TWI304137B - - Google Patents

Description

1304137 - * (1) IX. Description of the invention Φ _ [Technical field to which the invention pertains] The present invention relates to a method of manufacturing a crucible. [Prior Art] As a component of an optical system typified by an optical pickup, for example, a polarizing beam splitter is used. The polarized beam splitter is an optical component that separates the laser light emitted from the light source into a reflected light and a transmitted light; the reflected light or the light passing through any of the light temples is directed toward the other side of the optical disc. An APC (Auto Power Control) light-receiving element that detects the intensity of laser light. The reflected light reflected by the polarizing beam splitter is generally reflected at an angle of 90°, so that the polarizing separation film constituting the polarizing beam splitter is arranged at an angle of 45° with respect to the optical axis. Therefore, as the polarizing beam splitter, a square-shaped crucible is used, and the polarized light separation film is formed on the crucible at an angle of 45 to the optical axis. A method of manufacturing an optical device (prism) in which a polarizing separation film is formed at a specific angle is disclosed, for example, in Patent Document 1. In Patent Document 1, a plurality of the same plate glass is prepared, and the plate glass is laminated in a step shape to obtain a laminate, and then the layered body is cut as a split laminate, and the laminated body of the split laminate is repeatedly performed. • Cut off and get the final prism. At this time, in order to obtain an optical device in which a polarizing separation film is formed at a specific angle inside the crucible, the divided laminated body formed by cutting the laminated body is arranged along the inclined side wall having an angle corresponding to the inclination angle of the polarizing separation film. Stepped. [Patent Document 1] JP-A-2000- 1 998 1 0 (2) 1304137 SUMMARY OF THE INVENTION PROBLEMS TO BE SOLVED BY THE INVENTION However, a dielectric multilayer film formed in the last manufactured ruthenium (Patent Document 1) The so-called polarized light separation film must be formed with an extremely high angular accuracy to the incident surface of the light. Thus, in the manufacture of prisms, dielectric multilayer films have to be formed with extremely high angular accuracy. However, in the invention of the above Patent Document 1, it is difficult to satisfy the higher angular accuracy required by 稜鏡. In the invention of Patent Document 1, when a plurality of sheets of glass and a laminated body are laminated, an adhesive is applied between the sheets of the sheets to adhere thereto. At this time, the thickness error of each layer of the adhesive is generated. Since the adhesive is to be laminated in a plurality of layers, the adhesive of each layer accumulates thickness errors. Further, since the lamination and cutting of the plate glass and the split laminate are repeated, the above-mentioned errors are more accumulated, and a cutting error occurs even when the cutting is performed, so that the prism manufactured finally contains an extremely large error. Further, although the plate glass and the laminated body are arranged in a stepped shape along the inclined wall, a cutting error occurs during lamination or cutting, and the inclined wall itself may cause an error. The above error will have an effect, and the tilt angle of the film formed inside the finally manufactured prism may cause a great error. Therefore, the accuracy of the angle of high precision cannot be ensured. Therefore, in the invention of Patent Document 1, it is extremely difficult to form the dielectric multilayer film on the crucible with higher angular accuracy. It is therefore an object of the present invention to provide a method of manufacturing a crucible having a high degree of precision. (3) 1304137 - Means for Solving the Problem - The manufacturing method of the present invention is to manufacture a crucible having a dielectric multilayer film formed at a specific angle; and the feature is that a flat substrate, that is, a large substrate, And a small substrate having the same thickness and width as the large substrate and having a smaller depth than the large substrate, and honing on both sides to make the flatness and parallelism of the large substrate and the small substrate on both sides, the flat plate a double-sided honing process; and on both sides of the large substrate and the small substrate honed in the flat double-sided honing process, a dielectric film is formed on any two faces B to form a film-forming surface a film forming process of a dielectric multilayer film having a non-film-forming surface; and a process of mutually adhering the large-sized substrate and the small-sized substrate to adhere the film-forming surface to the non-film-forming surface, that is, staggered in the width direction The specific