KR20160080134A - Setting gauge for vertical centering of the rotor - Google Patents

Abstract

Provided is a gauge for setting vertical centering of a rotor, which comprises: a mounted member fixedly mounted on an attachment of cutting equipment to enable a worker to conveniently set a central line (Y-center) on a vertical line of the rotor while being manually rotated by the worker when the worker sets the central line (Y-center) on the vertical line crossing at a right angle to a central axis of the rotor; and a measurement member provided at the mounted member to be able to rotate to enable the worker to set the central line on the vertical line crossing at a right angle to the central axis of the rotor while being manually rotated by the worker. Thereby, the present invention enables the worker to simply, rapidly and precisely set the central line on the vertical line of the rotor in a short time whenever a process for slotting the rotor is performed.

Description

[0001] The present invention relates to a gauge for vertical centering of a rotor,

The present invention relates to a gauge for setting a vertical centering of a rotor, and more particularly to a gauge for setting a vertical centering of a rotor, (Y-center) on the vertical line of the rotor while manually rotating the rotor by a manual operation of the operator when setting the center of the rotor.

Generally, rotor machining is rough machining in which a large amount of base material is cut, and finishing machining is performed to shape the remaining shape after the rough machining.

In addition, one of the machining operations for machining the rotor after the finishing process is slotting that forms a slot. The slotting process of such a rotor is a modification of a roughing machine to a rotor machining machine .

However, in the slotting process of the rotor, the deviation of the degree of the equipment is about 0.03 to 0.3 mm, so that a new center is set every day.

In order to newly set the center of the rotor, a centering gauge equipped with a 5 × RPM amplifier is used. At this time, the dial of the centering gauge due to the rotation can not be confirmed by the operator.

Therefore, the center line (Y-center) perpendicular to the center axis direction of the rotor, which is the object of the slotting process, can not be accurately set.

On the other hand, as disclosed in Korean Patent No. 10-1410779 (hereinafter referred to as Patent Document 1), a conventional prior art for centering a rotor has a rotor mounted on a rotary table in a gas turbine assembling process, Such as a centering gauge jig for the centering of a broach machine and a broaching machine centering method using the same, has been proposed.

Further, as disclosed in Korean Patent Laid-Open Publication No. 10-2003-0051342 (hereinafter referred to as Patent Document 2), a center is mounted on each of opposite center mounting holes of a pair of spindles, A technique such as a centering method of a center of a rotation driving center device for holding and rotating a workpiece while holding the workpiece has been proposed.

In addition, as disclosed in U.S. Patent No. 7,721,801 (hereinafter referred to as Patent Document 3), a centering portion for continuously passing a rotating portion implemented on a polishing spindle at a central position while passing through the inner recess, And a contact portion which is located at a mutual center between the centering portion of the polishing spindle rotor and the inner recess of the rotating component through three supporting members disposed at arbitrary angular intervals from each other, There has been proposed a technique such as a spindle rotor for abrasion composed of a detachable device for securely fastening in the direction of the axis.

Korean Patent No. 10-1410779 Korean Patent Publication No. 10-2003-0051342 U.S. Patent No. US7621801

However, in the above-described Patent Documents 1 to 3, the means for setting the center (Y-center) on the vertical line orthogonal to the central axis direction of the rotor during slotting, It is disadvantageous in that it can not be provided.

The main object of the present invention is to solve the above-mentioned problems of the related art. The main object of the present invention is to provide a cutting tool which is mounted on an attaching part of a cutting machine and has a center line Y-center perpendicular to the center axis direction of the rotor (Y-center) on the vertical line of the rotor while manually rotating the rotor by manual operation of the operator when setting the vertical centering gauge of the rotor.

Another object of the present invention is to make it possible to more accurately set the center line on the vertical line.

Another object of the present invention is to enable an operator to grasp the vertical centering easily without slipping.

According to an aspect of the present invention, there is provided a setting gauge for setting a center line (Y-center) on a vertical line orthogonal to a center axis direction of the rotor due to a slotting process of a rotor, A mounting member which is mounted and fixed on the attachment of the frame; And a measuring member which is rotatably provided on the mounting member and rotates by manual operation of the operator and sets a center line on a vertical line perpendicular to the central axis direction of the rotor.

And when the center line on the vertical line is set by the measuring member, a maximum upper dead point and a lowest bottom dead center are set on the outer peripheral surface of the rotor by rotation.

