KR100552653B1 - Lens lens alignment device - Google Patents

Abstract

The present invention relates to a spectacle lens alignment device that allows the direction of the spectacle lens to be constantly moved to the measuring device by rotating the spectacle lens when the spectacle lens is transferred to the measuring device for measuring the center thickness of the spectacle lens.

The present invention is to align the spectacle lens introduced into the center thickness measuring instrument to have a predetermined direction, to install several driving rollers at equal intervals on one side and to the driving rollers to combine the rotary shaft and the coupling shaft, respectively, but the timing belt The rotation is made at the same rotational speed, and the coupling shaft is coupled to the fixed roller and the flow roller, but is connected to the timing belt at the inside of the fixed roller and the flow roller, the drive roller, the fixed roller and the flow roller is inside It is made to be inclined toward the end, but is made by the surface friction force of the driving roller to be high.

Description

Spectacle lens alignment device

1 is a perspective view of the spectacle lens of the present invention

Figure 2 is a side cross-sectional view of the spectacle lens of the present invention

3 is a front cross-sectional view of the spectacle lens of the present invention.

4 is a plan view of the present invention

5 is a plan view of main parts of the present invention

6 is a side view of main parts of the present invention;

7 is a front sectional view of main parts of the present invention.

Figure 8 is a side cross-sectional view of the use state of the present invention

[Description of Code for Major Parts of Drawing]

1: Glasses lens 2,3: Protruding part

10,11,12: drive roller 15: fixed roller 16: fluid roller

30,31: Timing Belt

In order to measure the data of the finished spectacle lens, first, the center thickness of the spectacle lens is measured by using a non-contact method. The spectacle lens has a different inclination and a different thickness depending on the frequency. An error occurred depending on the direction in which the spectacle lens was placed on the belt conveyor when measuring the central thickness by transporting the spectacle lens on the belt conveyor.

The spectacle lens is manufactured by using the same mold as the lens shape, and the two molds are separated by the thickness of the center of the spectacle lens to fix both sides with a tape or a mold fixture, and then the lens monoma is injected between the molds and cooled. The mold is separated to manufacture the spectacle lens, and the manufactured spectacle lens is subjected to coating and washing to measure the center and focus. The finished spectacle lens is placed in an envelope in which the measurement data is recorded and the packaging is Will be done.

In order to measure the data of pigmented spectacle lenses, the center thickness meter is used to measure the center thickness of the spectacle lenses in a non-contact manner. The spectacle lenses have different slopes and different thicknesses depending on the frequency. An error occurred depending on the direction in which the spectacle lens was placed on the belt conveyor when the spectacle thickness was measured while the spectacle lens was transported on the formed belt conveyor.

That is, the spectacle lens 1 is made of different thicknesses so that protrusions 2 and 3 protruding in four directions are formed on the rear side as shown in FIGS. 1 to 3, but the protrusions 2 facing each other ( 3) the height is made the same, so the four projections (2) (3) are present on the rear surface of the spectacle lens (1), and the heights of the two floors facing each other are the same but adjacent the projections (2) (3). ) Will have different heights.

In the case where the spectacle thickness is measured by transferring the spectacle lens 1 to the lower portion of the center measuring device with a belt conveyor having a center space, any of the projecting portions 2 of the rear protrusions 2 and 3 of the spectacle lens 1 ( Not only does the surface height of the spectacle lens 1 vary depending on whether or not 3) touches the belt conveyor, but the spectacle lens 1 is not horizontal when the projections 2 and 3 of different heights touch the belt conveyor. It could not be placed in an inclined state so that the exact center thickness could not be measured by the center thickness meter.

According to the present invention, when the spectacle lens is moved to the center thickness gauge, the spectacle lens is rotated in a horizontal state by using the projecting portion of the spectacle lens so that the projecting portion of the spectacle lens is placed at the center space of the belt conveyor. This eliminates the measurement error in the center thickness gauge.

The present invention is to align the spectacle lens introduced into the center thickness measuring instrument to have a predetermined direction, to install several driving rollers at equal intervals on one side and to the driving rollers to combine the rotary shaft and the coupling shaft, respectively, but the timing belt The rotation is made at the same rotational speed, and the coupling shaft is coupled to the fixed roller and the flow roller, but is connected to the timing belt at the inside of the fixed roller and the flow roller, the drive roller, the fixed roller and the flow roller is inside It is made to be inclined toward the end, but is made by the surface friction force of the driving roller to be high.

