KR20220069472A - Dial indicator instrument - Google Patents

Abstract

According to the present invention, a concentricity measuring apparatus comprises: a seating part on which an object to be measured is rotatably seated; a roller which frictionally contacts the upper side of the object to be measured which is seated on the seating part and causes the object to be measured to rotate; a driving part for rotationally driving the roller; first and second stoppers, respectively provided on both sides of the object to be measured in the axial direction thereof to prevent fine movement of the object to be measured in the axial direction; and a dial gauge which measures the concentricity of the object to be measured that frictionally contacts the other side of the side of the object to be measured and is rotated by frictional contact with the roller. Therefore, use of the concentricity measuring apparatus causes the concentricity of a small object to be directly measured simply and accurately while at the manufacturing site or the like.

Description

Concentricity meter {Dial indicator instrument}

The present invention relates to a concentricity measuring device for measuring the concentricity of an object to be measured having a cylindrical structure or the like.

Republic of Korea Patent Publication No. 10-2019-1405036 (registration date; June 2, 2014) discloses a 'shaft shaft concentricity measuring device'. Looking at this prior patent, by including a body part, a support part installed in the body part to rotatably support the shaft about the longitudinal axis of the shaft, and a positioning part for adjusting the position of the support part along the longitudinal direction of the shaft, the shaft It is characterized in that it is not necessary to have several types of equipment for each size of the .

However, the concentricity measuring device according to the prior art has a limitation in simply and stably and precisely measuring the concentricity of a small object to be measured directly at a manufacturing site or the like.

Republic of Korea Patent Publication No. 10-2019-1405036 (Registration date; June 2, 2014)

The present invention has been devised to solve the above problems, and it is an object of the present invention to provide a concentricity measuring device capable of measuring the concentricity of a small object to be measured simply and stably and precisely at a manufacturing site.

Concentricity measuring device according to the present invention for realizing the above object, the measuring object is seated so as to be rotatably seated; a roller which is brought into frictional contact with an upper portion of the object to be measured mounted on the seating portion and rotates the object to be measured; a driving unit for rotationally driving the roller; first and second stoppers respectively provided on both sides of the object to be measured in the axial direction to prevent the object to be measured from moving in the axial direction; and a dial gauge contacting the other side of the side of the object to measure the concentricity of the object being rotated by friction contact with the roller.

a pair of bearing shafts installed at the same height in the vertical direction and spaced apart from each other at a predetermined distance in the radial direction of the object; a plurality of bearings installed on each of the bearing shafts to rotatably support the object to be measured seated between the pair of bearing shafts.

The roller may be in frictional contact with one side of the upper portion of the object to be measured at a position eccentric at a predetermined angle in a rotational direction or a reverse rotational direction with respect to the vertical direction with respect to the object to be measured.

The roller includes a wheel coupled to the driving unit to be rotatable by the driving unit; It may include a friction material coupled to the outer peripheral surface of the wheel so that the object to be measured can be rotated together with the roller by frictional force.

The friction material may be formed of a rubber ring detachable from the outer circumferential surface of the wheel.

the first stopper is fixed to the table and is of a fixed type contacting either end of both ends along the longitudinal direction of the object to be measured; The second stopper is coupled to the table so as to be movable in the longitudinal direction of the object to be measured, and may be in contact with the other end of both ends in the longitudinal direction of the object to be measured.

The first stopper may include a first stopper pin fixedly installed on the table in a vertical direction.

The second stopper may include a rail fixedly installed on the table in a lengthwise direction of the object to be measured; a pin fixture having one side coupled to be movable along the rail; and a second stopper pin which is installed and fixed to the other side of the pin fixture in the longitudinal direction of the object to be measured and is in contact with the object to be measured.

The second stopper may further include a fixing pin that is detachably coupled to the pin fixture so as to fix the pin fixture to the rail and passes through the pin fixture and is closely attached to the rail.

According to the concentricity measuring device according to the present invention, the concentricity of a small object to be measured can be measured simply and accurately while carrying it to a manufacturing site or the like. In addition, according to the concentricity measuring device according to the present invention, the object to be measured can be rotated uniformly by the roller, and the axial movement of the object to be measured can be prevented. In addition, according to the concentricity measuring device according to the present invention, since the object to be measured can be rotatably seated by the bearing, precise and stable measurement is possible.

