KR100429333B1 - Reference set pointer - Google Patents

Abstract

The reference origin setter of the present invention is to minimize the coarse origin setting time through the circle trajectory of the light emitted from the laser diode to reduce the setting time of the machining equipment, the tool holder of the spindle which is the rotation axis of the machining equipment In the reference origin setter (4) mounted, the first pivot portion 13 is formed to have a fixed end 11 fixed to the shaft center of the tool holder 4 at the top and a coupling space 18 at the bottom. The support bracket 10 and the pivot axis 15 of the first pivot part 13 are coupled to the coupling space 18 so as to be swingable at a finite radius, and the second pivot part 22 is disposed at the bottom thereof. Inserted through the formed cradle 20 and the upper and lower through slots 27 of the cradle 20 is inclined and rotatably mounted on the second pivot portion 22 and finely tilted with a fine adjustment bolt 29. Including adjustable laser unit 30 The laser part 30 makes a circle trajectory by the afterimage effect of the laser light emitted from the laser part 30 when the laser unit 30 rotates together with the tool holder 4 of the spindle, and thus makes the circle trajectory and the center of the hole to be machined. Match.

Description

Reference origin setter {REFERENCE SET POINTER}

The present invention relates to a reference origin setter, and more particularly, to set a reference origin used for reference reference in machining equipment such as general purpose milling, numerical control milling, boring equipment, etc. It is about the flag.

In general, all machining equipment, even if tools, numerical control programs, operators, etc. are prepared, cannot start work unless the origin is set.

The origin setting is roughly set by manually turning the spindle, which is the axis of rotation of the machine out of the hole, first using an indicator, and then finely adjusted in the hole.

Here, the indicator refers to an instrument for weighing and measuring in accordance with the guidelines. The allowance for coarse origin setting is within 0.5 mm, and the allowance for fine origin setting is within 0.01 mm.

In particular, the origin setting operation usually takes 80% of the total origin setting time, and if the hole is large, it is not difficult to roughly center the circle.

FIG. 1 shows a machining equipment in which a predetermined part is cut to explain a general reference origin setting method, and shows a spindle 1 of a machining equipment. The spindle 1 has a tool holder ( 4) is attached and a multi-joint indicator (2) is attached to the outer peripheral surface. The indicator 2 is provided at the end with the instruction | indication 3 which points out a specific part in three-dimensional space. In particular, the guide (3) is coupled to the end of the ball (ball) to allow a smooth movement while minimizing contact resistance. That is, the ball of the guide 3 is arranged to contact the upper surface of the article 5 to be machined, and when rotating the spindle 1 manually, the article 5 draws a predetermined arc with the guide 3. It is to be rolled on the upper surface of.

The method of setting the origin of the hole 6 formed in the article 5 by using the indicator 2 is as follows.

That is, the operator first manually rotates the spindle 1 of the machining equipment outside the hole 6, adjusts the radius of rotation of the indicator 2 appropriately, and then the circular arc drawn while the guide 3 rotates in a circle. The rotational direction of the spindle 1 and the adjustment of the indicator 2 are repeatedly set until the distance between the diameter of the hole 6 and the diameter of the hole 6 is uniformly narrowed to within 0.5 mm, thereby setting the coarse origin.

At this time, the entire home setting time is mostly used to set the coarse origin that proceeds while rotating the spindle repeatedly. In the case of a large diameter rough origin setting work, even a mature worker to some extent, it requires very patient and focused, and can be performed after the general worker through a lot of trial and error. This is because only one point indicated by the indicator 3 of the indicator 2 can be seen by rotating the indicator in three-dimensional space.

Thereafter, the operator secondly positions the guide 3 of the indicator 2 in the hole 6 and at the same time rotates the spindle 1 to set the origin through fine adjustment within 0.01 mm.

That is, in the conventional home setting work, only the indicator is used, and thus, the coarse home setting work that takes most of the home setting time is inefficiently performed, which brings inconvenience to an inexperienced or inexperienced worker. This relatively long, or irregular work was carried out in a lame, which has a disadvantage in the entire machining process.

