JPH10180769A - Molding die for discontinuous surface lens - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a molding die for a discontinuous surface lens wherein all die split blocks can be held so as to be combined with one another at set positions with a high degree of a accuracy, eliminating completely the influence due to burrs, dusts, and inferior perpendicularly of end surfaces of the blocks themselves. SOLUTION: The molding die for a discontinuous surface lens includes a main die part 22 for forming the surface of a lens and an auxiliary die part 9 which is coupled with the part 22 to form a molding space therebetween. The main die part 22 is formed to have such construction that a plurality of spherical height adjusting spacers 27 are disposed on the inner bottom surface of a stationary frame 10 for assembling and a plurality of die split blocks 11, in each of which a small molding plane 11a so formed as to be opposed to each mirror surface of a lens is formed on one end surface of an axial body, are inserted into the frame 10, in a predetermined arrangement, so as to be mounted individually on the spacers 27. Each of the blocks 11 is supported by the spacer 27 having a diameter corresponding to dimensional error in axial length of each of the blocks to hold each plane 11a at a predetermined relative position.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mold for manufacturing a lens having a discontinuous surface such as an exposure correcting lens used for forming a fluorescent screen of a cathode ray tube (CRT) by exposure. It is about type.

[0002]

2. Description of the Related Art In general, a phosphor screen in which three phosphor layers of red, green and blue are regularly formed on the inner surface of a shadow mask type color cathode ray tube panel through an opening of a black light absorbing layer. The phosphor screen is usually formed by a photographic method using an exposure apparatus. As shown in FIG. 6, the exposure apparatus approximates a light source unit 1 and an exposure light beam 2 emitted from the light source unit 1 to a trajectory of an electron beam emitted from a cathode and deflected by a magnetic field during actual use. And a correction lens 3 for exposure. In this exposure apparatus, a CRT panel 7 on which a shadow mask 4 is mounted is installed so as to face the correction lens 3, and a photosensitive film or a phosphor slurry film formed on the inner surface of the panel 7 is applied to the correction lens 3. Exposure light beam 2 through shadow mask 4
Exposure.

Since the correction lens 3 needs to have a correction function of approximating the exposure light beam 2 to the trajectory of the electron beam for each of the exposure surfaces at different distances from the light source unit 1, the correction lens 3 has a third order in a predetermined direction. A plurality of originally inclined mirror planes 3a have discontinuous surfaces arranged in the column direction and the row direction (see Japanese Patent Application Laid-Open No. 8-153466). The correction lens 3 having such a shape is manufactured by a molding process using a thermoplastic resin or an ultraviolet curable resin using a molding die whose longitudinal sectional view is shown in FIG.

[0004] The molding die includes a main die portion 8 and a sub die portion 9.
It is composed of The main mold part 8 includes the fixed frame 1 for assembly.
0, M × N mold dividing blocks 11 are arranged in M rows and N rows.
The row direction pressing is performed in such a manner that the mold division blocks 11 are inserted in the row arrangement, and are pressed in the row direction (the left and right direction in the figure, in this case, the left direction) by screwing the row direction pressing bolts 13. The plate 12 and a column-direction pressing plate (not shown) which are pressed in the column direction (the front-rear direction of the drawing, in this case, the rear direction of the drawing) by screwing in the column-direction pressing bolts (not shown), respectively. Upon receiving the pressing force, it is fixed by the static friction force. Each mold division block 1
1 has a small forming surface 11a for forming a mirror plane 3a of the correction lens 3 on one end surface (upper surface in the figure), and each of these small forming surfaces 11a is set. It has a three-dimensional inclination inherent to the position. On the other hand, the auxiliary mold part 9 is a container having an opening corresponding to the fixed frame 10 for assembly, and has a resin injection port 14 on one side.
Is provided.

[0005] The molding die includes a main die portion 8 and a sub die portion 9.
After the molds are combined and the mold is clamped, the required resin is injected from the resin injection port 14 into the molding space 19 between the molding small plane 11a of each mold division block 11 and the inner surface of the sub-mold portion 9. Is injected to form the correction lens 3 described above.

[0006] The above-mentioned molding die includes a molding small plane 11a for forming each mirror plane 3a of the correction lens 3.
Is provided in each mold division block 11, and each mold division block 11 has a unique three-dimensional inclination on one end surface of a relatively small shaft-like body having a rectangular cross section. It has a shape having a small forming surface 11a. Therefore, in order to accurately mold the correction lens 3 having a complex surface shape having a discontinuous surface, in assembling the main mold portion 8, the relative height position of the mold division block 11, that is, each molding It is required to set the relative positional relationship of the planes 11 with extremely high precision and combine the divided mold blocks 11. Further, since the small forming flat surface 11a is required to be processed with extremely high inclination accuracy,
The mold division block 11 is formed using a hard and brittle material such as a cemented carbide as a material to be processed.

