TH64815B - Optical products with quarter discs, wavelengths and methods for manufacturing optical products. - Google Patents

Abstract

DC60 (18/11/16) Optical product consisting of mineral or organic glass substrates (1) and a unique transparent polymer layer (3). That the product will be assembled as well The intermediate layer (2) is the least in Direct contact with the main side of the substrate and the intermediate layer (multi-layer) of the polymer material is made from Oxide particles of minerals that are One kind of colloid Minimal and in an optional manner Such an intermediate (multi-layer) binder with initial porosity and initial porosity of the intermediate (multi-layer) layer is added with some material from the polymer layer. Or with a material that is either a substrate If the substrate material has been made from organically extracted glass and in an optional manner by having a partial binding agent in such a way that the intermediate layer (multiple) after Adding the porosity at the beginning of each will make A quarter wavelength disc has a wavelength in the range from 400 to 700 nm. Ideally, wavelengths are between 450 and 650 nm.

Claims (5)

Claims (all) which will not appear on the classifieds page. :------05/02/2018------(OCR) Page 7 of 8 Page 6 0. Method of Claim No. 59, where the anti-corrosion coating is applied Photo It is formed through a dipping or centrifugal coating and hardening 6 1. The method of claim 59, which further stipulates, shall include the procedure of Formation of an anti-reflective coating on an anti-corrosion coating 6 2. Method of claim 32, where the polymore layer is an anti-corrosion coating 6 3. Method of Claim 62, where the corrosion resistant coating is formed. It is formed by hardening of a mixture consisting of epoxialoxylene, dialkyl dialoxysilane. and colloidal silica or hydrolyzate of such mixtures 6 4. The method of claim 62 hereinafter shall include the procedure of Formation is applied as an anti-reflective coating on an anti-corrosive coating 6 5. The optical product complies with one of the preceding claims. where the quantity of Fluorine in the polymer filling material should be less than 5% by weight, preferably less than 1% by weight, preferably at 0% by weight. 6. The optical product pursuant to one of the preceding claims where the porosity of steep in the middle After initial addition it should be below 5%, preferably below 3%, preferably below 0%. 6 7. The optical product according to one of the claims. before where the material is steep Polymer is an impact resistant substrate with a thickness from 0.50 to 20 µm, preferably 0.5 to 2 µm. previously held the right where the material is steep The polymer is an abrasive protective layer with a thickness from 1 to 15 µm, preferably from 2 to 6 µm. 6 9. The optical product meets one of the pre-claims. this page where it assembles with one layer in between 7 0. The optical product pursuant to one of the preceding claims where the material is steep The transparent polymer provides an impact-resistant base layer. ------------ Revised 18/11/2016 1. Optical products which include : Organic glass substrate or absorbent. Straits, which are glass extracted from minerals. which includes at least one main aspect; transparent polymer material layer; and Intermediate (multilayer) one or more layers. where one or more intermediate (multilayer) layers are defined as: between and in direct contact with at least one primary side of the substrate and polymer material layer; which consists of particles of at least one colloidal mineral oxide; and which are porous, which are at least partially filled with a material from a polymer layer or The material is a substrate which is one of the organically extracted glass; where one or more interlayer (multilayer) forms a A quarter-wavelength sheet with wavelengths in the range from 400 to 700 nm 2. The optical product of Claim 1, where one or more intermediate (multilayer) layers are formed. A quarter-wavelength sheet whose wavelength ranges from 450 to 650 nm 3. The optical product of claim 1, where pores in one or more interlayer (multilayer) are formed. rise at least 40% by the volume of one or more interlayer (multilayer) shall form at least 50% by the volume of one or more intermediary (multilayer) layers. Consists of binders 6. Optical products of claim 5 where the porosity of one or more intermediate (multilayer) layers is at least partially filled with binder. A clause of Claim 6, where one or more interlayer (multilayer) binders have a minimum of 25% porosity. 8. The optical product of claim 7, where One or more intermediate (multilayer) binders have a minimum porosity of 30%. 9. The optical product of Claim 5, where the binder forms up to 30 % by weight, based on the total weight of mineral oxides in the dry state of one or more intermediate (multilayer) layers 1 0. The optical product of claim 5 where the binder is formed. to 25% by weight, which is based on the total weight of the mineral oxides in the dry state of one or more intermediate (multilayer) layers 1 1. The optical product of claim 5, where the binder will Formed 10 to 20% by weight, based on the total weight of mineral oxides in the dry state of one or more intermediate (multilayer) layers. 