interval is a stepped shape, and both ends of the large substrate in the depth direction are exposed as a reference surface to be laminated, thereby obtaining a laminated glass: a substrate adhesion process of the glass; and the layer is The laminated glass body is cut into a space of a length equal to or longer than the length of one side of the step in the direction parallel to the stepped inclination, thereby obtaining a laminated glass body cutting process of a plurality of multiple glass bodies; 1 and in the multiple glass body described above The two cut surfaces cut by the laminated glass body cutting process are double-sided honed, and the multiple glass double-sided honing works of the flatness and parallelism of the two cut surfaces are made; and the laminated glass body is a multiplexed glass body cutting process for obtaining a plurality of short strips of glass in a direction perpendicular to the honing surface, at a distance equal to or longer than one of the lengths of the ridges; and the reference formed at both ends of the short glass body The first short-length vitreous honing work for honing the cut surface cut in the above-mentioned multiple vitreous cutting process; and the surface honed by the first short vitreous 硏(4) 1304137 grinding project The second short strip vitreous honing work for the opposite side of the surface; and the short strip vitreous honed by the short strip vitreous honing project, in combination with the above multiple vitreous body The honing surface of the honing project, or the honing surface of the short-strip vitreous honing project, which is perpendicular to the direction, is cut at equal intervals to obtain a plurality of short-striped vitreous cutting works. Composition. According to the crucible manufacturing method of the present invention, when a large substrate and a small substrate are laminated, the both ends of the large substrate in the depth direction are laminated more prominently than the small substrate. The large substrate and the small substrate are honed on both sides in advance, and the flatness and parallelism are made. Therefore, the surface to be honed is often exposed as a reference surface. Then honing with the reference plane as a reference for higher angle accuracy. Here, although the large substrate and the small substrate are subjected to double-sided surface honing, the dielectric multilayer film is formed on both surfaces of the large substrate, and the dielectric multilayer film is not formed on both surfaces of the small substrate. at this time. The exposed reference surface (the surface that protrudes in the large substrate) is often formed with a dielectric multilayer film, so that the surface can be honed by the surface on which the dielectric multilayer film is formed. Therefore, it is possible to manufacture an ytterbium having an extremely high degree of accuracy in film forming a surface of a dielectric multilayer film. Further, in the double-sided surface of the large substrate and the small substrate which are surface-honed, the present invention can also be applied without forming a dielectric multilayer film on both surfaces of the small substrate on both sides of the large substrate. At this time, since the large-sized substrate is not formed into a dielectric multilayer film, the exposed dielectric surface is often not formed into a dielectric multilayer film. Therefore, -8 - (5) 1304137 honing is performed using the surface of the dielectric multilayer film which is not formed as a reference surface, and at this time, the film formed in the last yttrium has a dielectric multilayer film. It is the surface opposite to the reference surface via the adhesive. Therefore, it is necessary to manage the thickness of the adhesive with high precision, and sometimes the angle accuracy is lowered as compared with the case where the surface of the dielectric film having the dielectric film is formed as a reference surface. However, even if the surface of the dielectric multilayer film is not formed as a reference surface, the use of a reference surface having a high degree of flatness and parallelism as a reference does not change, so that it can be manufactured at a higher time. The accuracy of angular accuracy. Further, the present invention can also be applied to a film on which a dielectric multilayer film is formed on one side surface of a large substrate and a small substrate. At this time, in the exposed reference surface, a dielectric multilayer film was formed on one surface, but a dielectric multilayer film was not formed on the opposite surface. Therefore, the short glass body having the reference surface on which the dielectric multilayer film is formed and the short glass body having the unformed reference surface are produced in a ratio of one half. However, although the surface of the dielectric multilayer film is not formed, although the angle accuracy is lowered, the surface after the double-sided honing is used as the reference surface for