However, in the main mold portion 8 having the structure shown in FIG. 4, the relative positional relationship between the small molding surfaces 11a is determined by the axial length of each mold division block 11.
Cannot be adjusted. For example, the two-dot chain line in FIG.
A set value (design value) of the height of the mold division block 11 is shown, and the mold division block 11 shown by a solid line having an error in the axial length is formed of a hard and brittle material. For this reason, it is difficult to adjust the axial length by means such as removing an error by cutting.

Conventionally, as shown in FIG. 5, a reference plate 17 set to an accurate flatness is laid on the bottom surface of the fixed frame 10 for assembly, and
Is arranged on the upper surface of the upper surface of the substrate, the adjustment flat spacer 18 made of a soft metal whose back surface is set to an accurate flatness is placed. Since the adjustment plate spacer 18 made of a soft metal can be easily cut, the dimensional error in the axial direction length of the mold division block 11 is set by the mold division block 11 having the dimensional error in the adjustment plate spacer 18. This is absorbed by cutting the portion to be cut by the height error to the required thickness.

[0009]

However, the mold division block 11 has a small cross-sectional shape of about 10 mm × 10 mm and generally has a large number of 300 or more. Small burrs 20 generated when the adjustment plate spacer 18 made of soft metal is cut for adjusting the height of the mold division block 11 in the molding die,
Before inserting the mold dividing block 11, the fixing frame 1 for assembly
Under the influence of dust 21 and the like mixed in the inside, it is extremely difficult to assemble the mold division blocks 11 with high precision so that the molding small planes 11a are at predetermined predetermined positions. For example, in FIG. 5, four mold division blocks 1
Although 1A, 11B, 11D, and 11F are set to the height of the set value, the two mold division blocks 11C and 11E are used.
Is higher than the set value due to the influence of the dust 21 and the burr 20, and the other mold division block 11 </ b> G is higher than the set value due to the squareness failure of the bottom surface of itself. ing.

Therefore, the present invention completely eliminates the effects of burrs, dust, and the improper squareness of the end face of the mold division block itself, and holds all the mold division blocks at the positions of the set values with high precision. It is an object of the present invention to provide a mold for forming a discontinuous surface lens that can be combined by using the above method.

[0011]

In order to achieve the above object, the present invention provides a mold for forming a discontinuous surface lens having a plurality of small mirror planes having different inclinations disposed on a surface. The mold has a main mold part for forming the surface of the lens, and a sub mold part which is united with the main mold part and forms a molding space between the main mold part. The main mold portion has a plurality of height-adjusting spherical spacers having a predetermined diameter arranged in a predetermined arrangement on an inner bottom surface of a container-shaped assembling fixing frame, and is provided on each mirror plane. A plurality of mold division blocks each having a mirror-shaped molding small plane having a corresponding shape formed on one end surface of the shaft-like body are arranged in an arrangement corresponding to each mirror plane of the lens. Inserted inside the fixed frame, with each other end face Each of the mold divided blocks has a configuration supported in contact with each of the spherical spacers, and each of the mold division blocks is supported by the spherical spacer having a diameter corresponding to a dimensional error of each axial length, Each of the molding small planes is held in an arrangement having a predetermined relative positional relationship.

In this discontinuous surface lens molding die, when assembling the main mold portion, each mold divided block is inserted into the fixed frame for assembly in an arrangement corresponding to each mirror surface of the discontinuous surface lens. According to the dimensional error of the axial length of the mold division block to be inserted, a spherical spacer having a diameter capable of absorbing the dimensional error is selected and installed at a predetermined position on the inner bottom surface of the assembly fixing frame, A mold dividing block is placed on the spherical spacer. As a result, the height of each mold division block is adjusted by spherical spacers having different diameters, and each mold division block is supported at a set height position. Therefore, each molding small plane of each mold division block is positioned at a predetermined relative position. Placed in a relationship. The sub-mold is assembled with the main mold part assembled in this way, and mutually clamped, so that the molding space is surrounded by each molding small surface of the main mold part and the inner surface of the sub-mold part. By injecting the required resin, a discontinuous surface lens such as a correction lens for exposure used when forming a fluorescent screen of a CRT by exposure can be molded with resin.

