JP2013202779A - Multifunctional tool holder and device using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily align a rotation axis or a center axis of a machining tool, etc. with a center axis of a tool holder including a main shaft.SOLUTION: A holder part 2 includes first, second and third adjustment means for aligning a rotation axis or a center axis of a machining tool 4, etc. with a center axis of a multifunctional tool holder 1 including a main shaft. The first means is made means for adjusting float amount of a joint, the second means is made means for fixing the float amount adjusted by the first means, and the third means is made means for further evolving the axis alignment performed by the first and second means and bringing the alignment closer to zero.

Description

  The present invention relates to a multi-function tool holder used for secondary super finishing or reamer machining of an inner diameter of a work material, and in particular, a rotation axis or a center axis of a processing tool or the like and a center axis of a multi-function tool holder including a main axis. The present invention relates to a multi-function tool holder and an apparatus using the same.

It is well known to perform secondary super-finishing or reaming using a machining tool in which the shaft core is aligned with the pilot hole finishing of the pre-worked work material.
In this case, since the work material is usually fixed, the phase of the axis of the machining tool is changed, and this secondary super-finishing is performed.
For example, in Japanese Patent Application Laid-Open No. 2-30408, a holder for holding a work material can be floated on a plane and / or can be swung on a swing, and the holder is adjusted by an external operation to align the axis. The finishing tool is used to perform the finishing process. Japanese Patent Application Laid-Open No. 3-117533 discloses that the force applied to the O-ring provided in the body is used to adjust the axis of the processing tool. They are displaced and aligned.

  Japanese Patent Laid-Open No. 2-30408   JP-A-3-117533

Summary of invention

Problems to be solved by the invention

The one shown in Patent Document 1 is such that the adjustment ground 12 is turned to align the axis of the work material on the holder side, and the one shown in Patent Document 2 adjusts the correction screw 9, The axis is aligned.
In other words, the ones shown in Patent Documents 1 and 2 are such that the axis of the processing tool or work material is aligned with one (one place) adjusting means, so the precision that can be adjusted is limited. .
In other words, there is no description of means for providing the tool holder with adjusting means for further bringing the axis alignment accuracy obtained by the adjusting means closer to zero.

  The accuracy adjustment when chucking the machining tool with the holder is adjusted using the deflection accuracy of the tip at a predetermined distance from the chuck part of the machining tool in the direction of the cutting edge as an index. However, there was a limit to the tool holder, and the deflection accuracy was within 3 to 10 μm.

In addition, when finishing a workpiece with different required processing accuracy, the work efficiency cannot be improved because the processing holder has not been replaced until the processing accuracy has been changed. However, since a lot of time is required, the processing cost is increased. That is, since the machining accuracy of the conventional machining holder is within 3 to 10 μm, the machining holder can be used as it is in the machining work of the workpiece performed within this accuracy, but there is no limit. In the case of a work for machining a work material that requires machining accuracy close to zero, it was necessary to change to an expensive special specification holder.
For this reason, it is necessary to replace the processing holder, and it has not been possible to perform an efficient operation and an operation with low processing costs.

Means for solving the problem

  The present invention has been made to solve the above-mentioned problems, and the object of the present invention is to easily align the rotation axis or center axis of a processing tool or the like with the center axis of the tool holder including the main shaft, The present invention relates to an invention in which the processing accuracy is further improved and can be made close to zero.

  That is, the chucking holder holding the processing tool is supported by the shank through a joint so that the chucking holder can float and swing, and the chucking holder is displaced to the outer periphery of the shank. Alternatively, in a tool holder equipped with an adjustment screw or the like for aligning the center axis with the center axis of the tool holder, the rotation axis or center axis of the processing tool or the like is aligned with the center axis of the multi-function tool holder including the main axis. First, second and third adjusting means are provided, the first means is means for adjusting the float amount of the joint, the second means is means for fixing the float amount adjusted in the first, The third means is a multi-function tool holder and a device that uses this tool as a means of further evolving the axial alignment performed in the first and second, and bringing them closer to zero. That.

  The first adjustment means to adjust the float amount of the joint is to make a steel ball provided on the outer periphery of the shank project to the chucking holder side by operating the adjustment nut, and the chucking holder part with the joint to the shank. The multi-function tool holder according to claim 1, wherein the multi-function tool holder and the center axis of the multi-function tool holder including the spindle are aligned with the rotation axis or the center axis of the machining tool or the like. Device.

