KR101181440B1 - Center control apparatus for rotor processing of lathe - Google Patents

Abstract

The present invention is coupled to the collet chuck installed on one side of the shelf body, the spindle shaft is installed and rotated on the other side of the shelf, the rotor shaft is installed and processed between the collet chuck and the spindle shaft and the rotor shaft of the spindle shaft A center adjusting unit for adjusting the center and the center of the rotor shaft is included on the same line, the center adjusting portion is formed with a fixed block fixing hole to be fixed to the end of the rotor shaft, one end of the spindle shaft is inserted into the center An insertion hole is formed, and an installation groove is formed such that a surface corresponding to the rotor shaft is recessed inwardly so that the edge portion thereof protrudes, and a fixing block for guiding the position of the spindle shaft and inserted into the installation groove. It is formed to have an outer diameter smaller than the groove, the fixed block and the rotor sharp A movable block fixing hole is formed between the fixed block fixing hole and the fixed block fixing hole to be fixed to the rotor shaft and is formed to correspond to the insertion hole so that the spindle shaft is inserted, thereby adjusting the position of the inserted spindle shaft. According to the present invention, a movable block having a control hole formed therein and an adjusting member inserted from a side of the fixed block to pressurize the movable block are positioned so that the centers of the rotor shaft and the spindle shaft are located on the same line to process the rotor. There is an effect of reducing the defective rate of the rotor machining by increasing the accuracy.

Description

Center control apparatus for rotor processing of lathe}

The present invention relates to a lathe for rotor machining, wherein the center adjustment apparatus of the lathe for rotor machining to precisely align the center of the rotor shaft and the center of the spindle shaft when the spindle shaft of the lathe is inserted into the rotor shaft enables precise machining of the rotor shaft. It is about.

Generally, a turbine is a device that rotates at high speed by receiving rotational force from dynamic energy of high temperature and high pressure steam discharged from a power plant or a reactor, and is a rotor as a rotating central axis, and is coupled to a rotor to produce a high temperature, And a bucket for converting the dynamic energy of the high pressure steam into rotational energy.

As shown in FIG. 4, the collet chuck 2 is installed on one side of the shelf 1, and the collet chuck 2 is disposed on the other side of the shelf 1 so as to face the collet chuck 2. A rotating spindle shaft 4 is installed and rotated by a spindle shaft 4 which rotates by installing a workpiece, that is, a rotor shaft 5, between the collet chuck 2 and the spindle shaft 4 of the lathe 1. It is comprised so that the rotor shaft 5 to process may be processed.

The lathe 1 as described above is to continuously and repeatedly process the rotor of a single specification, the operator manually adjusts the length of the spindle shaft 4, as well as the spindle shaft 4 to the rotor shaft 5 It is made to center the spindle shaft 4 and the rotor shaft 5 when inserted.

Here, when the spindle 1 is not inserted exactly in the center of the rotor shaft 5, the lathe 1 is eccentric as the rotor is processed, and thus the processed rotor becomes a defective rotor shaft 5 and the spindle shaft 4. The process of centering) is very important.

By the way, the conventional lathe 1 is manually aligned with the center of the spindle shaft 4 and the center of the rotor shaft 5, there is a problem that the reliability of the operation is lowered as the spindle shaft 4 is moved to fit.

In particular, in order to perform the secondary machining after the primary machining, the rotor shaft 5 may be larger than the expected tolerance due to the shaking of the end after the primary machining, thereby adjusting the center of the spindle shaft 4 again. Since the tolerance at this time may be a very small tolerance, as shown in FIG. 5, a filler gauge 7 fitted to the tolerance between the rotor shaft 5 and the spindle shaft 4 is fitted to adjust the center thereof.

By the way, in order to fit the filler gauge 7 with the tolerance between the rotor shaft 5 and the spindle shaft 4, it is necessary to lift the spindle shaft 4 slightly and insert the filler gauge 7, but the rotor shaft 5 Since the spindle shaft 4 is a large equipment, the spindle shaft 4 is heavy and there is a problem that it is not easy to fit the filler gauge 7 by lifting it by hand.