The mounting member is composed of a mounting hole to be inserted and mounted on the attachment of the cutting equipment, and a mounting shaft to be mounted and fixed to the mounting hole.

The mounting hole includes an insertion body inserted on an attachment of a cutting tool, a mounting groove fixed to the insertion body by a pin or a bolt with an attachment of a cutting tool, and an insertion groove, .

The mounting shaft has one end inserted into the insertion groove and the other end in the form of a shaft having the measuring member.

The measuring member includes a rotating part rotatably provided on a mounting shaft of the mounting member, and a measuring gauge fixed to the rotating part and rotated together with the rotating part.

The measurement gauge is a dial gauge.

Wherein the rotation unit includes a wave earth which is rotatably supported by bearings interposed between the mounting shafts and is held and rotated by an operator, a gauge which is fixed to the wave earth and is rotated together with the wave earth to form a fastening groove for fastening the measurement gauge And a fixed shaft.

The waveguide is formed in a hollow tube shape in which one end is inserted into the mounting shaft and the other end of the gauge fixing shaft is inserted and fixed.

The surface of the waveguide further includes a non-slip portion for preventing an operator from slipping when gripped.

The non-slip portion is any one of a scratch shape, a concave-convex shape, and a plurality of grip protrusions formed on the surface of the wave earth.

The non-slip portion is a non-slip pad coupled to the surface of the waveguide.

The present invention relates to a method of setting a center line on a vertical line of a rotor mounted on an attachement of a cutting equipment and setting a center line on a vertical line of the rotor while manually rotating a worker when setting a center line perpendicular to the center axis direction of the rotor It is possible to set the center line on the vertical line of the rotor every time the slotting process of the rotor can be set simply, quickly, and accurately within a short time.

In addition, since the setting is performed quickly and accurately, the slotting process according to the slot machining is also performed more efficiently in the rotor.

In addition, since the center line on the vertical line can be set more accurately, the slotting work for forming the slot can be accurately performed without any error.

In addition, the operator can easily grasp the vertical centering without slipping when the vertical centering is set, so that the center line on the vertical line can be set more accurately.

1 is a partially exploded perspective view for explaining the present invention,
Figure 2 is a cross-sectional view of the combined state according to Figure 1,
FIG. 3 is a perspective view of the present invention in a state where the present invention is mounted on an attachment of a cutting tool,
4 is a front view and a side view for explaining the use state of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to or limited by the embodiments.

1 is a partially exploded perspective view for explaining the present invention, FIG. 2 is a sectional view of the combined state according to FIG. 1, FIG. 3 is a perspective view of the present invention in a state where the present invention is installed on an attachement of a cutting equipment, And is a front view and a side view for explaining the use state of the present invention.

A setting gauge 1 for setting a center line Y-center on a vertical line orthogonal to the direction of the central axis C of the rotor R according to the slotting process of the rotor R is shown.

According to the present invention, when a center line (Y-center) on a vertical line orthogonal to the center axis direction of the rotor according to the slotting process of the rotor is mounted on the attachment of the cutting equipment used in rotor machining, And a center line (Y-center) on a vertical line at a maximum point of the rotor can be easily set while rotating the rotor.

The setting gauge (1) according to the present invention comprises a mounting member (10) mounted and fixed on an attachment (102) of a cutting tool (100); And a measuring member 20 rotatably provided on the mounting member 10 to set a center line on a vertical line orthogonal to a direction of a central axis C of the rotor R while being rotated by a manual operation of an operator .

The cutting apparatus 100 has a known technical configuration and is provided on a base of a mounting apparatus on which a rotor is mounted and has a known technical configuration capable of moving in the axial direction of the rotor as well as up and down.

A maximum upper dead point C1a and a lowest dead point C1b on the outer circumferential surface of the rotor R are set so that the error range when the center line C1 on the vertical line is set to a minimum by the measuring member 20 do.

That is, the top dead center point C1a and the bottom dead center point C1b can be accurately set by checking the user's visual acuity immediately by rotating the measuring member 20 manually by an operator.

Accordingly, the operator first moves the cutting equipment to the upper and lower positions, sets the top dead center and the bottom dead center, and sets the center line on the vertical line while bringing the measuring member mounted by the mounting member on the attachment into contact with the outer peripheral surface of the rotor.