5 where the binder is polyurethane latex 1 3. Produce The optical product of claim 1, where the particle size of the mineral oxide colloidal materials (many types) range from 10 to 80 nm 1 4. The optical product of Claim 13, where the particle size of mineral oxides colloidal (many) species range from 30 to 80 nm 1 5. The optical product of Claim 14, where the particle size of mineral oxides colloidal mineral oxides (many types) range from 30 to 60 nm 1 6. The optical product of claim 1 where colloidal mineral oxides are SiO2, TiO2, ZrO2, SnO2, Sb2O3, Y2O3, Ta2O5 or mixtures consisting of one of these substances 1 7. Optical product of Claim 16 where the interlayer (multilayer) consists of mixtures of oxides of at least low index colloidal minerals. one maximum (nD25 < 1.54) and at least one high index colloidal mineral oxide (nD25 (formula) 1.54) 1 8. The optical product of claim 17 where the weight ratio of the oxide of Colloidal minerals, low to oxides of high index minerals range from 30/70 to 70/30 1 9. Optical Products Claim Article 17, where oxide mixtures of colloidal minerals are mixtures of SiO2 and TiO2 or a mixture of SiO2 and ZrO2 2 0. The optical product of Claim 1, further specified, shall include: Two Intermediate Layers 2 1. The optical product of Claim 1, further specified, which shall consist of Substrate, which is glass of organic matter from which the substrate, which is glass, is extracted from organic matter. Contains diethylene glycol bis (allyl carbonate) polymer diethylene glycol bis. (Allyl Carbonate) Copolymer Homopolycarbonate Copolycarbonate Poly(meth)acrylate Polythio(meth)acrylate, polyurethane, polythiourethane polyepoxide or polyepisulfide 2 2. The optical product of Claim 1 where the substrate has a refractive index nD25 that ranges from 1.55 to 1.80 2 3. The optical product of Claim 1. 22 where the substrate has a refractive index nD25 that ranges from 1.60 to 1.75 2 4. The optical product of claim 1 where the polymer layer is the cushioning layer 2 5. The optical product of claim 24 where the foundation consists of (meth)acrylic polymer thio(meth)acrylic polymer, polyester, polyurethane or material which Polythiourethane base 2 6. Optical products of claim 25 where the substrate is composed. Poly(meth)acrylic or polyurethane latex 2 7. The optical product of claim 24, further specified, shall include: Anti-corrosion coating applied on the impact-resistant base layer 2. 8. Optical product of claim 1, where the polymer layer, the coating layer Anti-corrosion 2 9. Optical products of claim 28, where the corrosion-resistant coating is applied. will result from the hardening of mixtures consisting of epoxialoxylene, dialkyl dialoxysilane and colloidal silica or hydrolyzate of such components as Major components 3 0. Optical products of clause 28 further specified which shall include Anti-reflective coating formed on the anti-corrosion coating 3 1. The optical product of claim 1, hereinafter referred to as optical lenses 3. 2. Methods for the manufacture of optical products which Includes: Coating of one or more colloidal mineral oxides on the main surface At least one surface of the support for the formation of one or more intermediate (multilayer) layers consisting of at least one colloidal mineral oxide. where one or more interlayer (multilayer) is porous; and the formation of one or more interlayers (multilayers) of the material layer. Optically transparent polymer or substrate, which is either organic glass; where the pores of one or more intermediary (multilayer) layers are filled. At least partially with a layered polymer material or with a substrate and interlayer (multilayer) one or more layers form a quarter wavelength sheet in Range from 400 to 700 nm 3 3. Method of Claim 32 where one or more interlayer (multilayer) At least one layer is formed into a quarter wavelength sheet in the range from 450 to 650 nm 3 4. Method of claim 32, where the backing is a glass substrate. extracted from minerals or organic material 3 5. Method of claim 32 where the backing is the main casting surface The formwork part of the formwork which is composed of at least a coating which is a layer of Optically transparent polymer material and the porosity of the intermediary layer (multilayer) has been filled. At least partially with a glass substrate which is extracted from organic matter 3 6. Method of Claim 35 where the substrate is formed by casting. Liquid mixtures that can be polymerized in formwork and polymerization of mixtures 3 7. Method of claim 32, where the transparent polymeric layer light or Substrate, which is organically extracted glass, is treated with a basic solution before reaching Formation of one or more intermediary (multilayer) layers 3 8. Method of claim 32, where the porosity of one or more intermediary (multilayer) layers is formed. at least 40% by the volume of one or more interlayer (multilayer) 3. 