JPH0531502B2 - - Google Patents

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) The present invention relates to a glass lens press molding apparatus using an induction heating method, and in particular, to improving uniform heating of a cavity portion. be.

(Conventional technology) In recent years, glass lens forming methods have changed from polishing, which requires a complicated process, to plasticizing a pre-measured glass lump using an induction heating method using high frequency, etc., and processing it using a precision press. In addition to glassy carbon, cavity dies using ceramics such as silicon carbide (SiC) or silicon nitride (Si ₃ N ₄ ) have been proposed. ing.

Conventionally, as a press-molding device for glass lenses of this type, a device as disclosed in Japanese Patent Application Laid-Open No. 49-81419 is well known. It is attached to a die holder made by Aito and heated by an induction heating coil, and in reality, the die holder is simply supported by a solid insulator. This is the current situation.

(Problem to be Solved by the Invention) However, in the case of such induction heating, the heating is usually concentrated on the surface area near the heating coil, so the center side of the die holder is closer to the outer diameter side. As a result, due to the relationship between the high frequency effective output A in the radial direction of the die holder and the temperature in induction heating as shown in Fig. 4, the temperature curve B produces a temperature gradient.

In the above-mentioned prior invention, since only one set of cavities is provided at the center of the die holder, there is almost no problem when the radius of the cavity, that is, the radius of the glass lens to be molded is small. However, if the radius of the glass lens becomes large, or if multiple cavities C are provided on the die holder as shown in Figure 3, the temperature may become uneven within one cavity C. This temperature non-uniformity causes
The fluidity of the raw glass differs partially, and as shown in Figure 3, burrs occur on the outer diameter side part a of the die holder, where the temperature is relatively high and the glass easily flows, while on the other hand, the glass has a low temperature. If the glass does not flow easily, the cavity part is not filled with glass, which may cause insufficient elongation of the corner parts of the side surfaces of the lens after molding, or uneven shrinkage, which may cause the lens to shrink. There were some problems such as distortion.

The present invention has been made under the above circumstances, and its purpose is to provide a glass lens press molding apparatus that can achieve uniform temperature distribution in the cavity. be.

[Structure of the invention] (Means for solving the problems) In order to solve the above problems, the present invention has the following features:
A press molding apparatus for glass lenses using induction heating means includes a mold and a die plate made of a material that surrounds and is heated by induction at least one set of cavity dies having a cavity surface corresponding to the lens surface of the glass lens. , comprising a hollow heat insulating body in contact with the vicinity of the outer periphery of the back surface of the die plate, and a support formed by communicating an inlet for supplying inert gas from outside the molding chamber into the internal space of the heat insulating body. , an exhaust means is provided for exhausting inert gas from the internal space of the heat insulator toward the inside of the molding chamber.

(Function) That is, the present invention has the above-mentioned configuration, so that the periphery and back surface of the cavity die for molding on the lens surface of a glass lens are surrounded by a die plate and a die plate that are heated by induction, and the die plate is heated by induction. A hollow insulating body is brought into contact with the outer circumference of the back of the plate, and inert gas is supplied from outside the molding chamber into the internal space of this insulating body, and the inert gas introduced into the internal space of this insulating body is Since the exhaust is directed toward the inside of the molding chamber, the heat that escapes from the die plate through thermal conduction can be removed by the heat insulator, so the outer periphery of the die plate receives more heat than the center. will be taken away,
This makes it possible to make the temperature distribution of the die plate uniform in the radial direction.

(Example) Hereinafter, an example of the present invention will be described in detail with reference to the drawings.

FIG. 1 schematically shows the overall configuration of a glass lens pressing apparatus according to the present invention, in which a heat-resistant glass tube 3 is hermetically installed between upper and lower fixed plates 1 and 2 to form a molding chamber 4. At the same time, an induction heating coil 5 is wound around the outer periphery of the heat-resistant glass tube 3.

Further, inside the molding chamber 4, there is an upper support 7 having an inert gas inlet 6 fixed to the upper fixed plate 1, and an inert gas held by the lower fixed plate 2 so as to be movable up and down. A lower support 9 having an inert gas inlet 8 faces each other in the vertical direction, and both supports 7 and 9 have upper and lower hollow insulators 10 communicating with the inert gas inlets 6 and 8. , 11 are attached, and die plates 12, 13 are attached to both the upper and lower insulators 10, 11, so that the hollow insulators 10, 11 are in contact with the vicinity of the outer periphery of the back of the die plates 12, 13. It's getting old.

The upper and lower die plates 12 and 13 support upper and lower molds 14 and 15, respectively,
The upper and lower die plates 12, 13 and the molds 14, 15 are each made of a material that is induction heated, such as a molybdenum alloy or a tungsten alloy.

Further, at least one pair of cavity dies 16, 17 having cavity surfaces 16a, 17a corresponding to the upper and lower lens surfaces of the glass lens are fitted and held in both the upper and lower molds 14, 15, and these cavity dies 16, 17 is a sintered ceramic such as silicon carbide (SiC) or silicon nitride (Si ₃ N ₄ ), and the surrounding area is
While surrounded by the upper and lower molds 14 and 15,
On the back side thereof, both the upper and lower die plates 12,1
3, and both the upper and lower molds 1
4 and 15 also serve as mold surfaces 14a and 15a forming part of the circumferential surface of the glass lens.

Furthermore, reference numeral 18 in the figure is an inert gas inlet provided in the upper fixed plate 1 so as to communicate with the inside of the molding chamber 4. As shown, a cooling effect is applied by supplying an inert gas into the molding chamber 4, and the inert gas introduced into the molding chamber 4 in this way is transferred to the lower fixed plate 2. The air is exhausted from the open exhaust port 19. Further, W in the figure is a raw material glass placed on the cavity surface 17a of the lower cavity die 17.