  In addition, the second means for fixing the float amount adjusted in the first, after adjustment by the first adjustment means, tighten the chucking holder outer periphery from the shank side with a plurality of adjustment screws provided on the outer periphery of the shank, A multi-function tool holder in which a shank and a chucking holder unit are integrated to fix the float amount and the axis is aligned, and an apparatus using the same.

  Further, the third adjusting means for further evolving the axial alignment performed in the first and bringing it close to zero is to provide a fitting ring on the outer periphery of the chucking holder portion, and a chucking holder with a plurality of adjusting screws provided on the fitting ring. A multi-function tool holder in which the outer periphery of the part is elastically deformed to displace the rotation axis or the center axis of a processing tool or the like so as to match the center axis of the multi-function tool holder including the main shaft, and an apparatus using the same.

Effect of the invention

Since the present invention has the configuration as described above, it is possible to operate the first to third adjusting means and perform work with different required processing accuracy with a single holder.
Therefore, unlike the conventional case, it is not necessary to replace the holder for each required processing accuracy, so that the working efficiency is improved, and the first to third adjustment means are used to reduce the processing accuracy to zero. It is possible to obtain a multi-function tool holder and an apparatus using the same.

It is a front view of a multifunction tool holder provided with the present invention, and is a figure accompanied by a collet chuck connected to the main shaft on one side and a processing tool on the other side. It is a partially cutaway sectional view of the multifunction tool holder in FIG. FIG. 3 is an exploded explanatory view of the multifunction tool holder shown in FIG. 2. It is a figure explaining a means to correct blade edge runout of a processing tool.

Hereinafter, an embodiment of a multi-function tool holder with runout adjustment of a processing tool (which may be a work material) according to the present invention will be described in detail with reference to FIGS.
FIG. 1 is a front view of a multi-function tool holder provided with the present invention, which is an explanatory view with a shank holder connected to the spindle on one side and a processing tool on the other side, and FIG. FIG. 3 is a cutaway sectional view of the functional tool holder, and FIG. 3 is an exploded explanatory view of the multifunction tool holder shown in FIG. 2.

First, in FIGS. 1-3, 1 is a multifunction tool holder main body. The multi-function tool holder main body 1 is composed of a chucking holder portion 2 with a joint, lock collar, fitting ring, etc., which will be described later, a shank 3 and the like.
Reference numeral 4 denotes a cutting processing tool such as a drill or a reamer held by the chucking holder portion 2. This machining tool 4 is usually used when the machining tool 4 performs secondary super-finishing or reamer machining on the hole of the work material opened by the pre-machining.

Further, the processing tool 4 is fixed to the chucking holder portion 2 by a tool fixing screw A6 through a lock collar 12 provided at the tip of the previous chucking holder portion 2. On the other hand, the mounting portion 3a of the shank 3 is mounted on a main shaft of a machine tool, for example, a machining center, via a shank holder 5 or the like.
In the drawing, the shank 3 is shown as an integral part, but it may be made by combining several parts.

The multifunction tool holder main body 1 has three adjusting means as shown in the figure. Reference numeral 7 denotes an adjusting nut constituting one of the adjusting means. The female screw 7a provided on the adjusting nut 7 is screwed into the male screw 3b provided on the shank 3 side. At this time, the steel ball 18 disposed in the three to six holes 3c provided at the position where the outer periphery of the shank 3 divides 360 degrees into 3 to 6 parts is adjusted by the tightening degree of the adjusting nut 7, and the steel ball 18 is The steel ball receiving part 17 is fixed by projecting to the chucking holder part 2 side, the float amount of the joint 13 is adjusted (range 0 to 0, 5 mm), and the chucking holder part 2 is connected to the shank 3 with the processing tool 4 The tool holder including the main shaft is fixed with a fixing screw C29 in the axial alignment direction. As a result, the float amount is fixed and the axis is aligned.
Reference numeral 18b denotes an auxiliary steel ball. The auxiliary steel balls 18b are provided before and after a screw A receiving portion 16 which will be described later, and are provided so as to hold the chucking holder portion 2 and to move smoothly with respect to the shank 3.
This series of mechanisms and means is the first adjusting means in the present invention.

