SU1381128A1 - Versions of polymer composition - Google Patents

Abstract

1. A polymer composition for producing films based on a thermoplastic polymer containing a chemical additive, characterized in that, in order to increase the absorption of the UV portion and increase the red component of solar radiation, the composition contains a European compound as a chemical additive selected from the group including EU (NO) J Hairdryer, where Hair Dryer is 1.10-phenanthroline, EuCl, is STTOFO, where TOFO is trioctylphosphine oxide, in the following ratio, wt.%: Polymer 99.00-99.99 Euro 0.01 - 1.00 2. Polymer composition for p of producing films based on a thermoplastic polymer containing a chemical additive, characterized in that, in order to increase the absorption of the UV portion and increase the proportion of the red component of solar radiation, the composition contains a europium compound selected from the group Ei (HFAA) s Hair dryer, where HFAA is hexafluoroacetylacetone. Hair dryer - 1,10-phenanthroline, Eu (TTA) DP, where TTA is tenoyltrifluoroacetone, DP - 2,2-dipyridyl, EudTA) phen, where TTA is tenoyltrifluoroacetone. Hairdryer - 1,10-phenanthroyl, Eu (BTFA) Fairy, where BTFA is benzoyl trifluoroacetone. Phenol - 1, 10- (ijeHaHTpo-LIN, Eu (DBM) s- 2DGSO, where DBM is dibenzoylmethane, DGSO is dihexyl sulfide oxide, in the following ratio, wt.%: Polymer 99,000-99,999 Europium 0,001- 1,000 3. Polymer composition for producing Ma-based thermoplastic composites with 00 to OC

Description

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of a polymer that contains a chemical additive, which, in order to increase the absorption of the UV part and increase the proportion of the red component of solar radiation, as a chemical additive, the composition contains the euro compound PII selected from the group including Eu (NOj) 3 3 TBP, where TBP is tributyl phosphate, EuCli 3 НСО, where НСО - oil sulfoxides of the formula R SO, where R is a hydrocarbon radical, with the following ratio of components, wt.%: Polymer 99.0-99.9

Connection europi 0.1-1.0

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4 The polymer composition for producing films based on a thermoplastic polymer containing a chemical additive, characterized in that, in order to increase the absorption of the UV portion and increase the proportion of the red component of solar radiation, the compound Europe contains EuClj 3 DHSO , where DGSO is dihexyl sulfoxide, with the following ratio of components, wt.%:

Polymer Compound Europium

98.0-99.9 0.1-2.0

one

The invention relates to new materials, namely, polymer compositions for the preparation of films based on thermoplastic polymers, active luminescent compounds, which can be used in greenhouse and greenhouse facilities.

The purpose of the invention is to increase the absorption of the UV-part and increase the proportion of the red component of solar radiation.

The invention is illustrated by the following examples.

Example I. Polymer polyethylene coating containing the active chemical additive EXiCNOj), x X Hair dryer, is obtained by impregnating a facet of polyethylene with a 10% solution of the active chemical additive in acetone followed by evaporation of the acetone. Thereafter, a film is produced from the obtained polyethylene granules by rolling. When the content of the components in the polymer coating is in a ratio of 99% by weight of PE and 1% by weight of Eu (NOj), the hair dryer absorbs 99% of the UV portion of the spectrum in the 350-380 nm region with the transformation of the absorbed UV light 62% and translucency films in the region of 580-700 nm 73%.

Example 2. It is similar to Example I, except that the ratio of the active additive and PE is 0.01: 99.99. With the content of components in the polymer coating in this ratio, it absorbs 90% of the ultraviolet part of the spectrum in the region of 350-380 nm with a transformation of the absorbed Y-light of 71% and a transmittance film in the region of 580-700 nm 74%.