By the way, the inert gas inlet ports 6 and 8 provided in both the upper and lower supports 7 and 9 are mainly for the purpose of air purging before temperature rise, and a large amount of inert gas after pressure molding is injected into the inert gas inlets 6 and 8. Internal space 10 of heat insulators 10 and 11
a, 11a to cool the portions in contact with both the upper and lower die plates 12, 13,
Both the upper and lower cavity dies 16, 17 can be cooled in a short time, and in this way, the internal spaces 10a, 11a of the insulators 10, 11
As shown in FIG. 2, the inert gas introduced into
A plurality of communication grooves 2 communicating with the inside of the molding chamber 4 are radially carved in at least one of the contact surfaces with the molding chamber 13 (in the illustrated embodiment, on the side of the heat insulators 10 and 11).
It is designed to be exhausted from 0.21.

The plurality of communication grooves 20 and 21 constituting the exhaust means as described above are connected to the heat insulators 10 and 11.
The inert gas is exhausted from the internal spaces 10a, 11a toward the inside of the molding chamber 4.
2, 13 and the heat insulators 10, 11 are formed so that the outer diameter side is larger than the inner diameter side, and the amount of heat escaping from the die plates 12, 13 through the heat insulators 10, 11 is removed. The diameter side is made larger.

Therefore, to explain the operation of the present invention, both the upper and lower die plates 12, 13, the upper and lower molds 14,
15 is heated by the induction heating coil 5, the temperature distribution becomes as shown by temperature curve B in FIG.
11, so this insulator 10, 11
Heat escapes from the die plates 12 and 13 by conduction. In addition, during the molding cycle of the glass lens, inert gas flows into the molding chamber 4 from the inert gas inlet 18, so that the heat insulator 10,
11 is cooled by this inert gas, which acts as a heat radiating member near the outer periphery of the die plates 12, 13, thereby making the temperature distribution of the die plates 12, 13 uniform in the radial direction. At this time, in order to prevent the die plates 12, 13 from being excessively cooled during temperature rise and pressure molding, inert Inert gas is not supplied through the gas inlet ports 6 and 8, or the flow rate is relatively small, and when cooling after pressure molding, a large amount of inert gas is supplied to achieve cooling in a short time. preferable. Further, the heat insulator 1
The means for exhausting the inert gas from the internal spaces 10a and 11a of Nos. 0 and 11 was provided in the portions in contact with the die plates 12 and 13 to improve the cooling effect.
As shown in FIG. 1, exhaust ports 22 and 23 may be provided on the sides of the heat insulators 10 and 11, and furthermore, these exhaust ports 22 and 23 and the die plate 1
A plurality of communication grooves 20 and 21 provided in the portions contacting the grooves 2 and 13 may also be provided together.

Note that the present invention is not limited to the above embodiments,
Of course, various modifications can be made without departing from the gist of the invention.

[Effects of the Invention] As is clear from the above description, according to the present invention, in a glass lens press molding apparatus using induction heating means, the periphery and back surface of the cavity die that is formed on the lens surface of the glass lens are induction heated. Surrounded by a mold and a die plate, a hollow heat insulator is brought into contact with the vicinity of the outer periphery of the back surface of the die plate, and an inert gas is supplied from outside the molding chamber into the internal space of the heat insulator, and further, Since the inert gas introduced into the internal space of the heat insulating body is exhausted toward the inside of the molding chamber, the heat escaping from the die plate by thermal conduction can be removed by the heat insulating body. Press molding of a glass lens has the excellent effect of making the temperature distribution in the radial direction of the die plate uniform because more heat is taken away from the outer circumference of the die plate than at the center. The device can be provided.

[Brief explanation of the drawing]

FIG. 1 is a schematic cross-sectional view showing an embodiment of the press-molding apparatus for glass lenses according to the present invention, FIG. 2 is a cross-sectional view of the exhaust portion taken along the line - FIG. FIG. 4 is an explanatory diagram of the cavity die holder which is a heating body, and FIG. 4 is an explanatory diagram showing the relationship between the high frequency effective output in the radial direction of the cavity die holder which is a heated body in induction heating and the temperature. 4... Molding chamber, 5... Induction heating coil, 7, 9
... Support, 6, 8 ... Inert gas inlet, 1
0,11...Insulator, 10a, 11a...Inner space, 12,13...Die plate, 14,15...
...Mold, 16, 17...Cavity die, 16
a, 17a...Cavity surface, 20, 21...Exhaust means (communication groove), W...Raw material glass.

Claims (1)

[Scope of Claims] 1. In a glass lens press molding apparatus using induction heating means, a material made of a material that surrounds the periphery and back side of at least one cavity die having a cavity surface corresponding to the lens surface of the glass lens and is heated by induction. A mold and a die plate, a hollow heat insulating body in contact with the vicinity of the outer periphery of the back surface of the die plate, and an inlet for supplying inert gas from the outside of the molding chamber into the internal space of this heat insulating body are formed in communication with each other. A press-molding apparatus for a glass lens, characterized in that the press-molding apparatus is provided with an exhaust means for exhausting inert gas from the inner space of the heat insulating body toward the inside of the molding chamber. 2. Claim 1, characterized in that the exhaust means is formed from a plurality of communication grooves that are radially carved in at least one of the contact surfaces between the die plate and the heat insulator and that communicate with the inside of the molding chamber. A press-molding device for glass lenses as described in 2. 3. According to claim 2, the plurality of communication grooves are formed such that the contact area between the die plate and the heat insulator is larger on the outer diameter side than on the inner diameter side. A press molding device for the glass lens described above.