9. Method of claim 32, where the porosity of one or more interlayer (multilayer) shall be Formed at least 50% by the volume of one or more interlayer (multilayer) 4 0. Method of claim 32, where the particle size of the mineral oxide is At least one or more colloids range from 10 to 80 nm 4 1. Method of Claim 40 where the particle size of the mineral oxide is At least one or more colloids range from 30 to 80 nm 4 2. Method of claim 41 where the particle size of the mineral oxides is At least one or more colloids range from 30 to 60 nm 4 3. Method of claim 32 where one or more interlayer (multilayer) 4. The method of claim 32, whereby the binder reaches 30% of one or more interlayers (multilayers) by weight, based on weight. Total of mineral oxides in dry state 4 5. Method of claim 44, where binding agent is 25% of one or more interlayers (multilayers) by weight, based on gross weight. of mineral oxides in the dry state 4 6. Method of claim 45, where binding is from 10 to 20% of one or more intermediate (multilayer) layers by weight, based on weight. total of oxides of minerals in dry condition 4 7. Method of claim 43 where the binder is polyurethane latex 4 8. Method of claim 32 where oxides of colloidal minerals combine with SiO2, TiOj, ZrOj, SnO2, Sb2O3, Y2O3 and/or Ta2O5 4 9. Method of claim 32, where at least one intermediary (multilayer) The class consists of mixtures of at least one colloidal mineral oxide (nD25 < 1.54) and at least one high index colloidal mineral oxide (nD25 (formula) 1.54) 5 0. Method of claim 49, where the weight ratio of the oxides of the mineral Colloidal low index to oxides of high index minerals range from 30/70 to 70/30 5 1. Method of claim 49, where colloidal mineral oxide mixtures are mixtures of SiO2 and TiO2. or mixtures of SiO2 and ZrO2 5 2. Method of Claim 32 which further stipulates that the composite by forming rise to at least two intermediaries 5 3. Method of Claim 32 where one or more intermediary (multilayer) layers It is formed on a glass substrate which is extracted from organic matter. and glass substrate The organic extracts were further identified to contain diethylene glycol bis. (Allyl Carbonate) Polymer diethylene glycol bis (Allyl Carbonate) Copolymer Homopolycarbonate Copolycarbonate Poly(meth)acrylate Polythio(meth) acrylate polyurethane polythiourethane polyepoxide or polyepisulphide 5 4. Method of claim 32 where the substrate has a refractive index nD25 that ranges from 1.55 to 1.80 5 5. Method of claim Article 54 at The substrate has a refractive index nD25 which ranges from 1.60 to 1.75 5 6. Method of claim 32 where the polymer material slopes is an impact-resistant substrate 5 7. Claim method Right Article 56 where the foundation consists of (meth)acrylic polymer Thio(meth)acrylic polymer, polyester, polyurethane, or polythiourethane based material 5 8. Methods of holding. Right Article 56 where the substrate material is poly(meth)acrylic or Polyurethane latex 5 9. Method of claim 56, which is further consolidated by forming a Anti-abrasive coating on the impact-resisting undercoat 6 0. Method of claim 59 where the anti-corrosion coating is formed. Formed through dipping or centrifugal coating and hardening 6 1. The method of claim 59, which further stipulates, shall consist of the procedure of Formation of an anti-reflective coating on an anti-corrosion coating 6 2. Method of claim 32 where the polymer layer is an anti-corrosion coating stage 6 3. Method Act of Claim 62, where the corrosion protective coating is formed It is formed by hardening of a mixture consisting of epoxialoxylene, dialkyl dialoxysilane. and colloidal silica or hydrolyzate of such mixtures 6 4. The method of claim 62 hereinafter shall include the procedure of Formation of an anti-reflective coating on an anti-corrosive coating 6 5. The optical product pursuant to one of the preceding claims where the amount of Fluorine in the polymer filling material will be less than 5% by weight, preferably below 1% by weight, preferably at 0% by weight. 6 6. Product optical in accordance with one of the preceding claims where the porosity of Intermediate After initial addition it should be below 5%, preferably below 3%, preferably above 0%. 6. The optical product according to one of the claims. Previously, where the material Polymer is an impact resistant primer with a thickness from 0.05 to 20 µm, preferably 0.5 to 2 µm. 6 8. The optical product meets one of the prior claims. this page where the material layer The polymer is an abrasion resistant coating with a thickness from 1 to 15 µm, preferably from 2 to 6 µm. This page where it comprises with one intermediate step 7 0. The optical product pursuant to one of the preceding claims at which the material stage Transparent polymer as a cushioning layer. and further assembling products as well Anti-abrasive coating applied on the shock-resisting undercoat, and protective coating. Reflection formed on the corrosion resistant coating ---------------------------------------------------- -------------------------- 1. An optical product consisting of a mineral or organic glass substrate. and a transparent polymer layer, which is characterized by the