Example 3. It is similar to example 1, except that the ratio of active additive and PE is 0.2: 99.8. When the content of the components in the polymer coating in this ratio, it absorbs 97% In 1 part of the spectrum in the region of 350-380 them with a transformation of the absorbed light of 69% and film transparency in the region of 580-700 nm 78%.

Example 4. Polymer polyvinyl chloride coating is prepared analogously to example 1 by impregnating PVC granules with a 10% active chemical additive solution in acetone, followed by a film. With the content of components in the polymer coating in the ratio of PVC to the active chemical additive of 99.6: 0.4, it absorbs 96% of the UV portion of the spectrum in the region of 350–380 nm with a transformation value of absorbed UV light of 69% and film transparency in the region of 580 -700 nm 79%.

Example 5. Similar to example 4, except that the polymer coating contains PVC and active0

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99.9: 0.1. It absorbs 93% of the UV part of the spectrum in the region of 350–380 with the transformation of absorbed UV light of 72% and film transparency in the region of 580–700 nm 75%.

Example 6. Similar to example 4, except that the polymer coating contains PVC sieve and active additive in the ratio of 99.2:: 0.8. It absorbs 98% of the UV portion of the spectrum in the region of 350–380 nm, with the magnitude of the transformation of the absorbed U 1 -light 65% and the transparency of the film in the region of 580–700 nm of 76%.

Example 7. Similar to example 1, except that they obtain a polymeric polypropylene coating containing G1 and active chemical additive in the ratio of 99.0: 1.0. It absorbs 99% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 64% and the film transparency in the region of 580-700 nm of 74%.

Example 8. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio of 99.99: 0.01. It absorbs 91% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 72% and the transparency of the film in the region of 580-700 nm of 73%.

Example 9. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio 99.85: 0.15. It absorbs 98% of the UV portion of the spectrum in the 350-380 nm region with the magnitude of the transformation absorbed UV radiation 68% and film transparency in the region of 580-700 nm 75%

Example 10. A polystyrene coating containing an active chemical additive is obtained by dissolving the additive in the monomer and its subsequent polymerization. Poly

dimensional coating contains PS and active chemical additive in the ratio of 99.9: 0.1. It absorbs 99% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV radiation of 64% and translucent film in the region of 580–700 nm of 70%. Example 11. Analogous to example 10, except that the polymer coating contains PS and is active

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; iyi. chemical additive in the ratio of 99.99: 0.01. It absorbs 93% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 64% and a translucency of the film in the area of 580–700 nm of 70%.

Example 11 a. Similar to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.99: 0.01. It absorbs 93% of the UV portion of the spectrum in the region of 350 ± 380 nm with a transformation of the absorbed UV radiation of 74% and film opacity in the region of 580-700 nm of 71%.

Example 12, similar to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.95: 0.05. It absorbs 99% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 69% and film transparency in the region of 580-700 nm of 73%.

Example 13. Similar to example 10, except that receive a polymer coating containing PMMA and active chemical additive in the ratio of 99.95: 0.05. It absorbs 99% of the UV portion of the spectrum in the region of 350–380 nm, with a transformation of absorbed UV radiation of 68%, and film transparency in the region of 580–700 nm, 72%.

Example 14, Analogous to Example 13, except that the polymer coating contains PMMA and the active chemical additive in a ratio of 99.99: 0.01. It absorbs 94% of 1 part of the spectrum in the region of 350 - 380 nm with a magnitude of transformation of the absorbed UV radiation of 72% and film transparency in the region of 350-700 nm of 66%.

Example 15., Similar to example 13, except that the polymer coating contains PMMA and active chemical additive in the ratio of 99.9: 0.1. It absorbs 99% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 63% and film transparency in the region of 580-700 nm of 63%.

