TH15304A - Methods and equipment for the manufacture of plastic lenses - Google Patents

Abstract

Equipment method And elements for making plastic lenses This method consists of liquid monomer Or mixtures of monomers and light-sensitive initiators into the compacted cavity And direct ultraviolet light to act on the lens making agent in the cavity. To make lenses from such substances

Claims (7)

1. Methods for making plastic lenses Containing a) A polymerized lens material is inserted into the designated cavity in the part between the first compression molding, approximately 1. 0-5. 0 m M and the second extrusion with a thickness of approximately 1. 0-5. 0 and b) direct urviolet radiation to at least one of the compression components. Or the aforementioned second compression while providing cooling with the first compression part. And the second compression with air at temperatures between 0 degrees C and less than 20 degrees C, which is directly supplied at a rate of about 1-30 m3 Standard feet (approximately 0. 028-0. 850 MB. m. Standard) per minute to the aforementioned compression section. To cool the first compression part and give it directly at a rate of about 1-30 cubic meters. Standard feet (approximately 0. 028-0. 850 MB. m. Standard) / minute To the aforementioned second-part compression To cool the second part of the press 2. Method of claim 1 where the air temperature is approximately 0-15 C. 3. Method of claim 1 where the air temperature is approx. 0 - 10 C. 4. Method of claim 1 where the air temperature is approximately 3-8 C. 5. The method of claim 1 where the compression cavity is cylindrical and the height of the cavity Variable through the diameter of the cavity. And where the intensity of the ultraviolet rays Has changed approximately in the proportion of the height of the cavity 6. Method of claim 1, where the compression is part one. And the aforementioned second compression Each has a surface, and the air is directed directly on the surface of the compression part one. And to the surface of the second compression part 7. Method of claim 1, where the compression is part one. And the aforementioned second compression Each has a center and an edge. And the air was directed directly from the edge of the first compression. To the center of the first such compression And from the edge of the second compression to the center of the said second compression edge 8. Method of claim 1 where the rate of air in contact with the aforementioned compressed air is approximately 4-20 m3. Standard feet (approximately 0. 113-0. 566 MB. m. Standard) per minute and the rate of air in contact with the aforementioned second compression is approximately 4-20 m3. Standard feet (approximately 0. 113-566 MB. m. Standard) / min 9. Method of claim 1 where the rate of air in contact with the aforementioned compressed air is approximately 9-15 m3. Standard feet (approximately 0. 255-0. 423 MB. m. Standard) per minute and the rate of air in contact with the aforementioned second compression is approximately 9-15 m3. Standard feet (approximately 0. 255-0. 423 MB. m. Standard) / min 1 0. The method as in claim 1, where the first or second part is approximately 2. 0-4. 0 mm 1 1. The method as in claim 1, where the first or second part is approximately 2. 5-3. 5 mm 1 2. Method for making plastic lenses of the desired curvature. Which consists of Adding a polymerized lens solution In the least defined compression cavity between the first compression cavity. And the second compression And by which the hollow The curvature of the lens is theoretically different from the desired curvature, and at least one is directed to urviolet radiation. In a partial compression and a second compression So that the part of the substance in the cavity receives the intensity of the ultraviolet light different from the rest of the substance in the cavity In this way, the substance is cured to form a lens with the desired curvature 1 3. The method of claim 12 that also includes Removing the lens template And heat the lens 1 4. Method of claim 13 where such heating gives the lens the required second curvature 1 5. Method of claim 12 where the intensity of such ultraviolet radiation Has been transformed through the first part Or a second tribute to incubation of the substance to make lenses with the desired curvature 1 6. Method for making plastic lenses Containing a) Adding a polymerized lens solution In the designated compression cavity between the pre-compression parts. And b) direct ultraviolet exposure to at least one of the first compression parts. And the aforementioned second compression While doing it simultaneously c) Cooling the first and second compression With air temperature less than 20 degrees C. Which is given directly at a rate of about 1-30 million baht. Standard feet (approximately 0. 028-0. 850 MB. m. Standard) / min To the first compression section to cool the first compression part. And which provides direct air at a rate of about 1-30 cubic meters. Standard feet (approximately 0. 028-0. 