In this molding die, since each mold division block is supported in point contact by the spherical spacer, dust mixed in the fixed frame for assembly is not removed from the mold division block formed by the spherical spacer. It only exists in the space between the other end face and the inner bottom face of the fixed frame for assembly, and has no adverse effect on the positioning of the mold division block. In addition, even if the mold division block has a perpendicularity defect in which one end surface is an inclined surface, this mold division block has a spherical spacer in point contact with the center point of the inclined surface at the designed value or almost the designed value. Therefore, it can be supported at the set height position without any trouble. Further, since the conventional adjusting flat plate for adjusting the height of the mold division block by changing the thickness by cutting is not used, the influence of the height of the mold division block by burrs does not occur. In addition, since a steel ball or the like that can be accurately formed to a predetermined diameter can be used as the spherical spacer, each mold divided block has a high precision in which the relative positional relationship between the molding small planes is extremely small. Can be used for position adjustment.

In the above invention, a reference plate set to an accurate flatness is laid on the inner bottom surface of the fixed frame for assembly, and each of the portions where the mold dividing blocks are to be arranged on the surface of the reference plate. Positioning plates with positioning holes formed in the center are placed on top of each other,
A configuration in which a plurality of spherical spacers are inserted into the respective positioning holes and mounted on the reference plate, and each half is held in the positioning hole in a state of protruding above the positioning plate. Is preferred.

Thus, the spherical spacer can be held at a predetermined position in the fixed frame for assembly without being blinded only by inserting the spherical spacer into the positioning hole. In addition, since the spherical spacer is placed on the reference plate set to an accurate flatness, the height position of the mold division block can be set more accurately.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is an exploded perspective view showing an assembling process of a mold for forming a discontinuous surface lens according to an embodiment of the present invention, FIG. 2 is a plan view of a main mold portion 22, and FIG. It is a longitudinal cross-sectional view which shows the shaping | molding process of a type | mold. In these drawings, the same components as those in FIGS. 4 and 5 are denoted by the same reference numerals, and description thereof is omitted.

As shown in FIG. 3, the main mold portion 22 of the molding die is replaced with the flat plate spacer 18 for adjustment as shown in FIG. A positioning plate 23 in which positioning holes 24 are respectively provided in the portions, and a spherical spacer 27 made of a steel ball inserted into each positioning hole 24 and placed on the reference plate 17 are provided. Accordingly, each mold division block 11 is placed on the spherical spacer 27 and is supported by the spherical spacer 27 in point contact. The above spherical spacer 2
7 is provided with a plurality of types which are strictly controlled in dimensional accuracy and set to an accurate diameter. Each molding small plane 11a of each mold division block 11 has an inclination θx in the row direction x and a column direction y of the arrangement of the mold division blocks 11 with respect to the reference plane.
The three-dimensional inclination is set to a unique value θx (i, j) and θy (i, j) by an address (i, j) corresponding to the correction lens 3. ing.

At the time of assembling the main mold portion 22 in the above-mentioned molding die, as shown by arrows in FIG. 1, each mold dividing unit 11 is fitted into a predetermined value in the assembly fixing frame 10 in a predetermined order. At this time, a spherical spacer 27 having a diameter capable of absorbing the dimensional error and positioning the mold division block 11 at a set value height is selected corresponding to each of the mold division blocks 11 to be fitted. The spherical spacer 27 is inserted into a predetermined positioning hole 24 of the positioning plate 23 and set. The spherical spacer 27 thus set is held by the positioning hole 24 so as not to be blinded while projecting a half part from the positioning hole 24.

As shown in FIG. 2, after all the mold division units 11 have been inserted, the row-direction pressing bolt 13
By screwing the column-direction pressing bolts 29 and the column-direction pressing bolts 29, the respective mold division units 11 are pressed in the row direction x and the column direction y via the row-direction pressing plate 12 and the column-direction pressing plate 28, respectively. When the mold division unit 11 is fixed by the static frictional force, the assembly of the main mold part 22 is completed.

The sub-mold portion 9 is combined with the assembled main mold portion 22 and clamped. As shown in FIG. 3, each sub-mold portion 9 is surrounded by the molding small flat surface 11a and the inner surface of the sub-mold portion 9. The required resin 30 is injected from the resin injection port 14 into the formed molding space 19, and a discontinuous surface lens such as the exposure correction lens 3 is molded with the resin.

In the main mold part 22 of the above-mentioned molding die,
Since each mold division block 11 is supported in point contact by the spherical spacer 27, even if the dust 21 enters the positioning plate 23 as shown in FIG.
Exists only in the space between the bottom surface of the mold division block 11 formed by the spherical spacer 27 and the positioning plate 23, and has no adverse effect on the positioning of the height of the mold division block 11. Has no effect.

