JP2016097458A - Centering jig for machine tool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a centering jig which is unnecessary to center again, if centering in a machine tool to be used once, even if machine tools are different.SOLUTION: A fitting mechanism 40 fitting in a vertical direction on a right angle coordinate position formed by a specified surface of a fixed base 10 and a specified surface of a moving base 20, is formed with a projecting/recessed portion made from four recessed portions 23, .., 26 and projecting portions 13, .., 16 formed with inclined surfaces of 45-80 degrees on both sides in parallel with a right angle coordinate (an X-axis, and a Y-axis) passing through a center point. By integrally fastening the fixed base 10 and the moving base 20 on a machine tool side with a fastening bolt, precise machining to a workpiece is enabled.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a machine tool centering jig capable of omitting centering of a workpiece in a machining table of a machine tool, for example, a lathe, a drilling machine, a boring machine, a milling machine, a grinding machine, a gear cutting machine, a machining center, a mold, and the like. As a centering tool such as an electric discharge machine of a carved electric discharge machine or a wire electric discharge machine, the center of the workpiece is continuously centered in a state where the machine tool is centered once without repeatedly performing the centering individually. The present invention relates to a centering jig for machine tools that can perform processing without being influenced by the above.

In Patent Document 1, a port is centered by a machining center, a port reference surface and a knock pin hole are finished using the center obtained by the centering as a reference, a reference pin is provided on a mandrel, and then the port is engraved. On the table of the electric discharge machine, the reference pin is positioned and set at the center of the reference hole of the electrode plate, the port bearing surface is processed and formed by the mandrel-shaped hole formed in the electrode plate, and the die is formed by the machining center Centering, finishing the die reference surface and knock hole with the center determined by this centering as a reference, forming a wire hole in the port contact surface with the center as a reference, and then cutting the die into a wire Set on an electric discharge machine and machine and form the die bearing surface with the wire inserted through the wire hole. Therefore, it is not necessary to machine and form the spigot part for positioning the port and die, the dowel pin and the dowel hole by actual matching, the production is simple and easy, and does not require the skill and labor of the operator. And die can be combined with high accuracy.

  In Patent Document 2, which is a conventional example, the posture of a workpiece having first and second surfaces intersecting each other is defined by the X-axis and Y-axis orthogonal to each other set in the machine tool with respect to the relative motion between the tool head and the machining table. A workpiece posture adjusting apparatus for adjusting based on an axis and a Z-axis, comprising: a mounting body for mounting a base and a workpiece; and a support mechanism for supporting the mounting body interposed between the base and the mounting body. The first correction means for correcting the inclination of the first surface of the workpiece with respect to the XY plane by driving the mounting body in the Z-axis direction, and the mounting body around an axis parallel to the Z-axis A second correction unit that corrects an inclination of the second surface with respect to the X-axis direction by being driven to rotate; the inclination of the first surface with respect to the XY plane and the inclination of the second surface with respect to the X-axis direction; Related coordinates A coordinate value detecting means for detecting, in which and a control means for controlling the operation of the correction means in response to a signal from the coordinate value detecting means.

With this configuration, coordinate values related to the inclinations of the first and second surfaces of the workpiece are detected, and the operation of each correction unit is controlled according to the detected coordinate values, so that the workpiece is brought into a desired mounting posture. It can be corrected automatically. Further, since the surface of the workpiece is corrected based on the motion axis of the machine tool, the correction can be performed with high accuracy without being affected by the mounting error between the base and the processing table.
Therefore, Patent Document 2 eliminates the need for human intervention, which has been a major obstacle when performing unattended automation of processing, and includes problems such as work replacement and fine adjustment of tilt and parallelism. This makes it possible to adjust the posture of the workpiece easily and accurately in a short time without depending on the skill of the worker, and can handle unattended automation.

JP 07-1253 A JP-A-10-138075

  As described above, since Patent Document 1 fixes a base on a processing table of a machine tool, adjusts the posture of the mounting body with respect to the base, and attaches a workpiece to the mounting surface of the mounting body. It is necessary to adjust the posture of the mounting body with respect to the base on the machining table. Moreover, it is necessary to adjust the rotational position of the attachment body around the Z axis, and fine adjustment is required even when machining with a specific machine tool. Of course, it was not applicable when the machining process was moved from a specific milling machine to a die-sinking electric discharge machine, a wire electric discharge machine or the like.

Further, Patent Document 2 fixes a base on a processing table of a machine tool, adjusts the posture of the mounting body with respect to the base, attaches the work to the mounting surface of the mounting body, and the work surface of the work becomes an XY plane. The Z-axis direction position of the central part of the four sides of the mounting body is adjusted so that each drive fixing member is fed back by a piezoelectric displacement element that adjusts the amount of displacement according to the applied voltage. It is fixed, and the posture of the workpiece is controlled easily and accurately in a short time. It is an invention of a control technique that is completely different from jigs, etc. When the machining process is moved to a machining machine or a wire electric discharge machine, it cannot be applied.

  Therefore, according to the present invention, for example, even if machine tools such as a milling machine, a grinding machine, and an electric discharge machine are different, if the machine tool to be used is centered once, then it is necessary to re-center. It is an object of the present invention to provide a centering jig for machine tools that can be used in common without questioning the type of machine tool to be used.

  A machine tool centering jig according to a first aspect of the present invention is a machine tool side fixed base that is attached to a machine tool side and specifies a centering position of a workpiece to be attached to the machine tool side, and the workpiece. A movable base that can be fixed to the fixed base on the machine tool side in a state in which the workpiece is mounted in the workpiece mounting hole, and the rectangular coordinates (X axis, Y passing through the center point) of the fixed base and the movable base. A fitting mechanism comprising a concave portion and a convex portion having inclined surfaces of 45 to 80 degrees formed on both sides parallel to the axis and the Z axis, and for fitting the fixed base and the movable base, and the fitting A fastening bolt for fastening the fixed base and the movable base together in a fitted state between the fixed base having the concave portion or the convex portion of the mechanism and the movable base having the convex portion or the concave portion; It is equipped with

Here, the fixed base on the machine tool side is attached to the machine tool side, and the centering position of the workpiece attached to the machine tool side, that is, the centering position of the machine tool and the rectangular coordinate position of the fixed base. The centering position (X axis = 0, Y axis = 0) is specified and fixed.
The movable base has a workpiece attachment hole in the center, and the workpiece is attached to the movable base and fixed to the fixed base on the machine tool side. The movable base is disposed in the workpiece attachment hole. The size and shape of the workpiece are not questioned. A specific centering position (X axis = 0, Y axis = 0) of a rectangular coordinate position may be uniquely determined between the fixed base and the workpiece.
The tightening bolt is configured such that a specific surface of the fixed base and a specific surface of the movable base are fitted, and the fixed base and the movable base are integrally screwed in the fitted state.
The movable base to which the workpiece is mounted is arranged such that one of the X-axis at one of the rectangular coordinate positions or one of the Y-axis centering positions, or one of the X-axis at the rectangular coordinate positions and the Y-axis with respect to the workpiece mounting hole. When one pair of tightening bolts is tightened and released, the centering position (X axis = 0, Y axis = 0) is uniquely determined.

Further, the fitting mechanism includes four inclined surfaces of 45 to 80 degrees formed on both sides parallel to the rectangular coordinate (X axis, Y axis) passing through the center point of the machine tool side base and the movable base. Consisting of a concave part and a convex part, the fixed base on the machine tool side and the movable base are fitted in a vertical direction (Z-axis direction) on a rectangular coordinate position (X-axis, Y-axis). Moreover, as for the fitting mechanism which consists of four concave parts and convex parts at this time, a mutual unevenness | corrugation fits.
When the inclined surface parallel to the rectangular coordinate (X axis, Y axis) passing through the center point of the fixed base on the machine tool side and the movable base is set to 45 to 80 degrees, the inclined surface is less than 45 degrees. Even if the machine tool side fixed base and the movable base are tightened, they are tightened without staying at a specific position assigned to them. Further, when the inclined surface exceeds 80 degrees, when the fixed base and the movable base on the machine tool side are tightened, the both are tilted. There is a possibility that both will mesh. Therefore, if the inclined surface is 45 to 80 degrees, the value is suitable because the fixed base and the movable base on the machine tool side slide to the original positions.

A centering jig for a machine tool according to a second aspect of the present invention is disposed on a surface opposite to a fitting mechanism side provided on the movable base, and a specific surface of the fixed base on the machine tool side and a specification of the movable base A protective frame that surrounds the rectangular coordinate position (X axis, Y axis) formed on the surface and the vertical direction (Z axis direction) is attached.
Here, the protective frame body does not directly receive an impact caused by a collision with another member or a drop on a workpiece disposed on the surface opposite to the fitting mechanism provided on the movable base. Formally, around the workpiece in a rectangular coordinate position (X axis, Y axis) formed by the specific surface of the fixed base and the specific surface of the movable base on the machine tool side, and It surrounds the vertical direction (Z-axis direction). Moreover, it is not always necessary to form the protective frame body with metal, and synthetic resin, synthetic rubber, wood, or the like can also be used.

The fixed base on the machine tool side of the centering jig for machine tools according to the invention of claim 3 is provided with a through-hole through which a cutting tool passes at the center, similarly to the movable base.
Here, the fixed base on the machine tool side is provided with a through-hole through which a cutting tool passes in the center like the movable base. Even when the machine tool is changed from a milling machine to an electric discharge machine, the machine tool It can be processed without the need to replace the centering jig. Here, the through hole through which the cutting tool passes is not necessarily limited to the center, and can be set from the workability of the machine tool. However, it is desirable to provide a through-hole through which the cutting tool passes in the center from the relationship of the visually recognizable centering position.

The fitting mechanism comprising the four concave portions and the convex portion of the centering jig for machine tools according to the invention of claim 4 is such that the four concave portions or the convex portions are fitted only at a specific position. It is set as the structure which unites.
Here, the fitting mechanism composed of the four concave portions and the convex portion is configured such that the four concave portions or the convex portions are fitted to each other only at a specific position, and has a specific shape. It is possible to make it possible to fit only when four of these match. Needless to say, the four concave portions or the convex portions can be fitted at two locations, or can be fitted at four locations.