850 MB. m. Standard) / min Go to the second recording To cool the second compression part 1 7. The claim method 16 also incorporates first direct ultraviolet radiation at an intensity less than approximately 10 mW / sq m. cm To at least one such compression To cure the material into a lens while in contact with the fluid with the first or second compression. To simultaneously cool the aforementioned partial or second compression and a second ultraviolet radiation directly to the lens at an intensity of approximately 150-300 mW / sq m. watch. At wavelengths of about 360-370 nm and about 50 -150 mW / sq. cm At the mean wavelength range 250-260 nm 1 8. The method, as in claim 17, also consists of third ultraviolet irradiation. Directly to the said lens 1 9. The method, as in Claim 18, also includes: To heat such lenses After the third dose of violet directly to such lenses 2 0. Method as in claim 19, where such lenses are heated to a temperature of 65-180 C. 2 1. Method as described in claim 19 where the lens has been heated for approximately 30 minutes less than 2 2. The method, as in claim 17, was given a second such ultraviolet radiation. Directly to such lenses It is less than about 1 minute 2 3. Method as in claim 18, where the third ultraviolet intensity is approximately 150-300 mW / sq. cm Where the wavelength range is about 360-370nm and about 50-150mW / sq. cm At the wavelength range is about 250-260 nm 2 4. Method as in claim 18, where a third ultraviolet is given directly to such lenses. It is less than about 1 minute 2 5. Method, as in claim 19, where the lens is heated to a temperature of about 65-180 degrees C. After the third ultraviolet was given directly to the lens 2 6. Method as in claim 19, where the lens is heated It is less than approximately 30 minutes after the third ultraviolet radiation was directed directly to the lens.2 7. The method, as in claim 16, also consists of direct irradiation of ultraviolet light through ring gasket to curing lensmaking agent 2 8. The method, as in Claim 27, also includes: Protection against ultraviolet rays From the impact on the compression part one Or the second part 2 9. The method, as in Claim 12, also includes: Cooling the substance in the lens cavity 3 0. The method, as in claim 12, also consists of cooling the lens cavity while directing ultraviolet radiation with at least one of the first and second extracts simultaneously 3. 1. The method, as in claim 12, also consists of cooling the lens cavity by directing air to at least one of the first and second compressions while providing ultraviolet radiation. Meet at least one of the first and second compression at the same time 3 2. The method, as in claim 12, also consists of cooling the cavity of the lens by direct airflow at a temperature of less than 20C. At least one of the first and second compression. While at least direct ultraviolet radiation in one of the first and second parts simultaneously 3 3. The method, as in claim 12, also consists of cooling the lens cavity by directing air at a temperature between 0-15 C. At least one of the first and second compression. While providing direct ultraviolet radiation to at least one of the first and second compression at the same time 3 4. The method is as in claim 12 where the compression cavity is cylindrical and the height of the cavity. Is proportional to the diameter of the cavity. And where the intensity of the ultraviolet rays varies approximately proportional to the height of the cavity 3 5. Method as in claim 31 where the cavity is compressed as a cylinder. And the height of the cavity varies through the cavity diameter. And where the intensity of the ultraviolet rays varies approximately To the height of the cavity 3 6. As mentioned in claim 12, where the first and second compressions each have a surface, and the air is directed at the face of the first and to the face. Of the aforementioned second compression 3 7. The method of claim 31, where the first and second compressions each have such a surface and air, are directed directly at the face of the first and to the face of the The aforementioned second compression 3 8. The method of claim 12 in which the first and second compression have center and edge. And the air is directed from the edge of the first compression unit to the center of the first compression unit 3 9. Method of claim 31 where the first and the second compression have center and edge. And the air was directed straight from the edge of the aforementioned compression to the center of the aforementioned compression 4 0. Method of claim 12 whereby the first and second compression Each has a center and edge, and the air is directed directly from the edge of the integral compression. To the center of the first such compression And from the aforementioned second compression Go to the center of the second compression 4 1. Method of claim 31 whereby the first and second compression Each has a center and edge, and the air is directed from the edge of the aforementioned compression to the center of the aforementioned compression. And from the edge of the second compression to the center of the second compression 4 2. The method of claim 12 in which the first and second compression have center and edge. And the air is directed from the center of the first compression to the edge of the first compression 4 3. Method of claim 31 where the first and the second compression have center and edge. And the air is directed from the center of the first compression to the edge of the first compression 4 4. The method of claim 12 whereby the first and second compression have center and edge. And the air is directed from the center of the first