JP2010100493A - Mold material and method for forming glass material using the mold material - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce production cost by acquiring a formed body at a high yield when a cylindrical glass product is formed. <P>SOLUTION: Regarding a mold material wherein a glass material is heated and melted so as to form the outline of a cylindrical glass product, the mold material comprises: a bottom plate; a cylindrical part arranged on the bottom plate in such a manner that either opening part is in contact with the bottom plate; a guide member having an outer diameter almost same as the inside diameter of the cylindrical part and freely slidably movable on the inner circumferential face of the cylindrical part to the upper and lower directions; a pressing fixture with an almost columnar shape arranged at the lower face of the guide member and in which the corner parts of a pressing face pressing the upper face of the glass material placed on the bottom plate in the cylindrical part are subjected to chamfering; and a load plate applying a load on the pressing fixture. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a mold material and a method for molding a glass material using the mold material. More specifically, the present invention is used when various glass materials such as quartz glass, silicate glass, or soda glass are molded into a desired shape while being heated and melted. The present invention relates to a mold material and a method for molding a glass material using the mold material.

  In recent years, glass products, particularly glass products made of quartz glass (hereinafter simply referred to as “quartz glass products” as appropriate) are not limited to optical devices such as optical lenses, but have durability and chemical stability. Taking advantage of the advantages, it is widely used in semiconductor manufacturing jigs, liquid crystal display (LCD) panel manufacturing photomasks or precision components for optical communication.

  In general, as a manufacturing process of such a quartz glass product, a process mainly using a removal process for removing an unnecessary region from an object to be processed, such as etching or grinding, has been adopted.

However, since the manufacturing process by etching is limited to relatively fine processing of the surface of the object to be processed, there is a problem that the glass product obtained thereby is limited.

  In addition, since the manufacturing process by grinding is performed to grind the processing object little by little to process it into a desired shape, it takes a lot of processing time and all unnecessary parts are ground from the processing object. The weight of the glass material that is larger than the weight of the glass product processed in this way is required, and problems have been pointed out in terms of production efficiency and production cost.

  For example, when trying to obtain a cylindrical quartz glass product, in a heating apparatus such as an electric furnace, a processing object that is a quartz glass material placed in the mold is heated and melted by a cylindrical mold. Then, an intermediate body that is a rough shape of the quartz glass product is manufactured by grinding the central portion of the molded body formed into a cylindrical shape, and the cylindrical quartz glass product is finished by further machining the intermediate body. It is made like that.

  In this way, the intermediate part is produced by grinding the central part of the molded article that has been heated and melted and formed into a cylindrical shape. For example, when producing a cylindrical quartz glass product having a large inner diameter, the intermediate is produced. In this case, since many parts of the molded body formed into a cylindrical shape are ground, the weight of the quartz glass material is more than 10 times the weight of the finished quartz glass product by further grinding the intermediate body. There was an increase in manufacturing costs.

Here, a method of manufacturing a cylindrical quartz glass product by grinding will be described in detail with reference to FIGS. 1 and 2.

  That is, FIG. 1A shows a schematic configuration perspective view of a mold material used in a conventional glass material molding method, and FIG. 1B shows an arrow A in FIG. FIG. 1 (c) shows a cross-sectional view taken along line BB of FIG. 1 (a), and FIG. 2 (a) shows a mold material and processing after heating and melting. A cross-sectional view of the object is shown, and FIG. 2B is a perspective explanatory view of the object to be processed shown in FIG.

  A mold material 100 used in the glass material molding method according to the conventional technique includes a bottom plate 12 and a cylindrical outer cylinder 14 which is disposed on the upper surface 12a of the bottom plate 12 and has a desired inner diameter. .

  The upper surface 12a of the bottom plate 12 and the inner peripheral surface 14a of the outer cylinder 14 are each coated with a release material.

In the above configuration, in order to manufacture a cylindrical quartz glass product, first, the workpiece 16 that is a quartz glass material is placed on the upper surface 12a of the bottom plate 12 in the outer cylinder 14, and the workpiece 16 is placed. The formed mold 100 is heated under a predetermined condition by a heater (not shown).

  Thus, when the mold member 100 is heated under predetermined conditions, the workpiece 16 is heated and melted, and the workpiece 16 heated and melted has an inner diameter of the outer cylinder 14 as shown in FIG. It is produced as a cylindrical shaped body having the same outer diameter.