1 is a perspective view of a concentricity meter according to an embodiment of the present invention;
Figure 2 is a plan view of the concentricity measuring instrument shown in Figure 1;
Figure 3 is a front view of the concentricity measuring instrument shown in Figure 1,
4 is a cross-sectional view taken along line 'A-A' shown in FIG. 2 .

A preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 to 4, the concentricity measuring device according to the present invention is for measuring the concentricity of the object 2 to be measured, such as a long cylinder in the axial direction, and a table 10 and a seating part 20 It includes a roller 30 , a driving unit (not shown), first and second stoppers 40 and 50 , and a dial gauge 60 . Hereinafter, for convenience of description, the longitudinal direction of the object 2 is referred to as a longitudinal direction, and the radial direction of the object 2 orthogonal to the longitudinal and vertical directions of the object 2 is referred to as a radial direction.

The table 10 may include a base plate 12 forming a floor and a pair of side plates 14 perpendicular to both ends in the longitudinal direction of the base plate 12 in the vertical direction. A plurality of legs 16 supporting the table 10 may be coupled to the bottom surface of the base plate 12 . The leg 16 may be formed of a rubber material.

The seating part 20 supports the measurement target 2 under the measurement target 2 , and in particular, the target 2 is configured to be rotatably seated. That is, the seating portion 20 may include a pair of bearing shafts 22 and a plurality of bearings 24 . Each of the bearing shafts 22 may be installed and fixed in the longitudinal direction on the table 10 . Both ends of each bearing shaft 22 may be respectively fixed to the side plate 14 of the table 10 . Each bearing shaft 22 may be detachably coupled to the side plate 14 of the table 10 by a bolt fastening method or the like. The pair of bearing shafts 22 may be installed at the same height in the vertical direction with respect to the bottom surface of the table 10 . The pair of bearing shafts 22 may be installed to be spaced apart from each other at a predetermined distance in the radial direction so that the object 2 to be measured can be stably seated therebetween.

The plurality of bearings 24 uniformly and stably support the object 2 to be rotatably seated between the pair of bearing shafts 22 . Each bearing 24 may be fixed by being fitted on the outside of the bearing shaft 22 . The plurality of bearings 24 may be formed to have the same size. The plurality of bearings 24 are installed in pairs in the radial direction in pairs, respectively, and may be installed separately on the bearing shaft 22 . At least two pairs of the plurality of bearings 24 may be installed along the longitudinal direction.

The roller 30 is circumscribed to the measurement target 2 seated on the seating portion 20 to rotate the measurement target 2 . The roller 30 may include a wheel 32 and a friction material 34 . The wheel 32 may be rotated by a driving unit about its longitudinal axis. The friction material 34 is coupled to the outer circumferential surface of the wheel 32 . The friction material 34 may be any material capable of increasing the frictional force between the roller 30 and the object 2 to be measured so that the object 2 to be measured can be easily rotated by the roller 30 . Preferably, the friction material 34 may be formed of a rubber ring that is detachable from the outer peripheral surface of the wheel 32 , so it is easy to replace according to wear, and the impact caused by frictional contact between the roller 30 and the object 2 to be measured is reduced. It can be absorbed by elastic force. The roller 30 is located on one side of the side of the measurement object 2 at a position eccentric at a certain angle in the rotational or reverse rotational direction with respect to the vertical direction rather than being installed in a line in the vertical direction based on the measurement object 2 Frictional contact is more preferable. Therefore, when the object 2 to be measured is rotated by the roller 30 , the external force in the longitudinal direction acting on the object 2 to be measured acts only in one direction, so that the micro-movement of the object 2 can be easily managed. Further, the roller 30 frictionally contacts the measurement object 2 from the opposite side to the dial gauge 60 centered on the measurement object 2 to uniformly and stably make the measurement object 2 together with the dial gauge 60. can be supported by

Such a roller 30 may be supported by being coupled to the table 10 by a roller support. The roller support may include a support shaft 70 and a roller block 72 .

The support shaft 70 may be installed long in the longitudinal direction on the table 10 and fixed to the side plate 14 of the table 10 . The support shaft 70 may be installed above the seating portion 20 so that the roller 30 can make frictional contact with the upper side of the object 2 to be measured. Accordingly, the roller 30 is brought into frictional contact with one side of the upper side of the object 2 to prevent vertical movement of the object 2 together with the seating portion 20 . The support shaft 70 may be installed at a location spaced apart from the object 2 by a certain distance in a radial direction with respect to the object 2 to be measured.

