JP2008207973A - Method for manufacturing lens blank and lens - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for manufacturing a lens blank capable of producing a lens blank having a desired form even in case of a large-sized lens blank and a method for manufacturing a lens capable of producing a lens having a desired form from the lens blank produced by the method. <P>SOLUTION: By using a press forming die having a concave part and/or a convex part on the forming surface for forming the main surface of a lens blank 1 and press forming a glass in a softened state heated at a temperature higher than that of the press forming die, the forming surface is transferred to the main surface of the lens blank and cooling of the lens blank is accelerated by transferring the concave part and/or the convex part formed on the forming surface so as to exist locally at the machining margin of the main surface of the lens blank which is removed by secondary processing. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a method of manufacturing a lens blank that is a base material for manufacturing a glass optical lens, and a method of manufacturing a lens that manufactures a lens using such a lens blank.

As a method for producing a glass lens, a method is known in which softened glass is press-molded using a pair of molds. Then, the glass press molding method is a method of making a press molded product having a shape approximate to a lens shape called a lens blank by press molding, and grinding and polishing the press molded product to finish the optical functional surface of the lens (hereinafter, referred to as a lens blank). And a method of forming an optical functional surface of a lens by press molding (hereinafter referred to as “precision press molding method”).
These two methods are common in terms of the glass press molding method, but the aspect differs greatly depending on whether the optical functional surface is finished by polishing or formed by press molding.

The precision press molding method creates a glass lump made of glass for one lens called a preform, and heats and raises the preform to a temperature at which the glass has a viscosity of 10 ⁶ to 10 ¹² dPa · s. After pressing with a press mold to form a lens, the glass and mold are cooled together to near the glass transition temperature with the mold closed (without releasing the glass), and then the mold is opened to release the glass. And take out the molded product. The reason why the mold is cooled in the closed state is to prevent the surface accuracy of the optical function surface press-molded by sink marks from being lowered.

  On the other hand, in the press polishing method, since the optical functional surface is finished by polishing, it is not necessary to cool the molded product over time when taking it out of the mold unlike the precision press molding method. Rather, in the press polishing method, priority is given to reducing the manufacturing cost by simplifying the throughput and press molding apparatus as much as possible.

For example, when a press mold is composed of a lower mold, an upper mold, and a body mold, a plurality of press molds share one upper mold, and a soft glass gob (viscosity is about 1 to 10 ³ dPa · s) ) Is placed on the lower mold fitted in the body mold, transferred to a position where the upper mold waits upward (hereinafter referred to as “press position”), stopped, the upper mold is lowered, and the glass gob is placed on the upper and lower molds. Press. The press time is very short, generally within a few seconds, and is in contrast to the press time for precision press molding (approximately several tens of seconds). And after shape | molding a glass gob to a lens blank shape, after releasing between an upper mold | type and glass, after cooling a press-molded product on a lower mold | type, a press-molded product is put into an annealing furnace and annealed. The glass gob is supplied again to the lower mold from which the press-molded product has been taken out and transferred to the press position to press the glass. In this way, the above steps are serially performed for each lower mold, and lens blanks are mass-produced.

Although the outline | summary of the press grinding | polishing method and the precision press molding method is as above, the example is described in patent document 1,2.
JP-A-1-257140 JP 2003-34541 A

Here, the precision press molding method is a method in which a glass having a high viscosity is pressed at a higher pressure than the press polishing method, and is molded into a desired shape over time. Therefore, it is not very suitable for molding a large lens.
On the other hand, the press polishing method presses low-viscosity glass, so the shape of the glass before and after pressing can be greatly changed, and a lens blank for finishing a large lens is manufactured with high productivity. can do.

By the way, in recent years, the following problems have become apparent when making a large lens blank.
That is, after press molding, the lens blank is generally placed in a continuous annealing furnace called a rare furnace. However, when the annealed lens blank is inspected, many of the lens blanks are out of the desired shape. And even if such a lens blank is polished, the target lens shape cannot be obtained, or a lens blank larger than usual is formed, and after the shape of the lens blank is adjusted by grinding, the optical functional surface Processing to finish the process must be performed, and the characteristics of the press polishing method are impaired.

  The present invention has been made to solve the above-mentioned problems, and is a lens blank manufacturing method capable of producing a lens blank having a desired shape even if it is a large lens blank, and is manufactured by this method. It aims at providing the manufacturing method of the lens which can produce the lens of a desired shape from the made lens blank.

  In order to investigate the cause of the defective shape of the lens blank described above, the present inventors investigated a lens blank after annealing (hereinafter referred to as “end sample”) and a lens blank before annealing (hereinafter referred to as “hot sample”). ) Was measured, the hot sample was molded according to the shape of the target lens blank, but the end sample was out of specification. From this result, it was found that the lens blank was deformed during annealing and the above-mentioned problem occurred. After reviewing this result, the following conclusion was reached.