  Then, by grinding the central portion of the molded body that is the workpiece 16 that has been heated and melted into a cylindrical shape, an intermediate body that is a rough shape of the desired cylindrical quartz glass product is produced, and this intermediate body is further ground, etc. Through the machining process, cylindrical quartz glass products finished to the final specified dimensions are manufactured.

As described above, according to the conventional technique, when manufacturing a cylindrical quartz glass product, the central portion of the molded body, which is the workpiece 16 heated and melted into a columnar shape, is ground to obtain an outline of the quartz glass product. Since it is necessary to obtain a shaped intermediate body, depending on the cylindrical shape to be molded, many parts of the molded body that is the workpiece 16 heated and melted into a columnar shape will be ground, and quartz glass for the manufactured quartz glass product will be ground. In some cases, the material was required to be 10 times or more in weight ratio, which caused an increase in manufacturing cost.

The prior art that the applicant of the present application knows at the time of filing a patent is as described above and is not an invention related to a known literature, so there is no prior art information to be described.

  The present invention has been made in view of the various problems of the conventional techniques as described above. The object of the present invention is to form a molded body with a high yield when molding a cylindrical glass product. The acquisition aims to provide a mold material for reducing the manufacturing cost and a glass product molding method using the mold material.

  In order to achieve the above object, the present invention provides a pressing jig in which a chamfering process is applied to a corner portion of a pressing surface when a glass material used for forming a cylindrical glass product is heated and melted. The glass material to be heated and melted is pressed into the glass material after being heated and melted so as to be processed into a columnar shape having a recessed central portion, that is, a shape close to a cylindrical shape. .

  Therefore, according to the present invention, a recess is formed in the molded body, which is a glass material after heat melting, so that the molded body is formed in a substantially cylindrical shape, and bubbles are formed on the inner wall surface of the recess formed in the molded body. Since it is not formed, an intermediate body, which is a rough shape of a glass product, can be obtained from the molded body with a high yield, and thus the manufacturing cost can be suppressed.

That is, the invention according to claim 1 of the present invention is a mold material for heating and melting a glass material to form a general shape of a cylindrical glass product, wherein the bottom plate is in contact with the bottom plate and one opening. A cylindrical portion disposed on the bottom plate, a guide member having an outer diameter substantially the same as the inner diameter of the cylindrical portion, and slidably movable in the vertical direction on the inner peripheral surface of the cylindrical portion; A substantially cylindrical pressing jig in which chamfering is performed on a corner portion of a pressing surface disposed on the lower surface of the guide member and pressing the upper surface of the glass material placed on the bottom plate in the cylindrical portion; The pressing jig has a load plate for applying a load.

  Moreover, invention of Claim 2 among this invention is invention of Claim 1 among this invention, The processing width of the chamfering process given to the corner | angular part of the said press surface is 2 mm or more and 200 m or less. It is what I did.

  Moreover, invention of Claim 3 among this invention is invention of Claim 1 among this invention, The processing width of the chamfering process given to the corner | angular part of the said press surface is the diameter of the said press surface. On the other hand, 1/30 to 1/10.

  Moreover, the invention according to claim 4 of the present invention is the invention according to any one of claims 1, 2, or 3 of the present invention, wherein the chamfering process applied to the corner of the pressing surface is as follows. The processing angle of the processing surface to be formed is formed so as to be 40 degrees or more and 50 degrees or less with respect to the pressing surface.

  Moreover, the invention according to claim 5 of the present invention is the invention according to any one of claims 1, 2, or 3 of the present invention, wherein the chamfering process applied to the corner of the pressing surface is as follows. The processing angle of the processing surface to be formed is formed so as to be 45 degrees with respect to the pressing surface.

  According to a sixth aspect of the present invention, there is provided a glass material molding method using a mold material in which a glass material is heated and melted to form a general shape of a cylindrical glass product using the mold material. When the glass material is placed on the bottom plate in the cylinder portion arranged on the top and the glass material placed on the bottom plate is heated and melted to form a column shape, the glass material is placed on the upper surface central portion of the glass material. By applying a load through a pressing jig in which a chamfering process is applied to a corner portion of a pressing surface that presses the glass material, a concave portion is formed in the central portion of the upper surface of the glass material.