When the measurement of the center line on the vertical line is completed, the mounting device is moved up and down so that the center line on the vertical line and the center axis direction of the rotor coincide with each other using the stationary mounting device. At this time, the center line on the vertical line of the rotor is set as an intermediate dimension that is obtained by dividing the whole dimension in which the rotor is moved in the upward and downward directions.

In addition, since the measuring member is rotatably provided, it is possible to set the highest possible top dead center and the lowest bottom dead center on the outer circumferential surface of the rotor by manual operation of the operator. That is, by setting the maximum top dead center and the bottom dead center as close as possible to the center axis direction of the rotor, the vertical moving center line can be set by minimizing the vertical moving width of the rotor.

In other words, when the center line on the vertical line is distant from the center axis direction of the rotor, the deviation width can be increased by increasing the upward and downward moving widths when the rotor is moved up and down. It is desirable to set a maximum overhead load and a bottom dead center as low as possible.

The error range of the center line on the vertical line should be controlled so as to be maintained within about 0.02 mm, so that it is preferable to perform this before the slotting process of the rotor every day. This is because, when the error is out of the error range, a large error is caused in the slotting process for forming a slot in the rotor, so that it is preferable to maintain the error within the error range.

The mounting member 10 includes a mounting hole 12 to be inserted and mounted on the attachment 102 of the cutting apparatus 100 so as to have a simple structure, As shown in Fig.

The mounting hole 12 has an insertion body 12a to be inserted on the attachment 102 of the cutting tool 100 and an attachment body 12a to which the attachment 102 of the cutting tool 100 and the pin A mounting groove 12b mounted and fixed by bolting, and an insertion groove 12c into which one end of the mounting shaft 14 is inserted and fixed. At this time, it is preferable that the insertion body 12a is formed in a cone shape like a normal conical shape so that the insertion body 12a can be easily inserted into the attachement 102.

One end of the mounting shaft 14 is inserted into the insertion groove 12c, and the other end is in the form of a conventional shaft having the measuring member 20.

As a result, the mounting member is not a complicated structure but a simple structure, so that it can be conveniently mounted and detached on the attachement of the cutting equipment without inconvenience or inconvenience.

Accordingly, when setting the center line on the vertical line of the rotor, the setting gauge of the present invention is quickly and simply installed and set by the attachments of the cutting equipment. When the cutting gauges are to be used for the cutting application, It also provides ease of use that can be used for the original cutting application by installing cutting tools after separation.

The measurement member 20 includes a rotation part 22 that is held by an operator on a mounting shaft 14 of the mounting member 10 so as to be rotatable and a rotation part 22 that is fixed to the rotation part 22 and rotates together with the rotation part 22 And a measurement gauge 24. At this time, it is preferable that the measurement gauge 24 is a conventional dial gauge whose scale is displayed by the measurer and the measurer.

In other words, the measuring member 20 has the rotation portion 22 provided on the mounting shaft 14 of the mounting member 10 so as to be rotatable in the direction required by the operator, that is, leftward or rightward, It is possible to set the maximum top dead center C1a and the minimum bottom dead center C1b on the outer circumferential surface of the rotor R while rotating the measuring gauge 24 fixed to the rotating portion 22. [

In other words, since the dial gauge, which is the measurement gauge 24, is rotated together with the rotary part 22, the range in which the dial gauge is rotated by the measurer can be ensured as wide as possible, and the setting of the maximum high- It will be possible.

Further, the operator has a condition of high accuracy because of the condition that the operator can directly identify the top dead center point C1a and the bottom dead center point C1b which are set while being rotated manually.

The rotating portion 22 includes a waveguide 22a which is rotatably provided by a normal bearing B interposed between the mounting shafts 14 and is held and rotated by an operator, And the connecting groove 22b 'is formed by being screwed or fastened by the fastening method or the like so that the measuring gauge 24 is rotated together with the waveguide 22a so as to be fastened by a conventional screw or pin connection method And a gage fixing shaft 22b. One end of the waveguide 22a is inserted into the mounting shaft 14 and the other end of the waveguide 22a is inserted into and fixed to the gauge fixing shaft 22b.

The waveguide 22a of the rotating portion 22 is not rotated in any one direction on the mounting shaft 14 but is smoothly moved without any interference in any direction required by the operator to rotate It has a condition that rotation can be made.

