KR200244268Y1 - Pattern Jig for making spectacle frames - Google Patents

Abstract

The present invention relates to a three-dimensional

In order to precisely hold the symmetrical position and to drill the pattern fixing hole 8 at a precise point

And a pattern jig for moving the pattern to a two-dimensional symmetrical position.

More specifically, both patterns are subjected to three-dimensional symmetry of the pattern by geometric principles

Position, and is uniformly dropped in the horizontal direction from the center hole 7 of both patterns

(8) perpendicular to the surface of the pattern,

To a pattern jig for precisely converting a pattern into a two-dimensional symmetrical position.

To this end, the present invention is characterized in that the pattern jig includes a horizontal corrector 26,

25, a symmetrical corrector 15 and an optical axis inclination angle fixing bolt 18,

The three-dimensional symmetric position of the pattern consisting of the line 9, the vertical center line 6 and the optical axis inclination angle 3

Dimensional symmetric position of the pattern thus obtained is converted into a two-dimensional symmetric position by the action of the horizontal correction pin 16,

And the position of the pattern fixing hole 8 is secured.

Description

Pattern jig for making spectacle frames

More particularly, the present invention relates to a pattern jig necessary for performing a basic operation of a metal frame assembly process, and more particularly, Dimensional symmetric position by converting the three-dimensional symmetrical position secured by the geometric principle into a two-dimensional symmetric position, thereby fixing the pattern fixing hole ( 8) to be precisely pierced.

Generally, to make precise spectacle frames in the basic process for making spectacle frames

Before entering the spectacle frame assembly process, the two patterns and the three-dimensional symmetry point of the groove line (13)

It is necessary to grasp the structure and shape of the completed frame in advance

Do. Here, the horizontal center line 9 and the vertical center line 6 of the pattern 12 are required to be precisely machined since they are drafted by assuming an already manufactured spectacle frame at the time of designing the spectacle frame. Since it depends on the hand and feel of the production engineer, its dimensional stability and work efficiency are not high.

Once the three-dimensional symmetrical positions of the pattern 12 and the groove line 13 are grasped,

In the lip process, the three-dimensional symmetric position of the obtained pattern is set as an assembly angle

In order to precisely fix to the ribs, the horizontal center line 9 and the vertical center line 6 in both patterns,

The pattern fixing hole 8 must be located at this exactly symmetrical point. That

In order to accurately align the horizontal and vertical patterns of the pattern 12 for assembling the frames,

A position for securing the position of the pattern fixing hole 8 at an exact symmetrical point of the two patterns

Numerical stability is paramount. However, until now,

When most of the definition was due to the senses and handmade skills of skilled frame builders

In view of the dimensional stability and efficiency of work required in the manufacture of precision spectacle frames,

It's been a problem now.

In order to solve the above-mentioned two problems, the present invention proposes a pattern for confirming the three-dimensional symmetric position of the finished frame before entering the frame manufacture phase during the manufacturing operation of the pattern (12) Dimensionally symmetrical positions of the groove 12 and the groove 13 are ensured by the geometrical principle and the dimensionally stable pattern fixation necessary for precisely shifting the fixture to the three- And it is an object of the present invention to precisely hold a point for piercing the hole 8 for use by geometrical principles.

In order to achieve the above object, the present invention proposes a method for obtaining a three-dimensional symmetric position of both patterns composed of the horizontal center line 9, the vertical center line 6 and the optical axis inclination angle 3 of the pattern 12, The vertical correction frames 20,21,22,23,24,25, the symmetric correction frames 14,15 and the optical axis tilt angle correction frames 17,17-1,17- 2, 18, 18-1) were attached. By the correction function of these devices, the three-dimensional symmetric positions of the two patterns were secured, and the three-dimensional symmetric positions thus obtained were converted into the two- The position of the pattern fixing hole 8 for precisely fixing the pattern 72 to the three-dimensional symmetrical position of the fixture for eyeglass frames can be easily grasped by the action of the horizontal correction pin 16 .

1 is a graph showing the three-dimensional symmetric position of a figure

2 is a plan view showing the range of the pattern optical axis inclination angle in the spectacle frame

3 is a graph showing the two-dimensional symmetric position of the pattern

Fig. 4 is a flow chart for converting a three-dimensional symmetric position to a two-

5 is a plan view showing the positions of the center hole of the pattern and the hole for fixing the pattern;

6 is a top perspective view of the pattern jig (operation diagrams of the horizontal correction frame, the vertical correction frame, and the symmetry correction frame)

7 is a bottom perspective view of the pattern jig (action diagram of the optical axis inclination angle fixing bolt and the plane correction bundle)