Reference numeral 8 denotes an adjustment cover A that constitutes a part of the second component of the adjustment means, and an adjustment screw A10 is provided below the adjustment cover A8 or the adjustment cover A8.
The adjustment cover A8 and an adjustment cover B9, which will be described later, are designed parts having a diamond-cut pattern on the surface, and there is no problem in performance without the adjustment cover A8 and the adjustment cover B9, which will be described later. is there. However, if it does, it will serve to stop the adjustment screw from falling (loosening prevention).
Further, the adjustment screw A10 is also provided in four screw holes 3d provided at positions where the outer periphery of the shank 3 is divided into 360 degrees.

  Thus, the second adjusting means is performed by the tightening degree of the adjusting screw A10 to the screw A receiving portion 16 provided in the chucking holder portion 2 from the adjusting cover A8 side. The second adjusting means secures the float amount determined by the first adjusting means, and the center axis of the multi-function tool holder 1 including the rotation axis and the main axis of the processing tool and the like by the tightening degree of the adjusting screw A10. It is an adjusting means for adjusting within 10 μm.

  That is, the outer periphery of the shank 3 is tightened to the outer periphery of the screw A receiving portion 16 provided on the chucking holder portion 2 by the adjustment screws A10 provided on the outer periphery of the shank 3, and the shank 3 and the chucking holder portion 2 are integrated to fix the float amount. At the same time, the position of the chucking holder portion 2 with respect to the shank 3 is adjusted to take measures for center runout described later. Thus, the runout between the machining tool 4 and the multifunction tool holder including the main shaft can be maintained within 3 to 10 μm. This series of mechanisms and means is used as the second adjusting means in the present invention.

The third adjusting means is performed by screwing the adjusting screw B11 into the screw hole 23 provided in the adjusting cover B9 and the fitting ring 22. At this time, only the fitting ring 22 may be screwed into the adjustment screw B11.
The adjustment screw B11 is provided in four screw holes 23 provided at positions that divide the outer periphery of the chucking holder portion 2 and the fitting ring 22 into 360 degrees.
The third adjusting means is means for fastening the adjusting screw B11 to the screw B receiving portion 21 of the chucking holder portion 2 from the fitting ring 22 side via the adjusting cover B9. Adjusting means for aligning the rotation axis or central axis of the multi-function tool holder with the central axis of the multifunction tool holder including the main axis.

  That is, a plurality of adjustment screws B11 provided on the outer periphery of the fitting ring 22 are aligned with a later-described core runout, and the corresponding adjustment screw B11 is tightened or loosened to provide an outer periphery of the screw B receiving portion 21 provided on the chucking holder portion 2. The chucking holder 2 is elastically deformed, the machining tool is displaced, and the rotation axis or the central axis of the machining tool 4 is aligned with the central axis of the multifunction tool holder including the main shaft. It is. As a result, the runout of the processing tool 4 can be reduced to zero within 3 to 10 μm obtained by the second adjusting means. This series of mechanisms and means is the third adjusting means in the present invention.

Next, referring to FIGS. 2 and 3, the first to third adjusting means described above will be described in detail.
In the figure, 1 is a multi-function tool holder, 2 is a chucking holder part, 3 is a shank, 6 is a tool fixing screw A, 7 is an adjustment nut, and 8 is an adjustment. The cover A, 9 is the adjustment cover B, 10 is the adjustment screw A, 11 is the adjustment screw B, and 12 is the lock collar.

First, the connection relationship between the chucking holder portion 2 and the shank 3 will be described.
The chucking holder portion 2 includes a joint 13 such as a universal joint. One end of the joint 13 has a pin 14 and is connected to the chucking holder portion 2, and the other end has a pin 15 and is connected to the shank 3.
The joint 13 is also a driving force transmission means, and adjusts the vibration between the machining tool gripped by the chucking holder portion 2 and the main spindle of the machining center or the like with its own adjustment function. Thus, the machining tool has a configuration for changing the center of the machining tool entering along the prepared hole of the work material whose center is changed.

Reference numeral 16 denotes a screw A receiving portion provided in a protruding shape on the outer periphery of the chucking holder portion 2, and a concave portion is formed on the protruding top portion. Reference numeral 17 denotes a steel ball (described later) receiving portion provided at the tip (main shaft side) of the screw A receiving portion 16. The steel ball receiving portion 17 is fitted on the shank 3 side.
The fitted portion is a steel ball receiving portion 17.
Thus, when the female screw 7a of the adjusting nut 7 is screwed into the male screw 3b on the shank 3 side, the steel ball 18 that appears and disappears on the steel ball receiving portion 17 side is positioned in the chucking holder portion 2 with the joint 13. In addition, the rotation axis of the processing tool 4 and the central axis of the multifunction tool holder 1 including the main shaft are adjusted in the range of 0 to 0 and 5 mm.