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Example 16. A polymer coating based on a Copolymer (30% PS and 70% HGMMA), containing its active chemical additive, is prepared by dissolving the europium compound in a mixture of styrene and methyl methacrylate monomers, taken in a ratio of 3: 7, followed by polymerization. The resulting coating contains a copolymer (30% PS + 70% PMMA) and an active chemical additive in a ratio of 99.9:: 0.1. It absorbs 99% of the UV portion of the spectrum in the region of the ZZO-ZZO nm with a transformation of the absorbed UV radiation of 62% and the transparency of the red component (580-700 nm) 64%.

Example 17. Analogous to example 16, except that the polymer coating contains a copolymer and an active chemical additive in a ratio of 99.95: 0.05. It absorbs 99% V-part of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 68% and light transparency in the region of the red component (380-700 nm) 73%.

Example 18. Similar to Example 16, except that the polymer coating contains a copolymer and a chemical additive in a ratio of 99.99: 0.01. It absorbs 92% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 71% and light transparency in the region of the red component (589-700 nm) of 65%.

The europium compound Eti (NOj) used as an active additive .j X -phene intensively absorbs UV radiation, does not violate the transparency of the polymer in the visible region, and intensely luminesces in the region of 580-700 H

The luminescent europium compounds in the region of 580-700 nm, intensively absorbing UV light, transform it into the red region, thereby improving the energy characteristics of the films. This property of the proposed polymer coatings is useful, since it is the red area that is the region of intensive light absorption by plants, which contributes to the acceleration of the growth and maturation of agricultural crops.

Optical properties of polymer films activated by Eu (NO j) s x X Hairdryer (thickness of PE, PVC, PP film

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0.15 mm, thickness of PS, PMMA and copolymer 3 mm), are given in table. one,

The range of quantitative content of the luminescent additive in the proposed polymer compositions is chosen empirically, the choice is due to the fact that when the content of the additive is below the specified limit, the intensity of the glow decreases sharply (to 30-40%), and the increase in the content of the specified limits for each polymer base results to a decrease in light transmittance to 40: -50%.

Example 19. Polymer polyethylene coating containing active chemical additive Eu (HFAA x X Hair dryer) is obtained by impregnating polyethylene granules with a 10% solution of an active chemical additive in acetone followed by evaporation of acetone. Thereafter, a film is produced from the obtained polyethylene granules by rolling. When the content of the components in the polymer coating in the ratio of 99 wt.% PE and I wt.% E a (HFAA) Hairdryer it absorbs 99% of the ultraviolet part of the spectrum in the region of 350-380 nm with an amount of transformation of the absorbed UV light of 70% and film transparency in area 580-700 nm 77%.

Example 20. It is similar to Example 1, except that the ratio of the active additive and PE is 0.01: 99.99. With the content of components in the polymer coating in this ratio, it absorbs 91% of the ultraviolet part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 79% and the light transmittance of the film in the region of –580–700 nm and 76%.

Example 21. Similar to example 1, except that the ratio of the active additive and PE is 0.6: 99.4. When the content of the components in the polymer coating in this ratio is, it absorbs 97% of the ultraviolet part of the spectrum in the region of 350–380 nm, with a transformation of the absorbed UV light of 74% and a translucency of the film in the region of 580–700 nm, 80%.

Example 22. Polymer vinyl chloride coating is prepared analogously to example 1 by impregnation

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PVC granules with a 10% solution of an active chemical additive in acetone with the following preparation of a film. When the content of components in the polymer coating in the ratio of PVC to the active chemical additive is 99.7: 0.3, it absorbs 98%. The UV part of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV light of 72% and a film transparency in the region of 580-700 nm is 77%.

Example 23. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.93:: 0.07. It absorbs 96% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 75% and film transparency in the region of 580–700 nm.81%.

Example 24. Similar to example 4, except that the poly ™ dimensional coating contains PVC and the active additive in a ratio of 99.98: 0.02 It absorbs 93% of the UV portion of the spectrum in the 350-380 nm region with the magnitude of the transformation of the absorbed UV light 78% and film transparency in the region of 580-700 nm 78%.