compression to the edge of the first compression. And from the center of the aforementioned second compression to the edge of the said second compression 4 5. The method of claim 31 where the first and second compression have center and edge. And the air is directed from the center of the first compression to the edge of the first compression. And from the center of the second compression to the edge of the second compression 4 6. Method of claim 12 where ultraviolet light is filtered in such a way that different concentrations of it are applied to different parts of the substance in the cavity 4 7. Method of claim 46 where ultraviolet light is filtered by a filter. Containing disks of opaque substances For the reduction of the ultraviolet light intensity at the center of such compression. Compared with the intensity of the ultraviolet light. That reach the edge of the compression During operation 4 8. Method of claim 46 where ultraviolet light is filtered by a filter containing Ring of opaque substances For reducing the intensity of ultraviolet light that reaches the edge of the compression Compared with the intensity of the ultraviolet light. That achieve the center of the said compression During operation 4 9. Method as in claim 46, where ultraviolet light is filtered by a filter consisting of a transparent, absorbent sheet material. The amount of ultraviolet light printed on the discs 5 0. Method, as in claim 49, where the perimeter density of the aforementioned contours It is the minimum at the point corresponding to the distance between the first compression components. And the aforementioned second compression And where the per-area density of the geometry is the highest at the point corresponding to the shortest distance between the first compression components. And the aforementioned second-part compression 5 1. Method of claim 31 where air is directed through a diffuser consisting of The cylindrical air ejector has a number of openings approximately the circumference of the chamber 5 2. Method of claim 51 where the diameter by the change of the said air opening varies approximately the circumference of the compartment 5 3. Method of claim 51 where the air is sprayed consists of an intake pipe. And the diameter of such opening Is the lowest value when it is close to the inlet ducts. And the diameter of the opening is the highest at the point in the circumference of the opening opposite the opening of the minimum diameter. 5 4. The claim 12 method also consists of a second dose of ultraviolet radiation directly to the lens. To make the lens have the required second curvature 5 5. The claim 13 method also consists of a second dose of ultraviolet radiation directly to the lens. To make the lens have the required second curvature 5 6. Method of claim 12 where ultraviolet radiation will have a total intensity of less than approx.10 mW / sq m. cm It also consists of a second procedure of direct ultraviolet radiation to the lens at an intensity of approximately 150-300 mW / sq m. cm At the maximum wavelength between 360-370 nm and about 50-150 mW / sq m. cm At the maximum wavelength between 250-260 nm to make the lens have the desired second curvature 5 7. The method of claim 13 is that the ultraviolet radiation has a total intensity of less than approx.10 mW / sq m. cm And also consists of steps A second exposure to ultraviolet rays directly to the lens at an intensity of approximately 150-300 mW / sq. M. cm At the maximum wavelength between 360-370nm and approximately 50-150 mW / sq. cm At the maximum wavelength between 250-260 nm to make the lens have the desired second curvature 5 8. Method of claim 55 where a second ultraviolet ray was directed directly to the lens for about 1 minute 5 9. Method of claim 13 Where the lens is heated to a temperature of about 65-180 C. It is less than about 30 minutes 6 1. Method of claim 60 that the substance also contains aromatherapy. Containing bis (allil carbonate) functional monomer 6 2. Method of claim 12 where the substance contains at least one polyethylene-functional nominal. Containing 3 unsaturated ethylene glycol groups selected from acrylil And Methacryilil 6 3. Method of claim 62 that the substance also complements what the bis (allyl carbonate) functional monomer 6 4. The method of claim 12 also consists of first-part and second-part compression in such a way that the cavity determines the theoretical curvature that when ultraviolet light is directed to the substance. This will give the substance the desired curvature of the lens.6 5. The method of claim 12 is where the cavity portion is subjected to a different intensity of ultraviolet light from the rest of the cavity, thus curing the substance into a curved lens. As needed 6 6. The method of claim 12, where at least one such compression will have center and edge. And where the intensity of the light received by the part of the substance closer to the center of the template is less than that of the light Obtained by the part of the substance close to the edge of the template, thus causing the substance to become a lens with a more negative force than the theoretical force of curvature 6 7. The method of claim 12, where at least one such compression will have center and edge. And where the intensity of the light received by the part of the substance closer to the center of the template is