The centering jig for a machine tool according to the first aspect of the present invention specifies the centering position of the workpiece by a fixed base on the machine tool side attached to the machine tool side, and is attached to the machine tool side. The workpiece is attached to the workpiece mounting hole of the movable base on the fixed base on the machine tool side. In this state, the specific surface of the fixed base and the specific surface of the movable base are fitted, and in the fitted state, the fixed base and the movable base on the machine tool side are integrally tightened with a tightening bolt.
The fitting mechanism for fitting in the vertical direction on the rectangular coordinate position formed by the specific surface of the fixed base on the machine tool side and the specific surface of the movable base is the rectangular coordinate (X axis, Y passing through the center point). Since the concave and convex portions are formed by four concave portions and convex portions formed with inclined surfaces of 45 to 80 degrees on both sides parallel to the axis), the fixed base and the movable base are integrated with a fastening bolt. Once tightened, the integration allows machining without any deviation.
Further, since the fixed base on the machine tool side and the movable base can be uniquely determined, even if the fixed base attached to the machine tool side is a specific lathe, a drilling machine, boring machine, milling machine, grinding machine Even if it is a gear cutting machine, machining center, die-sinking electric discharge machine, wire electric discharge machine, etc., if the centering position of a specific workpiece is set there, it is limited to the use of one type of processing machine Without attaching the machine tool side base to a plurality of machine tool sides in advance or sequentially, a plurality of machine tools can be used.
And the fitting mechanism which consists of the concave part and convex part which formed the 45-80 degree inclined surface in the both sides which are formed in the specific surface of the fixed base by the side of the machine tool and the specific surface of the movable base, for example, If the position where four pieces are fitted simultaneously is specified, the fitting is performed only at the specific position, and the directionality can be given. If the fitting mechanism consisting of four concave parts and convex parts formed with inclined surfaces of 45 to 80 degrees on both sides is fitted at 90 degree intervals, they can be fitted at four positions. Can do.
Further, the movable base to which the workpiece is attached has one of the X-axis at the rectangular coordinate position or one of the Y-axis centering positions, or one of the X-axis at the rectangular coordinate position and the workpiece mounting hole. If one pair of tightening bolts on the Y-axis is tightened or released, the centering position (X-axis = 0, Y-axis = 0) is uniquely determined, so there is no need to perform centering each time. .

The centering jig for a machine tool according to a second aspect of the present invention is further disposed on the opposite surface side of the fitting mechanism side provided on the movable base, and a specific surface of the fixed base on the machine tool side and the movable base. A protective frame that surrounds a rectangular coordinate position (X-axis, Y-axis) formed on a specific surface and its vertical direction (Z-axis direction) is attached.
Therefore, since it has a protective frame in addition to the configuration of claim 1, it is in the rectangular coordinate position (X axis, Y axis) formed by the specific surface of the fixed base on the machine tool side and the specific surface of the movable base. By surrounding the workpiece and the vertical direction (Z-axis direction), the workpiece disposed on the surface opposite to the fitting mechanism provided on the movable base collides with other members. Or do not receive impact directly from dropping. Further, the protective frame can be formed of synthetic resin or synthetic rubber, and the work piece being worked on can be stored in that state. And since processing scraps, such as cutting, are not scattered, the circumference is not polluted.

  Since the fixed base on the machine tool side of the centering jig for machine tools according to claim 3 is provided with a through-hole through which a cutting tool passes at the center, similarly to the movable base, claim 1 or claim In addition to the effect described in Item 2, since the machine tool side fixed base and the movable base pass through, the machine tool can perform work passing through the machine tool side fixed base and the movable base. For example, the degree of freedom of combination of the machine tools is increased as in a milling machine and a wire cut electric discharge machine. Further, since the through hole is provided in the center like the movable base, the centering position is easily visible.

  In the centering jig for machine tools according to claim 4, the fitting mechanism composed of the concave portion and the convex portion is configured such that four of the four concave portions or the convex portions are fitted only at a specific position. Therefore, in addition to the effects described in claims 1 to 3, the fitting mechanism including the four concave portions and the convex portions transmits an external force. Machining of workpieces with no gap becomes easy.

1A and 1B are perspective views showing a relationship between a fixed base and a movable base in a centering jig for machine tools according to an embodiment of the present invention. FIG. 1A is a perspective view seen from the upper side of the movable base, and FIG. It is the perspective view seen from the fixed base by the side of a machine. FIG. 2 is a perspective view showing the relationship between the machine tool side fixed base and the movable base in the machine tool centering jig according to the embodiment of the present invention, and (a) is a perspective view seen from the lower side of the movable base. (b) is a perspective view seen from the lower side of the machine tool side fixed base, (c) is a perspective view seen from the upper side of the fitting state of the movable base and the fixed base. FIG. 3 shows the relationship between the machine tool side fixed base and the movable base in the machine tool centering jig according to the embodiment of the present invention. FIG. 3A is a plan view seen from the upper side of the movable base. Is a front view as seen from the front. FIG. 4 is a cross-sectional view taken along line AA in FIG. FIG. 5 is a cross-sectional view in which the protective frame is removed from the cross-sectional view taken along line AA in FIG. FIG. 6 is an exploded perspective view of the machine tool side fixed base, the movable base, the workpiece, and the protective frame according to the embodiment of the present invention. 7A and 7B are explanatory views of the machine tool side fixed base in the machine tool centering jig according to the embodiment of the present invention. FIG. 7A is a perspective view of the fitting mechanism of the machine tool side fixed base, and FIG. It is explanatory drawing of the cross section of a mechanism. FIG. 8 is a developed perspective view of a specific machine tool side fixed base in the machine tool centering jig according to the embodiment of the present invention. FIG. 9 is an explanatory diagram of a state in which the machine tool centering jig according to the embodiment of the present invention is attached to the table of the machine tool.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that, in the embodiments, the same reference numerals and the same reference numerals are the same or corresponding functional parts, and therefore, redundant description thereof is omitted here.

[Embodiment]
1 to 9, for example, a work piece attached to a machine tool side to be machined such as a lathe, drilling machine, boring machine, milling machine, grinding machine, gear cutting machine, machining center, die-sinking electric discharge machine, wire electric discharge machine or the like. The fixed base 10 on the machine tool side that specifies the centering position of the object 50 is arranged on a bed or table of a machine tool by a known technique. For example, a known centering jig for a milling machine, a centering jig such as a dial gauge, or the like. Mounted using. Machine tool side such as lathe, drilling machine, boring machine, milling machine, grinding machine, gear cutting machine, machining center, die-sinking EDM, wire EDM etc. It can also be attached to each.
The workpiece 50 will be described as an example of small parts. However, when the present invention is carried out, the fixed base 10 on the machine tool side only corresponds to the size of the workpiece 50 relatively. Yes, it can be used without being limited to small parts.

The fixed base 10 on the machine tool side according to the present embodiment has an outer diameter of a square (a rectangular parallelepiped), but may be a rectangle or a circle. That is, as long as it can be easily mounted on the machine tool side, the shape is not questioned. The structure disposed on the bed and table of the machine tool may be bolted directly to the bed and table of the machine tool as long as the structure can be firmly attached. 1 is a screwing hole for attaching the fixed base 10 on the machine tool side with a bolt (not shown). In addition, the structure arrange | positioned at the bed of a machine tool in case of implementing this invention, and a table is not limited to what is screwed in the attachment hole 11 of FIG. 1, The attachment hole 11 side of FIG. It can be on the bolt side, or other attachment means.
The connection hole 12 of the central fixed base 10 is screwed with the jig mounting bolt 77. For example, the wire electrode of a wire electric discharge machine penetrates and has a shape that matches the appropriateness of the machine tool. You can also. For this reason, the connection hole 12 of the fixed base 10 on the machine tool side of the present embodiment has a small diameter or a large diameter as a through hole through which the cutting tool passes, or the shape thereof is a quadrilateral or more polygonal or a special shape. It may be a shape. In any case, it is preferable that the workpiece 50 can be freely attached and detached, and the core does not move when the workpiece 50 is attached again.

The central axes of the connection holes 12 of the fixed base 10 on the machine tool side according to the present embodiment are X-axis = 0, Y-axis = 0, and Z-axis = 0 in the rectangular coordinate position. The X axis of the rectangular coordinate is a straight line XX direction, the Y axis is a straight line YY direction, the Z axis is a straight line ZZ direction, and the Z axis is a loading direction of the fixed base 10 and the movable base 20. is there.
The convex portions 13 and 15 are disposed in the Y-axis direction, and the convex portions 14 and 16 are disposed in the X-axis direction. The convex portions 13 and 15 and the convex portions 14 and 16 are arranged at positions that are separated by an equal distance from the X-axis = 0, Y-axis = 0, and Z-axis = 0 positions of the rectangular coordinate position. Similarly, each of the convex portions 13 and 15 and the convex portions 14 and 16 has tightening holes 13a and 14a at equal positions from the X-axis = 0, Y-axis = 0, and Z-axis = 0 positions of the rectangular coordinate position. , 15a, 16a are formed.

The raised portions 13, 14, 15, and 16 have a height H ₁ rising from the upper surface of the fixed base 10, and the height of the straight raised portion h ₁ that is vertically raised from the upper surface of the fixed base 10. have. The straight rising portion h ₁ that rises vertically absorbs an error in the fitting depth between the fixed base 10 and the movable base 20.
Further, the inventor conducted an experiment by changing the angle θ _L = θ _R to 30, 45, 60, 70, 80, and 90 degrees. As a result, the angle θ _L and the angle θ _R on both sides along the X axis and the Y axis of the rectangular coordinate positions of the convex portions 13, 14, 15, 16 are inclined surfaces of 45 to 80 degrees. The inclined surface formed by 45 to 80 degrees of the angle θ _L and the angle θ _R on both sides along the X-axis and Y-axis of the convex coordinate portions 13, 14, 15 and 16 is a fixed base on the machine tool side. When the movable base 20 and the movable base 20 are mechanically coupled, the energy of the external force is easily transmitted between them. More preferably, the angle θ _L = θ _R is in the range of 60 to 80 degrees.