In the present invention, after the completed manufacturing of the spectacle lens (1) is transported by the conveyor (5) to move to the known center thickness measuring device 50, the spectacle lens (1) is aligned in a certain direction after the center thickness measuring device It moves to (50) so that measurement error does not occur.

The spectacle lens 1 moves on the conveyor 5 in a state in which the double-faced part faces upward, and the spectacle lens 1 has two pairs of protrusions 2 and 3 having different heights on the bottom thereof. Although adjacent protrusions 2 and 3 are formed at different heights, the protrusions 2 and 3 at opposite positions are the same height, and the spectacle lens 1 moves on the conveyor 5. When the projections (2) (3) to be brought into contact with the conveyor (5) is moved without considering the directionality, thereby the direction of the spectacle lens (1) in the center thickness measuring device 50 is not fixed will be.

When the spectacle lens 1 is moved to the center thickness measuring device 50 without directivity, the spectacle lens 1 is moved or less protruded with the projecting portion 2 protruding more to the bottom placed on the belt conveyor 51. (3) is moved on the belt conveyor 51, wherein the spectacle lens (1) measures the center thickness depending on which projection (2) (3) is moved to the belt conveyor (51) The difference in position caused a decrease in the accuracy of the measurement error.

In the present invention, the spectacle lens 1, which is moved from the conveyor 5 to the belt conveyor 51 of the center thickness meter 50, is aligned by aligning the projection lens 2 so that the direction of the protrusions 2 and 3 can be constantly moved. The lens packaging is easily made by preventing the occurrence of a measurement error while moving the lens 1 moving to the next stage to have a certain direction.

The aligner of the present invention is installed between the conveyor 5 of the automatic lens packing machine and the belt conveyor 51 of the center thickness gauge 50, and the spectacle lens 1 moving on the conveyor 5 has a certain direction. After the alignment is moved to the center thickness gauge (50).

The aligner continuously installs the first, second and third drive rollers 10, 11 and 12 into the frame 7, but the drive rollers 10, 11 and 12 are moved from the outside to the inside. The smaller diameter is gradually formed while the outer skin is covered with urethane or rubber, and the driving rollers 10, 11, 12 are connected to the rotation shaft 22 and the coupling shaft 23, 24 at the center thereof, 22 is coupled to another frame (8) while the coupling shaft (23, 24) is to be coupled to the fixed roller 15 and the flow roller (16) installed on another frame (8) 15) and the flow roller 16 is also formed in a smaller diameter from the outer side to the inner side, the fixed roller 15 and the flow roller 16 to the surface is made of a synthetic resin material.

In addition, the driving roller 10 is rotated by receiving the rotational power of the motor (not shown) to the driving shaft 21, and the driving rollers 10, 11 and 12 have a timing belt 30 at the smaller diameter. The driving rollers 10, 11, and 12 are all rotated with the same rotation speed in the same direction, but the rotation of the timing belt 30 is rotated by the rotation shaft 22 and the coupling shaft 23, 24. Each of which is transmitted to the rotary shaft 22 and the coupling shaft 23, 24 to rotate together.

Here, a general conveyor belt may be used without using the timing belt 30.

The rotating shaft 22 is covered with urethane or rubber on the outside and is supported by the frame 8 to be rotated, and the coupling shafts 23 and 24 are coupled to the fixed roller 15 and the flow roller 16, respectively. The roller is rotated but the fixed roller 15 is not rotated and remains fixed, and the flow roller 16 is not rotated by the rotational force, but the friction of the spectacle lens 1 is moved by the flow roller 16. To be rotated by movement.

Here, the second driving roller 11 and the fixed roller 15 are installed to protrude slightly upward.

And the timing belt 31 is coupled to the inner side of the driving rollers 10, 11 and 12 by applying a timing belt 31 to the coupling shafts 23 and 24 inside the fixed roller 15 and the moving roller 16. As shown in FIG. Rotating the spectacle lens 1 mounted on the upper side with the 30 to be directed at a certain direction and at the same time to move.

When operating a motor not shown in the present invention of such a configuration, the drive shaft 21 is rotated to rotate the drive roller 10 and the rotary shaft 22 coupled to the drive shaft 21, the rotation of the rotary shaft 22 Accordingly, the coupling shafts 23 and 24 coupled to the timing belt 30 are rotated, and the timing belt 31 is also rotated by the rotation of the coupling shafts 23 and 24. ) And the flow roller 16 is not rotated.

That is, the aligner rotates the driving rollers 10, 11, 12, the timing belt 30, 31, the rotation shaft 22, and the coupling shaft 23, 24 at the initial operation.