In addition, the chucking holder portion 2 with the joint 13 is attached to the shank 3 with one pin 15 and the other pin 14.
That is, the male screw 36a provided on the outer periphery of the fixing ring 36 is screwed into the female screw 3e provided at the end of the shank 3, and is further fixed by the fixing screw B28 so as to maintain the adjustment position. Is floated in the shank 3.
Reference numeral 36 denotes an adjustment ring, and reference numeral 24 denotes a wave ring. The adjustment ring 36 and the wavy ring 24 are for adjusting the amount of shaft center deflection of the processing tool 4, and the angle of the spring range of the wavy ring 24 is varied by the tightening amount of the adjustment ring 36.
That is, the male thread 36 a of the adjustment ring 36 is screwed into the female thread 3 e of the shank 3 with the wave ring 24 interposed therebetween. There is a fixing screw B28 for maintaining the state.
Therefore, the adjusting ring 36 and the wave ring 24 become the fourth adjusting means by the tightening or loosening function of the adjusting ring 36.
The steel ball receiving portion 17 is provided between the screw A receiving portion 16 and the positioning portion by the pin 15.
The first adjusting means is configured by the configuration of the chucking holder portion 2 built in the joint 13 and the configuration of the shank 3, and further the configuration of the steel ball 18 and the adjusting nut 7.

  19a is a metal washer, and 19b is a washer with a bearing in which a plurality of bearings are incorporated. The washer 19a and the steel ball holder 19b are provided between the fixing ring 36 and the screw A receiving portion 16 and between the screw A receiving portion 16 and the shank 3, and the chucking holder portion 2 is assembled to the shank 3. At this time, the movement of the chucking holder part 2 with respect to the shank 3 is made smooth and floatable.

Reference numeral 10 denotes an adjustment screw A. The adjustment screw A10 is screwed toward the screw A receiving portion 16 of the chucking holder portion 2 through a plurality of screw holes 3d provided in the shank 3 (including the adjustment cover 10). It is. Then, the chucking holder portion 2 including the joint 13 is positioned in the shank 3 by the degree of tightening of the plurality of adjustment screws A10 (tightening or loosening of a predetermined portion of the adjustment screw A10 based on a core runout measurement result described later). At the same time, the rotation axis of the machining tool 4 and the center axis of the multifunction tool holder 1 including the main axis are aligned within a range of 3 to 10 μm.
The above-described configuration of the built-in chucking holder portion 2 and the shank 3 as well as the adjusting screw A10, the screw A receiving portion 16, the washer 19a, and the steel ball holder 19b provide the second adjusting means. Is structured.

A screw B receiving portion 21 is provided in a concave shape on the outer periphery of the chucking holder portion 2, and this screw B receiving portion 21 supports the joint 13 so as to be floatable and swingable to the chucking holder portion 2. The pin 14 is provided.
That is, the chucking holder unit 2 is provided at a position away from the shank 3.
Reference numeral 22 denotes a fitting ring provided on the outer periphery of the chucking holder portion 2 so as to cover the previous screw B receiving portion 21.
Four screw holes 23 are provided on the outer periphery of the fitting ring 22 so as to divide 360 degrees into four equal parts.
When the adjustment screw B11 is screwed into the screw hole 23, the adjustment screw B11 reaches the screw B receiving portion 21 and elastically deforms the chucking holder portion 2.

As a result, the processing tool 4 held by the chucking holder portion 2 is displaced. This adjustment is performed based on the measurement results described later.
That is, the tightening and loosening of the adjusting screw B11 is performed based on the result of the center runout measurement of the processing tool 4 described later.
As a result, the runout state of the processing tool 4 which is within 3 to 10 μm by the second adjusting means can be brought close to zero as much as possible.
The illustrated adjustment cover B9 is a design part having a diamond-cut pattern on its surface, and there is no problem in performance even if it is not similar to the previous adjustment cover A10.
The third adjusting means is configured by the configuration of the chucking holder portion 2 incorporating the joint 13 and the configuration of the fitting ring 22 as well as the configuration of the adjusting screw B11 and the screw B receiving portion 21.