  According to a seventh aspect of the present invention, in the sixth aspect of the present invention, the glass material is a quartz glass material.

  Since the present invention is configured as described above, it is possible to obtain a molded body with a high yield when manufacturing a glass product having a cylindrical shape, so that the manufacturing cost can be reduced. It has an excellent effect of becoming.

  Hereinafter, an example of an embodiment of a mold material and a glass material molding method using the mold material according to the present invention will be described in detail with reference to the accompanying drawings.

  In the following description, the same or equivalent configuration as the mold member 100 used in the glass material molding method according to the prior art described with reference to FIGS. 1 and 2 is the same as the reference numeral used above. Detailed description of the configuration and operation will be omitted as appropriate by using reference numerals.

Here, FIG. 3 (a) shows a schematic configuration perspective view of the mold material used in the method for molding a glass material according to the present invention, and FIG. 3 (b) shows C in FIG. 3 (a). An arrow view is shown, and FIG. 3 (c) shows a DD cross-sectional view of FIG. 3 (a), and FIG. 4 shows the mold material shown in FIG. 3 (a). A perspective explanatory view showing the pressing jig is shown, and FIG. 5 (a) shows a cross-sectional view of the workpiece and mold after heating and melting, and FIG. 5 (b). FIG. 5A is a perspective explanatory view of the object to be processed shown in FIG.

The mold material 10 used in this glass material forming method includes a bottom plate 12, a cylindrical outer cylinder 14 which is disposed on the upper surface 12 a of the bottom plate 12 and has a desired inner diameter, and is substantially the same as the inner diameter of the outer cylinder 14. A guide member 20 having a disk shape having an outer diameter and movable on the inner peripheral surface 14a of the outer cylinder 14 so as to be slidable in the vertical direction is placed on the upper surface 20a of the guide member 20 to apply a load. The workpiece 16 that is a quartz glass material placed on the lower surface 20b of the guide member 20 and placed on the upper surface 12a of the bottom plate 12 so that the center is located on the central axis O of the load plate 22 and the outer cylinder 14. It has a substantially cylindrical pressing jig 18 that presses from above.

Here, the pressing jig 18 is chamfered by scraping off the corners of the lower surface 18b that is a surface pressing the workpiece 16 to form a chamfered surface 18d (FIG. 4A). To see.)

  In the example shown in FIG. 4, the chamfering in the pressing jig 18 is formed so that the boundary 18e between the side surface 18c and the chamfering surface 18d is a curved surface having a small curvature, and the chamfering processing is performed on the lower surface 18b. Although the example in which the boundary 18f with the surface 18d is formed to be a curved surface with a small curvature has been shown, the boundary 18e between the side surface 18c and the chamfered surface 18d is formed to have a curved surface with a large curvature, and the bottom surface You may form so that the boundary 18f of 18b and the chamfering surface 18d may become a curved surface with a large curvature.

  Further, in the chamfering process in the pressing jig 18, the chamfering surface 18d is preferably set to a processing angle α of 40 degrees or more and 50 degrees or less, more specifically 45 degrees with respect to the lower surface 18b (FIG. 4B). To see.)

  Further, the chamfering process in the pressing jig 18 is preferably performed so that the processing width W is 2 mm or more and 200 mm or less, and the processing width W is 1/30 to 1/10 with respect to the diameter of the lower surface 18b. Has been.

  By chamfering the corners of the pressing jig 18 in this manner, the resistance between the lower surface 18b of the pressing jig 18 and the workpiece 16 is reduced during heating and melting.

  Further, the upper surface 12a of the bottom plate 12, the inner peripheral surface 14a of the outer cylinder 14, the lower surface 18b of the pressing jig 18, the side surface 18c of the pressing jig 18, the chamfered surface 18d of the pressing jig 18, the lower surface 20b of the guide member 20 and The side surface 20c of the guide member 20 is covered with a release material.

Here, the load plate 22, the guide member 20, and the pressing jig 18 are configured to be movable along the central axis O of the outer cylinder 14 by applying a load manually or by a motor (not shown). At the same time, when manual or motor loads are removed, the load due to the weight of each of the load plate 22, the guide member 20, and the pressing jig 18 is moved downward along the central axis O of the outer cylinder 14. It is configured.