Incidentally, if the inclined surfaces of 45 to 80 degrees on both sides along the X-axis and Y-axis at the rectangular coordinate position are inclined surfaces of 45 degrees or less, the fitting between the fixed base 10 and the movable base 20 of the fitting mechanism 40 is performed. The tightening bolts 41, 42, 43, which are screwed into the tightening holes 13a, 14a, 15a, 16a while being held by the support holes 23a, 24a, 25a, 26a formed in the movable base 20 44, the tightening bolts 41, 42, 43, and 44 are cut or stretched, and machining by the machine tool becomes impossible.
Conversely, if the angle θ _L and the angle θ _R of the inclined surfaces on both sides along the X-axis and Y-axis at the rectangular coordinate position are 80 degrees or more, the machine tool side fixed base 10 and the movable base 20 in the Z-axis direction In the change, when the angle becomes large, the problem is that the movable base 20 is slidably coupled to the fixed base 10 and the fastening bolts 41, 42, 43, 44 are tightened so that they can be separated and cannot be separated. The bigger the possibility, the higher the possibility.
Therefore, according to the experiment by the inventor, it was confirmed that the angle θ _L and the angle θ _{R of the} inclined surface of 45 to 80 degrees on both sides along the X-axis and the Y-axis at the rectangular coordinate position can be used stably. It was. Of course, other shapes may be used if used for this purpose.

Although the movable base 20 of the present embodiment has a square outer diameter, it can be rectangular or circular like the fixed base 10. That is, as long as it is attached to the fixed base 10 on the machine tool side and can be easily centered, the shape is not questioned. Then, two pairs of mounting female screws 22b, 23b, 24b, and 25b are drilled from four directions in the workpiece mounting hole 21 for mounting the workpiece 50 on the movable base 20, and the workpiece is provided there. 50 positioning and detent locking screws 45, 46, 47, 48 are screwed together. The lock screws 45, 46, 47, 48 may be tightened as positioning of the workpiece 50, or may be tightened via mounting female screws 22 b, 23 b, 24 b, 25 b as detents during processing of the workpiece 50. . In particular, if the workpiece 50 is not machined, one pair from two directions is to fix two surfaces of the two pairs of mounting female screws 22b, 23b, 24b, and 25b from the four sides of the workpiece mounting hole 21. The lock screws 45, 46, 47, 48 may be screwed together, or the mounting position may be finely adjusted by a pair of lock screws 45, 46, 47, 48.

Specifically, the workpiece 50 according to the present embodiment is configured so that the machining part 51 machined into a specific shape, the pedestal 52 that maintains the machining part 51, and the workpiece attachment hole 21 are not inserted. And a fixing portion 54 fixed by a pair of lock screws 45, 46, 47, 48 with the entire workpiece 50 as an attachment position.
On the movable base 20 to which the workpiece 50 is attached, only one of the X-axis of the rectangular coordinate position, only one of the Y-axis, or the rectangular coordinate position with respect to the fixing portion 54 mounted in the workpiece mounting hole 21. The pair of lock screws 45, 46, 47, 48 or the pair of lock screws 45, 46, 47, or the two pairs of lock screws 45, 46, 47, 48 are tightened or released. , 48, the centering position (X axis = 0, Y axis = 0) is uniquely determined, so there is no need to perform centering each time.

The center of the workpiece attachment hole 21 is set to a rectangular coordinate position (X axis = 0, Y axis = 0). The convex portions 13 and 15 and the convex portions 14 and 16 of the fixed base 10 are formed with concave portions 23 and 25 and concave portions 24 and 26 of the movable base 20 at opposite positions. In the present embodiment, the convex portions 13 and 15 and the convex portions 14 and 16 of the fixed base 10, and the concave portions 23 and 25 and the concave portions 24 and 26 of the movable base 20 at the opposite positions of the fixed base 10 have the same shape. and shaving to form the inclined surface of the angle theta _L and the angle theta _R. In the present embodiment, the convex portions 13, 14, 15, 16 and the concave portions 23, 24, 25, 26 have the same shape. However, when the present invention is implemented, the convex portions 13, 14, 15 , 16 and the concave portion 23, 24, 25, 26, by performing the finishing on the way cutting, and change the shape, it is possible to change the angle theta _L and the angle theta _R of the inclined surface. Further, the height of the convex portions 13, 14, 15, 16 and the depth of the concave portions 23, 24, 25, 26 can be changed.

In other words, in the present embodiment, the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20 have the same shape, so that the fitting is performed every 90 degrees. The fitting position of the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20 is determined by the directionality in which the coupling mechanism 40 is fitted, and the workpiece 50 Is set.
However, when the fitting mechanism 40 that fits only when the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20 have a specific angle is used, the machine tool Can be fitted in the correct direction. The form in which the fitting is performed only in the case of this specific angle is the inclination angle of the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20, that is, the angle Any of θ _L and angle θ _R and their dimensions or arrangement can be set.

For example, the convex portions 13, 14, 15, 16 of the fixed base 10 of the fitting mechanism 40 and the concave portions 23, 24, 25, 26 of the movable base 20 are fixed to the fixed base 10 as shown in FIG. A gap h ₀ is generated in a state of being fitted to the movable base 20 connected thereto.
In other words, the convex portions 13 and 15 in the Y-axis direction have the width X ₂ -X ₁ , similar to the convex portions 14 and 16. A vertical distance h ₁ is formed from the upper surface of the fixed base 10, and the height is the left side angle θ _L and the height is the convex part interval H ₁ . Also it has been from the upper surface of the fixed base 10 to form a vertical distance h _1, from which the height of the convex portions the interval H ₁ at right angles theta _R. Here, the left angle theta _L will be equal to the right angle theta _R. Further, the convex portions 14 and 16 in the X-axis direction have a width Y ₂ -Y ₁ , similar to the convex portions 13 and 15.
Vertically downward from the lower surface of the movable base 20, a distance downwardly disposed a vertical distance h _2, has a height including a vertical distance h ₂ between recess spacing H ₂ there from left angle 180-θ _L. Similarly, it has a height also including vertical distance h ₂ at the right angle 180-theta _R side concave portion interval H _2.

Here, with respect to the convex portion 13 of the fixed base 10, and at the same time the concave portion 23 of the movable base 20 is fitted, by the left angle theta _L is and the right angle theta _R form slant convex portion of the fixed base 10 Reference numerals 13, 14, 15, and 16 are fitted into a fitting mechanism 40 including the concave portions 23, 24, 25, and 26 of the movable base 20. At this time, the slope left angle theta _L and a right angle theta _R form, slope left angle 180-theta _L and the right angle 180-theta _R is formed, surface contact in a parallel state, the upper surface of the fixed base 10 the lower surface of the movable base 20 is stopped in the state of the vertical distance h _1.
Here, even if the fastening bolts 41, 42, 43, 44 are screwed together, the convex portions 13, 14, 15, 16 of the fixed base 10 are connected to the concave portions 23, 24, 25, 26 of the movable base 20. The surface contact of the two contacts without meshing. Further, the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20 slide in the X-axis direction and the Y-axis direction of the fixed base 10 and the movable base 20. Even if a rotational force centered on the connection hole 12 of the fixed base 10 is applied, it is transmitted efficiently and transmitted as a rotational force on the other side.
Note that the slope of the left angle theta _L and a right angle theta _R form, slope left angle 180-theta _L and the right angle 180-theta _R form is worn with use, the error terms due to the abrasion There is little change.

In the case of the fitting mechanism 40 for fitting the convex portions 13, 14, 15, 16 and the concave portions 23, 24, 25, 26 only at a specific position, the convex portions 13, 14, 15, 16 the left angle theta _L tilt angle and / or inclined surface of the right angle theta _R of may be changed. Of course, the inclination angle of the left side angle 180-θ _L and / or the inclination angle of the right side angle 180-θ _R of the concave portions 23, 24, 25, 26 may be changed. Logically, the left angle θ _L (180−θ _L ) and / or the right angle θ _R (180−θ _R ) may be changed. The left angle θ _L and the left angle If the difference between the inclination angle of 180-θ _L, the right angle θ _R, and the right angle 180-θ _R is small, it is difficult to engage and separate, so the difference between the angles is preferably 3 to 10 degrees. Alternatively, it is desirable to make contact with the flat upper surfaces of the convex portions 13, 14, 15, 16.

Thus, in this Embodiment, the fitting mechanism 40 which fits the convex parts 13, 14, 15, 16 and the concave parts 23, 24, 25, and 26 as the same shape is comprised.
However, when practicing the present invention, the height of the convex portions 13, 14, 15 and 16, its position, by changing the angle theta _L and the angle theta _R of the inclined surface, also concave portion 23, also the depth of the valley about 24, 25, 26 (opposite of the convex portions 13, 14, 15, 16), by changing its position, angle 180-theta inclined surfaces _L and 180- angle theta _R, It can be set as the fitting mechanism 40 of the structure which does not fit unless it is the direction of the specific workpiece 50. FIG.

3 to 6, the protective frame 30 is disposed on the opposite surface side of the fitting mechanism 40 provided on the movable base 20, and the specific surface of the fixed base 10 on the machine tool side and the specific surface of the movable base 20. Specifically, in the space 31 surrounding the rectangular coordinate position (X axis, Y axis) and the vertical direction (Z axis direction) formed by the It is desirable that there is no mechanical contact between the workpiece 50 and the protective frame 30 and that the end of the workpiece 50 does not protrude from the end opening of the protective frame 30. For this reason, the inside of the protective frame 30 is formed in the space 31.

  In the protective frame 30 of the present embodiment, two-stage workpiece mounting holes 38a having different diameters are formed in the middle of the opposite angle of the protective frame 30, and two mounting bolts 39 are screwed there. In addition, it is adapted to be attached to the attachment female screw 37 on the upper surface of the movable base 20. Of course, in this embodiment, the protective frame 30 is attached to the opposite angle of the movable base 20 by the two attachment bolts 39, but each corner of the protective frame 30 is provided by the four attachment bolts 39. May be tightened. Further, the center of the opposite side of the protective frame 30 may be attached.

The protection frame 30 is attached inadvertently when a workpiece such as a spanner is hit against the workpiece 50 during the replacement work of the workpiece 50 or when the workpiece 50 is removed from the machine tool. Even if such a case occurs, the protective frame 30 receives the impact, and even if it is transmitted to the movable base 20, it is not transmitted to the workpiece 50. The workpiece 50 is prevented from being deformed or distorted by an impact.

In the above embodiment, it has been described that the fixed base 10 on the machine tool side is mounted on the bed and table of the machine tool. However, as shown in FIGS. You can also.
That is, on the mounting side of the fixed base 10 on the machine tool side, the mounting plate 71 made of steel, brass, brass or the like is inserted into the insertion hole 71a of the mounting object by the four bolts 72, and the mounting hole 11 in FIG. It is tightened.
The jig mounting bolt 77 includes a thick ring-shaped annular member 76, one surface having a square or hexagon, a mounting block 75 having an annular shape on the annular member 76 side, a washer 74, and a lock nut 73. They are screwed in sequentially.
Here, the attachment plate 71, the bolt 72, the lock nut 73, the washer 74, the attachment block 75, the annular member 76, and the jig attachment bolt 77 constitute a one-touch fixture 70 attached to the machine tool. Of course, the configuration of the one-touch fixture 70 is not limited to this configuration.