8 is an exploded view of the pattern jig

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

FIG. 1 is a graph showing a three-dimensional symmetrical position of a graphic form. FIG. 1 shows a cross-sectional view of a pattern 12 of the eyeglass frame during the manufacturing process of the eyeglass frame in which the shape and size of the groove line 13 and the optical axis inclination angle 3 coincide with each other. Dimensional symmetric position of the model pattern necessary for entering the assembly process is shown as a figure on the three - dimensional graph. It can be seen here that the point where the three-dimensional symmetric shapes Rl and Ll form a three-dimensional symmetry is represented by Ar (Xrn, Yrn, Zrn) and Al (Xln, Yln, Zln) on the X, Y and Z axes. Fig. 2 shows the symmetry principle of the three-dimensional graphic figure applied to the three-dimensional symmetry of the stereoscopic figure called the pattern 12 of the spectacle frame having the limited shape in the inclined angle and shape.

In FIG. 1, the central axes of the figures Rl and L1 are at arbitrary points rl (-x, -y) and 11 (x, y) on the X and Y axes, (X, 0), 12 (-x, 0) due to the difference in the optical axis inclination angle 4 of the pattern formed by the optical axis of the model eye in the spectacle frame and the pattern 12 , And the minute distance difference between the two groove lines 13 when assembling the spectacle frame is best expressed.

2 shows the correlation between the difference in the pattern optical axis inclination angle 4 and the distance difference between the two home shots. FIG. 2 shows the range of inclination angle (3) of the optical axis inclined from the X-axis of the horizontal center line (9) orthogonal to the optical axis of the model eye when viewed from the top, when the assembled frames are viewed from above. (4) of the pattern 12 inserted in the optical axis direction of the pattern.

Since the fine dimensional difference of the pattern 12 in the two-dimensionally symmetrical distance as viewed in FIG. 2 results from the difference in the optical axis inclination angle 3, the pattern 12 in which the two- A more precise three-dimensional symmetrical position composed of the horizontal center line 9 and the vertical center line 6 of the pattern 12 and the optical axis inclination angle 4 of the pattern is realized by symmetry of the optical axis inclination angle 3 which is a dimensional element . FIG. 3 shows the difference of the optical axis inclination angle 3.

In Fig. 3, the horizontal center line X and the two-dimensional

The symmetric position is the symmetry point on the X-axis, and Zr (-x.0), which is the intersection point of the optical axis and the X-axis,

And the inclination angle (θ) inclined with respect to Zl (x.0).

The inclination angle &thetas; is the inclination angle of the pattern appearing on the X axis, which is also referred to as tilt. Here, if only the optical axis inclination angle 4 of the pattern is symmetrical to the pattern 12 in which the two-dimensional symmetry is ensured on the X and Y axes, a three-dimensional symmetric position is formed. As a result,

The original symmetric position is secured. As a result,

The three-dimensional symmetric position of the pattern 12 and the groove line 13 assuming the completed state of the spectacle frame in advance

You will be able to verify.

On the other hand, the three-dimensional symmetric position of the pattern (12)

The same eyeglass frame assembly work that has to be precisely pinned and moved

In order to fix the pattern 12 to the eyeglass assembly jig,

The pattern 12 should have a precise pattern fixing hole 8 therebetween.

Here, the three-dimensional symmetrical position where the optical axis inclination angle 4 of the pattern is matched

When the pattern fixing hole 8 is directly drilled in the pattern 12, the position is fixed to the Y-axis correction reference plane 19-1

(4) of the optical axis of the pattern from the vertical direction

It is punctured at a place which is large.

Therefore, the correction operation for adjusting the offset position of the pattern 12 to the original accurate three-dimensional symmetrical position has to be dependent on the manual operation of the skilled eyeglass frame maker. Therefore, there was not much error in the dimensions of the same eyeglass frames. However, in order to precisely fix the pattern 12 to the pattern fixing pin of the eyeglass frame assembly for manufacturing a more precise spectacle frame without depending on the manual operation only for correcting the error of the position of the pattern 12 as described above, It should be drilled on the axis perpendicular to the pattern surface.

In order to assemble the spectacle frame, the pattern 12 must be precisely fixed to the jig for assembling the spectacle frame. In order to do so, the pattern fixing hole 8 must be located at a precise position. Thus, one pattern fixing hole 8 (? 5.1 mm) is drilled at a position which is uniformly spaced from the pattern center hole 7 (? 8. The hole at this time is divided into two types according to the size of the pattern 12. [ Here, the thickness of the pattern 12 is generally 3 mm to 6 mm, the small pattern is between 36 mm and 44 mm, the regular pattern is 46 mm to 64 mm, and in the case of the small pattern, The center distance of the hole 8 is set to 16 mm, and in the case of an ordinary pattern, it is set to 27 mm because this is an international standard. ISO l1380: 1994 (I) International Standard (Optics and Optical instruments - Ophthalmic optics - Formers)

In general, the position of the hole to be used for fixing the pattern on the pattern 12 is the position when the pattern is fixed to the fixture for assembling the frame, and since the most important work of assembling the frame is directly performed at this point, Is required. Here, the pattern fixing hole 8 should be formed on an axis orthogonal to the pattern surface, because the pattern fixing pin fixed to the pattern fixing jig is always set in the vertical direction.