greater than the intensity of the light received by the part of the substance closer to the edge of the template, thus causing the substance to become the lens that It has a less negative power than that of a lens with a theoretical curvature 6 8. The method of claim 12, where at least one such compression will have center and edge. And where the light intensity received by the part of the substance closest to the center of the template It is less than the intensity of the light receiving the part of the substance closer to the edge of the template, so it turns the substance into a lens with less positive energy than that of a lens with a curvature of 6 9. The method of claim 12, where at least one such compression will have center and edge. And where the intensity of the light received by the part of the substance closer to the center of the template is greater than the intensity of the light received by the part of the substance closer to the edge of the template, thus causing the substance to become the lens that It is more positive than the power of the theoretical curvature lens 7 0. The method of claim 1, where the first and second compression components have center and edge. And the air is directed from the edge of the pre-compression to the center of the pre-compression 7 1. The method of claim 1, where the first and second compression components have center and edge. And the air is directed from the center of the first compression to the edge of the first compression 7 2. The method of claim 1, where ultraviolet light is filtered in such a way that different intensities are applied to different parts of the substance in the cavity 7 3. Method of claim 72 where ultraviolet light is filtered by a filter containing a disk of opaque substance. For the reduction of the ultraviolet light intensity at the center of such compression. Compared with the intensity of the ultraviolet light. That reach the edge of the compression During operation 7 4. The device of claim 72 where the ultraviolet light is filtered by a filter containing a ring of opaque substance. For reducing the intensity of ultraviolet light that reaches the edge of the compression Compared with the intensity of the said ultraviolet light That achieve the center of the said compression During operation 7 5. Method of claim 72 where such ultraviolet light is filtered by a filter consisting of a permeable, permeable sheet material. A large amount of ultraviolet light is printed on the discs 7 6. The method of claim 75 where the perimeter density of the aforementioned contours It is the minimum at the point of correspondence to the distance between the first and the second compression. And where the per-area density of the geometry is the highest at the point corresponding to the shortest distance between the first and second compression 7 7. The method of claim 1, in which air is transmitted directly through such diffusers, consists of The cylindrical air ejector has a number of openings approximately the circumference of the chamber. 7 8. Method of claim 77 where the average diameter of the opening in the air jet extends approximately the circumference of the vent.7 9. Method of claim 77, where the air jet carries the air inlet sample. And the center line of the said opening Is low when it is close to the inlet ducts. And the diameter of the said opening is the highest at the point in the circumference of that opening opposite the opening whose diameter is the highest at the point in the circumference of the opening. Say that is opposite to a channel with such minimum diameter 8 0. The method of claim 1 where the ultraviolet radiation will have total intensities less than approx.10 mW / sq m. It also consists of a second procedure of direct ultraviolet exposure to lenses at an intensity of approximately 150-300 mW / ultraviolet at the maximum wavelength range of approximately 360-370nm and approximately 50-150 mW. / Sq. cm At the maximum wavelength range of about 250-260 nm 8 1. The method of claim 80, where a second ultraviolet radiation is supplied directly to such lenses. It is less than about 1 minute 8 2. The method of claim 1 also consists of heating the said lens. So that the temperature is about 65-180C for less than about 30 minutes 8 3. Method of claim 1 where the substance contains at least one polyethylene-functional monomer. Containing 2 unsaturated ethyl nicole groups selected from acrylil And Methadrab Lil 8 4. Method of claim 83 where the substance also contains aromatic bis (illicarbonate) -functional monomers 8 5. Method of claim 1 where the substance Contains at least one polyethylene-functional monomer. Containing 3 unsaturated ethylene glycol groups selected from acrylil And Matthew Lailil 8 6. Method of claim 85, where the substance also contains aromatic bis (allyl carbonate) -functional monomers 8 7. The method of claim 12 also consists of applying different intensities of ultraviolet light to different parts of at least one of the aforementioned pre- and second-segment 8 8. . Method of claim 87 where the intensity of ultraviolet light provided at the center of at least one of the first compression And the second is greater than the intensity of ultraviolet light directed at the edge of at least one of the aforementioned first and second compression 8 9. Method of claim 87 where the intensity of the ultraviolet light supplied directly at the center of at least one of the first and second compressions. Will be less than the intensity of ultraviolet light Given directly to the edge of at least one of the aforementioned first and second compressions 9 0. The method of claim 87 also consists of determining the desired curvature of the lens. And on the basis of this designation A different intensity of light is selected to be directed directly to parts of at least one of the first and second compressions. 