As is well known, the jig mounting bolt 77 has its free end screwed into the connection hole 12 of the fixed base 10 at the center of the fixed base 10, and the lock nut 73 fixes its position. Further, the attachment block 75 is screwed through the washer 74 to stop the washer 74. A fixing tool 83 on the machine tool side is inserted into a place formed by the attachment block 75 and the annular member 76, and is fixed while being pulled in a specific direction.
Accordingly, the one-touch fixing tool 70 is fixed to the portion formed by the attachment block 75 and the annular member 76 while being pulled in a specific direction by the fixing tool on the machine tool side. In this embodiment, since it is not necessary to fix a plurality of places, work efficiency is efficient.

FIG. 9 shows an example in which the one-touch fixture 70 is used. A slidable chucking device 81 is provided on the processing table 80 to hold the receiving jig 82. The receiving jig 82 is provided with a fixing tool 83 driven by hydraulic pressure or bolts, and is attached to the receiving jig 82 on the machine tool side fixed base 10. Here, if the center of the fixed base 10 on the machine tool side is aligned, the movable base 20 becomes the same core in a state where the workpiece 50 is attached to a specific surface of the movable base 20, and the workpiece 50 is centered. It ’s gone.
Therefore, the electrode 110 of the die-sinking electric discharge machine 100 shown in FIG. 9 can be controlled around its axis. Of course, in a lathe, drilling machine, boring machine, milling machine, grinding machine, gear cutting machine, machining center, wire electric discharge machine, etc., each machine tool is similarly moved by moving the workpiece 50 attached to the movable base 20. It is possible to perform the mounting process of the movable base 20 to which the workpiece 50 is mounted without performing centering.

  In the above embodiment, the connection hole 12 is provided in the center of the machine tool side fixing base 10, and the size of the connection hole 12 is fitted to the jig mounting bolt 77 of the one-touch fixing tool 70. When the present invention is carried out, the shape of the fixed base 10 can be the connection hole 12 having a size for mounting the workpiece 50 in the same manner as the workpiece mounting hole 21 for mounting the workpiece 50 of the movable base 20. . As a result, lathes, drilling machines, boring machines, milling machines, grinding machines, gear cutting machines, machining centers, wire electric discharge machines, etc. can be used freely. Similarly, by moving the workpiece 50 attached to the movable base 20 The mounting process of the movable base 20 to which the workpiece 50 is mounted can be performed without centering each machine tool.

The machine tool centering jig of the above embodiment is attached to the machine tool side, the machine tool side fixed base 10 for specifying the centering position of the work piece 50 attached to the machine tool side, and the workpiece. The movable base 20 that can be fixed to the fixed base 10 on the machine tool side with the 50 mounted in the workpiece mounting hole 21, and the fixed base 10 and the movable base 20 have rectangular coordinates (X axis, It consists of concave parts 23, 24, 25, 26 and convex parts 13, 14, 15, 16 formed with inclined surfaces of 45 to 80 degrees on both sides parallel to the Y axis and Z axis). The fixed base 10 and the convex portions 13, 14 having the fitting mechanism 40 for fitting with the concave portion 20 and the concave portions 23, 24, 25, 26 or the convex portions 13, 14, 15, 16 of the fitting mechanism 40. , 15, 16 or concave portions 23, 24 25,26 is to and a fastening bolt 41, 42, 43, 44 is tightened together with the fixed base 10 and the movable base 20 in a fitted state between the movable base 20 having a.

The machine tool centering jig of the above-described embodiment specifies the centering position of the workpiece 50 by the fixed base 10 attached to the machine tool side, and attaches it to the machine tool side. Further, the workpiece 50 is attached to the workpiece mounting hole 21 of the movable base 20 on the fixed base 10 on the machine tool side. In this state, the specific surface of the fixed base 10 on the machine tool side and the specific surface of the movable base 20 are fitted, and the fixed base 10 and the movable base 20 on the machine tool side are integrally fitted with the fastening bolt 41 in the fitted state. Tighten with 42, 43, 44.
Concave portions 23, 24, 25, 26 and convex portions 13, 14, 15 for fitting in a vertical direction on a rectangular coordinate position formed by a specific surface of the fixed base 10 on the machine tool side and a specific surface of the movable base 20. , 16 includes four concave portions 23, 24, 25 having inclined surfaces of 45 to 80 degrees formed on both sides parallel to the rectangular coordinate (X axis, Y axis) passing through the center point. , 26 and convex and concave portions 13, 14, 15, 16 are formed, so that the fixed base 10 and the movable base 20 on the machine tool side are integrally tightened with the tightening bolts 41, 42, 43, 44. If it is integrated, the workpiece 50 can be machined without any deviation.

Further, since the fixed base 10 and the movable base 20 on the machine tool side can be uniquely determined, even if the fixed base 10 on the machine tool side attached to the machine tool side is a specific lathe, a drilling machine or boring machine , Milling machines, grinding machines, gear cutting machines, machining centers, die-sinking electric discharge machines, wire electric discharge machines, etc., if you set the centering position of a specific workpiece 50 there, Without being limited to the use of a processing machine, a plurality of machine tools can be used if the fixed base 10 on the machine tool side is attached to a plurality of machine tool sides in advance or sequentially.

And four concave-shaped parts 23, 24, 25, 26 formed with inclined surfaces of 45 to 80 degrees on both sides formed on the specific surface of the fixed base 10 and the specific surface of the movable base 20 on the machine tool side, and If the fitting mechanism 40 which consists of the convex-shaped parts 13, 14, 15, 16 specifies the position which four pieces fit simultaneously, it will be fitted only in a specific position and can also give directionality. . If the fitting mechanism 40 consisting of the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16 having inclined surfaces of 45 to 80 degrees on both sides is formed every 90 degrees, It can be fitted at four positions.

The machine tool centering jig of this embodiment is disposed on the opposite surface side of the fitting mechanism 40 provided on the movable base 20, and the specific surface of the fixed base 10 and the specific surface of the movable base 20 on the machine tool side. A protective frame 30 is attached to surround the rectangular coordinate position (X axis, Y axis) and the vertical direction (Z axis direction).
Therefore, since the protective frame 30 is included, the periphery and the vertical direction of the workpiece 50 in the rectangular coordinate position (X axis, Y axis) formed by the specific surface of the fixed base 10 on the machine tool side and the specific surface of the movable base 20 are provided. By enclosing the direction (Z-axis direction), the workpiece 50 disposed on the opposite surface side of the fitting mechanism 40 provided on the movable base 20 is impacted by collision with another member or dropping. Do not receive directly. Further, it is possible to store the work piece in operation in a state of being formed of synthetic resin or synthetic rubber. And since processing scraps, such as cutting, are not scattered, the circumference is not polluted.

In the machine tool centering jig of the above-described embodiment, the machine tool side fixed base 10 is provided with the connection hole 12 for attaching the workpiece 50 at the center in the same manner as the movable base 20. Since the fixed base 10 on the side and the movable base 20 pass through, the machine tool can perform work that has passed through the fixed base 10 and the movable base 20 on the machine tool side, so that the machine tool is like a milling machine and a wire-cut electric discharge machine. The degree of freedom of combination increases.

In the machine tool centering jig of the above embodiment, the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16 has the four concave portions or Since the four protrusions are configured to be fitted only at a specific position, the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16 transmits an external force. Since it is a natural coupled state, it is easy to process the workpiece 50 without difficulty.

In the machine tool centering jig of the above embodiment, the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16 has the convex portions 13, 14. , 15 and 16 are constituted by protrusions or depressions having a truncated pyramid shape in cross section.
This projecting cross-sectional square frustum is formed on one or both sides with inclined surfaces, and the inclined surfaces of the recesses of the concave portions 23, 24, 25, 26 are joined to the inclined surfaces by the surfaces. In addition, since the coupling is performed at a rectangular coordinate position (X axis, Y axis), the movement in the X axis direction is prevented, and the movement in the Y axis direction is also prevented, so that the movable unit connected to the fixed base 10 is movable. The workpiece 50 attached to the base 20 can be easily processed without difficulty.

Further, the machine tool centering jig of the above-described embodiment is configured by the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16. However, when practicing the present invention, the present invention is not limited to the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16. The position (X axis, Y axis) only needs to be configured so as not to move relative to each other, and a complicated shape can be obtained by cutting with a die-sinking electric discharge machine or the like.

The movable base 20 of the machine tool centering jig according to the above-described embodiment includes the mounting female screws 22b, 23b, 24b, into which the workpiece 50 is screwed with one or two pairs of lock screws 45, 46, 47, 48. The workpiece 50 can be attached and released by tightening or releasing the bolt 25b, and the workpiece 50 can be replaced only by operating one or two pairs of lock screws 45, 46, 47, 48. Does not change, so the centering position does not change.
Of course, the set position of the workpiece 50 may be measured with a caliper or a micrometer and set to a specific position.

Although the fixed base 10 and the movable base 20 of the centering jig for machine tools of the above embodiment have been described in the case of processing a small part, the present invention is limited to the processing of a small part. It is not something.

The present invention has been described as a centering jig for a machine tool to be attached to a processing table of a machine tool. However, in the case of carrying out the present invention, it may be arranged so that the relative motion of the processing machine can be performed, and horizontal, vertical There is also no installation condition for.

DESCRIPTION OF SYMBOLS 10 Fixed base 12 Connection hole 13, 14, 15, 16 Convex part 20 Movable base 21 Workpiece attachment hole 23, 24, 25, 26 Concave part 30 Protection frame 40 Fitting mechanism 41, 42, 43, 44 Tightening Bolt 50 Workpiece

  The present invention relates to a machine tool centering jig capable of omitting centering of a workpiece in a machining table of a machine tool, for example, a lathe, a drilling machine, a boring machine, a milling machine, a grinding machine, a gear cutting machine, a machining center, a mold, and the like. As a centering tool such as an electric discharge machine of a carved electric discharge machine or a wire electric discharge machine, the center of the workpiece is continuously centered in a state where the machine tool is centered once without repeatedly performing the centering individually. The present invention relates to a centering jig for machine tools that can perform processing without being influenced by the above.