  When the lens blank after press molding is taken out from the press mold, the temperature inside the blank, particularly in the thick portion, is higher than the glass transition temperature, but the surface and the thin portion are solidified. For this reason, even if an external force is applied at the time of taking out, the lens blank is not deformed. And if a lens blank is cooled to room temperature as it is, a shape will also be maintained at the shape shape | molded by the press.

  On the other hand, if the lens blank is placed in an annealing furnace immediately after press molding, the lens blank will be warmed, and the cooling speed of the blank will slow down. Moreover, the heat which the center part of a lens blank holds becomes difficult to radiate | emit from a blank surface, heat stays on a blank surface, and a viscosity falls. As a result, the blank becomes soft and easily deforms.

Lens blanks are annealed by placing the lens blank on a flat surface to remove and reduce distortion inside the lens blank and to adjust the refractive index of the glass over a long period of time, gradually lowering the temperature of the lens blank. To go. For this reason, torque is generated inside the lens blank centering on the contact point with the plane due to its own weight, so that the lens blank is gradually deformed, and the deformation exceeds the allowable range after annealing.
In order to avoid such a situation, it is conceivable that annealing is performed in a state where it is placed on a mold, but as described above, the press polishing method has a feature in that a lens blank can be mass-produced with a limited number of molds. Therefore, the taste will be impaired.

  Therefore, the present inventors originally reduced the temperature difference because the deformation of the lens blank is caused by the temperature difference between the inside and the surface of the lens blank at the start of annealing and the temperature difference between the thick part and the thin part. We thought that the problem of lens blank deformation could be solved if annealing was started later. For example, if the cooling is promoted by spraying a gas on the thick part of the lens blank after press molding, the cooling of the thick part can be selectively promoted.

However, this method can be used only on the surface of the lens blank that has been released, and this method cannot be applied to the surface that has not been released. In order to promote cooling of the lens blank in a state before release, the present inventors have further studied, and in order to promote the heat conduction at the contact surface between the thick part and the mold, It came to think that it should just be larger than conduction.
The present invention has been completed based on such an idea, and provides the following means as means for solving the problems of the invention.

  That is, the manufacturing method of the lens blank according to the present invention includes the press molding step for producing a lens blank that is subjected to secondary processing including polishing and finished into a lens through at least a press molding step and an annealing step. The glass blank in a softened state at a higher temperature than the press mold, using a press mold having a recess and / or a protrusion on the molding surface for molding the main surface of the lens blank. As a result, the molding surface is transferred to the main surface of the lens blank, and the concave and / or convex portions are transferred so as to be localized in the margin of the main surface of the lens blank to be removed by the secondary processing. As a way to do.

  According to the manufacturing method of the lens blank according to the present invention as such a method, the contact area between the molding surface and the lens blank is increased, and the heat conduction from the lens blank immediately after press molding to the molding die is increased, Cooling of the lens blank on the contact surface can be promoted, and this makes it possible to manufacture a lens blank having a desired shape without reducing shape accuracy by annealing.

  Further, in the method of manufacturing a lens blank according to the present invention, when the lens blank has a thick part and a thin part, the temperature inside the thick part is less likely to be lower than the temperature inside the thin part. As a method of increasing the contact area between the part and the part corresponding to the thick part by providing the concave part and / or the convex part in a part of the molding surface of the part corresponding to the thick part. It is preferable to promote cooling of the thick part.

  Further, as another aspect of the method for manufacturing a lens blank according to the present invention, a lens blank having a thick part and a thin part that are subjected to secondary processing including polishing and finished into a lens is at least subjected to a press molding step and annealing. In the press molding process, a glass in a softened state having a higher temperature than the press mold is used by using a press mold having a molding surface for molding the main surface of the lens blank. After the molding surface is transferred to the main surface of the lens blank by press molding, the cooling at the contact surface between the portion corresponding to the thick portion and the molding surface is the portion corresponding to the thin portion and the Cooling the lens blank in such a way as to be accelerated more than cooling at the contact surface with the molding surface, and then removing the lens blank from the mold. May be the method via an annealing step is Eject and.

Moreover, the manufacturing method of the lens blank which concerns on this invention can be made into the method of producing the lens blank whose diameter is 30 mm or more.
The larger the diameter, the more easily a large temperature difference occurs in the lens blank, but according to the present invention, even when producing a lens blank having a diameter of 30 mm or more, the temperature difference is reduced and deformation during annealing is reduced. It can be prevented and reduced.

Moreover, the manufacturing method of the lens which concerns on this invention is a method of giving the secondary process including grinding | polishing with respect to the lens blank produced by the manufacturing method of the above lens blanks, and finishing it to a lens.
According to the method for manufacturing a lens according to the present invention as described above, a lens having a desired shape can be efficiently manufactured.

  As described above, according to the present invention, a lens blank having a desired shape can be manufactured without lowering the shape accuracy by annealing, and a lens having a desired shape can be produced from the lens blank thus manufactured. It can be manufactured efficiently.

  Hereinafter, preferred embodiments of the present invention will be described.