9 1. The method of claim 31 also consists of determining the required curvature of the lens. And on the basis of this designation Different intensity of light will be selected directly to at least one of the first and second compression parts, and then directly to the ultraviolet at different intensities. Different parts At least one of the first and second compression 9 2. The method of claim 12 also consists of directing the first set of ultraviolet rays directly into the recombinant for cavity lenses. To make the first lens with the desired first curvature of the lens And a second set of ultraviolet rays directly into the compound for the same cavity lens formation. To make a second lens with the required second curvature of the lens The first set of ultraviolet light differs from the second set of ultraviolet and the first lens curvature as desired. Will be different from the second curvature of the lens as desired 9 3. The claim 92 method also consists of determining the desired curve. And on the basis of this designation A different intensity of light to be directly directed to at least one of the first and second compression is selected. And then, ultraviolet light of different intensities is then directed directly to the parts of at least one of the aforementioned first and second compressions 9 4. The method of claim 1 continues. By direct radiation of ultraviolet light through a ring gasket to cure lens materials 9 5. The method of claim 12 also consists of direct irradiation of ultraviolet light through ring gaskets to curing lens materials. 9 6. The method of claim 1 in which the cavity theoretically determines the curvature of the lens from the desired curvature. It also consists of direct transmission of ultraviolet radiation to at least one of the first and second compression parts in such a way that the cavity portion Will receive different intensities of ultraviolet light from other parts of the cavity. Therefore, curing of the substance will be allowed to form a lens with the desired curvature 9 7. The method of claim 16, in which the cavity theoretically determines the curvature of the lens from the desired curvature. It also consists of direct transmission of ultraviolet radiation to at least one of the first and second compression parts in such a way that the cavity portion is exposed to different intensities of ultraviolet light. Lets form other parts of the cavity, so curing of substance is allowed to form lenses with the desired curvature.9 8. The method of claim 16 also consists of cooling the cavity of the lens by directing air at a temperature between 0-15C and at least one of the first and second compressions. While direct simultaneous ultraviolet radiation to at least one of the aforementioned first and second compression parts 9 9. The method of claim 16 is where the cavity is compressed as is cylindrical and its height varies through the cavity diameter. And where the intensity of ultraviolet radiation varies approximately proportional Of cavity height 10 0. The method of claim 16 where the first and second compressions have a surface and air. It is directed directly to the surface of the first section and to the surface of the second compression part 10 1. The method of claim 16 where the first and second compressions have center and edge. And air is directed from the edge of the section one to the center of the part of the compression part 10 2. The method of claim 16, where the first and second compressions have center and edge and air. Is sent directly from the center of the part compression to the edge of the part of the compression part 10 3. The method of claim 16 where ultraviolet light is filtered in such a way that its different intensities are applied to different parts. Of material in cavity 10 4. Method of claim 103 Where ultraviolet light is filtered by a filter. Containing disks of opaque substances For the reduction of the ultraviolet light intensity at the center of such compression. Compared to the intensity of the aforementioned ultraviolet light that reaches the edge of the compression part during use 10 5. Method of claim 103 where ultraviolet light is filtered by a filter composed of a large amount of ultraviolet-shaped translucent sheet material printed on it 10 6. Method of claim 16 where air is directed through the diffuser Consisting of an air jet with a cylinder And there are many openings in the perimeter of the channel 10 7. Method of claim 106 where the average diameter of the opening in the air jet is approximately the circumference of the chamber 10 8. The method of claim 16 also includes: Second exposure of ultraviolet rays directly to a lens to make a lens of the desired second curvature 10 9. The method of claim 16 also consists of removing the lens template and heating the lens 11 0. The method of claim 16 also consists of heating the