The machining tool 4 positioned and fixed to the chucking holder portion 2 by the third adjusting means in this way is finally fixed to the chucking holder portion 2 by the tool fixing screw A6 together with the lock collar 12. Is.
The multi-function tool holder 1 with the machining tool 4 is fixed to a spindle of a machining center (not shown), and performs a work piece super-finishing or reaming finishing work.

Next, an embodiment in which a coolant supply channel is incorporated in the multifunction tool holder 1 according to the present invention will be described with reference to FIG.
In the figure, the coolant supplied to the supply flow path 30 from the coolant supply source enters the chucking holder portion 2 incorporating the joint 13 through the circumferential groove 31 and the flow path 32 formed in the shank 3. The coolant that has entered the chucking holder portion 2 is supplied to the blade portion of the processing tool 4 through the flow path 33 of the processing tool 4.

In a series of supply paths extending across the two members that move relative to each other, that is, the chucking holder portion 2 and the shank 3, although not shown, an O-ring and an O-ring retainer are attached to the chucking holder portion 2. Of course, it is interposed in the connection part of the shank 3 to prevent coolant leakage to the outer periphery of the multifunction tool holder main body 1.
As a result, it is possible to ensure smooth plane floating and / or swinging of the shank 3 and the chucking holder portion 2 as well as the processing portion of the processing tool 4.

Next, with reference to FIG. 4, a means for correcting the blade runout of the processing tool 4 will be described.
First, the processing tool 4 is held by the tool fixing screw A6 on the lock collar 12 provided at the tip of the chucking holder 2. Next, the multi-function tool holder main body 1 holding the processing tool 4 is mounted on a spindle of a machine tool such as a machining center (not shown). Next, the test indicator 26 is pressed against the tip outer peripheral surface 4b of the blade portion 4a of the processing tool 4, and the maximum difference in reading of the test indicator 26 during the rotation of the main shaft is measured as the blade runout of the processing tool. Then, the angular position at which the cutting edge deflection of the machining tool 4 is highest is detected from the measured value.

  When the angle position at which the blade runout becomes the highest is detected, the rotation of the spindle is stopped, and the second and third adjustment screws A and B corresponding to the angular position at which the blade runout becomes the highest are tightened or loosened. Then, the cutting edge of the machining tool 4 that was in the misalignment state as indicated by the broken line is corrected as indicated by the solid line. As a result, the prepared hole in the work material is processed with the required processing accuracy.

The multifunction tool holder main body 1 having the above configuration can be used properly depending on the required finishing accuracy.
That is, when the pilot hole finishing is allowed within the usual 3 to 10 μm finishing accuracy, the first and second adjusting means can be used as the adjusting means, and the center runout adjustment can be performed. It is sufficient to add a third adjusting means in addition to the first and second adjusting means when the above is required.
Of course, when the prepared hole is machined by the first and second adjusting means, the machining tool 4 can absorb the deformation of the prepared hole by the action of the joint 13 and perform the finishing process. Is.
In other words, the multifunction tool holder main body 1 provided with the present invention can serve as two multifunction tool holders.

Since the present invention has the configuration as described above, the following effects can be obtained.
That is, the chucking holder holding the processing tool is supported by the shank through a joint so that the chucking holder can float and swing, and the chucking holder is displaced to the outer periphery of the shank. Alternatively, in a tool holder provided with an adjustment screw or the like that is aligned with the central axis of the tool holder 1 including the central axis and the main axis, the rotational axis or the central axis of the processing tool or the like is used as the central axis of the multi-function tool holder. First, second and third adjusting means are provided, the first means is means for adjusting the float amount of the joint, and the second means is means for fixing the float amount adjusted in the first, The third means is a multi-function tool holder and a device using the same, which is a means of further evolving the axial alignment performed in the first and second, and bringing it closer to zero. That.

By doing so, it is possible to operate the first to third adjusting means and perform two different types of required machining precision operations with one holder.
Therefore, unlike the conventional case, it is not necessary to replace the holder for each required processing accuracy, so that the working efficiency is improved, and the first to third adjustment means are used to reduce the processing accuracy to zero. Thus, a multifunction tool holder that can be brought close to the position and an apparatus using the same can be obtained.