In addition, since the filler gauge 7 sandwiched between the rotor shaft 5 and the spindle shaft 4 is not fixed, the position of the filler gauge 7 changes or leaves the rotor shaft during the operation. Since the rotation state of 5) is often poor and the above-described process must be repeated, there is a problem that the work is cumbersome and the working time increases and the defective rate increases.

Accordingly, the present invention has been made to solve the conventional problems as described above, the object of the present invention is that the center of the spindle shaft and the center of the rotor shaft inserted in the rotor shaft for processing the rotor shaft is located on the same line. It's in the ship.

Another object of the present invention is to be able to adjust the position of the spindle shaft inserted in the rotor shaft.

Another object of the present invention is to leave a predetermined space between the movable block and the fixed block to generate play.

Another object of the present invention is to allow the movable block to descend by its own weight.

Another object of the present invention is to prevent the movable block from leaving the fixed block.

In order to achieve the object as described above, the center adjustment apparatus of the lathe for rotor processing of the present invention includes a collet chuck installed on one side of the shelf body, a spindle shaft installed and rotated on the other side of the shelf, and between the collet chuck and the spindle shaft. And a center adjusting unit coupled to the rotor shaft and the rotor shaft installed and processed to adjust the center of the spindle shaft and the center of the rotor shaft to be located on the same line.

The center adjusting portion is formed with a fixing block fixing hole to be fixed to the end of the rotor shaft, the insertion hole for inserting one end of the spindle shaft is formed in the center, the surface corresponding to the rotor shaft so that the edge portion protrudes the inner side An installation groove is formed to be recessed so as to guide the position of the spindle shaft, and is inserted into the installation groove, and is formed to have an outer diameter smaller than the installation groove, and is installed between the fixing block and the rotor shaft. A movable block fixing hole corresponding to the fixing block fixing hole is formed to be fixed to the rotor shaft, and is formed to correspond to the insertion hole so that the spindle shaft is inserted, and an adjustment hole is formed to adjust the position of the inserted spindle shaft. Inserted from the side of the block and the fixed block is installed to press the movable block Characterized in that the member containing the section.

The adjustment hole of the movable block is formed larger than the insertion hole of the fixed block, the outer diameter of the coupling member inserted into the movable block fixing hole is characterized in that formed smaller than the inner diameter of the movable block fixing hole.

The adjusting member is installed to be inserted into the lower side of the fixed block, it is characterized in that it is installed to contact the side of the movable block.

A support ring member having a width wider than an end of the fixed block is further positioned between the fixed block and the rotor shaft to support the movable block, so that the support ring member is fixed to the fixed block.

As described above, the present invention has the effect that the centers of the rotor shaft and the spindle shaft are located on the same line to increase the accuracy of machining when machining the rotor, thereby lowering the defective rate of the rotor machining.

In addition, the present invention is to adjust the position by pressing the heavy spindle shaft at fine intervals as the adjustment member is made to press the movable block, the effect of increasing accuracy when matching the center of the rotor shaft and the spindle shaft have.

In addition, according to the present invention, as the outer diameter of the movable block is formed smaller than that of the fixed block, the gap between the movable block and the fixed block is generated to move only the movable block into which the spindle shaft is inserted, thereby moving the center of the spindle shaft and the rotor shaft. Because they can be matched precisely, the centering process can be easily performed with less force.

In addition, according to the present invention, since the movable member is lowered by its own weight when the adjusting member is lowered as the adjusting member pressurizing the movable block is installed at the lower side, the structure has a simple effect because it does not have to have a separate lowering means.

In addition, according to the present invention, as the support ring member is installed between the rotor shaft and the fixed block to support the movable block inserted into the installation groove of the fixed block, the movable block is prevented from escaping to the outside of the fixed block, and the support ring Since the member has a narrow area in contact with the rotor shaft, there is an effect of minimizing the friction force generated when the rotor shaft rotates.