lens to a temperature of approximately 65-180C for less than approximately 30 minutes 11 1. Method of claim 16 in which the substance contains at least one polyethylene-functional monomer with two unsaturated ethylene glycol groups. Selectable from acrylil and methacrylil 11 2. Method of claim 111 where the substance still contains aromatic bis (Allyl Carbonate) - Functional Monomer 11 3. The method of claim 16 also includes: The selection of the first and second templates in such a way that the hollow is theoretically defined as curvature. Which when direct ultraviolet light is given to the substance Will cause that substance to form a lens with the desired curvature 11 4. Method of claim 113 in which portions of the cavity contents are subjected to different intensities of ultraviolet light from other parts of the cavity. Therefore, the substance will be cured to become a lens with the desired curvature 11 5. Equipment for making plastic lenses that consist of One compression surface with a molded face and a non-molded face. A second compression garden with a non-molded face, such a second is distances from the first compression part during application in such a way that the a Part one compression And this second part defines the compression cavity to form pieces Generating light generator And direct ultraviolet light to at least one of the pre-compression. And the second part thereof during use A diffuser consists of a blast of air with a cylindrical cavity. The opening has a number of openings approximately the circumference of the channel. And the position of the channel is related to the first part. In order to provide air directly from the said opening to the non-molded surface of the pre-compressed section during use. And where the device can be adjusted To make plastic eyeglass lenses during use 11 6. A device for making plastic eyeglass lenses that includes One compression face with a molded face and a non-molded face with concentric and edge. Second extrusion with a molded surface And a non-cast face with a center and edges. There will be some distance from the aforementioned compression section during use. In such a manner that the aforementioned casting surfaces of this first and second compression Has set up a compression cavity Light generator For birth And direct ultraviolet light to at least one part And the second part thereof during use The diffusers are positioned relative to the first and second compressions to provide air directly from the edge to the center of the non-molded face of the first compressors during use. And from the edge to the center of the non-molded face surface of the second compression part during use and where the device is adjustable to make plastic goggles during use 11 7. The device of claim 116, where the diffusers will consist of a diffuser with a cylindrical cavity. The cylindrical cavity has many openings approximately the circumference of the channel. And the position of that channel is related to the compression part In order to provide air directly from the opening to the non-molded face of the first compression part during operation 11 8. Equipment of claim 115 where the diameter of the opening in the air jet varies approximately the circumference of the compartment 11 9. The device of claim 118, where the air intake, consists of an intake pipe. And the diameter of the said opening is the lowest value when it is close to the inlet pipe. And the diameter of the said cavity Will be the highest value at a point in the circumference of the channel opposite the channel with the lowest focal length 12 0. The equipment of claim 115 also consists of an ultraviolet filter installed between the light generator and the first compression element during operation and between the light generator and the second compression during operation. Idle 12 1. The equipment of claim 116 also consists of an ultraviolet filter installed between the light generator and the compression part one during operation and between the light generator and the second during use. P12 2. The device of claim 117, where it also consists of an inlet air cooler to provide air that is below ambient temperature, to the aerator during operation.12 3. A device for making plastic lenses that includes One compression surface with a molded face and a non-molded face. Second extrusion with a molded surface And such second-cast non-extruded faces are spaced from the first-part compression during use in such a way that the pre-cast face of the first and the non-extruded faces are These two sets up a compression cavity. Generating light generator And direct ultraviolet light to at least one of the pre-compression. And the second part thereof during use The air cooler is lower than the ambient temperature during use. The diffusers are connected to the cooled air directly from the non-molded cross-face coolers of the part compressors during the application and across the non-molded surfaces of the second compressions. During operation and where the device is adapted to make plastic eyeglass lenses during use and where the diffuser consists of a cylindrical air diffuser, there are numerous openings at Is approximately the circumference of the channel And the said channel is positioned relative to the first such compressed air In order to direct air from the opening to the unfinished surface of the