the honing, the tempering is still unchanged, so that a higher angle can be manufactured. The accuracy of the flaws. In addition, the angular accuracy will cause some inconsistency. Therefore, although a dielectric multilayer film is formed on one side surface of one of the large substrate and the small substrate, the side surface of one of the small substrates is entirely performed. Then, a dielectric multilayer film is formed in the same surface of one of the large substrates in the same range as the small substrate (when the laminated glass is formed, the same range as the small substrate is bonded in the large substrate range). Therefore, since the surface on which the dielectric multilayer film is not formed is often honed as a reference surface, the above inconsistency can be eliminated. (6) 1304137 - Effect of the invention The crucible manufacturing method of the present invention can produce crucible having a high angular accuracy. [Embodiment] Hereinafter, an embodiment of the present invention will be described based on a flowchart of Fig. 1. Figure 2 is the last manufactured 稜鏡10. The crucible 10 of the present embodiment is a block type optical element having a length of PL, and the dielectric multilayer film 3 is formed at an angle of 45 to the optical axis. Here, in the present embodiment, the diagonal length of each face of the crucible 10 (the long side of the face on which the dielectric multilayer film 3 is formed) is defined as the diagonal length PD of 稜鏡1〇 (= PLx , 2). Further, each of the faces of the crucible 10 is formed with a reflection preventing film having a reflection preventing function. Initially, as shown in Fig. 3, a plurality of flat substrates (substrates such as glass substrates) having different shapes are prepared. In Fig. 3(a), 'the large substrate 1 having a long side (width) having LX1, a short side (depth) having a length of LY1, and a thickness LZ1 is shown. In Fig. 3(b), a small substrate 2 having a width of LX1 and a length of LY2 (LY2 < LY1) and a thickness of L Z1 is shown. In addition, 'the last manufactured 稜鏡1 0' is to laminate and cut the large substrate 1 and the small substrate 2 to generate the width (LX1), depth (LY1), thickness (LZ1) and small size of the large substrate 1. The width (LX1), the depth (LY2), and the thickness (LZ1)' of the substrate 2 are all longer than the length PL of the prism 10 (1//~2) times. As an initial work, the two sides of the plurality of large-sized base-10-(7) 1304137 plates 1 and the small substrate 2 prepared by the honing are surface honed (step s). By this surface honing, both sides of the large substrate 1 and the small substrate 2 can achieve higher flatness and parallelism. Then, a dielectric multilayer film 3 is formed on both surfaces of the large substrate 1 (step S2). At this time, in the present embodiment, as shown in FIGS. 3( a ) and 3 ( b ), the both sides of the dielectric substrate 3 in which the dielectric multilayer film 3 is formed in the large substrate 1 are defined as the film formation surface C, and The both sides of the small substrate 2 are defined as a non-film formation surface N. Next, the large substrate 1 and the small substrate 2 are alternately laminated to obtain a laminated glass body 4 (step S3). In the laminated glass body 4, the large substrate 1 and the small substrate 2 are adhered by an adhesive material, and as shown in Fig. 4, the film formation surface C of each substrate is adhered to the non-film formation surface N to adhere to the laminate. Fig. 5 (a) and (b) are a front view and a side view of Fig. 4; the large substrate 1 and the small substrate 2 are staggered at a predetermined interval in the width direction, and are stacked in a stepped manner as a whole, in the depth direction. Then, both ends of the large substrate 1 are stacked to protrude from the small substrate 2. In addition, Fig. 4, Fig. 5(a) and Fig. 5(b) show a laminated glass body 4 in which three large substrates and two small substrates 2 are laminated; of course, the number of laminated substrates Can be set freely. As shown in Fig. 5(a), the large substrate 1 and the small substrate 2 are stacked in the same width direction as the substrate thickness LZ1. Thereby, the above-described stepped inclination angle of the laminated glass body 4 is formed at 45°. Then, as can be seen from Fig. 4 and Fig. 5(b), the two ends of the large substrate 1 are respectively protruded more than the small substrate 2 (i.e., as shown in Fig. 5(b), the ends are only equally protruded. "1/2x ( LY1 - LY2 )"), so that the protruding portion of the film formation surface C is exposed. Here, in the present embodiment -11. (8) 1304137, the portion exposed in the film formation surface C is defined as the reference plane B (as shown in Fig. 5(b), the reference plane b is formed in the large substrate 1. The two sides of the protruding part). The film formation surface C is made to have a high degree of flatness and parallelism, and the reference surface B is a