  Note that the load plate 22, the guide member 20, and the pressing jig 18 are configured such that their center of gravity is positioned on the central axis O.

  Further, the surface pressure at which the lower surface 18b of the pressing jig 18 presses the workpiece 16 that is a quartz glass material is set by the total weight of the pressing jig 18, the guide member 20, and the load plate 22. The surface pressure can be adjusted to a desired level by changing the weight of 22.

  For example, when a plurality of load plates 22 having a constant weight can be placed on the upper surface 20a of the guide member 20, an arbitrary weight can be obtained by adjusting the number of load plates 22 placed on the upper surface 20a of the guide member 20. To obtain a desired surface pressure.

Furthermore, each member used for the above-described mold member 10 is not particularly limited as long as it has high hot strength and chemical stability and is highly pure. However, since it is easy to machine, each member is manufactured. Is preferably made of carbon.

In the above configuration, for example, in order to manufacture a cylindrical quartz glass product, the workpiece 16 that is a quartz glass material is placed on the upper surface 12a of the bottom plate 12 so that the center is located on the central axis O of the outer cylinder 14. The mold material 10 is placed in such a manner that the load plate 22, the guide member 20, and the pressing jig 18 are moved downward along the center axis O of the outer cylinder 14 by the load due to their own weights. Argon gas, neon gas, It is placed in a heating apparatus such as an electric furnace that is heated to a predetermined temperature in an inert gas atmosphere such as nitrogen gas or a mixed gas thereof or in a vacuum.

  When the workpiece 16 begins to be heated and melted in the heating device, the pressing jig 18 is applied to the upper surface 16a of the workpiece 16 due to the loads of the load plate 22, the guide member 20, and the pressing jig 18 due to their own weights. The central portion is pressed to forcibly deform the central portion of the upper surface 16 a of the workpiece 16, and a concave portion along the outer shape of the pressing jig 18 is formed in the central portion of the upper surface 16 a of the workpiece 16. Formed (see FIGS. 5A and 5B).

  That is, the molded object that is the heat-melted workpiece 16 is molded into a substantially cylindrical shape in which the central portion of the upper surface 16 a is recessed by the mold material 10.

  As will be described in detail later with reference to the experimental results, bubbles do not remain on the inner wall surface of the molded body formed in the substantially cylindrical shape.

  At this time, the size of the concave portion formed in the central portion of the upper surface 16a of the molded body that is the heat-melted workpiece 16 can be adjusted by the diameter and thickness of the pressing jig 18.

In this way, the molded object that is the object 16 to be processed after heating and melting formed into a substantially cylindrical shape is ground and cut to a specified dimension in the next process, and processed as an intermediate body that is a rough shape of a cylindrical or ring-shaped quartz glass product. Then, the processed intermediate body is manufactured as a quartz glass product having a final shape and dimensions through a machining process such as further grinding.

As described above, in the case where an intermediate body that is a rough shape of a previous stage quartz glass product manufactured as a quartz glass product using the mold material 10 is manufactured, the molded body that is the heat-melted workpiece 16 is formed in the next step. The volume of the central portion can be reduced by forming the central portion to be ground and cut so that the intermediate portion of the quartz glass product can be ground and ground. The weight of the central portion to be cut can be reduced.

  Further, according to the mold member 10, the size of the concave portion formed in the central portion of the molded body that is the workpiece 16 after heating and melting can be adjusted by the diameter of the pressing jig 18 and the thickness in the direction of the central axis O. It is also possible to adjust the amount of the central portion that is ground and cut in the grinding and cutting process when producing the intermediate.

  That is, in order to reduce the weight of the glass material with respect to the glass product to be manufactured, the diameter of the pressing jig 18 is set to a size that approximates the inner diameter of the intermediate body of the glass product to be manufactured, and the center of the pressing jig 18 The thickness in the direction of the axis O may be a size that approximates the height of the intermediate body of the glass product to be manufactured.

In addition, it is preferable that the heating temperature of the workpiece 16 during heating and melting described above is, for example, 1500 to 2000 ° C., and more specifically, 1750 to 1900 ° C.

  This is because when the heating temperature of the workpiece 16 is less than 1500 ° C., the quartz glass has high viscosity, so that the quartz glass material is not easily deformed, and the mold material 10 may not be molded into the desired shape. In addition, when the heating temperature of the workpiece 16 exceeds 2000 ° C., the quartz glass material may decompose and react with carbon that is a material of each component of the mold 10.