Figure 1 is an exploded perspective view showing the center adjusting portion of the center adjusting apparatus of the lathe for rotor processing according to the present invention.
Figure 2 is a view showing that the center adjustment apparatus of the lathe for rotor processing according to the present invention is installed.
Figure 3a is a view showing that the center adjustment unit of the center adjustment apparatus of the lathe for rotor processing according to the present invention is lowered.
Figure 3b is a view showing that the center adjustment unit of the center adjustment apparatus of the lathe for rotor processing according to the present invention is elevated.
4 is a view showing a typical rotor machining lathe.
5 is a view showing a state in which a filler gauge is disposed between the rotor shaft and the spindle shaft in a conventional rotor machining lathe.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing the center adjustment unit of the center adjustment apparatus of the rotor machining shelf according to the present invention, Figure 2 is a view showing that the center adjustment apparatus of the rotor machining shelf according to the present invention is installed.

As shown, the center adjusting device of the lathe for rotor processing of the present invention is installed on the other side of the shelf (1) and the collet chuck (2) installed on the lathe 1 for processing the workpiece and rotate as shown in FIG. And the rotor shaft 20 installed between the collet chuck 2 and the spindle shaft 4 and processed between the spindle shaft 4 and the spindle shaft 4 and the rotor shaft 20. ) And a center adjuster 30 for centering the center of the rotor shaft 20 on the same line.

The spindle shaft 4 rotates the rotor shaft 20 to be described later while rotating by a driving unit (not shown), which is formed in a cone shape, and is formed so that the vertex portion of the cone is centered.

The rotor shaft 20 is formed into a tubular shape having a hollow portion at the center and is processed into the rotor by cutting or the like by a machining device not shown outside of the rotor shaft 20 when rotated by the spindle shaft 4.

The center adjuster 30 adjusts the position of the spindle shaft 4 finely so that the center of the spindle shaft 4 and the center of the rotor shaft 20 are located on the same line and the rotor shaft 20 is not eccentric. Is installed on the rotor shaft 20, and comprises a fixed block 310, the movable block 320 and the adjustment member 330 for adjusting the position of the movable block 320.

The fixed block 310 is formed with an installation groove 315 recessed inwardly on the rotor shaft 20 side, that is, the side corresponding to the rotor shaft 20, and has a conical spindle shaft at the center of the installation groove 315. An insertion hole 313 into which the spindle shaft 4 is tapered is formed so as to correspond to the shape of (4).

A plurality of fixing block fixing holes 311 are formed outside the insertion hole 313 so that the fixing block 310 may be radially coupled to the rotor shaft 20 about the insertion hole 313.

The movable block 320 has a step 325 formed so that one side thereof is inserted into the installation groove 315 of the fixed block 310, and the other side thereof protrudes outside the installation groove 315 of the fixed block 310.

In addition, an adjustment hole 323 having an outer diameter larger than that of the insertion hole 313 is formed in the center thereof, corresponding to the insertion hole 313 of the fixed block 310. In detail, the insertion hole 313 of the fixed block 310 is formed to taper to narrow the inner diameter toward the installation groove 315 from the position where the spindle shaft 4 is inserted, and the adjustment hole 323 is narrowed. It is formed larger than the inner diameter.

In addition, a plurality of movable block fixing holes 321 are formed on the outer side of the adjustment hole 323 to correspond to the fixed block fixing holes 311, and the coupling member 319 inserted into the fixed block fixing holes 311 is movable. The fixing hole 321 also penetrates to be coupled to the rotor shaft 20.

At this time, the coupling member 319 has an outer diameter of the coupling member 319 of the portion penetrating the movable block fixing hole 321 smaller than the movable block fixing hole 321, and the installation groove 315 of the fixed block 310 and It is preferable to generate a fine play between the movable block 320 inserted into the installation groove 315. In addition, although not shown in the drawings, the movable block fixing hole 321 may be formed larger than the fixing block fixing hole 311 to generate a play.

The support ring member 340 is further installed at the end of the fixed block 310 of the side in which the installation groove 315 is formed to support the side surface of the movable block 320 having the step 325 formed thereon, and the movable block 320 is installed. It prevents to escape to the outside of the groove 315.

Accordingly, support ring fixing holes 317 and 341 are formed in the end of the fixing block 310 and the support ring member 340, respectively, and the support ring fixing holes 317 and 341 are inserted into the support ring member 340 to fix the block. The fixing member 343 for coupling the 310 and the support ring member 340 is inserted.