As described above, the process of aligning the spectacle lens 1 by inserting the spectacle lens 1 into the aligner with the conveyor 5 while the aligner is operating is described.

The spectacle lens 1 moved on the conveyor 5 is shifted from the curved moving part 6 to the aligner, and the spectacle lens 1 is positioned so that the protrusions 2 and 3 face the bottom. Allow movement in the state.

The spectacle lens 1 moved from the conveyor 5 to the aligner moves on the second driving roller 11 and the fixing roller 15 while slightly rotating in one direction on the first driving roller 10 and the rotating shaft 22. After the rotation is further made by the driving roller 11, the third driving roller 12 and the moving roller 16 are moved, and the spectacle lens 1 is driven by the driving rollers 10 and 11. Movement of the aligner 12 is caused by the rotation of the belt 12 and the timing belts 30 and 31.

When the spectacle lens 1 is inserted into the aligner, the spectacle lens 1 does not have the directionality and the projection parts 2 and 3 are freely input. Therefore, in the present invention, the spectacle lens 1 uses the projection part 2 of the spectacle lens 1. The direction of the spectacle lens 1 is to be in a constant state and then moved to the center thickness meter 50.

First, when the spectacle lens 1 is fed into the aligner from the conveyor 5, the protruding portions 2 and 3 protruding to the bottom of the spectacle lens 1 come into contact with the first driving roller 10, and thus the first driving roller. The spectacle lens 1 is moved to the upper portion of the second driving roller 11, the timing belt 30, and the fixed roller 15 by the rotation of the 10, and the spectacle lens is mounted on the first driving roller 10. When the bottom surface of (1) touches, the bottom surface of the spectacle lens 1 comes into contact with the rotating shaft 22, but the contact resistance of the first driving roller 10 in contact with the spectacle lens 1 is made of a material such as urethane or rubber on the surface. Due to the higher than the contact resistance to the surface of the rotating shaft 22, the first drive roller 10 is made to rotate, so that the spectacle lens (1) protrudes a lot on the bottom surface 2 is a timing belt ( The movement is made while rotating in the direction located between 30) (31).

That is, the first driving roller 10 rotates the eyeglass lens 1 by the difference in frictional force between the first driving roller 10 and the rotating shaft 22 even if the eyeglass lens 1 is put in any direction, and the second driving roller 11 ) And the timing belt 30, 31, and the fixing roller 15, and the spectacle lens 1 has a small protruding portion 3 touching the timing belt 30, 31. The protruding part 2 which protrudes a lot is made to rotate in the direction located in the space part between the timing belts 30 and 31. As shown in FIG.

However, it is difficult to position the protruding portion 2 protruding to the bottom of the spectacle lens 1 in the center of the timing belts 30 and 31 by the action of the first driving roller 10. By using (11), the spectacle lens 1 may be further aligned.

The protruding portion 2 which protrudes from the first driving roller 10 to the bottom surface of the spectacle lens 1 rotates in a direction located between the timing belts 30 and 31 and is timingd with the second driving roller 11. When the belt 30, 31 and the fixed roller 15 is mounted on the upper portion, the second driving roller 12 is rotated and the fixed roller 15 is not rotated so that the upper portion of the timing belt 30 The spectacle lens 1 which is placed and moved is rotated so that the protruding part 2 which protrudes a lot is further rotated toward the center of the timing belt 30, 31, and the spectacle lens 1 is removed. When the rotation is performed by the two driving rollers 11, the bottom surface of the spectacle lens 1 comes into contact with the timing belts 30 and 31 so that the protruding portion 2 which protrudes a lot is the center of the timing belts 30 and 31. When it is located at, the bottom surface of the spectacle lens 1 has the same area as the timing belts 30 and 31 so that the spectacle lens 1 stops rotating and the spectacle lens 1 is low. Rotation stops in the direction in which the protruding portion 2 protruding from the surface is located in the center of the timing belts 30 and 31.

At this time, the second driving roller 11 is rotated and the fixed roller 15 is not rotated. The surface of the second driving roller 11 is covered with urethane or rubber, and the fixed roller 15 is made of synthetic resin. When a large difference occurs in the surface friction force, so that the spectacle lens 1 is placed on the second driving roller 11 and the fixed roller 15, the protruding portion 2 which protrudes a lot is the timing belt. The rotation is made in the direction located between the (30) and (31).

In addition, the second driving roller 11 and the fixed roller 15 are positioned above the position of the first driving roller 10 so that the bottom surface of the spectacle lens 1 is the second driving roller 11 and the timing belt. 30, 31 and the top of the fixed roller 15 is made easy to contact, and also the driving roller 10, 11, 12 and the fixed roller 15 and the flow roller 16 from the outside It is formed in an inclined shape toward the inside so that the bottom surface of the spectacle lens 1 can be easily contacted, so that the spectacle lens 1 can be moved and rotated.