Next, the experimental results performed by the inventor of the present invention using the mold 10 described above will be described in detail below.

  In this experiment, in order to confirm the effect of the chamfering process applied to the corner portion of the lower surface 18b of the pressing jig 18, the corner portion of the lower surface 18b serving as a pressing jig to press the workpiece 16 is used. As shown in FIG. 6C, the chamfering process is performed on the corner portion of the lower surface 30b that presses the workpiece 16 as the mold member 10 using the pressing jig 18 that has been chamfered and the pressing jig. Prediction of the intermediate body when producing an intermediate body that is a rough shape of a cylindrical quartz glass product from a workpiece 16 that is a cylindrical quartz glass material by using a mold member 50 that is not provided with a pressing jig 30. The actual number of images acquired was checked against the number of images acquired.

  The pressing jig 30 has a shape in which the corner of the lower surface 18b of the pressing jig 18 is not chamfered, and the outer diameter and thickness of the pressing jig 18 and the pressing jig 30 are the same. .

  That is, the mold material 50 shown in FIGS. 6A and 6B differs from the mold material 10 only in that the pressing jig 30 is used instead of the pressing jig 18.

  In addition, the expected number of intermediates to be obtained is predicted by dividing the height of the molded body 16 to be processed 16 obtained by heating and melting by the height of the intermediate to be processed into a specified dimension. did.

Specifically, the outer cylinder 14 uses two types having an inner diameter of 320 mm and an inner diameter of 420 mm, and an electric furnace is used as a heating device, and the inside of the electric furnace is heated at a pressure of 0.03 MPa and a nitrogen gas atmosphere. The state is set to 1800 ° C., and the cylindrical workpiece 16 is heated and melted in the electric furnace.

  Further, when using the outer cylinder 14 having an inner diameter of 320 mm, the pressing jig 18 and the pressing jig 30 having an outer diameter of 150 mm are used, and the chamfering process at the corner of the lower surface 18b of the pressing jig 18 at this time is performed at a processing angle. It was 45 degrees and the processing width was 10 mm. Furthermore, when using the outer cylinder 14 having an inner diameter of 420 mm, the pressing jig 18 and the pressing jig 30 having an outer diameter of 200 mm are used, and the chamfering process at the corner of the lower surface 18b of the pressing jig 18 at this time is performed at a processing angle. It was 45 degrees and the processing width was 15 mm.

  And the expected acquisition number of intermediates that are expected to be obtained by processing from the dimension of the molded object 16 to be processed after heating and melting to the specified dimension, and the molding that is actually processed object 16 after being heated and melted The number of intermediates obtained by processing the body to the specified dimensions by grinding and cutting was examined.

  Further, the workpiece 16 is given a load due to its own weight of the load plate 22, the guide member 20 and the pressing jig 18 in the mold 10, and the load plate 22, the guide member 20 and the pressing jig in the mold 50. A load due to the weight of each of 30 was applied.

7 (a) and 7 (b) show experimental results of experiments by the inventors of the present application.

  Here, No. 7 in FIG. 1-No. 6, the dimensions of the molded body that is the workpiece 16 after heating and melting in the mold 10 using the outer cylinder 14 having an inner diameter of 320 mm and using the pressing jig 18 as the pressing jig, and the workpiece after heating and melting. It is specified by grinding and cutting the expected number of intermediates that are expected to be obtained by processing from the size of the 16-shaped molded body to the specified size, and the molded body that is the workpiece 16 after heating and melting. The actual number of intermediates obtained by processing into different dimensions is shown.

  In addition, in FIG. 7-No. 10, the dimension of the molded body that is the workpiece 16 after heating and melting in the mold 10 using the outer cylinder 14 having an inner diameter of 420 mm and the pressing jig 18 as the pressing jig, and the workpiece after heating and melting. It is specified by cutting / grinding the expected number of intermediates that are expected to be obtained by processing from the dimensions of the 16-shaped molded body to the specified dimensions, and the molded body that is the workpiece 16 after heating and melting. The actual number of intermediates obtained by processing into different dimensions is shown.