[Lens Blank Manufacturing Method]
The method for producing a lens blank according to the present invention uses a press mold having a molding surface for molding the main surface of the lens blank, and press-molds glass in a softened state at a higher temperature than the press mold. The method includes at least a process and an annealing process for relaxing the residual stress after molding and removing distortion, and includes a first embodiment and a second embodiment described below.

  Here, the lens blank is a glass molded body that is finished into a lens that is a final product by performing secondary processing including polishing, and has an intermediate shape that approximates the shape of the lens as the final product. It shall mean a product. And such a lens blank has the part finished to a lens, and the part (henceforth "removal") removed by the said secondary process.

[First embodiment]
First, a first embodiment of a method for manufacturing a lens blank according to the present invention will be described. In the present embodiment, in the press molding step, a softened state in which a press mold having a concave portion and / or a convex portion is provided on the molding surface for molding the main surface of the lens blank, and the temperature is higher than that of the press mold. By pressing the glass gob on the lens blank, the molding surface of the press mold was transferred to the main surface of the lens blank, and the molding surface was provided so as to be localized in the margin of the main surface of the lens blank. The concave and / or convex portions are transferred.

The glass gob in the softened state can be obtained, for example, by separating a molten glass lump in an amount necessary for forming a lens blank from the molten glass flowing out. Moreover, it can also obtain by heating and softening the solidified glass lump of the quantity required for shaping | molding of a lens blank.
Although the temperature of the molten glass gob obtained by the former method rapidly decreases, it is press-molded while it is in a softened state. This method is called direct press, and the method of press molding the glass gob softened by the latter method is called reheat press.

[Direct press]
In the direct press, a molten glass lump is separated and pressed from a molten glass flow that continuously flows out. Therefore, a plurality of lower molds are successively transferred and retained below the molten glass flow to receive the tip of the molten glass flow, and then the molten glass flow is cut with a cutting blade called a shear. Thus, a molten glass lump for one lens blank is supplied onto the lower mold.
In addition, the lower mold | type stop position where a molten glass lump is supplied is called a cast position.

The lower mold on which the molten glass block is placed is unloaded from the casting position, and is transferred to and stopped at a stop position called a press position where the upper mold waits above. In this process, the temperature of the molten glass lump is lowered to become a soft glass gob suitable for press molding.
At the pressing position, the upper die is lowered, and the glass gob is press-molded with the lower die and the upper die. When using a trunk mold, the lower mold may be fitted into the trunk mold, and the lower mold and the trunk mold may be transferred and stopped together, or the upper mold may be fitted into the trunk mold, and the upper mold and the trunk mold may be combined together. It may be transferred and stopped.

The press mold is composed of a lower mold and an upper mold. When a barrel mold is used, the press mold is composed of a lower mold, an upper mold, and a trunk mold. The glass pressed by the upper and lower molds is spread into a space surrounded by the molding surfaces of the upper and lower molds (in the case of using a barrel mold, the space surrounded by the molding surfaces of the upper and lower molds and the barrel mold) and molded into a lens blank. Is done. Thereafter, the upper mold is released, returned to the upper standby position, and the lower mold on which the lens blank is placed is unloaded from the press position.
In the direct press, a glass gob having a viscosity of about 1 to 10 ³ dPa · s is press-molded. The pressing time is generally less than 10 seconds although it depends on the size of the lens blank.

  Next, the lens blank is cooled to a temperature at which the lens blank is not deformed, and is removed from the lower mold while the lower mold remains at the lens blank extraction position, and placed in an annealing furnace. The molded lens blank is generally annealed through a continuous annealing furnace called rare, and a lens blank from which distortion has been removed is completed.

  After taking out the lens blank, the lower mold is transferred again to the casting position and the above steps are repeated. By repeating the above steps sequentially for each lower mold, lens blanks are formed one after another from molten glass that flows out continuously.

From the production of the lens blank of the same specification, the weight of the glass gob, the temperature at the time of supply on the lower mold, the time from the supply of the glass gob onto the lower mold until the start of press molding, the time spent on press molding, etc. It is desirable to keep it constant. For that purpose, it is preferable to keep the outflow speed of the molten glass constant, to make the period for separating the molten glass lump constant, and to perform the transfer and stop of each lower mold in synchronization.
As a specific example, a plurality of, for example, 6 to 20 lower molds are arranged on the circumference around the rotation axis of the turntable, the turntable is index rotated, and each lower mold is cast, pressed, The lens blank is sequentially transferred and stopped at the lens blank take-out position.

[Reheat press]
In the reheat press, molten glass is cast into a mold, formed into a glass block, glass plate, glass rod, etc., annealed, cut or cleaved to make a glass piece called a cut piece, and this cut piece is used as it is. Alternatively, the edge is rounded, barrel-polished, ground and polished is used as a glass gob, and heated, softened, and press-molded.

  A plurality of lower molds are also used in the reheat press, and a glass gob is arranged on the lower mold and passed through a heating furnace called a softening furnace. The glass gob and the lower mold are heated while passing through the softening furnace by the heater arranged in the softening furnace, so that the glass gob is softened.