Example 25. Similar to example 1, except that receive polymeric polypropylene coating containing W1 and active chemical additive in the ratio of 99.75: 0.25. It absorbs 99% of the UV spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 70% and the translucency of the film in the region of 580–700 nm of 76%.

Example 26. Similar to Example 7, except that the dimensional coating contains PP and akti; - chemical additive in the ratio of 99.95: 0.02. It absorbs 90% of the UV spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 78% and the translucency of the film in the region of 580–700 nm of 77%.

Example 27. Similar to Example 7, except that the polymer coating contains PP and an active chemical additive in a ratio of 99.9: 0.1. It absorbs 96% of the UV part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV radiation of 74% and light transparency of the film in the region of 580–700 nm of 82%.

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Example 28. A polystyrene coating containing the active chemical additive is obtained by dissolving the additive in the monomer and its subsequent polymerization. The polymer coating contains PS and an active chemical additive in the ratio of 99.99: 0.01. It absorbs 90% of the UV portion of the spectrum in the region of 350-D80 nm with a transformation of the absorbed UV radiation of 77% and film co-transparency in the region of 580-700 nm of 78%.

Example 29. Similar to Example 10, except that the polymer coating contains PS and the active chemical additive in a ratio of 99.97: 0.03. It absorbs 94% of the UV part of the spectrum in the region of 350 ± 380 nm with a magnitude of transformation of the absorbed UV radiation of 72% and film opacity in the region of 580-700 nm of 83%.

Example 30. Similar to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.95: 0.05. It absorbs 98% of the UV spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 67% and film translucency in the region of 580–700 nm of 79%.

Example 31. Similar to Example 10, with the exception that a polymer coating g is prepared, containing also an active chemical additive in a ratio of 99.95: 0.05. It absorbs 99% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 70% and film transparency in the region of 580-700 nm of 83%.

Example 32. Similar to the example of 13, except that the polymer coating contains PMMA and the active chemical additive in the ratio of 99.999: 0.001. It absorbs 90% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 78% and the luminosity of the film in the region of 580-700 nm of 83%.

Example 33 .. Similar to example 13, except that the polymer contains PMMA and the active chemical additive in a ratio of 99.98: 0.02. It absorbs 95% of the UV spectrum in the 350 -

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380 nm with a magnitude of transformation of absorbed UV radiation of 73% and light transparency of the film in the region of 580-700 nm of 88%.

Example 34. A polymer coating based on a copolymer (30% PS and 70% IIMMA) containing an active chemical additive is obtained by dissolving the europium compound in a mixture of styrene and methyl methacrylate monomers taken in a ratio of 3: 7, followed by polymerization -. The resulting coating contains a copolymer (30% PS + + 70% PMMA) and an active chemical additive in the ratio of 99.95: 0.05. It absorbs 98% of the UV portion of the spectrum in the region of 350-380 with a transformation of 70% absorbed UV radiation and a translucency of 81% in the red component (580-700 nm).

Example 35. Similar to Example 16, except that the polymer coating contains a copolymer and a chemical additive in the ratio of 99.999: 0.001. It absorbs 90% of the UV portion of the spectrum in the region of 330-380 nm with a magnitude of transformation of the absorbed UV radiation of 79% and a translucency in the region of the red component (580-700 nm) of 82%.

Example 36. Similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in the ratio of 99.97: 0.03. It absorbs 94% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 73% and a luminosity in the region of the red component (580–700 nm) of 85%.

The Europium Eu (HFAA) compound used as an active additive is xxXFen absorbs UV radiation intensively, does not violate the transparency of the polymer in the visible region, and intensely luminesces in the region of 580 700 nm.