On the other hand, referring to Figure 2, the lower side of the fixed block 310, the adjustment member insertion hole 331 is formed, the adjustment member insertion hole 331 in the mounting groove 315 of the fixed block 310 from the lower side. The adjusting member 330 is inserted to press the movable block 320 inserted therein.

Thus, if the adjustment member 330 does not pressurize the movable block 320, the movable block 320 is moved downward by its own weight.

Hereinafter, with reference to the drawings will be described in detail the operation of the center adjustment apparatus of the lathe for rotor processing according to the present invention.

Figure 3a is a view showing that the center adjustment unit of the center adjustment apparatus of the rotor machining lathe according to the present invention is lowered, Figure 3b is a view showing the center adjustment unit of the center adjustment apparatus of the lathe machining rotor according to the present invention is elevated. to be.

As shown, the position of the spindle shaft 4 is finely adjusted to position the center of the spindle shaft 4 and the rotor shaft 20 in a straight line, but the position of the spindle shaft 4 is moved downward. To move, move the adjustment member 330 to the lower side.

Then, the movable block 320 moves downward from the play between the coupling member 319 and the movable block fixing hole 321 by its own weight so that the conical center of the spindle shaft 4 coincides with the center of the rotor shaft 20. You can do that.

On the contrary, as shown in FIG. 3B, when the center of the spindle shaft 4 needs to move upward, the adjustment member 330 is moved to the movable block 320 to move the movable block 320 to the coupling member 319. The clearance between the movable block fixing holes 321 may be moved finely upward.

Therefore, the center adjusting unit 30 according to the present invention can finely adjust the spindle shaft 4 to position the center of the spindle shaft 4 and the rotor shaft 20 in a straight line, and the spindle shaft 4 The eccentricity of the rotor shaft 20 which rotates by this can be prevented.

1: lathe 2: collet chuck
4: spindle shaft
20: rotor shaft
30: center adjustment unit
310: fixed block 311: fixed block fixing hole
313: insertion hole 315: mounting groove
319: coupling member
320: movable block 321: movable block fixing hole
323: adjusting hole 325: step
330: adjusting member 331: adjusting member insertion hole
340: support ring member 343: fixing member

Claims (5)

A collet chuck installed on one side of the shelf body;
A spindle shaft installed and rotated on the other side of the shelf;
A rotor shaft installed and processed between the collet chuck and the spindle shaft; And
A center adjuster coupled to the rotor shaft to adjust the center of the spindle shaft and the center of the rotor shaft to be in the same line;
The center control unit,
A fixing block fixing hole is formed to be fixed to the end of the rotor shaft, and an insertion hole into which one end of the spindle shaft is inserted is formed in the center thereof. A fixed block which is formed and guides the position of the spindle shaft;
Is inserted into the installation groove, is formed to have an outer diameter smaller than the installation groove, is installed between the fixed block and the rotor shaft is formed in the movable block fixing hole corresponding to the fixed block fixing hole is fixed to the rotor shaft A movable block shaped to correspond to the insertion hole and having the spindle shaft inserted therein and having an adjustment hole for adjusting a position of the inserted spindle shaft; And
Inserted from the side of the fixed block adjustment member is installed to press the movable block; Center adjustment apparatus for a lathe for rotor processing, characterized in that it comprises a.
delete The method of claim 1,
The adjustment hole of the movable block is formed larger than the insertion hole of the fixed block, the outer diameter of the coupling member to be inserted into the movable block fixing hole is center adjustment of the rotor processing shelf, characterized in that formed smaller than the inner diameter of the movable block fixing hole. Device.
The method of claim 1,
The adjustment member is installed so as to be inserted into the lower side of the fixed block, the center adjustment apparatus of the lathe for the rotor processing, characterized in that installed in contact with the side of the movable block.
The method of claim 1,
Rotor processing lathe, characterized in that the support ring member having a wider width than the end of the fixed block is further positioned between the fixed block and the rotor shaft to support the movable block, the support ring member is fixed to the fixed block. Center adjuster.

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