The lower mold on which the softened glass gob is placed passes through the softening furnace, is sent to the press position, descends the upper mold waiting above the press position, presses the glass with the upper and lower molds, and forms the upper and lower molds. Spread into the space between the surfaces and mold into a lens blank. In the reheat press, a barrel mold may be used as in the direct press.
In the reheat press, a glass gob having a viscosity of 10 ⁴ dPa · s to 10 ^5.6 dPa · s, preferably 10 ⁴ dPa · s to 10 ^5.4 dPa · s is press-molded. The press time is almost the same as that of the direct press.

After press molding, the upper mold waits in its original position, the lens blank molded on the lower mold is cooled, and after it reaches a temperature that does not deform due to external force, it is taken out from the lower mold and annealed in an annealing furnace. A glass gob is again supplied to the lower mold that has been emptied after taking out the lens blank, and heated, softened, and press-molded.
The lens blank can be mass-produced by sequentially performing the above steps using a plurality of lower molds.

  In both the direct press and the reheat press as described above, a known heat-resistant mold material such as cast iron such as FCD450 or stainless steel such as SUS303 can be used as the material of the press mold.

In both the direct press and the reheat press, the lens blank immediately after the press molding is cooled on the lower mold while being released from the upper mold. In the present embodiment, cooling of the thick part of the lens blank is promoted in this state.
In order to promote cooling of the thick part, it is possible to blow the cooling gas on the surface of the thick part of the lens blank that has been released from the upper mold. If it is going to make it, cooling gas must be sprayed strongly and the lens blank surface will become depressed by the wind pressure of cooling gas.

  Therefore, in the present embodiment, the molding surface for press molding the main surface of the lens blank to be processed into the optical functional surface of the lens, that is, the lower mold molding surface and / or the upper mold molding surface, the recess and / Or a press mold provided with convex portions. And in a press molding process, the recessed part and / or convex part which were provided in the molding surface are transcribe | transferred to a glass gob.

  By doing in this way, the recessed part and / or convex part which were provided in the molding surface maintain the state closely_contact | adhered with the lens blank (glass gob) until it releases. For this reason, there is no change in the overall shape of the lens blank itself, but the contact area between the molding surface and the lens blank is larger than when no concave portions or convex portions are provided on the molding surface.

For example, when a plurality of grooves are formed concentrically around the center point of the molding surface, the cross-sectional shape of the groove viewed from the diameter direction of the concentric circles is a straight line with two sides as slopes and one side as an opening. If it is a triangle, the contact area between the molding surface and the lens blank (glass gob) can be doubled by providing such a groove.
In addition, when providing a groove | channel as mentioned above, the groove | channel itself may be considered as a recessed part, and the part between a groove | channel may be considered as a convex part.

  In this embodiment, since the glass gob in a softened state at a higher temperature than the press mold is press-molded, the temperature of the press mold is kept lower than the temperature of the lens blank immediately after press molding. For this reason, by increasing the contact area, heat conduction from the lens blank to the mold can be increased, and cooling of the lens blank on the contact surface can be promoted. This makes it possible to manufacture a lens blank having a desired shape without lowering the shape accuracy by an annealing step performed later.

  Here, the concave and convex portions transferred to the lens blank are not present in the lens of the final product, and the concave and convex portions are not reflected in the shape of the lens. The size of the concave and convex portions when viewed from the direction perpendicular to the molding surface (hereinafter referred to as “the size when viewed in plan”). In the example of the groove, the width of the groove, that is, (The length of the opening) is sufficiently smaller than the size of the entire molding surface. For example, the size of the concave and convex portions in plan view is preferably 1 mm or less, and 0.7 mm or less. It is more preferable. In addition, if the size of the concave portion and the convex portion in plan view is too small, it becomes difficult for the glass to enter the concave portion, or the cooling promotion effect is diminished. The thickness is preferably 0.2 mm or more, and more preferably 0.4 mm or more.

The depth of the concave portion and the height of the convex portion are each preferably 0.1 to 1 mm, and more preferably 0.1 to 0.5 mm. When the concave portion and the convex portion are adjacent to each other, the height difference between the convex portion and the concave portion is regarded as the depth of the concave portion or the height of the convex portion. If the height or depth is too large, the margin must be increased more than necessary, increasing the labor and time of processing including polishing, and increasing the processing waste (sludge) that is discarded without becoming a lens. Therefore, it is not preferable from the viewpoint of cost and environment. On the other hand, if the height or depth is too small, the contact area between the lens blank and the molding surface cannot be increased significantly, such being undesirable.
In addition, it is preferable that the thickness of the margin is 0.2 to 1.5 mm. The portion formed by transferring the concave portion and convex portion of the molding surface to the glass blank by press molding is called a transfer molding portion. The thickness of the margin is determined by the depth of the concave portion transferred to the transfer molding portion and the convex portion. Take larger than the height.