One side of the roller block 72 may be coupled to and supported by the support shaft 70 , and the roller 30 may be coupled to the other side to allow relative rotation. The roller block 72 may be rotatably coupled to the support shaft 70 . Accordingly, the roller 30 rotates along the measurement object 2 according to the change in the outer diameter of the measurement object 2 , so that it can come into close frictional contact with the measurement object 2 at any time. The rotation of the roller block 72 may be limited by a fixing pin (hereinafter, referred to as a 'first fixing pin 74' for convenience of description). That is, the first fixing pin 74 is detachably coupled to the roller block 72 by a bolt fastening method, etc., and penetrates the roller block 72 to be in close contact with the support shaft 70 , thereby forming the first fixing pin 74 and The rotation of the roller block 72 may be restricted by friction between the support shafts 70 .

The driving unit may be configured using an electric motor. The driving unit may be mounted inside the roller block 72 .

The first and second stoppers 40 and 50 are respectively provided on both sides of the object 2 in the axial direction to prevent micro-movement of the object 2 in the axial direction. The first stopper 40 may be of a fixed type, and the second stopper 50 may be formed of a movable type that is movable along the longitudinal direction in response to a change in length of the object 2 to be measured.

The first stopper 40 is fixed to the table 10 so as to be in contact with either end of both ends along the longitudinal direction of the object 2 seated on the seating portion 20 . Preferably, the first stopper 40 may be formed of a first stopper pin fixedly installed on the base plate 12 of the table 10 in the vertical direction. The first stopper pin may be formed in a cylindrical shape. Therefore, the first stopper pin is in contact with the measurement object 2 to prevent axial micro-movement, but the contact area with the measurement object 2 can be the smallest possible so as not to interfere with the rotation of the measurement object 2 . have. The first stopper pin may be installed at a position adjacent to one of the pair of side plates 14 of the table 10 in the longitudinal direction. The first stopper pin may be installed in the middle between the pair of bearing shafts 22 in the radial direction.

The second stopper 50 places the object 2 in the center in the longitudinal direction and contacts the other end of the object 2 from the opposite side to the first stopper 40 to prevent micro-movement in the axial direction, and furthermore, the length It may be coupled to the table 10 so as to be movable along the direction. That is, the second stopper 50 includes a rail, a pin fixture 52 , a second stopper pin 54 , and a fixing pin (hereinafter, referred to as a 'second fixing pin 56' for convenience of description). may include The rails are installed long along the longitudinal direction on the table 10 so that both ends may be fixed to the side plate 14 of the table 10, respectively. One side of the pin fixture 52 is fitted to the rail so as to be movable and rotatable in the longitudinal direction, and the second stopper pin 54 may be fixed to the other side. Meanwhile, the rail may be configured separately, but the above-described support shaft 70 may also serve as a rail, and thus the overall structure may be more simplified. The second stopper pin 54 is installed long in the longitudinal direction of the object 2 to be measured, one end is fixed to the pin fixture 52, and the other end is at the end surface along the length direction of the object 2 to be measured. can be contacted. The other end of the second stopper pin 54 may be formed in a round shape to facilitate relative rotation of the object 2 to be measured. The second fixing pin 56 is detachably coupled to one end of the pin fixture 52 by a bolt fastening method, etc., and penetrates one end of the pin fixture 52 to be in close contact with the rail, thereby the second fixing pin 56 . By fixing the pin fixture 52 to the rail by frictional force between the rail and the rail, the longitudinal movement and rotation of the pin fixture 52 can be limited.

The dial gauge 60 is in contact with the other side of the side of the object 2 to measure the concentricity of the object 2 rotated by the roller 30 . The dial gauge 60 may be supported by a gauge fixture 62 . One side of the gauge fixture 62 may be rotatably fitted to the support shaft 70 described above, and the dial gauge 60 may be fixed to the other side. The gauge fixture 62 may be selectively fixed to the support shaft 70 by a third fixing pin 64 . That is, the third fixing pin 64 is detachably coupled to one end of the gauge fixture 62 by a bolt fastening method, etc., penetrates through one end of the gauge fixture 62 and is in close contact with the support shaft 70 to make the third The gauge fixture 62 is fixed to the support shaft 70 by friction between the fixing pin 64 and the support shaft 70 , so that movement and rotation of the gauge fixture 62 can be restricted.

When describing in detail the effect of the small concentricity measuring device according to an embodiment of the present invention configured as described above, as follows.