The optical properties of polymer films activated by Her (HFAA) 3 x X Phen (film thickness of PE, PVC, PP 0.15 mm, thickness of PS, PMMA and copolymer 3 mm) are listed in Table. 2

The range of quantitative content of the luminescent additive in the proposed polymer compositions is chosen empirically. Choice of

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This is explained by the fact that when the content of the additive is below the specified limit value, the intensity of the glow decreases sharply (to 30-40%), and an increase in c (higher than the specified limits for each polymer base leads to a decrease in light transmittance to 40-50%.

Example 37. Polymer polyethylene coating containing the active chemical additive Her (TTA) x X DP is obtained by impregnating the polyethylene granules with a 10% solution of the active chemical additive in acetone followed by evaporation of the acetone. Thereafter, a film is produced from the obtained polyethylene granules by rolling. When the content of components in the polymer coating in the ratio of 99 wt.% PE and 1 wt.% Her (TTA), x X DP, it absorbs 98% of the UV part of the spectrum in the region 350-380 nm with the magnitude of the transformation of the absorbed UV light 67% and film translucency in the region of 580-700 nm 78%.

Example 38. Similar to example 1, except that the ratio of active additive and PE is 0.01: 99.99. With the content of components in the polymer coating in this ratio, it absorbs 89% of the UV part of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV light of 76% and film transparency in the region of 580-700 nm of 77%.

Example 39. Similar to example 1, except that the ratio of the active additive and PE is 0.5: 99.5. With the content of components in the polymer coating in this ratio, it absorbs 95% of the UV part of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV light of 69% and film transparency in the region of 580-700 nm of 78%.

Example 41. Similar to example 4, except that the polymer coating contains PVC and active additive in a ratio of 99.9: 0.1. It absorbs 95% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 73% and film transparency in the region of 580–700 nm of 81%.

Example 42. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.95: 0.05.

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It absorbs 90% of the UV portion of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV light of 77% and film transparency in the region of 580–700 nm of 78%.

Example 43. It is similar to Example 1, except that a polymeric polypropylene coating is obtained containing PP and an active chemical additive in a ratio of 99.0:: 1.0. It absorbs 99% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 67% and a film transparency in the region of 580-700 nm of 78%.

Example 44. Similar to example 7, except that the polymer coating contains PCS and an active chemical additive in the ratio of 99.99: 0.01. It absorbs 90% of the UV part of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV-T1 radiation of 75% and film transparency in the region of 580-700 nm 80%

Example 45. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio of 99.4: 0.6. It absorbs 96% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 72% and film transparency in the region of 580–700 nm of 83%.

Example 46. A polystyrene coating containing an active chemical additive is obtained by dissolving the additive in the monomer and then polymerizing it. The polymer coating contains PS and an active chemical additive in the ratio of 99.9: 0.1. It absorbs 92% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of absorbed UV radiation of 76% and film transparency in the region of 580–700 nm of 79%.

Example 47. It is similar to Example 10 with the exception that the polymer coating contains PS and the active chemical additive in the ratio of 99.85: 0.15. It absorbs 97% of the UV portion of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 72% and a film with a translucency of 580–700 nm of 82%.

Example 48, similar to example 10, except that the polymer coating contains PS and AK

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tive chemical additive in the ratio of 99.75: 0.25. It absorbs 99% of the UV portion of the spectrum in the region of 350 - 380 nm with a magnitude of transformation of the absorbed UV radiation of 68% and a film transparency in the region of 580-700 nm of 78%.

Example 49. Similar to Example 10, except that a polymer coating is obtained containing PMMA and an active chemical additive in a ratio of 99.95: 0.05., It absorbs 96% of the UV portion of the spectrum in the 350-380 nm region with the magnitude of the transformation of the absorbed UV radiation is 67% and film translucency in the region of 580-700 nm is 82%.

Example 50. Similar to example 13, except that the polymer coating contains PMMA and active chemical additive in the ratio of 99.999: 0.001. It absorbs 87% of the UV portion of the spectrum in the 350-380 nm region, with a magnitude of transformation of the absorbed UV radiation of 76% and a film translucency in the 580-700 nm region, 81%.