first compression part during use 12 4. Equipment for making plastic eyeglass lenses Containing One compression surface with a molded face and a non-molded face. Second extrusion with a molded surface And such second-part extruded faces are spaced from type I compression during application in such a way that the first and second non-cast surfaces are Has set up a compression cavity Generating light generator And direct ultraviolet light to at least one of the compression elements. The first and the second part thereof, during use The machine cools the air to a temperature below the ambient temperature during use. The diffuser is connected to the cooled air directly from the air cooler across the non-molded face of the part one compressors during the operation and across the non-molded face of the part one compressors. The second, during operation and where the device is adjusted to make plastic eyeglass lenses during use and where the diffuser There will be a position relative to the said first and second compression. In order to direct air from the edge to the center of the non-molded face of the integral compression part. During use And from the edge to the center of the non-molded face of the aforementioned second extrusion during use 12 5. Device according to one of the claims 115-121 where the compression cavity is cylindrical and the distance between the first and second compression cavity varies through the diameter of the compression cavity. As mentioned 12 6. Device according to one of the claims of Articles 120-121, where the filter provides variable intensity ultraviolet light to the first compression element. And the second directly during use 12 7. Equipment according to any of the claims 120-121, where the filter contains disks of a opaque substance. For the reduction of ultraviolet light intensity at the center of such compression. Compared with the intensity of the aforementioned ultraviolet light reaching the edge of such compression 12 8. Device according to one of the claims 120-121, where the filter consists of a ring of opaque substance. For the reduction of ultraviolet light intensity that achieves the edge of the relative compression section. With the intensity of the ultraviolet light reaching the center of such compression 12 9. Equipment according to any of the claims 120-121, where the filter will consist of A transparent sheet material with a large amount of ultraviolet light-absorbing shape is printed on it.13 0. Equipment according to any of the claims 120-121, where the filter will consist of A large amount of ultraviolet-absorbent shape transparent sheet material is printed on it. And where the density per unit area of the shape It is the minimum at the point corresponding to the distance between the first compression components. And where the perimeter of the geometry is the maximum value at the point corresponding to the shortest distance between the first and second compression. 13 1. Equipment according to any of the claims 115,116,117,123 or 124 where the device will be operational for curing. A mixture of a liquid lens to make an eyeglass lens that takes less than an hour 13 2. Equipment according to any of the claims 115,116,117,123 or 124 where the device also contains a connected air cooler. To provide air below 20 c to the diffuser during operation 13 3. System for making plastic eyeglass lenses consisting of (i) equipment for making lenses Containing One compression surface with a molded face and a non-molded face. A second extrusion with a molded face and a non-molded face. This second compression unit is spaced from the first during operation. In such a way that the aforementioned casting surfaces of the first and second extrusions define the molded cavity. Generating light generator And to provide ultraviolet light directly connected to at least one of the aforementioned first and second compression parts during operation. Connected air diffuser To allow air directly to pass through the non-molded face of the first compression part during use And through the non-molded surface of the second compression part during use and where the diffuser It consists of an air jet with a cylindrical cavity. These openings contain many openings approximately the circumference of the air chamber. With cylindrical cavity Which there are many openings in the approximate range The circumference of the said cavity And that channel is positioned relative to the aforementioned compression section In order to direct air from the opening to the unfastened surface of the aforementioned compression part during use, and (ii) a mixture used to make a modified lens for curing into a deformed lens. Eye quality solids when cured in such devices where the system can be modified to incubate the lens composition to make the optical quality solid lenses over time. That is less than an hour 13 4. A system for making plastic eyeglass lenses that includes (i) Equipment for making lenses consisting of One compression surface with a molded face and a non-molded face. A second extrusion with a molded face and a non-molded face. The second compression will have some distance from the first compression during use. In such a way that the aforementioned casting surfaces of this first and second compression form a molded cavity. Generating light generator And to provide ultraviolet light