In Patent Document 1, a port is centered by a machining center, a port reference surface and a knock pin hole are finished using the center obtained by the centering as a reference, a reference pin is provided on a mandrel, and then the port is engraved. On the table of the electric discharge machine, the reference pin is positioned and set at the center of the reference hole of the electrode plate, the port bearing surface is processed and formed by the mandrel-shaped hole formed in the electrode plate, and the die is formed by the machining center Centering, finishing the die reference surface and knock hole with the center determined by this centering as a reference, forming a wire hole in the port contact surface with the center as a reference, and then cutting the die into a wire Set on an electric discharge machine and machine and form the die bearing surface with the wire inserted through the wire hole. Therefore, it is not necessary to machine and form the spigot part for positioning the port and die, the dowel pin and the dowel hole by actual matching, the production is simple and easy, and does not require the skill and labor of the operator. And die can be combined with high accuracy.

  In Patent Document 2, which is a conventional example, the posture of a workpiece having first and second surfaces intersecting each other is defined by the X-axis and Y-axis orthogonal to each other set in the machine tool with respect to the relative motion between the tool head and the machining table. A workpiece posture adjusting apparatus for adjusting based on an axis and a Z-axis, comprising: a mounting body for mounting a base and a workpiece; and a support mechanism for supporting the mounting body interposed between the base and the mounting body. The first correction means for correcting the inclination of the first surface of the workpiece with respect to the XY plane by driving the mounting body in the Z-axis direction, and the mounting body around an axis parallel to the Z-axis A second correction unit that corrects an inclination of the second surface with respect to the X-axis direction by being driven to rotate; the inclination of the first surface with respect to the XY plane and the inclination of the second surface with respect to the X-axis direction; Related coordinates A coordinate value detecting means for detecting, in which and a control means for controlling the operation of the correction means in response to a signal from the coordinate value detecting means.

With this configuration, coordinate values related to the inclinations of the first and second surfaces of the workpiece are detected, and the operation of each correction unit is controlled according to the detected coordinate values, so that the workpiece is brought into a desired mounting posture. It can be corrected automatically. Further, since the surface of the workpiece is corrected based on the motion axis of the machine tool, the correction can be performed with high accuracy without being affected by the mounting error between the base and the processing table.
Therefore, Patent Document 2 eliminates the need for human intervention, which has been a major obstacle when performing unattended automation of processing, and includes problems such as work replacement and fine adjustment of tilt and parallelism. This makes it possible to adjust the posture of the workpiece easily and accurately in a short time without depending on the skill of the worker, and can handle unattended automation.

JP 07-1253 A JP-A-10-138075

  As described above, since Patent Document 1 fixes a base on a processing table of a machine tool, adjusts the posture of the mounting body with respect to the base, and attaches a workpiece to the mounting surface of the mounting body. It is necessary to adjust the posture of the mounting body with respect to the base on the machining table. Moreover, it is necessary to adjust the rotational position of the attachment body around the Z axis, and fine adjustment is required even when machining with a specific machine tool. Of course, it was not applicable when the machining process was moved from a specific milling machine to a die-sinking electric discharge machine, a wire electric discharge machine or the like.

Further, Patent Document 2 fixes a base on a processing table of a machine tool, adjusts the posture of the mounting body with respect to the base, attaches the work to the mounting surface of the mounting body, and the work surface of the work becomes an XY plane. The Z-axis direction position of the central part of the four sides of the mounting body is adjusted so that each drive fixing member is fed back by a piezoelectric displacement element that adjusts the amount of displacement according to the applied voltage. It is fixed, and the posture of the workpiece is controlled easily and accurately in a short time. It is an invention of a control technique that is completely different from jigs, etc. When the machining process is moved to a machining machine or a wire electric discharge machine, it cannot be applied.

  Therefore, according to the present invention, for example, even if machine tools such as a milling machine, a grinding machine, and an electric discharge machine are different, if the machine tool to be used is centered once, then it is necessary to re-center. It is an object of the present invention to provide a centering jig for machine tools that can be used in common without questioning the type of machine tool to be used.

A machine tool centering jig according to a first aspect of the present invention is a machine tool side fixed base that is attached to a machine tool side and specifies a centering position of a workpiece to be attached to the machine tool side, and the workpiece. A movable base that can be fixed to a fixed base on the machine tool side in a state in which an object is mounted in a workpiece mounting hole, and the fixed base and the movable base are in the X-axis direction and the Y-axis of rectangular coordinates passing through the center point An inclined surface of 45 to 80 degrees is formed on an opposing surface parallel to a straight line passing through the center point of the concave portion and the convex portion, and the fixed base and the movable base. And a fitting mechanism between the fitting base and the fixed base having the concave portion or the convex portion of the fitting mechanism and the movable base having the convex portion or the concave portion. One fixed base and one movable base The tightening is to and a fastening bolt.

Here, the fixed base on the machine tool side is attached to the machine tool side, and the centering position of the workpiece attached to the machine tool side, that is, the centering position of the machine tool and the rectangular coordinate position of the fixed base. The centering position (X axis = 0, Y axis = 0) is specified and fixed.
The movable base has a workpiece attachment hole in the center, and the workpiece is attached to the movable base and fixed to the fixed base on the machine tool side. The movable base is disposed in the workpiece attachment hole. The size and shape of the workpiece are not questioned. A specific centering position (X axis = 0, Y axis = 0) of a rectangular coordinate position may be uniquely determined between the fixed base and the workpiece.
The tightening bolt is configured such that a specific surface of the fixed base and a specific surface of the movable base are fitted, and the fixed base and the movable base are integrally screwed in the fitted state.
The movable base to which the workpiece is mounted is arranged such that one of the X-axis at one of the rectangular coordinate positions or one of the Y-axis centering positions, or one of the X-axis at the rectangular coordinate positions and the Y-axis with respect to the workpiece mounting hole. When one pair of tightening bolts is tightened and released, the centering position (X axis = 0, Y axis = 0) is uniquely determined.

Further, the fitting mechanism includes four inclined surfaces of 45 to 80 degrees formed on both sides parallel to the rectangular coordinate (X axis, Y axis) passing through the center point of the machine tool side base and the movable base. Consisting of a concave part and a convex part, the fixed base on the machine tool side and the movable base are fitted in a vertical direction (Z-axis direction) on a rectangular coordinate position (X-axis, Y-axis). Moreover, as for the fitting mechanism which consists of four concave parts and convex parts at this time, a mutual unevenness | corrugation fits.
When the inclined surface parallel to the rectangular coordinate (X axis, Y axis) passing through the center point of the fixed base on the machine tool side and the movable base is set to 45 to 80 degrees, the inclined surface is less than 45 degrees. Even if the machine tool side fixed base and the movable base are tightened, they are tightened without staying at a specific position assigned to them. Further, when the inclined surface exceeds 80 degrees, when the fixed base and the movable base on the machine tool side are tightened, the both are tilted. There is a possibility that both will mesh. Therefore, if the inclined surface is 45 to 80 degrees, the value is suitable because the fixed base and the movable base on the machine tool side slide to the original positions.

A centering jig for a machine tool according to a second aspect of the present invention is disposed on a surface opposite to a fitting mechanism side provided on the movable base, and a specific surface of the fixed base on the machine tool side and a specification of the movable base A protective frame that surrounds the rectangular coordinate position (X axis, Y axis) formed on the surface and the vertical direction (Z axis direction) is attached.
Here, the protective frame body does not directly receive an impact caused by a collision with another member or a drop on a workpiece disposed on the surface opposite to the fitting mechanism provided on the movable base. Formally, around the workpiece in a rectangular coordinate position (X axis, Y axis) formed by the specific surface of the fixed base and the specific surface of the movable base on the machine tool side, and It surrounds the vertical direction (Z-axis direction). Moreover, it is not always necessary to form the protective frame body with metal, and synthetic resin, synthetic rubber, wood, or the like can also be used.

The fixed base on the machine tool side of the centering jig for machine tools according to the invention of claim 3 is provided with a through-hole through which a cutting tool passes at the center, similarly to the movable base.
Here, the fixed base on the machine tool side is provided with a through-hole through which a cutting tool passes in the center like the movable base. Even when the machine tool is changed from a milling machine to an electric discharge machine, the machine tool It can be processed without the need to replace the centering jig. Here, the through hole through which the cutting tool passes is not necessarily limited to the center, and can be set from the workability of the machine tool. However, it is desirable to provide a through-hole through which the cutting tool passes in the center from the relationship of the visually recognizable centering position.

The fitting mechanism comprising the four concave portions and the convex portion of the centering jig for machine tools according to the invention of claim 4 is such that the four concave portions or the convex portions are fitted only at a specific position. It is set as the structure which unites.
Here, the fitting mechanism composed of the four concave portions and the convex portion is configured such that the four concave portions or the convex portions are fitted to each other only at a specific position, and has a specific shape. It is possible to make it possible to fit only when four of these match. Needless to say, the four concave portions or the convex portions can be fitted at two locations, or can be fitted at four locations.

The centering jig for a machine tool according to the first aspect of the present invention specifies the centering position of the workpiece by a fixed base on the machine tool side attached to the machine tool side, and is attached to the machine tool side. The workpiece is attached to the workpiece mounting hole of the movable base on the fixed base on the machine tool side. In this state, the specific surface of the fixed base and the specific surface of the movable base are fitted, and in the fitted state, the fixed base and the movable base on the machine tool side are integrally tightened with a tightening bolt.
The fitting mechanism for fitting in the vertical direction on the rectangular coordinate position formed by the specific surface of the fixed base on the machine tool side and the specific surface of the movable base is the rectangular coordinate (X axis, Y passing through the center point). Since the concave and convex portions are formed by four concave portions and convex portions formed with inclined surfaces of 45 to 80 degrees on both sides parallel to the axis), the fixed base and the movable base are integrated with a fastening bolt. Once tightened, the integration allows machining without any deviation.
Further, since the fixed base on the machine tool side and the movable base can be uniquely determined, even if the fixed base attached to the machine tool side is a specific lathe, a drilling machine, boring machine, milling machine, grinding machine Even if it is a gear cutting machine, machining center, die-sinking electric discharge machine, wire electric discharge machine, etc., if the centering position of a specific workpiece is set there, it is limited to the use of one type of processing machine Without attaching the machine tool side base to a plurality of machine tool sides in advance or sequentially, a plurality of machine tools can be used.
And the fitting mechanism which consists of the concave part and convex part which formed the 45-80 degree inclined surface in the both sides which are formed in the specific surface of the fixed base by the side of the machine tool and the specific surface of the movable base, for example, If the position where four pieces are fitted simultaneously is specified, the fitting is performed only at the specific position, and the directionality can be given. If the fitting mechanism consisting of four concave parts and convex parts formed with inclined surfaces of 45 to 80 degrees on both sides is fitted at 90 degree intervals, they can be fitted at four positions. Can do.
Further, the movable base to which the workpiece is attached has one of the X-axis at the rectangular coordinate position or one of the Y-axis centering positions, or one of the X-axis at the rectangular coordinate position and the workpiece mounting hole. If one pair of tightening bolts on the Y-axis is tightened or released, the centering position (X-axis = 0, Y-axis = 0) is uniquely determined, so there is no need to perform centering each time. .