In addition, the previous origin setting work that roughly sets the origin first requires a great concentration on the worker who checks only one point indicated by the indicator's instructions, thereby acting as a factor that increases the fatigue of the worker or is very burdensome. It is a major factor in creating the environment.

Therefore, the present invention has been made to solve the problems of the prior art as described above, it is possible to reduce the setting time of the machining equipment by minimizing the coarse origin setting time through the circle trajectory of the light emitted from the laser diode It is an object of the present invention to provide a reference origin setter that can easily set a home position even for beginners and improve the overall origin setting work environment.

1 is a perspective view of a machining equipment cut out a predetermined portion to explain a general reference origin setting method,

2 is a perspective view for explaining a configuration of a reference origin setter according to an embodiment of the present invention;

3 is an exploded perspective view for explaining the coupling relationship of the reference origin setter shown in FIG.

4 to 6 are side views for explaining the operation of the reference origin setter shown in FIG.

<Description of Symbols for Main Parts of Drawings>

4 tool holder 10 support bracket

13: first pivot portion 15: pivot axis

20: holder 22: second pivot portion

26: guide slit 27: slot

29: fine adjustment bolt 30: laser unit

An object of the present invention as described above is a reference origin setter mounted on a tool holder of a spindle, which is a rotational axis of a machining equipment, the first end of which has a fixing space formed on the upper end and having a coupling space at the bottom thereof. A support bracket having a pivot portion, a cradle coupled to the coupling space so as to be swingable at a finite radius by a pivot axis of the first pivot portion, and having a second pivot portion formed at a lower portion thereof; Is inserted through the inclined and pivotably mounted to the second pivot portion and includes a laser portion for finely adjusting the tilt angle with a fine adjustment bolt, the afterimage of the laser light emitted from the laser portion when the laser portion rotates with the tool holder of the spindle Effect to create a circle trajectory and to set the origin by matching the circle trajectory to the center of the hole It is achieved by a reference origin setter characterized by the above.

In addition, according to the present invention, it is preferable that the cradle is provided with a finite arc-shaped guide slit so that the end of the rotation limit bolt is fastened to the first pivot portion, it is preferably rotated on the basis of the support bracket.

In addition, according to the present invention, the laser unit is equipped with a small size portable power supply, such as a mercury battery, a laser diode and its circuit inside the housing to emit a laser light with strong straightness and low light divergence, the hinge hole on the lower surface It is preferable to form them symmetrically.

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

2 is a perspective view for explaining the configuration of the reference origin setter, Figure 3 is an exploded perspective view for explaining the coupling relationship of the reference origin setter, Figures 4 to 6 is an operating relationship of the reference origin setter Side views for explaining.

As shown in Fig. 2, the reference originator of the present invention is a measuring tool applied to a machining equipment having a spindle and mounted to a tool holder 4 of the spindle. That is, the reference origin setter is fastened to a seating hole formed in the lower shaft center of the tool holder 4, and for this purpose, a trunnion type support bracket 10 having a circular fixed end of a diameter corresponding to the seating hole is supported. It is mounted inclined to the second pivot portion through the cradle 20 coupled to the swing operation with a finite radius in the first pivot portion of the bracket 10 and the upper and lower through slots of the cradle 20, The tilt angle can be finely adjusted by the fine adjustment bolt 29, or the pivot axis 15 and the rotation limiting bolt 16 are configured by the laser unit 30 that can adjust the tilt angle relatively large.

The laser unit 30 is rotatably coupled to the support bracket 10 and the cradle 20 at a finite radius, is mounted obliquely based on the axis of the spindle, and then rotates with the spindle when the laser unit 30 rotates. By using the afterimage effect of the laser light (red straight light) continuously emitted from, a circular trajectory easily visible to the naked eye is drawn. Based on this circle trajectory, the reference origin setter of the present invention easily and easily sets the origin of a hole (particularly very useful for large diameters).