Dimensional stability is deteriorated when the pattern 12 is moved and fixed to the eyeglass assembly mounting hole in a state in which the pattern fixing hole 8 is shifted from the axis orthogonal to the pattern surface. According to the conventional method, when the size of the pattern fixing hole 8 is previously drilled larger than the diameter of the pattern fixing pin (5 mm), and the pattern 12 is fixed to the eyeglass frame assembly fixture, Dimensional horizontal symmetry position of the pattern 12 by correcting the horizontal center line 9, the vertical center line 6 and the optical axis inclination angle 3 depending on the sense and manual operation of the skilled eyeglass frame operator Go through the process.

The process of securing a three-dimensional symmetrical position during the operation for assembling the spectacle frame is separately performed when the pattern fixing hole 8 is drilled and when the fixture is fixed to the fixture for the spectacle frame. The cumulative tolerance becomes larger. Therefore, by inserting the horizontal correction pin 16 into the model eyepiece 1, the optical axis inclination angle 4 of the pattern is adjusted to 0 degrees by the three-dimensional symmetric position formed in FIG. Here, setting the optical axis inclination angle 4 to 0 degrees means that the surface of the pattern 12 is spatially parallel to the Y-axis correction reference plane 19-1. Therefore, the pattern fixing hole 8 is precisely punched Dimensional symmetric position of the pattern for the pattern.

Fig. 8 shows the disassembly and assembly of the pattern jig for punching the pattern fixing hole 8 that operates according to the geometric principle. By applying this principle to the actual pattern making process, FIG. 4 is a flowchart showing a process for finding a three-dimensional symmetric position and precisely securing a two-dimensional symmetric position required for drilling the pattern fixing hole 8 again. FIG. 6 and FIG. 1 is a top perspective view and a bottom perspective view showing a simple embodiment of the invention.

6 and 7 will be described with reference to the flow chart of FIG. The pattern 12 to be formed with the pattern fixing hole 8 is inserted into the groove line 13 and attached to the model eyepiece 1. P2 and P3 use the horizontal correction bolt 27 to move the horizontal ruler 26 up and down to align the horizontal center line 9 of both patterns so that the distance between the horizontal ruler 26 and the X- So that both the patterns are parallel to the horizontal center line X. At this time, when the pattern 12 is brought into close contact with the horizontal member 26,

(9) is secured.

When the horizontal center line 9 is secured, next, in P4 and P5,

(Yr, Yl) is set at a symmetrical position and corrects the vertical center line (6). At this time, when the loop 11 of the groove line 13 in which the patterns 12 are inserted is brought into close contact with the X-axis correcting element 23 on the Y-axis correcting element 21 for correcting the vertical center line 6, The distance from the correction reference plane 19 to the X-axis corrector 23 is the same so that both patterns are located at symmetrical positions in the X and Y axes. That is, the pattern 12 and the waveguide 13 of the groove 13 are brought into close contact with the X-axis correcting element 23, thereby securing the vertical center line 6 forming the parallax of the vertical symmetry axis 5 of the pattern.

When the horizontal center line 9 and the vertical center line 6 are secured in P6 and P7,

(5), and the symmetry distance from the vertical symmetry axis (5) to both patterns is secured in accordance with the action of the symmetry element (15). Thus, the horizontal center line 9, from which the pattern 12 is referenced from the X axis, and the vertical center line 6, which is the reference from the Y axis, are symmetrically secured

Both the patterns are fixed to the X-axis correction reference plane 19 and the Y-axis correction reference planes 19-1 and 19-2 by fixing the pattern to the pattern eye 1 with the pattern center fixing bolts 10 in the course of P8 and P9 Dimensional, symmetrical position of the pattern 12 at a distance symmetrical to that of the pattern 12 is ensured.

At P1O, P11, and P12, two-dimensional symmetrical positions of the pattern 12 secured at the top

The optical axis inclination angle 4 of the pattern is measured to determine the Y-axis correction reference plane 19-1 and the vertical center line 6

Symmetric with respect to the pattern, corrects the error of the fine optical axis inclination angle on both sides of the pattern

When the eyeball is fixed with the optical axis inclination angle fixing bolt, the three-dimensional symmetric position of the pattern 12 is

. Here, since the three-dimensional symmetric position is secured,

The final position for assembling the pattern 12 by fixing the pattern 12 to the eyeglass assembly jig

.