  Further, in FIG. 11-No. 15, the dimensions of the molded object 16 to be processed 16 after heating and melting in the mold 50 using the outer cylinder 14 having an inner diameter of 320 mm and using the pressing jig 30 as the pressing jig, and the processing target after heating and melting. It is specified by cutting / grinding the expected number of intermediates that are expected to be obtained by processing from the dimensions of the 16-shaped molded body to the specified dimensions, and the molded body that is the workpiece 16 after heating and melting. The actual number of intermediates obtained by processing into different dimensions is shown.

  In addition, in FIG. 16-No. 20, the dimensions of the molded body 16 as the workpiece 16 after heating and melting, and the workpiece after heating and melting in the mold 50 using the outer cylinder 14 having an inner diameter of 420 mm and using the pressing jig 30 as the pressing jig. It is specified by cutting / grinding the expected number of intermediates that are expected to be obtained by processing from the dimensions of the 16-shaped molded body to the specified dimensions, and the molded body that is the workpiece 16 after heating and melting. The actual number of intermediates obtained by processing into different dimensions is shown.

Here, No. 7 in FIG. 11-No. As shown in FIG. 15, in the mold 50 using the pressing jig 30 as the pressing jig, the cylindrical outer shape (OD) having a specified dimension is 308 mm from the workpiece 16 of the quartz glass material of about 13 kg. Yes, the inner diameter (ID) is 170 mm, and the expected number of intermediates obtained by processing the height (t) to 16 mm is four. The obtained number of intermediates was 2 to 3, and the expected number of intermediates obtained did not match the actual number obtained, and the actual number obtained was less than the expected number.

  On the other hand, No. 7 in FIG. 1-No. As shown in FIG. 6, in the mold 10 using the pressing jig 18 as the pressing jig, the cylindrical outer shape (OD) having a specified dimension is 308 mm from the workpiece 16 of the quartz glass material of about 13 kg. Yes, the inner diameter (ID) is 170 mm, and the expected number of intermediates obtained by processing the height (t) to 16 mm is four. In addition, the number of acquired intermediates was four, and the expected number of acquired intermediates coincided with the actual number of acquired intermediates.

In addition, in FIG. 16-No. As shown in FIG. 20, in the mold 50 using the pressing jig 30 as the pressing jig, the cylindrical outer shape (OD) having a specified dimension is 401 mm from the workpiece 16 of the quartz glass material of about 20 kg. Yes, the inner diameter (ID) is 229 mm and the height (t) is processed to 18 mm, while the expected number of intermediates obtained is 3; Further, the obtained number of intermediates was 1 to 2, and the expected number of acquired intermediates did not match the actual number of acquired sheets, and the actual number of acquired sheets was less than the expected number of acquired sheets.

  On the other hand, No. 7 in FIG. 7-No. As shown in FIG. 10, in the mold 10 using the pressing jig 18 as a pressing jig, a cylindrical outer shape (OD) having a specified dimension is 401 mm from a workpiece 16 of a quartz glass material of about 20 kg. Yes, the inner diameter (ID) is 229 mm and the height (t) is processed to 18 mm, and the expected number of intermediates obtained is 3 or 4, but actually processed to the above dimensions The obtained number of intermediates was also 3 or 4, and the expected number of intermediates and the actual number of obtained intermediates matched.

As described above, in the mold material 10 using the pressing jig 18 in which the chamfering process is performed on the corner portion of the lower surface 18b that presses the workpiece 16 as the pressing jig, the workpiece 16 is the workpiece 16 after being heated and melted. It was possible to obtain the same number of intermediates as the number of intermediates expected to be obtained by processing from the dimensions of the molded body to the specified dimensions.

  On the other hand, in the mold material 50 using the pressing jig 30 in which the chamfering process is not performed on the corner portion of the lower surface 30b that presses the workpiece 16 as the pressing jig, the molding is the workpiece 16 after heating and melting. The number of intermediates obtained by processing to the specified dimensions was less than the expected number of intermediates expected to be obtained by processing from the body dimensions to the specified dimensions. .

Here, in the mold material 50 using the pressing jig 30 as the pressing jig, bubbles were formed on the inner wall surface 16b of the molded body which is the workpiece 16 after heating and melting.

  On the other hand, in the mold 10 using the pressing jig 18 as the pressing jig, no bubbles were formed on the inner wall surface 16b of the molded body that is the workpiece 16 after being heated and melted.