As shown in FIG. 3, the support bracket 10 has an inverted 'Y' shape as a whole, and forms a body portion 12 having a rectangular cross section under the circular fixed end 11 mentioned above. A pair of first pivot portions 13 extends integrally under the body portion 12 to form a predetermined coupling space 18 corresponding to the thickness of the cradle 20. In the first pivot portion 13, pivot holes 14 are formed to coincide with the engagement direction of the pivot shaft 15, respectively. In particular, one of the first pivot portions 13 is formed with a pin-shaped bolt hole 17 at a position coinciding with the guide slit 26 of the cradle 20.

In addition, the cradle 20 has a 'c' shape, and forms an upper and lower through slots 27 having a long hole shape with a width and a relatively long length slightly larger than the diameter of the laser unit 30 thereon. The slot 27 is fastened to the fine adjustment bolt 29 in a direction perpendicular to the hole direction of the slot. In addition, the cradle 20 forms a second pivot portion 22 to form a coupling space 28 of the laser unit 30 in the lower portion. Pivot holes 21 are formed in each second pivot portion 22. In addition, the cradle 20 forms a through hole 24 and a guide slit 26 at a position eccentrically to the left. Here, the guide slit 26 is formed to have a predetermined depth with a finite arc to seat the end of the rotation limit bolt 16, the base 20 can be rotated finitely relative to the support bracket (10). To be.

In addition, the laser unit 30 includes a small size power supply such as a mercury battery, a laser diode, and a circuit thereof inside the housing 32 to emit laser light having strong straightness and low light emission. The hinge holes 31 are formed symmetrically. The laser unit 30 is similar to a device called a 'laser pointer', and will be omitted from this description in order to clearly describe the coupling relationship between the main components of the present invention.

In the following, the coupling relationship between the reference origin setter according to the present invention will be described.

First, the laser unit 30 is inserted in the axial direction through the upper and lower through slots 27 of the cradle 20, so that the hinge hole 31 to match the pivot hole 21 of the second pivot portion 22. It is disposed and coupled to the cradle 20 so as to swing by a pivot bolt 23.

The cradle 20 is inserted into the engaging space 18 of the support bracket 10, and then matches the through hole 24 with the pivot hole 14, and supports the support bracket so as to swing by the pivot shaft 15 and the nut. Coupled to (10). In addition, the pin-shaped rotational restriction bolt 16 forms irregularities in the handle portion, and after tightening the threaded portion formed on the opposite side to the pin-shaped bolt hole 17, the end of the screw portion is disposed inside the guide slit 26. . This rotation limit bolt 16 serves to limit the rotation of the cradle 20 to a finite circumferential angle corresponding to the finite arc length of the guide slit 26. In addition, when further tightening the pin-shaped rotational restriction bolt 16, the end is fixed to the guide slit 26, and consequently serves to fix the cradle 20 to the support bracket (10).

In the following, the operation relationship of the reference origin setter according to the present invention described in detail above will be described.

As shown in FIG. 4, the reference origin setter may adjust the size of the red circle trajectory by the laser light generated by the laser unit 30 using the pivot shaft 15 and the rotation limit bolt 16.

That is, the operator fixes the support bracket 10 to the tool holder 4 of the spindle, operates the laser unit 30, and then rotates the spindle at a predetermined speed (about 1500 rpm) for rough home setting. At this time, the laser beam is continuously emitted from the laser unit 30 rotating while being inclined to the support bracket 10 at a basic tilt angle (a), thereby rotating (a) the circular path on the upper surface of the article 5 to be machined. Create

In order to form a relatively large circular trajectory, the worker loosens the pivot shaft 15 and the rotation limit bolt 16 and rotates the holder 20 by a predetermined tilt angle with respect to the support bracket 10 (b). ). Then, by tightening the pivot shaft 15 and the rotational restriction bolt 16 so that the holder 20 is fixed to the support bracket 10 and then rotating the spindle in the manner described above, the article to be machined A relatively large circle trajectory is formed on the upper surface of (5) (c).

FIG. 5 shows that the circular trajectory of the laser beam is adjusted according to the change of the tilt angle due to the rotation d of the fine adjustment bolt 29. When the operator rotates the fine adjustment bolt 29 toward the entrance, the upper portion of the laser unit 30 is pushed up by the end of the bolt and rotates finely based on the second pivot portion 22 of the cradle 20. Thus, the circular trajectory is made finely small. When the fine adjustment bolt 29 is rotated to the opposite side, the circular trajectory can be made fine.