Example 51. Similar to example 13, except that the polymer coating contains PMMA and the active chemical additive in the ratio of 99.98: 0.02. It absorbs 93% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 71% and film opacity in the region of 580-700 nm of 86%.

Example 52. A polymer coating based on a copolymer (30.P.P. and 70% PMMA) containing an active chemical additive is prepared by dissolving the europium compound in a mixture of styrene and methyl methacrylate monomers, taken in a ratio of 3: 7, followed by polymerization . The resulting coating contains a copolymer (30% PS + 70% PMMA) and an active chemical additive in the ratio of 99.9: 0.1. It absorbs 98% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of absorbed UV radiation of 67% and translucency in the region of the red component (580-700 nm) of 79%.

Example 53. Similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in

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the ratio of 99.999: 0.001. It absorbs 90% of the UV part of the spectrum in the region of 350-380 with the transformation of the absorbed UV radiation of 74% and translucency in the region of the red component (580-700 nm) 80%.

Example 54. Similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in wearing 99.94: 0.06. It absorbs 95% of the UV portion of the spectrum in the region of 350 - 380 nm with a transformation of the absorbed UV radiation of 72% and light transparency in the region of the red component (580-700 nm) of 83%.

Used as an active additive, the Europium Eu compound (TTA), x X DG1, intensively absorbs UV radiation, does not violate the transparency of the polymer in the visible region, and intensively luminesces in the region of 580–700 nm.

Optical properties of polymer films activated by Eu (TTA) s-DP (film thickness of PE, PVC, PP 0.15 mm; tolprl on PS, PMMA and copolymer 3 mm),

are given in table. 3

The range of quantitative content of the luminescent additive in the proposed polymer compositions is chosen empirically. The choice is due to the fact that when the content of the additive is below the specified limit, the intensity of the glow decreases sharply (to 30-40%), and an increase in the content of more than the specified limits for each polymer base leads to a decrease in translucency to 40-50%.

- Example 55. A polymer poly ethylene coating containing the active chemical additive Eu (TTA) -xF fairies is obtained by impregnating polyethylene granules with a 10% solution of the active chemical additive in acetone and subsequent evaporation of acetone. Thereafter, a film is produced from the obtained polyethylene granules by rolling. When the content of the components in the polymer coating in the ratio of 99% by weight of PE and 1% by weight of Eu (TTA) t, x X Phen, it absorbs 98% of the UV portion of the spectrum in the 350-380 nm region with a transformation of the absorbed UV light of 70% and translucency of the film in the region of 580–700 nm 80%.

Example 56. Analogous to Example 1, with the exception that

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wearing the active additive and PE is taken from 0.01: 99.99. When the content of the components in the polymer coating in this ratio, it absorbs 89% of the UV part of the spectrum in the region of 350-380 nm with an amount of transformation of the absorbed UV light of 86% and a film transparency in the 580-700 nm region of 77%.

Example 57. Similar to example 1, except that the ratio of active additive and PE is 0.1: 99.9. With the content of components in the polymer coating in this ratio, it absorbs 94% of the UV portion of the spectrum in an area of 350–380 nm with a transformation of the absorbed UV light of 76% and a film translucency in the region of 580–700 nm of 82%.

Example 58. Polymer irrigation of an chloride chloride coating is prepared analogously to example 1 by impregnating PVC granules with an I0% solution of an active chemical additive in acetone, followed by the preparation of a film. When the content of components in the polymer coating in the ratio of PVC to the active chemical additive is 99.5: 0.5, it absorbs 97% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV light of 80% and film transparency in the region of 580- 700 nm 81%.

Example 59. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.9: 0.1. It absorbs 90% of the UV portion of the spectrum in the region of 350–380 nm, with a transformation of the absorbed UV light of 88% and a film transparency in the region of 580–700 nm of 82%.

