated, there is a disadvantage that takes a lot of work time.

In order to solve the above-mentioned problems, the present invention provides a portable biaxial shaft matching device capable of quickly and easily performing the operation in the case of matching the concentricity and parallelism between the two axes, and accurately measuring the axial error between the two axes. It aims to provide.

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows the conventional shaft shaft matching device between both axes.

Figure 2 is a view showing a zero point adjustment operation of the portable shaft between the shaft center matching device according to the present invention.

Figure 3 is a view showing the operation of matching the shaft center between the two shafts with a portable shaft between two shafts according to the present invention.

4 is a cross-sectional view of FIG. 3 viewed from the A-A direction.

* Brief description of symbols for the main parts of the drawings *

13: Dial gauge for parallelism check 14: Dial gauge for concentricity check

21: reference pin 22: dial gauge holder

23: dial gauge 24: slave pin

100: reference axis 200: subordinate axis

In order to achieve the above object, the present invention is a reference pin; A dial gauge holder; Dial gauge; A portable biaxial shaft matching device (hereinafter, referred to as "axial matching device") composed of subordinate pins is provided.

Hereinafter, embodiments of the shaft matching device according to the present invention will be described in detail with reference to the accompanying drawings. On the other hand, in the description of the embodiment will be described clearly the positional relationship of the shaft matching device according to the present invention by using the terms left and right with respect to the accompanying drawings.

In order to match the shaft center between the two shafts with the shaft center matching device according to the present invention, the operation of adjusting the zero point of the dial gauge according to the present invention should be performed in advance.

2 is a view showing a zero point adjustment operation of the shaft matching device according to the present invention.

One end of the reference pin 21 is attached to the end of the reference axis (100). The reference pin 21 is a cylindrical pin, wherein the vertical cross section of the reference pin 21 is preferably concentric with the vertical cross section of the reference axis 100. That is, it is very preferable that the center line of the reference pin 21 and the center line of the reference axis 100 coincide with each other.

The size of the outer diameter of the reference pin 21 does not matter whether it is larger or smaller than the size of the outer diameter of the reference axis 100, the outer diameter of the reference pin 21 is always constant with respect to the longitudinal direction of the reference pin 21. It is very desirable to maintain size.

The dial gauge holder 22 is composed of a hollow cylinder, the reference pin 21 is inserted into one side inlet of the dial gauge holder 22. At this time, it is preferable that there is a minimum clearance between the inner diameter of the dial gauge holder 22 and the outer diameter of the reference pin 21 so that the dial gauge holder 22 can slide. The smaller the value, the smaller the measurement error of the shaft center between the two axes. However, in the present invention, the vertical cross-sectional shape of the outer circumferential surface of the dial gauge holder 22 is not necessarily limited to a circular shape. That is, the vertical cross-sectional shape of the outer circumferential surface of the dial gauge holder 22 may be any polygon. In other words, the outer circumferential surface of the dial gauge holder 22 may have a shape in which several planes are connected in the circumferential direction.

The dial gauge 23 is a dial gauge commonly used. A measuring unit 23a is attached to a lower end of the dial gauge 23, and the measuring unit 23a is connected to a spring inside the body of the dial gauge 23. When pressure is applied to the end of the measuring unit 23a and the measuring unit 23a is pushed into the body of the dial gauge 23, this causes the spring connected to the measuring unit 23a to contract. The magnitude of the elastic force of the spring generated is visualized by the scale indicated by the scale needle of the dial gauge 23. In the same principle, when the pressure applied to the end of the measuring unit 23a decreases and the measuring unit 23a protrudes out of the body of the dial gauge 23, this is connected to the measuring unit 23a. The spring is relaxed and the magnitude of the elastic force of the spring as a result is visualized by the scale indicated by the scale needle of the dial gauge 23.

The dial gauge 23 is attached to the dial gauge holder 22, wherein the measuring unit 23a penetrates the hollow cylinder wall of the dial gauge holder 22 to form an interior of the dial gauge holder 22. It is configured to be in the form of protruding into space. For convenience of shaft measurement between the two shafts according to the present invention, the position where the dial gauge 23 is attached is preferably near the inlet of the other side of the inlet where the reference pin 21 is inserted onto the dial gauge holder 22. Do.

In addition, it is preferable that at least three dial gauges 23 are attached at equal intervals along the circumferential direction outside the dial gauge holder 22. In this embodiment, four dial gauges 23 are arranged at intervals of 90 ° along the circumferential direction outside the dial gauge holder 22, but the present invention dares to use the number of dial gauges 23. It is not limited to four.

