EP0847330A1

EP0847330A1 - Method and composition for the manufactue of ophthalmic lenses

Info

Publication number: EP0847330A1
Application number: EP96930670A
Authority: EP
Inventors: Ronald David Blum
Original assignee: Individual
Current assignee: Individual
Priority date: 1995-09-01
Filing date: 1996-09-03
Publication date: 1998-06-17
Also published as: KR19990044298A; BR9610409A; IL123478A0; WO1997009170A1; JP2001510404A; AU6963596A; MX9801691A; CA2230646A1; CN1200696A

Abstract

A curing method for ophthalmic lenses or semi-finished lens blanks wherein a curable resin is first exposed to radiation in the wavelength range of 400-800 nm and subsequently subjected to heat or radiation of different wavelength or intensity than that used in the first step. The polymerizable resin preferably comprises: (1) a first photoinitiator that is activated by radiation in the wavelength range of 400-800 nm and (2) a thermal initiator which is activated by heat, or a second photoinitiator which is activated by radiation of different wavelength or intensity than that used to activate the first photoinitiator.

Description

METHOD AND COMPOSITION FOR THE MANUFACTURE OF OPHTHALMIC LENSES

FIELD OF THE INVENTION:

This invention relates to improved methods by which plastic resins can be cured to form ophthalmic lenses, semifinished blanks and optical preforms . Ophthalmic lenses often have complex geometries, with certain prescriptions having variations in thicknesses across the optic area of greater than an order of magnitude. Since the curing process is accompanied by shrinkage, a key objective of curing process development efforts is to be able to accommodate shrinkage without unduly increasing the cure time. I have developed a curing method for ophthalmic lenses that uses visible light to initiate cure, while nevertheless creating a colorless product.

BACKGROUND:

Curing of organic polymerizable resins to form ophthalmic lenses and semifinished blanks has traditionally involved the use of thermal polymerization initiators as described, for example, in US Patent

3,038,210, issued to Hungerford, et al., and US Patent 3,222,432, issued to Grandparret. More recently, photocuring processes have been disclosed involving the use of ultraviolet initiators, for example, US Patent 4,166,088, issued to Neefe, and US Patent Nos. 5,364,256 and 4,879,318 to Lipscomb. Photocuring processes have allowed the development of cure cycles that are considerably shorter than standard thermal curing cycles. In all cases, it is necessary to ensure that the cure profile, which determines the rate of shrinkage, allows the cure of the bulk resin to take place in a controlled fashion while the surface still retains substantial adhesion to the mold. In this way, the lens does not undergo a prerelease, does not develop optical aberrations caused by the formation of local heterogeneities in the resin mass due to uneven flow, and does not develop surface defects or cracks due to resin shrinkage. In U.S. Patent No. 4,919,850, issued to me, I disclose a two stage cure process involving the use of ultraviolet polymerization initiators that allow the resin to gel under a low level of ultraviolet illumination. In this way, the initial cure rate is maintained at a low level, until the resin mass becomes a gel and mass flow ceases within the curing lens. This is important, because the risk of developing optical aberrations is highest at the initial stages of the curing process when local exotherms can induce optical aberrations through resin flow. After the material has undergone gelation, the cure rate is accelerated by increasing ultraviolet light intensity. Increasing light intensity also serves to maintain the pace of curing as the initiator becomes depleted. Alternatively, the cure rate is also accelerated in the second stage by using UV light of a shorter wavelength. A commercial version of this process has now been introduced by the Rapidcast Corporation.

A disadvantage of the two stage process, as disclosed in U.S. Patent No. 4,919,850 is that it typically uses two curing chambers for efficient implementation.

SUMMARY OF THE INVENTION:

An advantage of the present invention is that a process is provided which can be efficiently implemented using a single chamber.

Another advantage of the invention is that the scope of the two stage curing process is expanded, rendering it applicable to resin formulations covering a wide range of chemical reactivities, functionalities, shrinkage properties, and thermal expansion characteristics.

According to an embodiment of the present invention, a curing method for ophthalmic lenses or semi-finished lens blanks is described wherein a curable resin is first exposed to radiation in the wavelength range of 400-800 NM. Then, the curable resin is subjected to heat or radiation of different wavelength or intensity than that used in the first step. The polymerizable resin preferably comprises: (1) a first photoinitiator that is activated by radiation in the wavelength range 400-800 NM and (2) a thermal initiator which is activated by heat, or a second photoinitiator which is activated by radiation of different wavelength or intensity than that used to activate the first photoinitiator.

According to another embodiment of the invention, an ophthalmic lens, semifinished blank or optical preform is provided according to any of the methods described or claimed herein.

The above and other objects, advantages and embodiments will become readily apparent to those of skill in the art upon reading the description and claims set forth below.

Unless indicated to the contrary, each reference cited herein is incorporated by reference in its entirity.

DETAILED DESCRIPTION OF THE INVENTION:

I have developed a cure process that utilizes room light in a first stage to initiate cure and reach the gel state. A second stage of the cure process can subsequently be completed, by application of thermal energy, by application of UV light, or both. The initial curing stage may take place either directly under room light, or in chambers employing visible light bulbs.

Since polymerization initiators which are activated by visible light are generally highly colored, it may appear at first sight that their use would be incompatible with the proposed application (i.e., to make an ophthalmic lens which is preferably colorless, or water white) . Recently, a new class of photopolymerization initiators has been commercialized which begin as a colored species and are activated by visible light, but upon activation form colorless photodissociation products. I discovered that .such photoinitiators can be used to develop cure processes for ophthalmic lenses and semi-finished blanks.