part of the film formation surface C, so that the reference surface b is also made to have a high degree of flatness and parallelism. As is apparent from the subsequent work, the honing process is performed by using the reference plane B as a reference, and the crucible 10 in which the dielectric multilayer film 3 is formed with extremely high angular accuracy (45°) can be obtained. This will be described later. Then, the laminated glass body 4 is cut along a broken line in FIG. 4 in a direction parallel to the stepped inclination or at an angle of 45° on the basis of the end surface, and cut by a wire saw or the like at a specific interval (step S4). . By this cutting, the multiple vitreous bodies 5 as shown in Fig. 6(a) can be obtained in plural. At this time, the cutting interval of the laminated glass body 4 is as shown in Fig. 4, and the amount of honing is added to the diagonal line PD of the prism 10. This will be described later. Here, in the later-described process, the time at which the multiple vitreous bodies 5 are generated in the step S4, the cut surfaces of the multiple glass bodies 5, 5Α, 5Β (the two cut surfaces when the laminated glass bodies 4 are cut: Fig. 6 ( a) indicated as upper and lower), if it has a high degree of flatness and parallelism, the cut surfaces 5A, 5B will constitute one side of the 稜鏡1〇 and its opposite side. However, after the cutting in step S4, the flatness of the cut faces 5A, 5B of the multiple glass body 5 cannot be ensured. Therefore, the cut surfaces 5A and 5B of the multiple glass bodies 5 are honed, and the honing surfaces 5C and 5D are formed as shown in Fig. 6(b) (step S5). By this honing, the honing surfaces 5C, 5D can be made to have a higher degree of flatness and parallelism, and can constitute one side of the 稜鏡1 及其 and the opposite side thereof, respectively. At this time, the interval between the honing surfaces 5 C and 5 D of the multiplexed glass body 5 after honing is 之一10 -12 - (9) 1304137 one side length PL, and the doubling of the multiple glass body 5 is performed. Thereby, the two faces of 稜鏡1 〇 can be strictly formed. However, the thickness of the multiple vitreous body 5 by the honing in the step S5 (the interval between the honing surfaces 5 C and 5 D) becomes thin. Therefore, in the step S4, the cut of the laminated glass body 4 is first predicted by the amount of the honing amount of the honing, and the space is reserved in advance to perform the cutting. Specifically, the diagonal length PD of the 稜鏡10 has an interval of the honing amount α to cut the laminated glass body 4, thereby honing the honing amount, and making the multiple vitreous body 5 Flatness. In addition, in step S4, the cutting of the laminated glass body 4 is not at the interval of one side of the 稜鏡1 PL, and the interval of the honing amount α is added, but the diagonal length PD of the 稜鏡1〇 is added with honing. The reason for the interval of the amount α is to cut off, because the length of the short side corresponds to the diagonal length PD of the crucible 10 in the end faces of the multiple vitreous bodies 5. Then, the end faces 5E and 5F of the honed multi-glass body 5 shown in Fig. 6(b) are composed of a part of the large-sized substrate 1 or the small-sized substrate 2 of the uppermost and lowermost stages of the laminated glass body 4. The large substrate 1 and the small substrate 2 constituting the laminated glass body 4 have high degree of flatness and parallelism in the step S1, so that the end faces 5E and 5F of the multiple glass body 5 can be used as a reference. Therefore, the cut surfaces 5A and 5B are honed with the end faces 5E and 5F as a reference, and the honing surfaces 5C and 5D and the film-formed dielectric multilayer film 3 can be formed with a high angular accuracy of 45°. The angle between the film surface C. Next, the honing surfaces 5 C, 5 D of the multiple vitreous bodies 5 after honing are formed into a -13-(10) 1304137 film anti-reflection film (step S6). As described above, the multiple S honing surfaces 5 C and 5 D are formed on one side of the 稜鏡 1 ,, so that the film reflection preventing film is formed. Since the multi-glass body 5 is produced: 10, if the anti-reflection film is formed in advance, the anti-reflection film of ί can be formed at one time. Then, as shown by the broken line of the multiple glass body (b) in which the antireflection film is formed, it is cut at a predetermined interval from the honing surfaces 5C and 5D (step S7). By this cutting, the short glass body 6 of τρ: is shown in (a). Here, when the dicing of the multiple glass bodies 5 is performed, the cut surfaces 6A and 6B are not secured as in the case of the glass body 4 (two cut surfaces in the case of the glass body 5: the opposite is shown in Fig. 7(a)) Flatness and parallelism. Then, the cut surface 6A, which has a high degree of flatness and parallelism, constitutes the opposite side of the 稜鏡10. However, when the multi-glass body 5 is cut, the parallelism is not maintained. Therefore, in