When the reference pin 21 is inserted into the dial gauge holder 22, the four dial gauges 23 penetrating through the side wall of the dial gauge holder 22 are respectively measured at the end 23a. In contact with the outer peripheral surface of the reference pin 21 and at the same time to apply a predetermined pressure. In this state, each of the four dial gauges 23 displays a predetermined scale, and, if the reference pin 21 and the dial gauge holder 22 are inserted into the dial gauge holder 22, respectively. If 4) have concentric axes, the scales displayed by the four dial gauges 23 will all be the same. On the contrary, if the reference pin 21 and the dial gauge holder 22 have different center axes, At least one of the two dial gauges 23 will display a different scale than the other dial gauges.

0 point adjustment of the shaft matching device according to the present invention by adjusting so that the scales indicated by the four dial gauges 23 are all the same value while the reference pin 21 is inserted into the dial gauge holder 22. The task is complete.

When the zero point adjustment is completed as described above, the slave pin 24 is inserted into the inner space generated on the dial gauge holder 22 by moving the dial gauge holder 22 to the left. As a result, a shaft matching operation between the reference axis 100 and the slave axis 200 is performed.

3 is a view showing the operation of matching the shaft center between the two shafts with the shaft center matching device according to the present invention, Figure 4 is a view showing a cross-sectional view of Figure 3 in the A-A direction.

One end of the slave pin 24 is attached to the end of the slave shaft (200). The slave pin 24 is a cylindrical pin, wherein the vertical cross section of the slave pin 24 preferably forms a concentric circle with the vertical cross section of the subordinate shaft 200. That is, it is very preferable that the center line of the slave pin 24 and the center line of the slave shaft 200 coincide with each other.

It is preferable that the size of the outer diameter of the slave pin 24 is slightly smaller than the size of the outer diameter of the reference pin 21 in order to increase the precision of the work, and the outer diameter of the slave pin 24 is the slave pin 24. It is highly desirable to always maintain a constant size for the longitudinal direction of.

When the subordinate pin 24 is inserted into the dial gauge holder 22, a gap between the inner diameter of the dial gauge holder 22 and the outer diameter of the subordinate pin 24 increases by a small amount. The attachment portion 23a of the dial gauge 23 further protrudes out of the body of the dial gauge 23. As a result, since the spring connected to the attachment part 23a is relaxed, the scale needle of the dial gauge 23 indicates a smaller scale than when the zero point is adjusted.

At this time, if the concentricity between the reference axis 100 and the subordinate axis 200 coincide, the four dial gauges 23 attached to the dial gauge holder 22 all point to the same scale, but the reference axis 100 ) And the concentricity between the subordinate shaft 200 does not match, at least one of the four dial gauges 23 attached to the dial gauge holder 22 displays a different scale than the other dial gauges.

By adjusting the slave pins 24 to be inserted in the dial gauge holder 22 so that the scales indicated by the four dial gauges 23 are all the same, both axes based on one cross section of the slave pins You can match the concentricity of the liver.

In the above state, in order to match the parallelism between the two axes, the degree to which the scale indicated by the dial gauge 23 changes when the dial gauge holder 22 is moved left and right may be checked. That is, if the parallelism between the two axes is the same, even if the dial gauge holder 22 is moved from side to side, the scales indicated by the four dial gauges 23 all maintain the same value. When the dial gauge holder 22 is changed from side to side, at least one of the four dial gauges 23 displays a different scale from the other dial gauges.

As a result, if the scales of the dial gauge 23 checked at at least two points on the slave pin 24 coincide with each other, concentricity and parallelism between the reference axis 100 and the slave axis 200 coincide with each other. .

Although the embodiments of the present invention have been described above, this is only an example and the spirit of the present invention is not limited thereto, and various changes and modifications may be possible. However, it will be understood through the appended claims that such changes and modifications fall within the scope of the present invention. For example, the portable biaxial shaft matching device according to the present invention may replace a dial gauge and use a digital indicator or an electric micrometer as the measurement equipment.

The shaft matching device according to the present invention is simple in structure, so the manufacturing cost is low. In addition, by using the shaft matching device according to the present invention, it is possible to obtain a highly accurate measurement result while simplifying the shaft matching work.

In addition, the shaft matching device according to the present invention has a wide range of applications because it can be always portable because it can be manufactured in a portable type.

Claims (4)

A reference pin whose one end is attached to the end of the reference axis; A dial gauge holder having a hollow cylinder and having one reference hole inserted therein; A plurality of dial gauges attached along the circumferential direction outside the dial gauge holder; One end is attached to the end of the slave shaft and the other end is a portable two-axis shaft matching device including a slave pin is inserted into the other opening of the dial gauge holder The method of claim 1, The dial gauge includes a measuring unit, and the measuring unit is configured to be formed so as to protrude into the inner space of the dial gauge holder through the hollow cylinder wall of the dial gauge holder, the shaft between the two shaft shaft matching device The method of claim 1, Three or more dial gauges are arranged at equal intervals along the circumferential direction outside the dial gauge holder. The method of claim 1, The dial gauge holder is a portable biaxial shaft matching device, characterized in that configured to slide on the slave pin and / or the reference pin in the state in which the slave pin and / or the reference pin is inserted into the space inside the body.