Thereby, a condition that the setting position can be accurately set by positioning the measuring gauge 24, which is fastened by the fastening groove 22b 'of the gauge fixing shaft 22b, to the correct position is provided.

On the other hand, the surface of the waveguide 22a further includes a non-slip part (not shown) for preventing an operator from slipping when gripping.

The non-slip portion is formed by a known scratch machine formed on the surface of the waveguide 22a to form a checkerboard or comb-shaped scratch, or a concave-convex form or a plurality of grip protrusions. The concavo-convex shape and the grasping projection may be formed by a process such as cutting in the fabrication of the wave gap, or may be separately bonded or attached to the wave front by a known method.

In other words, by allowing the operator to easily grasp and rotate the wave earth by the non-slip part formed so that no slip occurs on the surface of the wave earth when the worker grips and rotates the wave earth, the stable and accurate rotation Lt; / RTI >

Therefore, when the top dead center and the bottom dead center are set on the outer circumferential surface of the rotor by the measurement gauge, it is possible to position the rotor precisely.

In addition, the non-slip portion may be formed by machining, bonding or attaching to the surface of the waveguide, or may be a non-slip pad (not shown) formed in the shape of a tube formed of ordinary rubber or silicone. That is, the non-slip pad is covered on the outer surface of the waveguide, and the waveguide pad is coupled to the outer surface of the waveguide in a separately manufactured state, thereby eliminating the above-mentioned troublesome process of separate processing or attachment or coupling.

1: Setting gauge
10: mounting member 12: mounting hole
12a: insertion body 12b: mounting groove
12c: insertion groove 14: mounting shaft
20: measuring member 22: rotating part
22a: wave earth 22b: gauge fixed shaft
22b ': fastening groove 24: measuring gauge
100: Cutting device 102: Attachment
B: Bearing C: Rotor center axis
C1a: top dead center C1b: bottom dead center
R: Rotor

Claims (12)

A setting gauge for setting a center line on a vertical line orthogonal to a center axis direction of the rotor due to slotting processing of the rotor,
Wherein the setting gauge comprises: a mounting member mounted and fixed on the attachment of the cutting equipment; And
And a measuring member rotatably provided on the mounting member and configured to set a center line on a vertical line orthogonal to a center axis direction of the rotor while being rotated by a manual operation of an operator. The method according to claim 1,
Wherein when the center line on the vertical line is set by the measuring member, a maximum upper dead point and a lowest bottom dead point are set on the outer peripheral surface of the rotor by rotation. The method according to claim 1,
Wherein the mounting member is composed of a mounting hole to be inserted and mounted on the attachment of the cutting equipment, and a mounting shaft to be inserted and fixed to the mounting hole. The method of claim 3,
The mounting hole includes an insertion body inserted on an attachment of a cutting tool, a mounting groove fixed to the insertion body by a pin or a bolt with an attachment of a cutting tool, and an insertion groove, And a gauge for setting the vertical centering of the rotor. 5. The method of claim 4,
Wherein the mounting shaft has one end inserted into the insertion groove and the other end being in the form of a shaft having the measuring member. The method of claim 3,
Wherein the measuring member includes a rotating portion rotatably mounted on a mounting shaft of the mounting member, and a measuring gauge fixed to the rotating portion and rotated together with the rotating portion. The method according to claim 6,
Characterized in that the measuring gauge is a dial gauge. The method according to claim 6,
Wherein the rotation unit includes a wave earth which is rotatably supported by bearings interposed between the mounting shafts and is held and rotated by an operator, a gauge which is fixed to the wave earth and is rotated together with the wave earth to form a fastening groove for fastening the measurement gauge And a stationary shaft. 9. The method of claim 8,
Wherein the waveguide is formed in a hollow tube shape in which one end is inserted into the mounting shaft and the gauge fixing shaft is inserted and fixed to the other end in a hollow tube shape. 10. The method of claim 9,
Wherein a surface of the waveguide further comprises a non-slip portion for preventing an operator from slipping when gripped. 11. The method of claim 10,
Wherein the non-slip portion includes any one of a scratch shape, a concavo-convex shape, and a plurality of grip protrusions formed on the surface of the wave earth. 11. The method of claim 10,
Wherein the non-slip portion is a non-slip pad coupled to a surface of the waveguide.

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