fact that the product is assembled with at least an intermediate layer in direct contact. With the main side of the substrate and the polymer layer, the intermediate layer (multilayer) is made up of oxide particles. of the mineral that is at least one colloid and, in an alternative manner binder Such an intermediate (multilayer) layer with initial porosity and initial porosity of Intermediate layers (multilayers) are filled with material from the polymer layer. or with a material which is Substrates either if the material The substrate is made of organically extracted glass and, in an alternative way, by having a substance Partially bonded in such a way that the intermediate (multilayer) layer after the initial porosity addition each A quarter-wavelength sheet has The wavelength is in the range from 400 to 700 nm, the wavelength should be between 450 and 650 nm. at No binder interlayer (multilayer), at least 40% by volume, ideally at least 50% by volume 3. Optical product according to claim 2, which is characteristic. that by having the binder and before adding The interlayer has a porosity of at least 25%, if preferably at least 30% by volume. 4. The optical product according to claims 1 to 3, which is characterized by size of oxide particles The range of colloidal minerals (many kinds) is in the range from 10 to 80 nm, preferably from 30 to 80, and at best, from 30 to 60 nm. Nometer 5. The optical product according to claims 1 to 4, which is characterized by having 30% binder, preferably 25%, preferably 10% to 20% by weight, based on water. The total weight of the oxides of the mineral in its dry state Intermediate layer (multilayer) 6. The optical product according to one of the foregoing claims, which is characterized by The binder is polyurethane latex. 7. The optical product according to one of the foregoing claims, which is characterized by oxides of colloidal minerals Lloyds are selected from among SiO2, TiO2, ZrO2, SnO2, Sb2O3, Y2O3, Ta2O5 and their mixtures. ) will include Mixtures of oxides of at least low index colloidal minerals (n25D<1.54) and oxides of high index colloidal minerals (n25D<1.54). at least (n25D>or=1.54) 9. The optical product according to claim 8, which is characterized by the weight ratio of the oxide of the mineral that is The low index colloids to oxides of high index minerals range from 30/70 to 70/30 1 0. The optical product according to claim 8 or 9, which is characterized by Colloidal mineral oxide mixtures are mixtures of SiO2 and TiO2 or mixtures of SiO2 and ZrO2 1 1. The optical product pursuant to one of the foregoing claims, characterized by The product will be assembled together with a layer between the two middle layers 1. Substrate, which is a glass that Organic extracts are selected from among the polymers and copolymers of diethylene glycol bis. (allyl carbonate) homo-and copolycarbonate poly(meth) acrylate polythio (meth) acrylate polyurethane enough lithium urethane polyepoxide, polyepisulphide and Assembling them together 1 3. The optical product according to one of the foregoing claims, which is characterized by Substrates have a refractive index N23D, which ranges from 1.55 to 1.80. should be in the range from 1.60 to 1.75 1 4. The optical product according to one of the foregoing claims, which is characterized by The polymer material layer is the impact resistant foundation layer 1 5. Products according to claim 14, which are characterized by A primer is a material based on (meth) acrylic polymer thio (meth) acrylic polymer polyester polyurethane. n polythiourethane or the combination thereof 1 6. Products according to Claim 15 which are characterized by that the substrate material is poly(meth)acrylic or polyurethane latex 1 7. Products under any of claims 1 to 13 which is unique in that the polymer material layer is the anti-corrosion coating layer 1. 8. Products according to claim 17, which are characterized by that the protective coating Corrosion will result from the curing of the substance. Mixture which consists of alkoxysilane epoxy dialkydil Coxylene and colloidal silica or hydrolyzate of such components are the main ingredients. 1 9. Products according to claims 14 to 16. which is unique in that The product will be assembled together with the coating. Anti-abrasion surface applied on an impact-resistant base layer 2 0. The product complies with any of claims 17 to 19. which is unique in that The product will be assembled together with the coating. Anti-reflective surface formed on the anti-corrosion coating 2 1. The optical product according to claims 1 to 20, which is characterized by the fact that the product is an optical lens. Glass Lens 2 2. A method for producing optical products, which is characterized by the fact that the method is assembled. including at a minimum the procedure of a) the formation on the main surface of the support; of sulphates of oxides of that mineral is at least a colloid In an alternative manner, the binder of the middle layer at least of oxides of colloidal minerals. minimal and in The optional feature is initially porosity; b) Formation of optically transparent polymer layers or glass substrates. extracted from one of the organic substances on the intermediate layer (multilayer); and c) the interlayer porosity (multilayer) is to be either filled with the material. one of the floors or of the substrate formed at step (b) and in an alternative manner with a binder in such a way that that the interlayer (multilayer) after filling the initial porosity is partial, each of which gives the sheet a quarter wavelength. The wavelength ranges from 400 to 700 nm. range from 450 to 650 nm 2. 