In both the direct press and the reheat press, the surface of the glass gob immediately before press molding is very hot. Therefore, from the glass gob surface containing glass components (for example, alkali metals, boric acid, fluorides, etc.) that exhibit significant volatility at high temperatures, the components are volatilized and optically non-uniform portions called striae near the surface. Occurs. The striae need to be removed because they become a factor that degrades the lens performance. However, the striae is limited to a range of margins, and the striae is completely removed by the above processing.
In addition, when glass gob with striae at a uniform depth is pressed with a molding surface having convex parts, it seems that the striae penetrates deep into the part pressed by the convex parts. At times, the convex portion enters the glass gob surface layer so that the striae of the portion pressed by the convex portion do not enter deeply.

  By the way, in a lens having a positive refractive power such as a biconvex lens, a plano-convex lens, or a convex meniscus lens, the thickness at the lens central portion (the optical axis and its peripheral portion) is thicker than the thickness at the lens peripheral portion. A lens blank for making such a lens has a shape that approximates the lens shape, and the central portion is thicker than the peripheral portion. That is, the lens blank for making a lens having positive refractive power has a thick portion at the center and a thin portion at the periphery.

  On the other hand, lenses with negative refractive power, such as biconcave lenses, plano-concave lenses, and concave meniscus lenses, are thinner at the center of the lens than at the periphery of the lens. It is thinner than the part. That is, the lens blank for making a lens having negative refractive power has a thick portion at the center and a thin portion at the periphery.

The temperature inside the thick part is less likely to be lower than the temperature inside the thin part, which causes deformation of the lens blank during annealing. Therefore, in the production of a lens blank having a thick part and a thin part, the above-mentioned concave part and / or convex part is provided in the part where the thick part of the molding surface is pressed, and the thick part is pressed and the thick part. Increase the contact area with and promote cooling of the thick part.
In addition, although the said recessed part and / or convex part may be provided also in the part which presses the thin part of a molding surface, cooling of a thin part may be accelerated | stimulated, but a thin part may be damaged by shrinkage | contraction by rapid cooling. Such a phenomenon is called can cracking and is remarkable in the case of a glass having a large expansion coefficient. Therefore, from the viewpoint of preventing cracking, it is preferable not to provide the concave portion or the convex portion in the portion where the thin portion is pressed.

  Which of the molding surfaces of the upper and lower molds is provided with the concave portion and / or the convex portion may be determined as follows. The options are: when the concave and / or convex portions are provided only on the upper mold forming surface (hereinafter referred to as “Case 1”), when provided only on the lower mold forming surface (hereinafter referred to as “Case 2”), upper mold and lower There are three cases (hereinafter referred to as “case 3”) provided on the molding surface of the mold.

Case 1 is effective when one upper mold is shared by a plurality of lower molds as described in the description of the direct press. In this method, if the concave and / or convex portions are formed on one upper mold forming surface, it is possible to save the trouble of forming the concave and / or convex portions on a plurality of lower mold forming surfaces. This method is also effective when the glass is difficult to extend during press molding. This is because the concave portion and / or the convex portion on the lower mold forming surface become resistance to the elongation of the glass. In case 2, after releasing the mold from the upper mold, when taking out the lens blank on the molding surface of the lower mold, the contact time between the lens blank and the concave portion and / or the convex portion can be made longer than case 1. Further, the cooling effect of the thick part can be enhanced as compared with the case 1. Case 3 is a system that can maximize the cooling effect of the thick portion.
In selecting the cases 1 to 3, the shape and size of the lens blank, the properties of the glass to be used, the number of lower molds and upper molds may be determined.

  The convex and concave parts of the lens blank formed by transferring the concave and convex parts are not only necessary for the lens, but also impair the function of the lens, so they are localized in the margin removed by processing including polishing. And then completely removed by the processing.

[Lens blank]
Next, a lens blank that is particularly effective to which the present invention is applied will be described.

First, in terms of dimensions, it is suitable for producing a lens blank of 30 mm or more, more suitable for producing a lens blank of 40 mm or more, and more suitable for producing a lens blank of 50 mm or more. Thus, in a lens blank having a large diameter, a large temperature difference is likely to occur between the thick part and the thin part or between the surface and the inside immediately after press molding. Such a temperature difference causes deformation of the blank during the above-described annealing.
According to the present invention, even in such a lens blank that can easily cause a large temperature difference, the temperature difference can be reduced, and deformation during annealing can be prevented and reduced.

Next, as for the glass constituting the lens blank, a lens made of fluorophosphate glass, lanthanum borate glass (glass containing B ₂ O ₃ and La ₂ O ₃ as glass components), or phosphate glass. It is preferable for producing a blank, more preferably applied to fluorophosphate glass or lanthanum borate glass (glass containing B ₂ O ₃ and La ₂ O ₃ as glass components), and more preferably applied to fluorophosphate glass.