The centering jig for a machine tool according to a second aspect of the present invention is further disposed on the opposite surface side of the fitting mechanism side provided on the movable base, and a specific surface of the fixed base on the machine tool side and the movable base. A protective frame that surrounds a rectangular coordinate position (X-axis, Y-axis) formed on a specific surface and its vertical direction (Z-axis direction) is attached.
Therefore, since it has a protective frame in addition to the configuration of claim 1, it is in the rectangular coordinate position (X axis, Y axis) formed by the specific surface of the fixed base on the machine tool side and the specific surface of the movable base. By surrounding the workpiece and the vertical direction (Z-axis direction), the workpiece disposed on the surface opposite to the fitting mechanism provided on the movable base collides with other members. Or do not receive impact directly from dropping. Further, the protective frame can be formed of synthetic resin or synthetic rubber, and the work piece being worked on can be stored in that state. And since processing scraps, such as cutting, are not scattered, the circumference is not polluted.

  Since the fixed base on the machine tool side of the centering jig for machine tools according to claim 3 is provided with a through-hole through which a cutting tool passes at the center, similarly to the movable base, claim 1 or claim In addition to the effect described in Item 2, since the machine tool side fixed base and the movable base pass through, the machine tool can perform work passing through the machine tool side fixed base and the movable base. For example, the degree of freedom of combination of the machine tools is increased as in a milling machine and a wire cut electric discharge machine. Further, since the through hole is provided in the center like the movable base, the centering position is easily visible.

  In the centering jig for machine tools according to claim 4, the fitting mechanism composed of the concave portion and the convex portion is configured such that four of the four concave portions or the convex portions are fitted only at a specific position. Therefore, in addition to the effects described in claims 1 to 3, the fitting mechanism including the four concave portions and the convex portions transmits an external force. Machining of workpieces with no gap becomes easy.

1A and 1B are perspective views showing a relationship between a fixed base and a movable base in a centering jig for machine tools according to an embodiment of the present invention. FIG. 1A is a perspective view seen from the upper side of the movable base, and FIG. It is the perspective view seen from the fixed base by the side of a machine. FIG. 2 is a perspective view showing the relationship between the machine tool side fixed base and the movable base in the machine tool centering jig according to the embodiment of the present invention, and (a) is a perspective view seen from the lower side of the movable base. (b) is a perspective view seen from the lower side of the machine tool side fixed base, (c) is a perspective view seen from the upper side of the fitting state of the movable base and the fixed base. FIG. 3 shows the relationship between the machine tool side fixed base and the movable base in the machine tool centering jig according to the embodiment of the present invention. FIG. 3A is a plan view seen from the upper side of the movable base. Is a front view as seen from the front. FIG. 4 is a cross-sectional view taken along line AA in FIG. FIG. 5 is a cross-sectional view in which the protective frame is removed from the cross-sectional view taken along line AA in FIG. FIG. 6 is an exploded perspective view of the machine tool side fixed base, the movable base, the workpiece, and the protective frame according to the embodiment of the present invention. 7A and 7B are explanatory views of the machine tool side fixed base in the machine tool centering jig according to the embodiment of the present invention. FIG. 7A is a perspective view of the fitting mechanism of the machine tool side fixed base, and FIG. It is explanatory drawing of the cross section of a mechanism. FIG. 8 is a developed perspective view of a specific machine tool side fixed base in the machine tool centering jig according to the embodiment of the present invention. FIG. 9 is an explanatory diagram of a state in which the machine tool centering jig according to the embodiment of the present invention is attached to the table of the machine tool.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that, in the embodiments, the same reference numerals and the same reference numerals are the same or corresponding functional parts, and therefore, redundant description thereof is omitted here.

[Embodiment]
1 to 9, for example, a work piece attached to a machine tool side to be machined such as a lathe, drilling machine, boring machine, milling machine, grinding machine, gear cutting machine, machining center, die-sinking electric discharge machine, wire electric discharge machine or the like. The fixed base 10 on the machine tool side that specifies the centering position of the object 50 is arranged on a bed or table of a machine tool by a known technique. For example, a known centering jig for a milling machine, a centering jig such as a dial gauge, or the like. Mounted using. Machine tool side such as lathe, drilling machine, boring machine, milling machine, grinding machine, gear cutting machine, machining center, die-sinking EDM, wire EDM etc. It can also be attached to each.
The workpiece 50 will be described as an example of small parts. However, when the present invention is carried out, the fixed base 10 on the machine tool side only corresponds to the size of the workpiece 50 relatively. Yes, it can be used without being limited to small parts.

The fixed base 10 on the machine tool side according to the present embodiment has an outer diameter of a square (a rectangular parallelepiped), but may be a rectangle or a circle. That is, as long as it can be easily mounted on the machine tool side, the shape is not questioned. The structure disposed on the bed and table of the machine tool may be bolted directly to the bed and table of the machine tool as long as the structure can be firmly attached. 1 is a screwing hole for attaching the fixed base 10 on the machine tool side with a bolt (not shown). In addition, the structure arrange | positioned at the bed of a machine tool in case of implementing this invention, and a table is not limited to what is screwed in the attachment hole 11 of FIG. 1, The attachment hole 11 side of FIG. It can be on the bolt side, or other attachment means.
The connection hole 12 of the central fixed base 10 is screwed with the jig mounting bolt 77. For example, the wire electrode of a wire electric discharge machine penetrates and has a shape that matches the appropriateness of the machine tool. You can also. For this reason, the connection hole 12 of the fixed base 10 on the machine tool side of the present embodiment has a small diameter or a large diameter as a through hole through which the cutting tool passes, or the shape thereof is a quadrilateral or more polygonal or a special shape. It may be a shape. In any case, it is preferable that the workpiece 50 can be freely attached and detached, and the core does not move when the workpiece 50 is attached again.

The central axes of the connection holes 12 of the fixed base 10 on the machine tool side according to the present embodiment are X-axis = 0, Y-axis = 0, and Z-axis = 0 in the rectangular coordinate position. The X axis of the rectangular coordinate is a straight line XX direction, the Y axis is a straight line YY direction, the Z axis is a straight line ZZ direction, and the Z axis is a loading direction of the fixed base 10 and the movable base 20. is there.
The convex portions 13 and 15 are disposed in the Y-axis direction, and the convex portions 14 and 16 are disposed in the X-axis direction. The convex portions 13 and 15 and the convex portions 14 and 16 are arranged at positions that are separated by an equal distance from the X-axis = 0, Y-axis = 0, and Z-axis = 0 positions of the rectangular coordinate position. Similarly, each of the convex portions 13 and 15 and the convex portions 14 and 16 has tightening holes 13a and 14a at equal positions from the X-axis = 0, Y-axis = 0, and Z-axis = 0 positions of the rectangular coordinate position. , 15a, 16a are formed.

The raised portions 13, 14, 15, and 16 have a height H ₁ rising from the upper surface of the fixed base 10, and the height of the straight raised portion h ₁ that is vertically raised from the upper surface of the fixed base 10. have. The straight rising portion h ₁ that rises vertically absorbs an error in the fitting depth between the fixed base 10 and the movable base 20.
Further, the inventor conducted an experiment by changing the angle θ _L = θ _R to 30, 45, 60, 70, 80, and 90 degrees. As a result, the angle θ _L and the angle θ _R on both sides along the X axis and the Y axis of the rectangular coordinate positions of the convex portions 13, 14, 15, 16 are inclined surfaces of 45 to 80 degrees. The inclined surface formed by 45 to 80 degrees of the angle θ _L and the angle θ _R on both sides along the X-axis and Y-axis of the convex coordinate portions 13, 14, 15 and 16 is a fixed base on the machine tool side. When the movable base 20 and the movable base 20 are mechanically coupled, the energy of the external force is easily transmitted between them. More preferably, the angle θ _L = θ _R is in the range of 60 to 80 degrees.

Incidentally, if the inclined surfaces of 45 to 80 degrees on both sides along the X-axis and Y-axis at the rectangular coordinate position are inclined surfaces of 45 degrees or less, the fitting between the fixed base 10 and the movable base 20 of the fitting mechanism 40 is performed. The tightening bolts 41, 42, 43, which are screwed into the tightening holes 13a, 14a, 15a, 16a while being held by the support holes 23a, 24a, 25a, 26a formed in the movable base 20 44, the tightening bolts 41, 42, 43, and 44 are cut or stretched, and machining by the machine tool becomes impossible.
Conversely, if the angle θ _L and the angle θ _R of the inclined surfaces on both sides along the X-axis and Y-axis at the rectangular coordinate position are 80 degrees or more, the machine tool side fixed base 10 and the movable base 20 in the Z-axis direction In the change, when the angle becomes large, the problem is that the movable base 20 is slidably coupled to the fixed base 10 and the fastening bolts 41, 42, 43, 44 are tightened so that they can be separated and cannot be separated. The bigger the possibility, the higher the possibility.
Therefore, according to the experiment by the inventor, it was confirmed that the angle θ _L and the angle θ _{R of the} inclined surface of 45 to 80 degrees on both sides along the X-axis and the Y-axis at the rectangular coordinate position can be used stably. It was. Of course, other shapes may be used if used for this purpose.