directly connected to at least one of the aforementioned first and second compression parts during operation. Connected air diffuser To pass air directly through the unmolded face of the first compression part during operation and through the unmolded face of the second compression during use. And where the diffuser consists of a coolant for air conditioning, it consists of an air jet with a cylindrical cavity with a number of openings. That is approximately the circumference of the channel and that channel is positioned relative to the first compression part. In order to direct air from the opening to the non-molded face of the first compression During operation, and (ii) a mixture used to make a modified lens to cure solid lenses of quality only when cured in the apparatus and where the system can be modified to cure the resulting mixture. Used to make a solid lens of quality to the eye in less than an hour 13 5. A plastic lens-making system consisting of (i) Equipment for making lenses consisting of A prefabricated compression with a cast face, a concentric and edged unmolded face. Second extrusion with a molded surface And a non-molded face with a thin center and a second compression edge There will be some distance from the first compression part during application in such a way that the aforementioned casting surfaces of this first and second compression form a molded cavity. Generating light generator And to direct ultraviolet light to at least one of the aforementioned first and second compression parts during operation. Connected air diffuser To pass air directly through the unmolded surface of the first compression during use and through the non-molded face of the second compression during use. And where the diffusers are positioned relative to the aforementioned first and second compressions. In order to direct air from the edge to the center of the non-molded face of the part one compression during operation. And from the edge to the center of the non-molded face of the second extrusion during use 13 6. System according to one of the claims 133-134, in which the non-molded surfaces of the first and second compressions have center and edge. And where the diffusers are positioned relative to the aforementioned first and second compressions in order to direct air from the edge to the center of the non-molded face of the first compression part. During operation and from the edge to the center of the non-molded face of the second extrusion during use 13 7. System of claim 133 where the diameter of the opening in the air jet varies approximately the circumference of the compartment.13 8. The system of claim 137, where the air inlet, consists of an intake pipe. And the diameter of the said opening is the lowest value when it is close to the inlet pipe. And the diameter of the opening is the highest at the point in the circumference of the opening opposite the minimum diameter. 13 9. System of claim 134 where the air cooler is connected to provide air below 20 c to the diffuser during operation 14 0. The system of claim 135 where the diffusers will consist of an air cooler to cool the air to a temperature below the ambient temperature during use. 1. System of claims 133-135 and 140 where the mixture will contain photoreceptors. And at least one polyethylene-functional monomer with a group At least two groups of unsaturated ethyllicol are selected from acrylills. And Methacryilil And where the mixture can be cured, exposing to ultraviolet light. To make clear lenses for glasses in less than an hour 14 2. Any claim based system of Articles 133-135 and 140 where the ingredients There will be at least one polyethylene-functional monomer with at least two unsaturated ethylene-ethylene groups selected from the acrylion. T And methacrylil and aromatic bis (Illil Carbonate) - Functional Monomer And where the mixture is cured, exposed to ultraviolet light to make clear eyeglass lenses In less than an hour 14 3. One of the claim systems of Articles 133-135 and 140 in which the mixture is cured to form clear eyeglass lenses. It has a thickness of more than 1.5 mm and is free from cracks, breaks, streaks and streaks, and has a slight iridescent and slight shadow. (Regardless), all of which happen in less than an hour. When exposed to ultraviolet light, size less than 10 milliwatts per square centimeter. While in the compression cavity 14 4. Any of the claim systems of Articles 133-135 and 140 where the mixture, when cured, It can be separated from the glass template by hand in a non-stick case. 5. One of the claim systems of Articles 133-135 and 140 also consist of an ultraviolet filter mounted between the light source and the aforementioned compression chamber. During use and between the aforementioned light generator and compression during operation 14 6.System according to claim 145, where the filter contains a disintegrating effect for the reduction of the ultraviolet intensity at the center of the compression as compared to the intensity of the light. Such ultraviolet reaches the edge of the compression. 14 7. System according to claim 145, where the filter consists of a ring of opaque matter for the reduction of the ultraviolet intensity that reaches the edge of the compression component relative to the ultraviolet intensity. The aforementioned violet seal that attains the center of the compression