  The glass is a glass having a small viscosity change with respect to a temperature change in a temperature range from the temperature of the lens blank immediately after press molding to the glass transition temperature. Such glass has a small increase in viscosity even when cooled at a constant temperature as compared with other glasses, and is difficult to solidify. For this reason, the blank is easily deformed by its own weight due to heating during annealing. Therefore, by promoting the cooling of the thickest part of the blank that is most delayed or the internal cooling by the method of the present invention, even when the lens blank is made of the glass, deformation during annealing can be prevented and reduced.

[Annealing process]
Next, annealing of the lens blank will be described. Immediately after the press molding, the lens blank is put in an annealing furnace, and annealing is started at the transition temperature of the glass forming the lens blank. It is preferable that the temperature drop speed of the lens blank during annealing is in the range of 10 ° C./hour to 50 ° C./hour. After the temperature of the lens blank becomes lower than the strain point, the lens blank is taken out from the annealing furnace, and the annealing is finished.

  Annealing not only serves to prevent or damage the lens blank during processing including polishing, which will be described later, by reducing or removing distortion inside the lens blank, and also serves to finely adjust the refractive index. As the annealing furnace, a known continuous annealing furnace (rare furnace), batch-type annealing furnace, or the like may be used.

The annealed lens blank is ground and polished by a known method to finish the lens. At this time, the transfer molding part formed by transferring the concave part and / or convex part of the molding surface during press molding is removed. In particular, if the transfer molding part remains on the optical functional surface of the lens, the function as the lens is impaired. Therefore, it is preferable to completely remove the transfer molding part on the optical functional surface by processing including polishing.
The lens surface thus obtained may be coated with an antireflection film or the like as necessary.

[Second Embodiment]
Next, a second embodiment of the lens blank manufacturing method according to the present invention will be described. In this embodiment, when manufacturing a lens blank having a thick part and a thin part, in the press molding process, a press mold having a molding surface for molding the main surface of the lens blank is used, rather than a press mold. By press-molding a glass gob in a softened state at a high temperature, the molding surface of the press mold is transferred to the main surface of the lens blank, and then the portion corresponding to the thick part of the lens blank and the molding surface The lens blank is cooled such that cooling on the contact surface is promoted more than cooling on the contact surface between the portion corresponding to the thin portion of the lens blank and the molding surface.

In the first embodiment described above, the portion corresponding to the thick portion of the lens blank is formed on the forming surface in order to promote cooling of the contact surface between the portion corresponding to the thick portion of the lens blank and the forming surface. A concave part and / or a convex part are provided in the part, and the contact area between the part and the part corresponding to the thick part of the lens blank is increased.
On the other hand, in this embodiment, the following cooling promotion means is employ | adopted instead of providing such a recessed part and a convex part, or using this together.

For example, a lower mold is assembled using a mold material that presses a thick part and a mold material that presses a thin part, and the thick part is forcibly cooled (for example, air cooling, water cooling, or a combination thereof), and the thin part is Even if natural cooling (not forced cooling) is performed or both the thick part and the thin part are forcibly cooled, the cooling capacity of the thin part can be set smaller than that of the thick part.
Furthermore, the material that forms the molding surface that presses the thick part is different from the material that forms the molding surface that presses the thin part, and the heat conduction of the material that forms the molding surface that presses the thick part. It is also possible to make the degree larger than the thermal conductivity of the material forming the molding surface for pressing the thin portion. These materials need only have sufficient heat resistance with respect to the temperature of the molten glass, and known materials may be appropriately selected from such conditions.

  Although the present embodiment is different from the first embodiment in the cooling promotion means, the other methods can be the same as those in the first embodiment, and thus detailed description of other configurations is omitted.

  Hereinafter, based on an Example, this invention is demonstrated in detail.

FIG. 1 is an explanatory view showing a cross-sectional shape (cross-section in a plane including the optical axis C) of a lens blank 1 for producing a plano-convex lens by grinding and polishing.
A surface indicated by R1 in the drawing is a first surface finished to be a convex surface, and is a spherical surface having a curvature radius of 84.0 mm. The surface indicated by R2 in the figure is a second surface finished to be a flat surface, and is a spherical surface having a curvature radius of 550.0 mm. The diameter is 90 mm and the edge thickness is 5.3 mm. And the margin of this lens blank 1 is 1.0 mm. Further, the lens blank 1 has a thick portion 2 in the range within a radius of 35 mm around the optical axis C and a thin portion 3 on the outside thereof.

In manufacturing such a lens blank 1, first, a mold material made of cast iron (FCD450) is processed to produce an upper mold 10, a lower mold 21, and a body mold 22. FIG. 2 is an explanatory view showing a vertical cross section when the lower mold 21 is fitted into the body mold 22 and arranged opposite to the upper mold 10. The upper mold forming surface 10a is processed into a spherical shape obtained by inverting the first surface R1 of the lens blank 1, and the lower mold forming surface 21a is processed into a spherical shape obtained by inverting the second surface R2.
In addition to the cast iron, stainless steel (for example, SUS303) or the like may be used as a mold material constituting the press mold.