Although the movable base 20 of the present embodiment has a square outer diameter, it can be rectangular or circular like the fixed base 10. That is, as long as it is attached to the fixed base 10 on the machine tool side and can be easily centered, the shape is not questioned. Then, two pairs of mounting female screws 22b, 23b, 24b, and 25b are drilled from four directions in the workpiece mounting hole 21 for mounting the workpiece 50 on the movable base 20, and the workpiece is provided there. 50 positioning and detent locking screws 45, 46, 47, 48 are screwed together. The lock screws 45, 46, 47, 48 may be tightened as positioning of the workpiece 50, or may be tightened via mounting female screws 22 b, 23 b, 24 b, 25 b as detents during processing of the workpiece 50. . In particular, if the workpiece 50 is not machined, one pair from two directions is to fix two surfaces of the two pairs of mounting female screws 22b, 23b, 24b, and 25b from the four sides of the workpiece mounting hole 21. The lock screws 45, 46, 47, 48 may be screwed together, or the mounting position may be finely adjusted by a pair of lock screws 45, 46, 47, 48.

Specifically, the workpiece 50 according to the present embodiment is configured so that the machining part 51 machined into a specific shape, the pedestal 52 that maintains the machining part 51, and the workpiece attachment hole 21 are not inserted. And a fixing portion 54 fixed by a pair of lock screws 45, 46, 47, 48 with the entire workpiece 50 as an attachment position.
On the movable base 20 to which the workpiece 50 is attached, only one of the X-axis of the rectangular coordinate position, only one of the Y-axis, or the rectangular coordinate position with respect to the fixing portion 54 mounted in the workpiece mounting hole 21. The pair of lock screws 45, 46, 47, 48 or the pair of lock screws 45, 46, 47, or the two pairs of lock screws 45, 46, 47, 48 are tightened or released. , 48, the centering position (X axis = 0, Y axis = 0) is uniquely determined, so there is no need to perform centering each time.

The center of the workpiece attachment hole 21 is set to a rectangular coordinate position (X axis = 0, Y axis = 0). The convex portions 13 and 15 and the convex portions 14 and 16 of the fixed base 10 are formed with concave portions 23 and 25 and concave portions 24 and 26 of the movable base 20 at opposite positions. In the present embodiment, the convex portions 13 and 15 and the convex portions 14 and 16 of the fixed base 10, and the concave portions 23 and 25 and the concave portions 24 and 26 of the movable base 20 at the opposite positions of the fixed base 10 have the same shape. and shaving to form the inclined surface of the angle theta _L and the angle theta _R. In the present embodiment, the convex portions 13, 14, 15, 16 and the concave portions 23, 24, 25, 26 have the same shape. However, when the present invention is implemented, the convex portions 13, 14, 15 , 16 and the concave portion 23, 24, 25, 26, by performing the finishing on the way cutting, and change the shape, it is possible to change the angle theta _L and the angle theta _R of the inclined surface. Further, the height of the convex portions 13, 14, 15, 16 and the depth of the concave portions 23, 24, 25, 26 can be changed.

In other words, in the present embodiment, the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20 have the same shape, so that the fitting is performed every 90 degrees. The fitting position of the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20 is determined by the directionality in which the coupling mechanism 40 is fitted, and the workpiece 50 Is set.
However, when the fitting mechanism 40 that fits only when the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20 have a specific angle is used, the machine tool Can be fitted in the correct direction. The form in which the fitting is performed only in the case of this specific angle is the inclination angle of the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20, that is, the angle Any of θ _L and angle θ _R and their dimensions or arrangement can be set.

For example, the convex portions 13, 14, 15, 16 of the fixed base 10 of the fitting mechanism 40 and the concave portions 23, 24, 25, 26 of the movable base 20 are fixed to the fixed base 10 as shown in FIG. A gap h ₀ is generated in a state of being fitted to the movable base 20 connected thereto.
In other words, the convex portions 13 and 15 in the Y-axis direction have the width X ₂ -X ₁ , similar to the convex portions 14 and 16. A vertical distance h ₁ is formed from the upper surface of the fixed base 10, and the height is the left side angle θ _L and the height is the convex part interval H ₁ . Also it has been from the upper surface of the fixed base 10 to form a vertical distance h _1, from which the height of the convex portions the interval H ₁ at right angles theta _R. Here, the left angle theta _L will be equal to the right angle theta _R. Further, the convex portions 14 and 16 in the X-axis direction have a width Y ₂ -Y ₁ , similar to the convex portions 13 and 15.
Vertically downward from the lower surface of the movable base 20, a distance downwardly disposed a vertical distance h _2, has a height including a vertical distance h ₂ between recess spacing H ₂ there from left angle 180-θ _L. Similarly, it has a height also including vertical distance h ₂ at the right angle 180-theta _R side concave portion interval H _2.

Here, with respect to the convex portion 13 of the fixed base 10, and at the same time the concave portion 23 of the movable base 20 is fitted, by the left angle theta _L is and the right angle theta _R form slant convex portion of the fixed base 10 Reference numerals 13, 14, 15, and 16 are fitted into a fitting mechanism 40 including the concave portions 23, 24, 25, and 26 of the movable base 20. At this time, the slope left angle theta _L and a right angle theta _R form, slope left angle 180-theta _L and the right angle 180-theta _R is formed, surface contact in a parallel state, the upper surface of the fixed base 10 the lower surface of the movable base 20 is stopped in the state of the vertical distance h _1.
Here, even if the fastening bolts 41, 42, 43, 44 are screwed together, the convex portions 13, 14, 15, 16 of the fixed base 10 are connected to the concave portions 23, 24, 25, 26 of the movable base 20. The surface contact of the two contacts without meshing. Further, the convex portions 13, 14, 15, 16 of the fixed base 10 and the concave portions 23, 24, 25, 26 of the movable base 20 slide in the X-axis direction and the Y-axis direction of the fixed base 10 and the movable base 20. Even if a rotational force centered on the connection hole 12 of the fixed base 10 is applied, it is transmitted efficiently and transmitted as a rotational force on the other side.
Note that the slope of the left angle theta _L and a right angle theta _R form, slope left angle 180-theta _L and the right angle 180-theta _R form is worn with use, the error terms due to the abrasion There is little change.

In the case of the fitting mechanism 40 for fitting the convex portions 13, 14, 15, 16 and the concave portions 23, 24, 25, 26 only at a specific position, the convex portions 13, 14, 15, 16 the left angle theta _L tilt angle and / or inclined surface of the right angle theta _R of may be changed. Of course, the inclination angle of the left side angle 180-θ _L and / or the inclination angle of the right side angle 180-θ _R of the concave portions 23, 24, 25, 26 may be changed. Logically, the left angle θ _L (180−θ _L ) and / or the right angle θ _R (180−θ _R ) may be changed. The left angle θ _L and the left angle If the difference between the inclination angle of 180-θ _L, the right angle θ _R, and the right angle 180-θ _R is small, it is difficult to engage and separate, so the difference between the angles is preferably 3 to 10 degrees. Alternatively, it is desirable to make contact with the flat upper surfaces of the convex portions 13, 14, 15, 16.

Thus, in this Embodiment, the fitting mechanism 40 which fits the convex parts 13, 14, 15, 16 and the concave parts 23, 24, 25, and 26 as the same shape is comprised.
However, when practicing the present invention, the height of the convex portions 13, 14, 15 and 16, its position, by changing the angle theta _L and the angle theta _R of the inclined surface, also concave portion 23, also the depth of the valley about 24, 25, 26 (opposite of the convex portions 13, 14, 15, 16), by changing its position, angle 180-theta inclined surfaces _L and 180- angle theta _R, It can be set as the fitting mechanism 40 of the structure which does not fit unless it is the direction of the specific workpiece 50. FIG.

3 to 6, the protective frame 30 is disposed on the opposite surface side of the fitting mechanism 40 provided on the movable base 20, and the specific surface of the fixed base 10 on the machine tool side and the specific surface of the movable base 20. Specifically, in the space 31 surrounding the rectangular coordinate position (X axis, Y axis) and the vertical direction (Z axis direction) formed by the It is desirable that there is no mechanical contact between the workpiece 50 and the protective frame 30 and that the end of the workpiece 50 does not protrude from the end opening of the protective frame 30. For this reason, the inside of the protective frame 30 is formed in the space 31.

  In the protective frame 30 of the present embodiment, two-stage workpiece mounting holes 38a having different diameters are formed in the middle of the opposite angle of the protective frame 30, and two mounting bolts 39 are screwed there. In addition, it is adapted to be attached to the attachment female screw 37 on the upper surface of the movable base 20. Of course, in this embodiment, the protective frame 30 is attached to the opposite angle of the movable base 20 by the two attachment bolts 39, but each corner of the protective frame 30 is provided by the four attachment bolts 39. May be tightened. Further, the center of the opposite side of the protective frame 30 may be attached.

The protection frame 30 is attached inadvertently when a workpiece such as a spanner is hit against the workpiece 50 during the replacement work of the workpiece 50 or when the workpiece 50 is removed from the machine tool. Even if such a case occurs, the protective frame 30 receives the impact, and even if it is transmitted to the movable base 20, it is not transmitted to the workpiece 50. The workpiece 50 is prevented from being deformed or distorted by an impact.

In the above embodiment, it has been described that the fixed base 10 on the machine tool side is mounted on the bed and table of the machine tool. However, as shown in FIGS. You can also.
That is, on the mounting side of the fixed base 10 on the machine tool side, the mounting plate 71 made of steel, brass, brass or the like is inserted into the insertion hole 71a of the mounting object by the four bolts 72, and the mounting hole 11 in FIG. It is tightened.
The jig mounting bolt 77 includes a thick ring-shaped annular member 76, one surface having a square or hexagon, a mounting block 75 having an annular shape on the annular member 76 side, a washer 74, and a lock nut 73. They are screwed in sequentially.
Here, the attachment plate 71, the bolt 72, the lock nut 73, the washer 74, the attachment block 75, the annular member 76, and the jig attachment bolt 77 constitute a one-touch fixture 70 attached to the machine tool. Of course, the configuration of the one-touch fixture 70 is not limited to this configuration.

As is well known, the jig mounting bolt 77 has its free end screwed into the connection hole 12 of the fixed base 10 at the center of the fixed base 10, and the lock nut 73 fixes its position. Further, the attachment block 75 is screwed through the washer 74 to stop the washer 74. A fixing tool 83 on the machine tool side is inserted into a place formed by the attachment block 75 and the annular member 76, and is fixed while being pulled in a specific direction.
Accordingly, the one-touch fixing tool 70 is fixed to the portion formed by the attachment block 75 and the annular member 76 while being pulled in a specific direction by the fixing tool on the machine tool side. In this embodiment, since it is not necessary to fix a plurality of places, work efficiency is efficient.