A preferred photoinitiator is BAPO, available from Ciba Geigy Corp. This photopolymerization initiator is actually a mixture of two photoinitiators,

Bisdimethoxybenzoyl Trimethylpentyl Phosphine Oxide (25%, by weight) and 2-Hydroxy 2-Methyl 1-Phenyl Propanone (75% by weight) . The phosphine oxide derivative absorbs visible light in the wavelength range 400-450 NM range, and initiates polymerization of resins incorporating acrylic, methacrylic, vinylic or allylic derivatives. Under normal room illumination, the cure rate is slow. Therefore, the mold assemblies do not require cooling or other temperature control to undergo gelation. Nevertheless, precise temperature control does produce a more uniform product and improves product consistency and yield. If temperature control mechanisms are provided, they should be employed to control the temperature at or near room temperature, i.e., at about 15°C to 35°C. While not wishing to be bound by any particular theory, it is believed that this photoinitiator works in the following fashion. The phosphine oxide derivative is activated and undergoes photodissociation under room light, leaving the acetophenone derivative unaffected. The phosphine oxide derivative undergoes bleaching on photodissociation, so that the polymerizing resin mass becomes less colored as polymerization progresses. Once the resin has undergone gelation, the mold assembly is placed in a chamber equipped with ultraviolet light bulbs emitting radiation in the wavelength range of 300-

380 NM. The near ultraviolet radiation activates the acetophenone derivative, causing the curing process to become accelerated. At the same time, the dissociation of the phosphine oxide derivative is completed, completing the bleaching process. A residual faint yellow hue can be corrected by an addition of a small amount of a bluing additive, such as TINOPAL (available from Ciba Geigy Corp.) to the resin formulation.

When UV photoinitiators (such as the acetophenone derivative) are used during the second stage of cure, the mold assembly may be heated along a preestablished temperature profile, ultimately reaching a final temperature in the range of about 90°-150°C, to complete the cure process and to obtain a final lens product with a glass transition temperature in the range of about

100°-175°C. if no heat is applied and the temperature maintained at or near room temperature, the final product has a lower glass transition temperature (e.g., in the range of about 30°-50°C) . In all cases, the cure process should be completed. The extent of the cure process can be monitored, for example, by a differential scanning calorimetric analysis of the material after cure. Whether heating is necessary to complete the cure generally depends on the monomers used in the resin formulation. Thus, if monomers used in the formulation can form homopolymers which have glass transition temperatures considerably above the room temperature

(15°-30°C) , then an elevated temperature is desirable to complete the cure process.

Alternatively, a phosphine oxide derivative may be used which initiates cure under visible light as before. However, a thermal polymerization initiator, such as a peroxide, a peracetate, a percarbonate or an azo derivative may be used to complete the second stage (post-gel cure) by placing the mold assembly in a thermal curing oven, typically a convection oven. The two stage polymerization process described above may be carried out in glass molds, in metal molds or in a combination thereof. Metal molds with reflective inner surfaces may be especially useful in reflecting radiation back into the resin mass and conducting excess heat away from the resin mass. Metal molds may also be made thinner, and thus can have a lower thermal mass than glass molds. Alternatively, glass molds with metallized surfaces may be employed for resin formulations which require a metal mold for adhesion and thus prevent prerelease during cure.

The two stage polymerization method can be employed to produce lenses from resin formulations covering a wide range of chemical reactivities, functionalities, shrinkage properties, and thermal expansion characteristics. Both monomers and oligomers may be employed, and polymeric or small molecular weight additives can be included to alter physical properties of the resin formulation, such as viscosity and surface energy, as well as chemical properties of the formulation, such as oxidative and photothermal or hydrolytic stability.

Claims

CLAIMSWhat is claimed is:

1. A curing method for ophthalmic lenses or semi- finished lens blanks comprising: (A) providing a mold and a polymerizable resin, said polymerizable resin comprising (1) a first photoinitiator that is activated by radiation in the wavelength range 400-800 NM and (2) an initiator selected from the group consisting of (a) a thermal initiator which is activated by heat and (b) a second photoinitiator which is activated by radiation of different wavelength or intensity than that used to activate the first photoinitiator; (B) exposing the curable resin to radiation in the wavelength range of 400-800 NM; and (C) subsequently subjecting the curable resin to a curing environment selected from (1) heat and (2) radiation of different wavelength or intensity than that used in step (B) .

2. The method of claim 1, further comprising heat treating subsequent to step (C) .

3. The method of claim 1, in which light delivered by incandescent light bulbs is used to provide said radiation in the wavelength range of 400-800 NM.

4. The method of claim 1, in which light delivered by fluorescent light bulbs is used to provide said radiation in the wavelength range of 400-800 NM.

5. The method of claim 1, in which step (B) further comprises control of temperature in the range 15°C-45°C.

6. The method of claim 1, in which said first photoinitiator is Bisdimethoxybenzoyl Trimethylpentyl Phosphine Oxide.

7. The method of claim 1, in which said second photoinitiator is selected as the initiator.

8. The method of claim 7, in which said second photoinitiator is .2-Hydroxy 2-Methyl 1-Phenyl Propane.

9. The method of claim 1, in which said thermal initiator is selected as the initiator.

10. The method of claim 11, in which said thermal initiator is selected from the group consisting of a peroxide, a peracetate, a percarbonate and an azo derivative.