Next, it was processed with an NC lathe so that a plurality of grooves were concentrically formed in a region surrounded by a circle having a radius of 35 mm from the center of the upper mold forming surface 10a. At this time, the cross-sectional shape of the groove was V-shaped, the groove width (opening width) was 0.6 mm, and the depth was 0.2 mm. The total number of grooves was 53. These grooves will be referred to as a concentric groove group 30.
FIG. 3 is an enlarged partial cross section of the concentric groove group 30, and corresponds to a portion surrounded by a chain line in FIG. For the convenience of processing, no groove is provided in the central portion, but since the area is very small compared to the range where the concentric groove group 30 is formed, there is no problem in promoting cooling of the thick portion 2.

  In this embodiment, the lens blank 1 is molded by direct pressing. After the press molding is finished, the surface on the upper mold 10 side (first surface R1) is released immediately, and the surface on the lower mold 21 side (second surface). The lens blank 1 is cooled to such an extent that the surface R2) is not released and is not deformed by the external force on the lower die 21 when taken out.

In the cooling process, the concentric groove group 30 is transferred and formed in the thick portion 2 of the first surface R1. The concentric groove group 30 increases the contact area between the thick portion 2 on the first surface R1 and the upper mold forming surface 10a by 1.2 to 1.5 times. As a result, heat conduction from the thick part 2 to the lower mold 21 on the first surface R1 side can be increased, and cooling can be greatly promoted.
At this time, from the second surface R2 side, cooling of the thick portion 2 may be promoted by blowing cooling gas or the like, but the gas blowing is performed so that the second surface R2 is not deformed by high-pressure cooling gas blowing. Adjust the pressure when attaching.

  In this embodiment, twelve sets of molds 20 in which the lower mold 21 is fitted in the body mold 22 are arranged at equal intervals on the same circumference on the turntable. Then, the turntable is index-rotated so that each mold 20 is sequentially transferred to and stopped at the twelve stop positions. Among these, a stop position is set as a cast position, and an outflow pipe for molten glass is arranged above, and a cutting blade called a shear for cutting a molten glass flow flowing out from the pipe at a constant speed is arranged.

  The lower end of the molten glass flow that has flowed out of the pipe is received by the vicinity of the center of the lower mold forming surface of the mold that remains at the casting position. In this state, the molten glass flow is cut from the middle, and the lower mold forming surface 21 a A desired amount of molten glass gob is obtained. Next, the turntable is index-rotated, and the mold 20 on which the glass gob is placed is transferred to and stopped at a stop position called a press position where the upper mold 10 stands by above. Then, when the mold 20 is stopped, the upper mold 10 is lowered, the glass gob is pressed together with the lower mold 21, and the space surrounded by the upper mold 10, the lower mold 21, and the body mold 22 is filled with glass. Then, the lens blank 1 is formed. The pressing time is optimized in the range of 2 to 3 seconds.

  Next, the upper mold 10 is raised, and the upper surface (first surface R1) of the lens blank 1 is released from the upper mold 10, and the lens blank 1 is cooled on the lower mold 21 as described above. At the stopping position before returning to the casting position, the first surface R1 of the lens blank 1 is sucked and taken out from the lower mold forming surface 21a using a vacuum robot. The position at which the lens blank 1 is taken out may be determined based on whether or not the lens blank 1 is cooled to a temperature at which the lens blank 1 is not deformed by the external force applied at the time of taking out as described above. The mold 20 from which the lens blank 1 has been taken out is transferred again to the casting position, and the above steps are repeated.

  By repeating these steps using twelve sets of molds 20, lens blanks can be mass-produced from a continuously flowing molten glass flow.

The glass used in this example is a fluorophosphate glass having a refractive index nd of 1.49700, an Abbe number νd of 81.61, and a glass transition temperature of 455 ° C., and is formed on the lower mold surface 21a. The temperature and viscosity of the glass during supply (during casting) were about 900 ° C. and 30 dPa · s, and the temperatures of the lower die 21, the barrel die 22, and the upper die 10 were set to about 400 ° C.
In the present embodiment, the glass at the time of casting is not so high, and therefore the press mold is not forcibly cooled.

The upper and lower surfaces of the lens blank 1 taken out from above the lower mold 21 are reversed, placed in a continuous annealing furnace with the first surface R1 facing downward, and moved from the glass transition temperature to a zone set to a gradually lower temperature. However, it was gradually cooled to near room temperature at a speed of 30 ° C. per hour.
The lens blank (hot sample) 1 before annealing and the lens blank (end sample) 1 after annealing thus obtained were evaluated.

  First, the radius gauge A having a concave spherical surface with a radius of curvature of 84.0 mm is brought into contact with the first surface R1 of each of the hot sample and the end sample, and the radius gauge B having a concave spherical surface with a radius of curvature of 550.0 mm is obtained. The hot sample and the end sample were brought into contact with the second surface R2.