FIG. 9 shows an example in which the one-touch fixture 70 is used. A slidable chucking device 81 is provided on the processing table 80 to hold the receiving jig 82. The receiving jig 82 is provided with a fixing tool 83 driven by hydraulic pressure or bolts, and is attached to the receiving jig 82 on the machine tool side fixed base 10. Here, if the center of the fixed base 10 on the machine tool side is aligned, the movable base 20 becomes the same core in a state where the workpiece 50 is attached to a specific surface of the movable base 20, and the workpiece 50 is centered. It ’s gone.
Therefore, the electrode 110 of the die-sinking electric discharge machine 100 shown in FIG. 9 can be controlled around its axis. Of course, in a lathe, drilling machine, boring machine, milling machine, grinding machine, gear cutting machine, machining center, wire electric discharge machine, etc., each machine tool is similarly moved by moving the workpiece 50 attached to the movable base 20. It is possible to perform the mounting process of the movable base 20 to which the workpiece 50 is mounted without performing centering.

  In the above embodiment, the connection hole 12 is provided in the center of the machine tool side fixing base 10, and the size of the connection hole 12 is fitted to the jig mounting bolt 77 of the one-touch fixing tool 70. When the present invention is carried out, the shape of the fixed base 10 can be the connection hole 12 having a size for mounting the workpiece 50 in the same manner as the workpiece mounting hole 21 for mounting the workpiece 50 of the movable base 20. . As a result, lathes, drilling machines, boring machines, milling machines, grinding machines, gear cutting machines, machining centers, wire electric discharge machines, etc. can be used freely. Similarly, by moving the workpiece 50 attached to the movable base 20 The mounting process of the movable base 20 to which the workpiece 50 is mounted can be performed without centering each machine tool.

The machine tool centering jig of the above embodiment is attached to the machine tool side, the machine tool side fixed base 10 for specifying the centering position of the work piece 50 attached to the machine tool side, and the workpiece. The movable base 20 that can be fixed to the fixed base 10 on the machine tool side with the 50 mounted in the workpiece mounting hole 21, and the fixed base 10 and the movable base 20 have rectangular coordinates (X axis, It consists of concave parts 23, 24, 25, 26 and convex parts 13, 14, 15, 16 formed with inclined surfaces of 45 to 80 degrees on both sides parallel to the Y axis and Z axis). The fixed base 10 and the convex portions 13, 14 having the fitting mechanism 40 for fitting with the concave portion 20 and the concave portions 23, 24, 25, 26 or the convex portions 13, 14, 15, 16 of the fitting mechanism 40. , 15, 16 or concave portions 23, 24 25,26 is to and a fastening bolt 41, 42, 43, 44 is tightened together with the fixed base 10 and the movable base 20 in a fitted state between the movable base 20 having a.

The machine tool centering jig of the above-described embodiment specifies the centering position of the workpiece 50 by the fixed base 10 attached to the machine tool side, and attaches it to the machine tool side. Further, the workpiece 50 is attached to the workpiece mounting hole 21 of the movable base 20 on the fixed base 10 on the machine tool side. In this state, the specific surface of the fixed base 10 on the machine tool side and the specific surface of the movable base 20 are fitted, and the fixed base 10 and the movable base 20 on the machine tool side are integrally fitted with the fastening bolt 41 in the fitted state. Tighten with 42, 43, 44.
Concave portions 23, 24, 25, 26 and convex portions 13, 14, 15 for fitting in a vertical direction on a rectangular coordinate position formed by a specific surface of the fixed base 10 on the machine tool side and a specific surface of the movable base 20. , 16 includes four concave portions 23, 24, 25 having inclined surfaces of 45 to 80 degrees formed on both sides parallel to the rectangular coordinate (X axis, Y axis) passing through the center point. , 26 and convex and concave portions 13, 14, 15, 16 are formed, so that the fixed base 10 and the movable base 20 on the machine tool side are integrally tightened with the tightening bolts 41, 42, 43, 44. If it is integrated, the workpiece 50 can be machined without any deviation.

Further, since the fixed base 10 and the movable base 20 on the machine tool side can be uniquely determined, even if the fixed base 10 on the machine tool side attached to the machine tool side is a specific lathe, a drilling machine or boring machine , Milling machines, grinding machines, gear cutting machines, machining centers, die-sinking electric discharge machines, wire electric discharge machines, etc., if you set the centering position of a specific workpiece 50 there, Without being limited to the use of a processing machine, a plurality of machine tools can be used if the fixed base 10 on the machine tool side is attached to a plurality of machine tool sides in advance or sequentially.

And four concave-shaped parts 23, 24, 25, 26 formed with inclined surfaces of 45 to 80 degrees on both sides formed on the specific surface of the fixed base 10 and the specific surface of the movable base 20 on the machine tool side, and If the fitting mechanism 40 which consists of the convex-shaped parts 13, 14, 15, 16 specifies the position which four pieces fit simultaneously, it will be fitted only in a specific position and can also give directionality. . If the fitting mechanism 40 consisting of the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16 having inclined surfaces of 45 to 80 degrees on both sides is formed every 90 degrees, It can be fitted at four positions.

The machine tool centering jig of this embodiment is disposed on the opposite surface side of the fitting mechanism 40 provided on the movable base 20, and the specific surface of the fixed base 10 and the specific surface of the movable base 20 on the machine tool side. A protective frame 30 is attached to surround the rectangular coordinate position (X axis, Y axis) and the vertical direction (Z axis direction).
Therefore, since the protective frame 30 is included, the periphery and the vertical direction of the workpiece 50 in the rectangular coordinate position (X axis, Y axis) formed by the specific surface of the fixed base 10 on the machine tool side and the specific surface of the movable base 20 are provided. By enclosing the direction (Z-axis direction), the workpiece 50 disposed on the opposite surface side of the fitting mechanism 40 provided on the movable base 20 is impacted by collision with another member or dropping. Do not receive directly. Further, it is possible to store the work piece in operation in a state of being formed of synthetic resin or synthetic rubber. And since processing scraps, such as cutting, are not scattered, the circumference is not polluted.

In the machine tool centering jig of the above-described embodiment, the machine tool side fixed base 10 is provided with the connection hole 12 for attaching the workpiece 50 at the center in the same manner as the movable base 20. Since the fixed base 10 on the side and the movable base 20 pass through, the machine tool can perform work that has passed through the fixed base 10 and the movable base 20 on the machine tool side, so that the machine tool is like a milling machine and a wire-cut electric discharge machine. The degree of freedom of combination increases.

In the machine tool centering jig of the above embodiment, the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16 has the four concave portions or Since the four protrusions are configured to be fitted only at a specific position, the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16 transmits an external force. Since it is a natural coupled state, it is easy to process the workpiece 50 without difficulty.

In the machine tool centering jig of the above embodiment, the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16 has the convex portions 13, 14. , 15 and 16 are constituted by protrusions or depressions having a truncated pyramid shape in cross section.
This projecting cross-sectional square frustum is formed on one or both sides with inclined surfaces, and the inclined surfaces of the recesses of the concave portions 23, 24, 25, 26 are joined to the inclined surfaces by the surfaces. In addition, since the coupling is performed at a rectangular coordinate position (X axis, Y axis), the movement in the X axis direction is prevented, and the movement in the Y axis direction is also prevented, so that the movable unit connected to the fixed base 10 is movable. The workpiece 50 attached to the base 20 can be easily processed without difficulty.

Further, the machine tool centering jig of the above-described embodiment is configured by the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16. However, when practicing the present invention, the present invention is not limited to the fitting mechanism 40 including the four concave portions 23, 24, 25, 26 and the convex portions 13, 14, 15, 16. The position (X axis, Y axis) only needs to be configured so as not to move relative to each other, and a complicated shape can be obtained by cutting with a die-sinking electric discharge machine or the like.

The movable base 20 of the machine tool centering jig according to the above-described embodiment includes the mounting female screws 22b, 23b, 24b, into which the workpiece 50 is screwed with one or two pairs of lock screws 45, 46, 47, 48. The workpiece 50 can be attached and released by tightening or releasing the bolt 25b, and the workpiece 50 can be replaced only by operating one or two pairs of lock screws 45, 46, 47, 48. Does not change, so the centering position does not change.
Of course, the set position of the workpiece 50 may be measured with a caliper or a micrometer and set to a specific position.

Although the fixed base 10 and the movable base 20 of the centering jig for machine tools of the above embodiment have been described in the case of processing a small part, the present invention is limited to the processing of a small part. It is not something.

The present invention has been described as a centering jig for a machine tool to be attached to a processing table of a machine tool. However, in the case of carrying out the present invention, it may be arranged so that the relative motion of the processing machine can be performed, and horizontal, vertical There is also no installation condition for.

DESCRIPTION OF SYMBOLS 10 Fixed base 12 Connection hole 13, 14, 15, 16 Convex part 20 Movable base 21 Workpiece attachment hole 23, 24, 25, 26 Concave part 30 Protection frame 40 Fitting mechanism 41, 42, 43, 44 Tightening Bolt 50 Workpiece

Claims (4)

A fixed base on the machine tool side that is attached to the machine tool side and identifies a centering position of a workpiece to be attached to the machine tool side;
A movable base that can be fixed to a fixed base on the machine tool side in a state in which the workpiece is mounted in a workpiece mounting hole;
The fixed base and the movable base include a concave portion and a convex portion in which inclined surfaces of 45 to 80 degrees are formed on both sides parallel to the rectangular coordinates (X axis, Y axis, Z axis) passing through the center point. A fitting mechanism for fitting the fixed base and the movable base;
Tightening the fixed base and the movable base together in a fitted state between the fixed base having the concave portion or the convex portion of the fitting mechanism and the movable base having the convex portion or the concave portion. A centering jig for machine tools, characterized by comprising an attached bolt. A rectangular coordinate position (X-axis, Y-axis) formed on the surface opposite to the fitting mechanism provided on the movable base and formed by a specific surface of the fixed base on the machine tool side and a specific surface of the movable base; The centering jig for machine tools according to claim 1, further comprising a protective frame that surrounds the vertical direction (Z-axis direction). The centering jig for machine tools according to claim 1 or 2, wherein the fixed base on the machine tool side is provided with a through hole through which a cutting tool for cutting the workpiece passes. The fitting mechanism including the concave portion and the convex portion of the fixed base and the movable base has a configuration in which four of the four concave portions or the convex portions are fitted only at specific positions. The centering jig for machine tools according to claim 1.

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