The first adjustment means to adjust the float amount of the joint is to make a steel ball provided on the outer periphery of the shank project to the chucking holder side by operating the adjustment nut, and the chucking holder part with the joint to the shank. A multi-function tool holder and a device using the multi-function tool holder which are displaced with respect to each other so that the rotation axis or center axis of a processing tool or the like matches the center axis of a multi-function tool holder including a main axis.
By doing this, the operator turns the adjustment nut provided on the outer periphery of the shank little by little to align the rotation axis or center axis of the machining tool and the center axis of the work material with the multifunction tool holder. Since it only has to be displaced, the adjustment work can be facilitated.

  In addition, the second adjustment means for fixing the float amount adjusted in the first, after the adjustment in the first means, tighten the chucking holder outer periphery from the shank side with a plurality of adjustment screws provided on the outer periphery of the shank, A multi-function tool holder in which a shank and a chucking holder unit are integrated to fix a float amount and align an axis, and an apparatus using the same. As a result, it is possible to obtain a multi-function tool holder capable of further increasing the processing accuracy of the first adjusting means and processing the workpiece with an accuracy within 3 to 10 μm, and an apparatus using the same.

Further, the third adjusting means for further evolving the axial alignment performed in the first and bringing it close to zero is to provide a fitting ring on the outer periphery of the chucking holder portion, and a chucking holder with a plurality of adjusting screws provided on the fitting ring. A multi-function tool holder in which the outer periphery of a part is elastically deformed to displace a rotation axis or a center axis of a processing tool or the like so as to match a center axis of a multi-function tool holder including a main axis, and an apparatus using the same.
As a result, the rotation axis or center axis of a machining tool or the like and the center axis of the multi-function tool holder including the main axis can be easily matched, and the machining accuracy can be further improved and approached to zero.

DESCRIPTION OF SYMBOLS 1 Multi-function tool holder 2 Chucking holder part 3 Shank 3a Attachment part 3b Male screw 3c Hole 3d Screw hole 3e Male screw 4 Processing tool 4a Blade part 4b Outer peripheral surface 5 Shank holder 6 Tool fixing screw A
7 Adjustment nut 7a Female screw 8 Adjustment cover A
9 Adjustment cover B
10 Adjustment screw A
11 Adjustment screw B
12 Lock collar 13 Joint 14 Pin 15 Pin 16 Screw A receiving portion 17 Steel ball receiving portion 18 Steel ball 18b Auxiliary steel ball 19a Metal washer 19b Steel ball retainer 20 Coolant supply device 21 Screw B receiving portion 22 Fitting ring 23 Screw hole 24 Wave spring 26 Test indicator 28 Fixing screw B
29 Fixing screw C
30 Channel 31 Circumferential Groove 32 Channel 33 Channel 36 Fixed Ring 36a Male Thread

Claims (4)

  The chucking holder holding the machining tool is supported by the shank through a joint so that it can float and swing on the shank, and the chucking holder is displaced to the outer periphery of the shank so that the axis of rotation or the center of the machining tool etc. In a tool holder equipped with an adjusting screw etc. that aligns the axis with the center axis of the tool holder, the rotation axis or center axis of the processing tool etc. is aligned with the center axis of the multi-function tool holder including the main axis. First, second and third adjusting means are provided, the first means is a means for adjusting the float amount of the joint, the second means is a means for fixing the float amount adjusted in the first, Is a multi-function tool holder and a device using the tool holder, which is a means of further evolving the axis alignment performed in the first and second, and bringing it closer to zero.   The first adjustment means to adjust the float amount of the joint is to move a steel ball provided on the outer periphery of the shank to the chucking holder side by operating the adjustment nut, and to displace the chucking holder part with the joint relative to the shank. The multifunction tool holder according to claim 1, wherein a rotation axis or center axis of a processing tool or the like is aligned with a center axis of a multifunction tool holder including a main shaft.   The second adjusting means for fixing the float amount adjusted in the first step is to tighten the chucking holder outer periphery from the shank side with a plurality of adjusting screws provided on the outer periphery of the shank after the adjustment by the first means. The multi-function tool holder according to claim 1 and an apparatus using the same, wherein the chucking holder part is integrated to fix the float amount, and the axis is aligned.   The third adjustment means to further evolve the axial alignment performed in the first and bring it closer to zero is to provide a fitting ring on the chucking holder outer periphery and a plurality of adjustment screws provided on the fitting ring outer periphery. The multi-function tool holder according to claim 1, wherein the multi-function tool holder and the center axis of the multi-function tool holder including the main axis are aligned with each other by elastically deforming the rotation axis or the center axis of the processing tool or the like. A device using this.

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