  This is because the lower surface 30b of the pressing jig 30 that presses the upper surface 16a of the workpiece 16 in the mold 50 presses the heated and melted workpiece 16 to form a recess in the center of the workpiece 16. At this time, since the corner of the lower surface 30b of the pressing jig 30 moves so as to slide with the heated and melted workpiece 16, the diffusion of water vapor generated from the inside of the workpiece 16 is hindered. This is because bubbles are considered to be formed on the inner wall surface 16b of the molded body that is the workpiece 16 after being heated and melted.

  For this reason, the intermediate body obtained by processing into the dimension actually specified from the molded object which is the processed object 16 after heating and melting molded in the mold member 50 is a portion other than the part in which bubbles are formed in the molded body. There are more parts that cannot be used, and the actual number of acquisitions is less than the expected number of acquisitions.

  On the other hand, in the intermediate body obtained by processing the molded body, which is the workpiece 16 after being heated and melted molded in the mold material 10, into the actually specified dimensions, bubbles are formed on the inner wall surface 16b in the molded body. Therefore, there are few unusable parts, and the actual number of acquired sheets can be obtained as many as the expected number of acquired sheets.

From the above results, when producing an intermediate body that is a rough shape of a quartz glass product, the mold material 10 using the pressing jig 18 as the pressing jig is the mold material 50 using the pressing jig 30 as the pressing jig. It was confirmed that the intermediate can be obtained more efficiently.

  That is, in the mold material 50 using the pressing jig 30 in which the chamfering process is not performed on the corner portion of the lower surface 30b to be pressed as the pressing jig, it is specified from the dimensions of the molded body that is the workpiece 16 after being heated and melted. As the pressing jig, the obtained number of intermediates obtained by processing to the specified dimensions is smaller than the expected number of intermediates expected to be obtained by processing into In the mold material 10 using the pressing jig 18 whose chamfering is applied to the corner portion of the lower surface 18b that is the pressing surface, the mold material 10 is processed to the specified dimension from the dimension of the molded body that is the workpiece 16 after being heated and melted. It was confirmed that the expected number of intermediates to be obtained and the number of intermediates obtained by processing to the actually specified dimensions were the same.

  Therefore, the quartz glass product is produced by producing an intermediate body of the quartz glass product by using the mold material 10 using the pressing jig 18 whose chamfering is applied to the corner portion of the lower surface 18b as a pressing jig. Can be produced with a high yield, and the production cost can be further reduced.

As described above, in the mold material 10 according to the present invention, when the intermediate body which is the rough shape of the previous stage quartz glass product manufactured as a cylindrical quartz glass product is produced, the workpiece 16 which is the quartz glass material. The workpiece 16 is heated and melted in a state where the central portion of the workpiece 16 is pressed by the pressing jig 18 whose chamfering is applied to the corner portion of the lower surface 18b that is pressed by the workpiece. The molded body has a substantially cylindrical shape in which a concave portion is formed at the center of the upper surface 16a.

  Furthermore, since no bubbles are formed on the inner wall surface 16b of the recess formed in the central portion of the upper surface 16a of the molded body that is the workpiece 16 after heating and melting, the molded body is obtained by being processed to the actually specified dimensions. The obtained number of obtained intermediates is the same as the expected number of obtained intermediates that are expected to be obtained by processing the molded body into a specified dimension.

  For this reason, it is possible to obtain an intermediate that is a rough shape of a quartz glass product with a high yield from the molded body that is the workpiece 16 after being melted and molded using the mold material 10 according to the present invention. Cost can be suppressed.

The embodiment described above can be modified as shown in the following (1) to (3).

  (1) In the above-described embodiment, the workpiece 16 is applied with the load due to its own weight of the load plate 22, the guide member 20, and the pressing jig 18, but is not limited thereto. Needless to say, a load may be applied from the outside by manual operation or automatic operation.

  (2) In the above-described embodiment, a quartz glass product is manufactured using a quartz glass material. However, the glass product manufactured according to the present invention is not limited to this. According to the present invention, a glass product can be manufactured using glass other than quartz glass, for example, silicate glass or soda glass.

  When a glass material other than the quartz glass material is used, the numerical values such as the heating temperature described above may be appropriately selected depending on the glass material used.