order to honing the cut surfaces 6A and 6B to make a degree of progress, the short glass body 6 must be produced in consideration of the amount of honing. In the case of the multiple vitreous body 5, the cutting is performed at an interval of one side length PL of the crucible 10/3. However, the cutting of step S7 is carried out in the direction parallel to the plane of the crucible 1〇 in the diagonal length PD of the crucible 10, but in the prism 10 PL with the addition of the grinding amount 0. Cut off at intervals. However, although it is necessary to perform the flatness and the parallelism of the double-sided surface after the honing of the cut surfaces 6A, 6B, at this time, it is necessary to make the 硏: the glass body 5 at the time point to generate a plurality of 稜鏡I number 稜鏡10 5, For example, in the direction of the sixth direction, the seventh cut layer of glass is cut to cut the multiple glass into the side and its 6B, if one side is protected and its flatness and flatness are flat, the cut and the multiple vitreous lines are added. Therefore, it is not one side of the length of the grinding to make the double-sided 14- (11) 1304137 honing the film-forming surface C strictly to 45 °. Therefore, the reference surface B at both ends of the exposed glass body 6 is used as a reference for the honing surface B as one of the film forming surfaces C, and since the film forming surface c is flat and parallel, the reference plane B is used. The surface after the honing by the reference can be formed strictly with the film formation surface C by 45. Angle. At the beginning, as shown in Fig. 7(b), the honing surface 6C is obtained by honing the short glass body section 6A (step S8: first glazing process). An example of the mode of the honing is shown in Fig. 8. As shown in Fig. 8(a), the die 7 is formed on both side wall portions 7S, and each of the side wall portions 7S is formed in plural to form a placing portion 7P for placing both ends of the short strip 6. The placement portion 7P is formed with a notch portion, and the projection portion P of the short glass body 6 is held at the mouth portion (the portion of the short glass body end where the reference surface B is exposed). The slit of the placement portion 7P is composed of a vertical surface 7PA and a slope 7PB, and the angle between the slope 7PB and the mold surface 7B is strictly 45°. Further, the vertical plane 7PA and the oblique angle are strictly formed at 45 degrees. Then, the shape of the notched portion of the placing portion 7P is an isosceles triangle, and the height of the vertical surface 7PA is smaller than the length PL of the 稜鏡1〇. Further, the shape of the placement portion 7P of the mold 7 is maintained at an angle, and the side wall portions 7S provided on both sides of the mold 7 are spaced apart from each other in the depth direction dimension LY2 of the small substrate 2, so that The short glass body 6 is placed 'configured to be slightly longer than the size LY2). Further, the portion 7P provided in Fig. 8(b) is formed with a separation groove 7S for protecting the edge of the short glass body portion P placed on the placement portion 7P. Out of short. The reference has a higher grinding, then the 6-cut short strip glass is used to set the side glass body to the two sides of the cut 6 by 7 bottom 7PB, one of the right angles is high and the exact side is the same (the real depth is not, put The protrusion -15-(12) 1304137 of 6 places the protruding portion P of the short glass body 6 in the placing portion 7P. Fig. 8(b) shows a sectional view in which the cut surface 6A of the short glass body 6 is placed as the upper surface. In the protruding portion P of the short glass body 6, the reference surface B is brought into contact with the inclined surface 7PB of the placing portion 7P, and the honing surface 5D is placed against the vertical surface 7PA. The inclined surface 7PB of the placing portion 7P and the mold 7 The angle of the bottom surface 7B is ensured to be an angle of 45° with high precision, and the angle between the reference surface B of the short glass body 6 and the honing surface 5D is also 45°. Thus, the protruding portion P of the short glass body 6 is tightly fitted. On the other hand, the interval between the cut surfaces 6 A and 6 B of the short glass body 6 is formed to be slightly longer than the length PL of one side of the 稜鏡1 ,, so that the cut surface 6A becomes a side wall. The upper portion 7U of the portion 7S is slightly raised. Therefore, the cut surface 6A of the ridge 1 , is raised, and the honing proceeds to wait. The length of one side of the prism 1 is PL. At this time, the target is honed to the ridge line position of the reference plane B, whereby the honing can be performed at a length PL equal to one side of the 稜鏡10. b), it can be obtained that the short glass body 6 is a short strip shape in which the cross section of the large substrate 1 is an isosceles right triangle (the length of both sides of the right angle is PL). 