As shown in FIG. 6, the reference origin setter can finely adjust the size of the circle trajectory to be formed on the upper surface of the article 5 by moving the support bracket 10 in the axial direction of the tool holder 4. That is, when the operator adjusts the mounting depth h of the support bracket 10 while unfastening and tightening the fixing bolt (not shown) coupled to the tool holder 4, the laser beam emitting light in the conical direction is consequently the article ( A circular trajectory having a small amount of change w is formed on the upper surface of 5). In addition, the operator can axially move a bed (not shown) supporting the article 5 in the axial direction together with a method of moving the support bracket 10 in the tool holder 4 in the axial direction to produce the same effect. .

In the following, a method of setting the origin roughly using the reference origin setter of the present invention as described above will be described.

First, after installing the reference origin setter in which the laser part 30 of this invention was inclined suitably in the tool holder 4, the power supply of the laser part 30 is turned ON. The operator rotates the spindle at 1500 rpm of the machining equipment. As the spindle rotates, the tool holder 4 and the laser portion 30 of the reference origin setter rotate, and the linear laser light emitted from the laser portion 30 rotates in a conical shape. The afterimage effect forms a circular trajectory around the hole of the object to be machined. At this time, when the diameter of the hole is large, the rotational speed of the spindle may be rotated at a higher speed so that the laser beam is easily seen. Afterwards, the operator transfers the bed, so that the center of the circle trajectory and the hole of the object coincide, so that the rough setting of the primary is easily completed.

Then, the operator completes the origin setting by performing the fine adjustment operation using the indicator.

As described in detail above, the reference origin setter of the present invention can quickly and easily perform a rough origin setting operation, thereby rapidly progressing the entire origin setting operation, and has an advantage of increasing productivity and manufacturing efficiency through shortening of working time. .

In addition, the reference origin setter of the present invention makes it easy to visually check the circular trajectory made by the laser light, so that even a beginner can easily and easily perform the origin setting operation.

In addition, the reference origin setter of the present invention is particularly effective in setting the origin of the hole of a large diameter, and can adjust the circle diameter of the laser light freely and conveniently using a pivot axis, a rotation limiting bolt, a fine adjustment bolt, and the like. Not only setting but also precise origin setting work is possible.

In addition, the reference origin setter of the present invention has an effect that can bring excellent effects and maintenance efficiency as a relatively simple machine tool.

The technical idea of the reference origin setter of the present invention has been described above with the accompanying drawings, but this is by way of example only for describing the best embodiment of the present invention and not for limiting the present invention. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (3)

In the reference origin setter mounted on the tool holder 4 of the spindle, which is the axis of rotation of the machining equipment, A support bracket (10) having a first pivot portion (13) formed at a top thereof with a fixed end (11) fixed to the shaft center of the tool holder (4) and having a coupling space (18) at the bottom thereof; The cradle 20 is coupled to the coupling space 18 so as to swing in a finite radius by the pivot axis 15 of the first pivot portion 13, the second pivot portion 22 is formed at the bottom Wow, Inserted through the upper and lower through slots 27 of the cradle 20 is inclined and rotatably mounted on the second pivot portion 22, the laser portion capable of finely adjusting the tilt angle with a fine adjustment bolt 29 Including 30, When the laser unit 30 rotates together with the tool holder 4 of the spindle, a circle trajectory is created by the afterimage effect of the laser light emitted from the laser unit 30, and the circle trajectory and the center of the hole to be machined are made. A reference origin setter characterized by setting the origin by matching. The method of claim 1, The cradle 20 is provided with a finite arc-shaped guide slit 26 so that the end of the rotational restriction bolt 16 fastened to the first pivot portion 13 is seated, thereby referring to the support bracket 10. Reference origin setter, characterized in that the finite rotation. The method of claim 1, wherein the laser unit 30 is a portable power source, a laser diode and a circuit mounted inside the housing 32 to emit a laser light with strong straightness and low light emission, the hinge hole on the lower surface Reference origin setter, characterized in that the (31) are formed symmetrically.