The portion corresponding to the optical axis C of the lens blank 1 is the center, the portion close to the edge 4 is called the periphery, and the periphery of the blank 1 and the radius G A are in contact with the center of the lens blank 1 and the radius gauges A and B. The gap formed between the center of the lens blank 1 and the radius gauge in a state where the periphery of the lens blank 1 and the radius gauges A and B are in contact with each other is called a middle gap.
When there is an external gap, the radius of curvature of the surface of the lens blank 1 in contact with the radius gauges A and B is smaller than the radius of curvature of the radius gauges A and B. The radius of curvature of the surface of the lens blank 1 is larger than the radius of curvature of the R gauge.

  As a guideline, even if there is an outside skiing or medium skiing, the clearance should be 40 to 50% or less of the margin for outside skiing, and the gap should be 60 to 70% or less of the margin for margining. For example, the desired optical functional surface can be finished by grinding and polishing, but if the gap is too large, the lens cannot be finished in a desired shape due to insufficient margin.

In this example, 1,000 lens blanks 1 were experimentally press-molded, 50 hot samples and 50 end samples were taken at random, and shape evaluations using R gauges A and B were performed.
As a result, in both the hot sample and the end sample, the outer space on the first surface R1 was 0.3 mm or less and the middle space was 0.4 mm or less. This is the shape accuracy that can be finished into a lens of a required shape by grinding and polishing with a margin of 1.0 mm.

The annealed lens blank 1 thus obtained was ground and polished, and a lens having a shape in which a margin of 1.0 mm in depth was removed from the blank having the shape shown in FIG.
In the above embodiment, the concentric groove group 30 is provided only on the upper mold forming surface 10a. However, the concentric grooves are formed only on the lower mold forming surface 21a or on both the upper mold forming surface 10a and the lower mold forming surface 21a. A group 30 may be provided.

[Comparative example]
Except for using an upper mold that does not have concentric grooves on the molding surface, 1000 lens blanks were press-molded in the same manner as in the examples, and the shape evaluation was performed on each of fifty hot samples and end samples. The hot sample was almost the same as the evaluation result of the example. However, in the end sample, both the inner space on the first surface R1 and the outer space on the second surface R2 were 0.8 to 1.2 mm. It was. This is because the blank was annealed with the first surface R1 facing down, and the periphery of the blank fell due to its own weight, and the radius of curvature of the first surface R1 increased and the radius of curvature of the second surface R2 decreased. It is thought that.

  In order to finish such an end sample into a lens having a desired shape, a margin of 1.0 mm is not sufficient. Eventually, these lens blanks are defective.

  While the present invention has been described with reference to the preferred embodiment, it is needless to say that the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the present invention. .

  According to the present invention, a lens blank having a desired shape can be manufactured without lowering the shape accuracy by annealing, and a lens can be efficiently manufactured from this lens blank.

It is explanatory drawing which shows the cross-sectional shape in an example of a lens blank. It is explanatory drawing which shows the vertical cross section in an example of a press molding die. FIG. 3 is an enlarged view of a portion surrounded by a chain line in FIG. 2.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Lens blank 2 Thick part 3 Thin part 10 Upper mold | type 10a Upper mold | molding surface 20 Mold 21 Lower mold | die 21a Lower mold | molding surface 30 Concentric groove group

Claims (5)

In producing a lens blank that is subjected to secondary processing including polishing and finished into a lens, through at least a press molding step and an annealing step,
In the press molding process,
By using a press mold in which concave and / or convex portions are provided on the molding surface for molding the main surface of the lens blank, press molding glass in a softened state at a higher temperature than the press mold,
The molding surface is transferred to the main surface of the lens blank, and the concave and / or convex portions are transferred so as to be localized in the margin of the main surface of the lens blank that is removed by the secondary processing. A method of manufacturing a lens blank characterized by the above. The lens blank has a thick part and a thin part,
Of the molding surface of the press mold, the concave portion and / or convex portion is provided in a portion where the portion corresponding to the thick portion is formed, and the contact area between the portion and the portion corresponding to the thick portion is increased. The manufacturing method of the lens blank of Claim 1. In producing a lens blank having a thick part and a thin part that are subjected to secondary processing including polishing and finished into a lens, through at least a press molding process and an annealing process,
In the press molding process,
Using a press mold having a molding surface for molding the main surface of the lens blank, press-molding glass in a softened state at a higher temperature than the press mold, thereby forming the lens blank on the main surface. After transferring the molding surface,
The lens blank is cooled such that cooling at the contact surface between the portion corresponding to the thick portion and the molding surface is promoted more than cooling at the contact surface between the portion corresponding to the thin portion and the molding surface. And
Thereafter, the lens blank is taken out of the mold and subjected to an annealing process.   The manufacturing method of the lens blank of any one of Claims 1-3 which produces a lens blank whose diameter is 30 mm or more.   A lens blank produced by the method for producing a lens blank according to any one of claims 1 to 4, and subjected to secondary processing including polishing to finish the lens, thereby producing a lens.

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