6B honing (2nd short glass honing: step S9). At this point of time, in the short glass body 6, the honing surfaces 5C, 5D and 6C are precisely modified at a higher angle to the film forming surface C. Therefore, the remaining cut surface 6B is honed with the honing surface 6C as a reference surface, and the honing surface 6D is formed as shown in Fig. 7(c). Further, the honing surfaces 5C, 5D, and 6C are all aligned. The film surface C is modified with a high degree of precision, so it is not limited to the honing surface 6C, and the honing surface 6D can be formed by using any one surface, any two surfaces, or on the basis of all the surfaces - 16 - (13) 1304137. As mentioned above, all faces of the honing surfaces 5C, 5D, 6C, 6D, etc. will form one face of the 稜鏡10, and can be repaired at a higher angle. The short glass body 6. In addition, the above-mentioned mold 7 is merely an example, and the main point of the present invention is to honing one part of the film formation surface C, that is, the reference surface B as a reference, so the mold 7 is not limited to the eighth. As shown in the figure, any one can be applied as long as it can be honed by the reference plane B. Then, when honing the cut surface 6B, the honing surfaces 5C, 5D, and 6C are described. The honing is performed on the basis of the honing, but it is also possible to prepare a honing tool which can be honed by the reference plane B, and the honing of the cut surface 6B is performed by the dies. Then, the honing surfaces 6C and 6D are not formed. Since the antireflection film is formed, the antireflection film is formed on both surfaces (step S1 0), and then, in the direction perpendicular to the honing surfaces 5C, 5D, 6C, and 6D, as indicated by a broken line in Fig. 7(c), The cutting is performed at intervals (step S 1 1 ). At this time, the cutting interval is equal to the length PL of the prism 1 来 to perform cutting. Thereby, a dielectric multilayer film 3 having a side length of PL and having an angle of 45° as shown in Fig. 2 can be formed, and a crucible 10 having a higher angular precision can be obtained. As described above, the present invention prepares two kinds of substrates having the same width and thickness and different depth dimensions, that is, a large substrate and a small substrate, respectively forming a dielectric multilayer film on one side, and a large substrate and a small substrate. Accumulate several pieces. In this case, both ends of the large substrate are laminated more prominently in the depth direction than the small substrate, whereby a part of the surface on which the dielectric multilayer film is formed is often exposed as the reference surface. A higher angle of accuracy can be achieved by honing the benchmark. -17- (14) 1304137 In addition, the prism 10 of the above-described embodiment has a cubic shape and is formed to have a surface of the dielectric multilayer film 3 of 45°. Therefore, when the large substrate 1 and the small substrate 2 are joined, The layers are stacked at intervals equal to the substrate thickness LZ1 in the width direction. That is, by shifting LZ 1 in the width direction, the above-mentioned stepped angle can be formed at 45 °. However, if the distance in the width direction is not the interval of LZ1, the angle of the above step can be formed at an angle different from 45°. In step S4, the laminated glass body 4 is cut in a direction parallel to the stepped inclination. However, if the stepped angle is formed at an angle different from 45°, the dielectric formed in the last manufactured prism 10 is formed. The multi-layered film 3 can be formed to have a different angle from 45°. Further, the shape of the crucible 10 may be different from the cube. Further, at this time, although it is an angle different from 45, it is possible to manufacture a dielectric multilayer film 3 which is formed at 稜鏡10 with a high angular accuracy. Further, although the optical pickup device is exemplified in the present invention, the present invention is not limited thereto, and any article may be applied as long as it is a dielectric multilayer film formed at a specific angle in a square shape. For example, as an optical component constituting a liquid crystal projector that performs color separation and color synthesis, a color separation 亦可 can also be applied. The color separation 稜鏡 also uses a square shape, which is distinguished by a reflection/transmission color separation film by the wavelength of the incident light, and is formed at an angle of 45° to the optical path. Thus, the color separation 稜鏡 can also be applied to the present invention. BRIEF DESCRIPTION OF THE DRAWINGS [Fig. 1] shows a flow chart of the process flow of the present invention (Fig. 2). Fig. 18-(15) (15) 1304137 [Fig. 3] Large substrate and small substrate Three-dimensional view [Fig. 4] A perspective view of a laminated glass body [Fig. 5] Front and side views of a laminated glass body [Fig. 6] A perspective view of a multiple glass body [Fig. 7] A perspective view of a short glass body [Fig. 8] Stereoscopic view and enlarged view of the mold [Description of main components] 1 : Large substrate 2 : Small substrate 3 : Dielectric multilayer film 4 : Laminated glass body 5 : Multiple glass body 6 : Short glass body 7 : Die B : Reference plane C : film formation surface N: non-film formation surface