The spectacle lens 1 rotated by the second driving roller 11 and the fixed roller 15 is mounted on the timing belts 30 and 31 so that the third driving roller 12 and the flow roller 16 are rotated. The third driving roller 12 is rotated, but the flow roller 16 is not rotated itself, and the movement of the spectacle lens 1 can be easily moved. Since only the rotation is made, the spectacle lens 1 placed on top of the third driving roller 12 and the flow roller 16 has a protruding portion 2 which protrudes a lot between the timing belts 30 and 31. Is located and the less protruding portion 3 is rotated in contact with the upper timing belt 30, 31 is moved to the center thickness meter (50).

Therefore, in the center thickness measuring device 50, the protruding portion 2 protruding from the bottom of the spectacle lens 1 is moved toward the front, and the protruding portion 3 protruding less is moved toward both sides so that the same condition is always maintained. Since the measurement is made at, the error occurrence rate can be greatly reduced.

The aligner of the present invention drives the rollers 10, 11, 12, the rotating shaft 22, the fixed roller 15, the flow roller 16, and the timing belts 30, 31 move the spectacle lens 1. It is rotated and made to have a certain direction and then discharged, the driving rollers 10, 11, 12 inclined inwardly are wrapped in a material such as urethane or rubber having a large frictional resistance on the surface, and the fixed roller 15 ) And the flow roller 16 is made of a synthetic resin with a low friction resistance, but the timing belts (30) and (31) inside the driving rollers (10) (11) and (12) and the fixed roller (15) and the flow roller (16). Is rotated, so that the driving rollers 10, 11, 12, which protrude in the lower part of the spectacle lens 1, are projected to the lower part of the spectacle lens 1, even if the spectacle lens 1 is fed into the aligner in any direction. To the bottom surface of the spectacle lens 1 so that different frictional resistances act on both sides when moving while touching the rotating shaft 22, the fixed roller 15, the flow roller 16, and the timing belt 30, 31. The protruding part 2 which protrudes a lot is located between the timing belts 30 and 31, and is discharged so that the measurement error in the measurement of the center thickness can be reduced while the spectacle lens 1 moves even in a certain direction, It can be put in the direction.

As such, the present invention rotates the eyeglass lens while rotating the eyeglass lens prior to measuring the center thickness of the spectacle lens, but uses the bottom protrusion of the spectacle lens to align the spectacle lens to have a predetermined direction, thereby measuring the center thickness. While significantly lowering the next step in the packaging step can be put in a certain direction in the bag.

Claims (5)

The drive rollers 10, 11, 12 are installed spaced apart from each other inside the frame 7, but the drive rollers 10, 11, 12 are formed to have an inclined shape from the outside to the inside, The driving roller 10 is provided with a rotating shaft 22 coupled to the frame 8, while the driving rollers 11 and 12 are coupled to the coupling shafts 23 and 24, but the coupling shafts 23 and 24 are coupled. The fixed roller 15 and the flow roller 16 is coupled to the frame 8 and inclined from the outer side to the inner side thereof, and the rotating roller 22 and the coupling shaft 23 and 24 are driven rollers. 10) Glasses eyeglasses characterized in that the timing belts 30 and 31 are provided on the inside of the 11, 12, the fixed roller 15, and the flow roller 16, on which the spectacle lens 1 is placed. Lens alignment device. According to claim 1, the driving rollers 10, 11, 12 is covered with a high friction material such as urethane or rubber outward, the fixed roller 15 and the flow roller 16 has a relatively low friction force Eyeglass lens alignment device, characterized in that the production of synthetic resin. The spectacle lens alignment device according to claim 1, wherein the driving rollers (11) and the fixed rollers (15) are installed to protrude upward from the position of the driving rollers (10) (12). According to claim 1, the driving rollers 10, 11, 12 are rotated equally in the same direction under the motor rotational force, the fixed roller 15 is kept fixed, the flow roller 16 is a spectacle The spectacle lens alignment device, characterized in that the friction rotation is made in accordance with the movement of the lens (1). According to claim 1, wherein the protruding portion (2) protruding to the back of the spectacle lens (1) is located between the timing belts 30, 31, the protruding portion (protruding less toward the back of the spectacle lens 1) 3) is rotated to move in contact with the upper portion of the timing belt (30) (31), the spectacle lens alignment device.

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