The object 2 to be measured is seated on the seating part 20 to be rotatably supported by the bearing 24 , and the object 2 to be measured is brought into close contact with the first stopper pin.

Next, the second stopper pin 54 is brought into close contact with the object 2 by moving and rotating the pin fixture 52 , and then the pin fixture 52 is connected to the support shaft 70 with the second fixing pin 56 . ) is fixed to Then, by moving and rotating the roller block 72 , the roller 30 is brought into contact with the upper side of the measurement target 2 seated on the seating part 20 , and then the connecting rod is connected to the support shaft by the first fixing pin 74 . (70) is fixed. In addition, the gauge fixture 62 is moved and rotated to bring the dial gauge 60 into contact with the object 2 to be measured, and then the gauge fixture 62 is fixed to the support shaft 70 by the third fixing pin 64 . .

After the preparation is completed, when the driving unit is operated, the roller 30 rotates, and the object 2 to be measured is moved together with the roller 30 due to frictional contact between the friction material 34 of the roller 30 and the object 2 to be measured. It is rotated, and at the same time, the concentricity of the object 2 to be measured can be measured by the dial gauge 60 .

The concentricity measuring device according to the present invention constructed and operated as described above is manufactured in a small size that is easy to carry and carried to a manufacturing site, etc. to simply and accurately measure the concentricity of a cylindrical structure with a diameter of 7 to 30 mm. useful.

As described above, the technical ideas described in the embodiments of the present invention may be implemented independently or in combination with each other. In addition, although the present invention has been described through the embodiments described in the drawings and detailed description of the invention, these are merely exemplary, and those of ordinary skill in the art to which the present invention pertains may make various modifications and equivalent other embodiments therefrom. It is possible. Accordingly, the technical protection scope of the present invention should be defined by the appended claims.

2; subject 10; table
20; seat 22; bearing shaft
24; bearing 30; Roller
32; wheel 34; friction material
40; a first stopper 50; 2nd stopper
60; dial gauge 70; support shaft

Claims (9)

a seating part on which the object to be measured is rotatably seated;
a roller which is brought into frictional contact with an upper portion of the object to be measured mounted on the seating portion and rotates the object to be measured;
a driving unit for rotationally driving the roller;
first and second stoppers respectively provided on both sides of the object to be measured in the axial direction to prevent the object to be measured from moving in the axial direction;
a dial gauge contacting the other side of the side of the object to measure the concentricity of the object being rotated by frictional contact with the roller;
Concentricity meter including. The method according to claim 1,
The seating part
a pair of bearing shafts respectively installed long in the longitudinal direction of the measurement object and fixed to the table, installed at the same height in the vertical direction and spaced apart from each other at a predetermined distance in the radial direction of the measurement object;
a plurality of bearings installed on each of the bearing shafts to rotatably support an object to be measured seated between the pair of bearing shafts;
Concentricity meter including. The method according to claim 1,
the roller is in frictional contact with one side of the upper portion of the object to be measured at a position eccentric at a certain angle in a rotational direction or a reverse rotational direction with respect to the vertical direction with respect to the object to be measured; concentricity meter. 4. The method according to any one of claims 1 to 3,
the roller is
a wheel coupled to the driving unit so as to be rotatable by the driving unit;
and a friction material coupled to an outer circumferential surface of the wheel so that the object to be measured can be rotated together with the roller by frictional force. 5. The method according to claim 4,
The friction material is a concentricity measuring device made of a rubber ring detachable from the outer peripheral surface of the wheel. 4. The method according to any one of claims 1 to 3,
the first stopper is fixed to the table and is of a fixed type contacting either end of both ends along the longitudinal direction of the object to be measured;
the second stopper is a movable type that is coupled to the table so as to be movable along the length direction of the object to be measured, and is in contact with the other end of both ends along the length direction of the object to be measured; concentricity meter. 7. The method of claim 6,
The first stopper is a concentricity measuring device including a first stopper pin fixedly installed in the vertical direction on the table. 7. The method of claim 6,
The second stopper
a rail fixedly installed on the table in a lengthwise direction of the object to be measured;
a pin fixture having one side coupled to be movable along the rail;
a second stopper pin which is installed and fixed to the other side of the pin fixture in the longitudinal direction of the object to be measured and is in contact with the object to be measured;
Concentricity meter including. 9. The method of claim 8,
The second stopper further includes a fixing pin that is detachably coupled to the pin fixture so as to fix the pin fixture to the rail, and passes through the pin fixture to be in close contact with the rail.

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