Claims (1)

1304137 \Ηγ 4S X. Patent application scope / No. 9 5 1 1 6 4 2 0 Patent application Revision of Chinese patent application scope Amendment of August 27, 1997 of the Republic of China 1. A method of manufacturing a prism, manufactured at a specific angle a prism having a dielectric multilayer film formed by using a large substrate having a flat substrate, and a small substrate having a thickness and a width similar to that of the large substrate and having a smaller depth than the large substrate; Honing, making a flat double-sided honing work for the flatness and parallelism of the large-sized substrate and the small-sized substrate on both sides, and the large-sized substrate and the small-sized substrate which are honed in the flat-plate double-sided honing process On both sides of the film, a dielectric multilayer film is formed on any two surfaces to form a dielectric film of a film formation surface and a non-film formation surface; and the large substrate and the small substrate are used to make the above The process in which the film-forming surface is adhered to the non-film-forming surface to be adhered to each other, that is, the specific interval is staggered in the width direction and the both ends of the large substrate are in the depth direction. a substrate is adhered to the reference surface to obtain a substrate adhesion process of the laminated glass body; and the laminated glass body is cut into a diagonal length of the ridge or more in a direction parallel to the stepped inclination At the interval, a laminated glass body cutting process of a plurality of multiple glass bodies is obtained; and in the multiple glass body, the two cut surfaces cut by the laminated glass body cutting process are double-sided honed' a multi-glass double-sided honing process for cutting plane flatness and parallelism; 1304137 and cutting the above-mentioned multiple vitreous body perpendicular to the surface honed by the above-mentioned multiple glass engineering, and cutting off the interval of the above degree or more And obtaining a plurality of short strips of vitreous; and forming a short strip of vitreous honing cut in the multiple vitreous cutting process described above formed on both ends of the short strip of vitreous; and shorting the first The vitreous honing project is required to honing the second short strip of vitreous on the opposite side of the surface and honing the first short vitreous honing and glazing The short strip glass body is obtained by honing the honing surface of the glass double-side honing project, or the body honing work and the second short glass honing work surface are perpendicular to each other, and are cut at equal intervals. The composition of the multiple glass cutting works. 2. According to the first aspect of the invention, in the substrate bonding process, the large substrate plate is shifted in the width direction by the thickness of the substrate so that the inclination angle is 45 °. 3. According to the prism described in the first paragraph of the patent application, in the first short glass vibrating engineering, the vertical surface having the length of one side of the crucible is equal to the height, and the double side of the glass is honed. The long grinding glass cuts the honing surface of the cut surface on which the reference surface is based, and is the base grinding process; the second short glass is shortened by the honing prism honed by the multiple glass first short glass The manufacturing method of the strip glass, and the method for manufacturing the stepped shape of the small-sized base described above, the mold having the inclined surface at an angle of −2 to 1304137 • 45° with respect to the vertical surface, and supporting the both ends of the short glass body Then, the cut surface cut by the multiple vitreous cutting process in the short glass body is honed to the height of the vertical surface. The method for manufacturing a prism according to the first aspect of the invention, wherein the second short glass vibrating process is to honing the first short glass honing project based on the reference surface. Nothing to think about. 5. The manufacturing method according to the first aspect of the invention, wherein the manufacturing method of the crucible is performed after the multi-glass double-side honing process described above. Grinding two 硏' grinding surfaces, forming an anti-reflection film; • After the second short vitreous honing work, the honing surface of the first and second short vitreous honing works, The film formation has the above anti-φ radiation preventing film.