In order to drill the pattern fixing hole 8 for fixing the pattern 12 to the eyeglass frame assembly jig P13, 14, and 15, in order to punch the pattern fixing hole 8, three-dimensional symmetric positions of the pattern 12 secured at P1O, P11, , The long axis tilt angle (4) of the pattern fixed by the optical axis tilt angle fixing bolt (18) is released,

The position of the pattern 12 which is in close contact with the eyeball is detected by the Y-axis correction reference plane 19-1 and the horizontal correction pin hole 16-2 by inserting the horizontal correction hole 16 into the horizontal correction hole 16-1 and the horizontal correction pin hole 16-2 of the eyeball, . As a result, a two-dimensional symmetrical position of the pattern 12 for precisely machining the pattern fixing hole 8 is realized

5, assuming the completed state of the spectacle frame, the imaginary positions of the horizontal center line 9 and the vertical center line 6 drawn on the model pattern and the actual positions of the pattern center hole 7 and the pattern fixing hole 8 .

6 shows the action of the horizontal correction frames 25, 27, 27, 28 for correcting the horizontal center line 9 of the pattern,

22, 23, 24, 25 for correcting the vertical center line 6, and a symmetry correction frame (not shown) which operates to position at a symmetrical distance from the vertical axis of symmetry 5

The first and second patterns 14 and 15 ensure the two-dimensional symmetric position first. Here, in order to confirm the fixed position of the pattern 12 for assembling the spectacle frame by assuming the completed spectacle frame, a three-dimensional symmetrical position must be realized. For this purpose, the optical axis inclination angle 4 of both patterns is symmetrically corrected and fixed with the optical axis inclination angle fixing bolt 18 of the pattern. The three-dimensional symmetric position of the obtained pattern is obtained by loosening the optical axis inclination angle correcting bolt 18 of the pattern,

Dimensional symmetric position for punching the pattern fixing hole 8 by inserting the horizontal correction pin 16 into the pattern fixing hole 1. [ As a result, the pattern 8 attached to the pattern jig is held in the pattern fixing hole

(8).

At this time, when the pattern jig 38 is rotated 180 degrees in the vertical direction,

Which is necessary for drilling the pattern fixing hole 8 with the drilling machine.

The guide holes 31, 32, and 33 are pierced. Two pattern fixing holes 8 are formed in each of the left and right patterns,

Three drill guide holes 31, 32 and 33 are formed on the left and right sides, respectively.

It has a pattern fixing hole 8 of a small pattern (34 mm to 46 mm) and a regular pattern (46 mm to 64 mm)

In order to secure it on one drill guide plane, which is close to the vertical symmetry axis 5

Hole is a guide for punching the small-pattern pattern fixing hole 8,

And also serves as a guide for punching the pattern fixing hole 8 of the turn. In this way

The pattern jig securing the position of the two-dimensional symmetry and the pattern fixing gun hole 8 in the vertical direction

By mounting on the ring machine, the precise position of the pattern for machining the pattern fixing hole

.

As described above, the present invention realizes a precise three-dimensional symmetrical position of the pattern 12 and the groove line 13 of the spectacle frame by the principle of symmetry of the geometric figures before assembling the spectacle frame for accurate spectacle frame manufacture, The precise position of the pattern 12 and the groove line 13 of the completed spectacle frame can be confirmed before entering the fabrication step.

Also, by simply converting the three-dimensional symmetric position of the pattern 12 implemented here to the two-dimensional symmetric position by the symmetry principle of the geometric figure, the pattern fixing holes 8 ), Thereby improving the dimensional stability of the pattern necessary for the manufacture of spectacle frames and the efficiency of the manufacturing process

Claims (2)

In the pattern jig in a stage prior to fixing the pattern, which is an initial stage of the spectacle frame assembling process, to the jig for assembling the spectacle frame, In order to ensure a three-dimensional symmetrical position in which both the patterns 12 and the groove lines 13 are symmetrical on the X, Y, and Z axes, that is, the horizontal correction function is performed so that both the patterns 12 and the groove lines 13 are horizontal The vertical correction frames 20, 21, 22, 23, 24 and 25 for correcting the position of the both patterns 12 and the groove lines 13 in the vertical direction, A symmetry correction frame 14 or 15 for causing the pattern 12 and the groove 13 to be symmetrical, an optical axis tilt angle correction frame 17, 17-1, 17-2, 18, 18-1) and a model eyepiece (1). A pattern (12) which is finally secured in accordance with claim 1, wherein a pattern perpendicular to the pattern surface In order to drill the fixing hole 8 precisely, the three-dimensional symmetric position is shifted to the two-dimensional symmetrical position In converting, The pattern 12 and the defective line 13 are horizontally aligned with the Y-axis correction reference plane 19-1, (1) and a plane correction frame (16, 16-1, 16-2) that act to make the side pattern symmetrical.