  (3) You may make it combine the above-mentioned embodiment and the modification shown in above-mentioned (1) and (2) suitably.

  INDUSTRIAL APPLICABILITY The present invention can be used when a glass product having a cylindrical shape is manufactured by forming various types of glass such as quartz glass, borosilicate glass, or soda glass.

FIG. 1A is a schematic configuration perspective view of a mold material used in a conventional glass material molding method, and FIG. 1B is a view in the direction of arrow A in FIG. Moreover, FIG.1 (c) is BB sectional drawing of Fig.1 (a). 2A is a cross-sectional view of the workpiece and mold after heating and melting in FIG. 1A, and FIG. 2B is a workpiece that has been heated and melted in FIG. 2A. FIG. FIG. 3 (a) is a schematic explanatory perspective view of the mold material used in the method for molding a glass material according to the present invention, and FIG. 3 (b) is a view taken in the direction of arrow C in FIG. 3 (a). FIG. 3C is a sectional view taken along the line DD of FIG. 4A is a perspective explanatory view of the pressing jig in the mold material shown in FIG. 3A, and FIG. 4B is a side view of the pressing jig in the mold material shown in FIG. 5A is a cross-sectional view of the workpiece and mold after heating and melting in FIG. 3A, and FIG. 5B is the heating and melting workpiece shown in FIG. 5A. It is a perspective explanatory view of a thing. FIG. 6A is a schematic configuration perspective view of a mold material used as a comparative example in an experiment conducted by the inventor of the present application, and FIG. 6B is a cross-sectional view taken along line EE of FIG. FIG.6 (c) is a perspective explanatory view of the pressing jig in the mold shown in FIG. 6 (a). Fig.7 (a) is a chart which shows the experimental result using the type | mold material which used the pressing jig which performed the chamfering process, and FIG.7 (b) uses the pressing jig which has not performed the chamfering process. It is a graph which shows the experimental result using the used mold material.

Explanation of symbols

10, 50, 100 Mold material 12 Bottom plate 14 Outer cylinder 16 Workpiece 18, 30 Pressing jig 20 Guide member 22 Load plate

Claims (7)

In a mold material that heats and melts a glass material to form a general shape of a cylindrical glass product,
The bottom plate,
A cylindrical portion disposed on the bottom plate in contact with the bottom plate and one opening;
A guide member that has substantially the same outer diameter as the inner diameter of the cylindrical portion and is slidably movable in the vertical direction on the inner peripheral surface of the cylindrical portion;
A substantially cylindrical pressing jig in which chamfering is performed on a corner portion of a pressing surface disposed on a lower surface of the guide member and pressing an upper surface of a glass material placed on the bottom plate in the cylindrical portion;
A mold material, comprising: a load plate that applies a load to the pressing jig. In the mold material according to claim 1,
A mold material, wherein a processing width of chamfering applied to a corner portion of the pressing surface is 2 mm or more and 200 m or less. In the mold material according to claim 1,
A mold material, wherein a processing width of chamfering applied to a corner portion of the pressing surface is 1/30 to 1/10 with respect to a diameter of the pressing surface. In the mold material according to any one of claims 1, 2, or 3,
The mold material, wherein the chamfering process applied to the corner portion of the pressing surface is formed such that a processing angle of the processing surface to be formed is 40 degrees or more and 50 degrees or less with respect to the pressing surface. In the mold material according to any one of claims 1, 2, or 3,
The mold material, wherein the chamfering process applied to the corner portion of the pressing surface is formed such that a processing angle of the processing surface to be formed is 45 degrees with respect to the pressing surface. In the glass material molding method using a mold material that molds a rough shape of a cylindrical glass product using a mold material by heating and melting the glass material,
When the glass material is placed on the bottom plate in the cylindrical portion arranged on the bottom plate, and the glass material placed on the bottom plate is heated and melted to form a column shape, the glass material is placed at the center of the upper surface of the glass material. Using a mold material characterized in that a concave portion is formed in a central portion of the upper surface of the glass material by applying a load through a pressing jig in which a chamfering process is applied to a corner portion of the pressing surface that presses the glass material. Molding method of glass material. In the molding method of the glass material using the mold material according to claim 6,
The glass material is a quartz glass material. A method for molding a glass material using a mold material.

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