3. The method according to claim 22, which is characterized by whether the backing is a substrate, which is glass extracted from mineral or organic substances 2 4. The method according to claim 22, which is characterized by that the support is a surface for Main casting of formwork part which consists of at least the coating, which constitutes the material layer. Optically transparent polymer and its porosity The beginning of the intermediate (multilayer) layer is filled with organic glass substrate 2. 5. The method according to claim 24, which is characterized by that the substrate will be formed by casting a mixture that Synthesis into liquid form polymer in casting and synthesis of mixture to polymer 2 6. Method according to claim 23, which is characterized by that the method will include Prior to step (a) treatment of the substrate with the base solution 2 7. Any method of claims 22 to 26. which is unique in that the porosity At the beginning of the interlayer (multilayer), without binder, it is 40% by volume at least 2. 8. Methods of one of Claims 22 to 26. which is unique in that the porosity without any binders The inductance of the intermediary layer (multilayer) shall be 50 % by volume at a minimum 2. 9. Any method of claims 22 to 28. which is unique in that the size of mineral oxide particles Colloidal species (many types) range from 10 to 80 nm, preferably from 30 to 80 nm, and preferably from 30 to 60. nm 3 0. Any method of claims 22 to 29 which is unique in that there will be Binder up to 30%, if good then 25%, better than that should be from 10% to 20% by weight, based on weight. inclusion of mineral oxides in the dry state of Intermediate Layer (Multilayer) 3 1. Any of the methods under Claims 22 to 30 which is unique in that The binder is polyurethane latex 3. 2. Any method of claims 22 to 31. which is unique in that the oxide of colloidal minerals was selected from among SiO2, TiO2, ZrO2, SnO2, Sb2O3, Y2O3, Ta2O5 and its mixture 3. 3. Method pursuant to one of Claims 22 to 32. which is unique in that The interlayer (multilayer) shall consist of mixtures of colloidal mineral oxides, the least low index (n25D<1.54) and colloidal mineral oxides. Lloyd's high index is at least (n25D>or=1.54) 3 4. The method according to Claim 33, which is characterized by the fact that the weight ratio of Oxides of colloidal minerals Low to oxides of high index minerals range from 30/70 to 70/30 3 5. Methods of one of Claims 33 to 34. which is unique in that the mixture Colloidal mineral oxides are mixtures of SiO2 and TiO2 or mixtures of SiO2 and ZrO2 3. 6. Any method of claims 22 to 33. which is unique in that the method will consolidated with the formation The image is formed as a layer between the two middle layers. 3. 7. Any of the methods according to claims 22 to 36 which is unique in that the substratum which is a glass extracted from Organics are selected from among the polymers and copolymers of diethylene glycol bis. (Allyl Carbonate) Homo-and Poly Carbonate Poly (Meth) Acrylate Polythio (Meth) Acrylate Polyurethane Poly Thiourethane polyepoxide Polyepisulphide and its combination 3 8. Methods of claims 22 to 37. which is unique in that the substratum It has a refractive index N25D which ranges from 1.55 to 1.80, preferably in the range from 1.60 to 1.75 3. 9. Any method of claim 22 to 38. which is characterized by the fact that the polymer material layer is the cushioning layer 4 0. Method according to claim 39, which is characterized by the fact that the substrate is a material based on (meth) Acrylic polymer thio (meth) acrylic polymer polyester polyurethane polythiourethane or combining them together 4 1. The method according to Claim 40, which is characterized by whether the substrate material is poly(meth)acrylic or polyurethane tex 4 2. Any method of claims 22 to 38 which is unique in that the polymer material layer is the anti-corrosion coating layer 4. 3. The method according to claim 42, which is characterized by that the coating prevents corrosion will result from the curing of the mixture. which includes alkoxysilane epoxy dialkyl dialk Sisilane and colloidal silica or hydrolyzate of such constituents are the main constituents. 4. Any method of claims 39 to 41 which is unique in that the method will assembled by forming Formed as an anti-impact primer by dipping or accretion, centrifugal and curing of the anti-corrosive coating. 4 5. Any method of claims 42 to 44 which is unique in that the method will consolidated with the formation The figure is formed with an anti-reflective coating on the anti-corrosion coating.