Further, the mold dividing block 11 at the left end in FIG.
Although the bottom is inclined and the right angle is poor, such a mold divided block 11 has a center point C on the bottom surface as a design value, and is inclined in any direction through the center point C. In general, it is formed in a shape that matches. Accordingly, since the spherical spacer 27 is supported in point contact with the center point C, which is the design value or almost the design value, the mold division block 11 can be supported at the set height position without any trouble. Further, the spherical spacer 27 is provided with the positioning hole 24.
And is placed on the reference plate 17. However, since the reference plate 17 is not cut for adjusting the height of the mold division block 11, there is no influence of the conventional burr. In addition, the reference plate 17 is set to an accurate flatness, and the height of the mold division block 11 is adjusted by placing a spherical spacer 27 accurately formed with a predetermined diameter on the reference plate 17. . As a result, each mold division block 11 can perform height adjustment with extremely high accuracy such that the relative positional relationship between the molding small planes 11a is, for example, an error of ± 50 μm or less, and a precise discontinuous surface lens can be formed. Can be formed.

[0023]

As described above, according to the mold for forming a discontinuous surface lens according to the first aspect of the present invention, each mold divided block is supported by spherical spacers in point contact, so that it is fixed for assembly. Even if dust is mixed in the frame, the dust only exists in the space around the spherical spacer and does not adversely affect the positioning of the mold division block. Also,
Even if it is a mold division block with a perpendicularity defect with one end face being an inclined surface, this mold division block has a spherical spacer in point contact with the center point at the designed value or almost the designed value on the inclined surface. Since it is supported, it can be supported at the set height position without any trouble. Furthermore, since the conventional adjusting flat plate is not used, there is no influence of the height of the mold division block due to burrs. In addition, since a steel ball or the like that can be accurately formed to a predetermined diameter can be used as the spherical spacer, each mold divided block has a high precision in which the relative positional relationship between the molding small planes is extremely small. The height can be adjusted with.

According to the second aspect of the present invention, the spherical spacer can be held at a predetermined position in the fixed frame for assembly by merely inserting it into the positioning hole without blinding. . In addition, since the spherical spacer is placed on the reference plate set to an accurate flatness, the height position of the mold division block can be set more accurately.

[Brief description of the drawings]

FIG. 1 is an exploded perspective view showing a process of assembling a mold for forming a discontinuous surface lens according to an embodiment of the present invention.

FIG. 2 is a plan view of a main mold part in the molding die.

FIG. 3 is a longitudinal sectional view of a molding process of the molding die.

FIG. 4 is a longitudinal sectional view of a conventional molding die.

FIG. 5 is a longitudinal sectional view of another conventional molding die.

FIG. 6 is a configuration diagram for explaining a use state of a discontinuous surface lens that can be formed by a molding die of the present invention.

[Explanation of symbols]

 Reference Signs List 3 Exposure correction lens (discontinuous surface lens) 3a Mirror plane 9 Secondary mold part 10 Assembly fixed frame 11 Mold division block 11a Small molding plane 17 Reference plate 19 Molding space 22 Main mold part 23 Positioning plate 24 Positioning hole 27 Spherical spacer

Claims (2)

[Claims] 1. A molding die for molding a discontinuous surface lens having a plurality of small mirror planes having different inclinations disposed on a surface thereof, wherein a main mold portion for forming a surface of the lens is provided. And a sub-mold part that is united with the main mold part and forms a molding space between the main mold part and the main mold part. The main mold part is a container-shaped assembly fixed frame. On the inner bottom surface, a plurality of spherical spacers for height adjustment having a predetermined diameter are arranged in a predetermined arrangement, and a mirror-shaped molding small plane having a shape corresponding to each of the mirror planes is used as an axis. A plurality of mold dividing blocks each formed on one end face of the body are inserted into the assembly fixing frame in an arrangement corresponding to each mirror plane of the lens, and each other end face is individually formed. Configuration supported in contact with each of the spherical spacers Wherein each of the mold division blocks is supported by the spherical spacer having a diameter corresponding to the dimensional error of each axial length, and each of the molding small planes is arranged in a predetermined relative positional relationship. A molding die for a discontinuous surface lens, wherein the molding die is held. 2. A reference plate set at an accurate flatness is laid on an inner bottom surface of the fixed frame for assembly, and a central portion of each of the portions where the mold dividing block is to be disposed on the surface of the reference plate. Positioning plates each having a positioning hole formed thereon are placed one on top of the other, and a plurality of spherical spacers are inserted into the respective positioning holes and placed on the reference plate, and each half is placed on the reference plate. The molding die for a discontinuous surface lens according to claim 1, wherein the molding die is held in the positioning hole while protruding above the positioning plate.