Example 60. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.7:: 0.3. It absorbs 93% of the UV part of the spectrum in the region of 350–380 nm with the magnitude of the transformation of the absorbed light of U 84% and the transparency of the film in the region of 580–700 nm 89%.

Example 61 Similar to example 1, except that a polymeric polypropylene coating is obtained containing PP and an active chemical additive in the ratio of 99.0: 1.0. It absorbs 96% of the UV spectrum in the region of 350-380 nm with a magnitude

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78% of the absorbed transformations and a film translucency in the region of 58 (7700 nm, 77%.

Example 62. It is similar to example 7, except that the polymer coating contains PP and an active chemical additive in a ratio of 99.99: 0.01. It absorbs 91% of the spectrum in the region of nm with a transformation of the absorbed UV radiation 87 and the translucency of the film in the region of 580-700 nm of 79%.

Example 63. It is similar to Example 7, except that the polymer coating contains PP and an active chemical additive in a ratio of 99.9: 0.1. It absorbs 9A% of the UV portion of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 83% and a film translucency in the region of 580–700 nm of 82%.

Example 64. A polystyrene coating containing an active chemical additive is obtained by dissolving the additive in the monomer and its subsequent polymerization. The polymer coating contains PS and active chemical additive in the ratio of 99.9: 0.1. It absorbs 96% of the UV spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 70% and film transparency in the region of 580-700 nm 77%.

Example 65, Similar to Prgmer 10, except that the polymer coating contains PS and an active chemical additive in the ratio of 99.975: 0.025. It absorbs 88% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 79% and film opacity in the region of 580–700 nm of 79%.

Example 66. It is similar to example 10, except that the polymer coating contains PS and an active chemical additive in a ratio of 99.95: 0.05. It absorbs 93% of the Y-part of the spectrum in the range 350 - 380 nm with the magnitude of the transformation of the absorbed At 1 shot, 73% and film transparency in the 580–700 nm region are 83%.

Example 67. Similar to Example 10, with the exception that a polymer coating is obtained containing PMMA and the active chemical additive in a ratio of 99.95: 0.05. It swallowed

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 98% of the UV part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV radiation of 70% and film opacity in the region of 580–700 nm of 80%.

Example 68. Similar to example 13, except that the polymer coating contains PMMA and the active chemical additive in the ratio of 99.999: 0.001. It absorbs 89% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed radiation of 78% and a film transparency in the region of 580-700 nm of 82%.

Example 69. Similar to npir-measure 13, except that the polymer coating contains PMMA and the active chemical additive in a ratio of 99.98: 0.02. It absorbs 96% of the UV portion of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 74% and a film transparency of 580–700 nm of 92%.

Example 70. A polymer coating based on a copolymer (30% PS and 70% PMMA) containing an active chemical additive is prepared by dissolving the europium compound in a mixture of styrene and methyl methacrylate monomers, taken in a ratio of 3: 7, followed by polymerization . The polymer coating contains a copolymer (30% PS + 70% PMMA) and an active chemical additive in the ratio of 99.9: 0.1. It absorbs 97% of the UV portion of the spectrum in the region of 350-380 nm, with a transformation of the absorbed UV radiation of 68% and translucency in the region of the red component (580-700 nm) of 82%.

Example 71. Similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in the ratio of 99.999: 0.001. It absorbs 88% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 76% and light transparency in the region of the red component 80% (580-700 nm).

Example 72. Similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in the ratio of 99.96: 0.04. It absorbs 94% of the UV part of the spectrum in the 350-

50

171

380 nm with a transformation of the absorbed UV ™ radiation of 73% and light transparency in the region of the red component (580-700 nm) 86%.

Used as an active additive, the europium compound (STDTL), X Hairdryer intensively absorbs UV radiation, does not violate the transparency of the polymer in the visible region, and intensely luminesces in the region of 580–700 nm.

The optical properties of polymer films activated by Eu (TTA) 5 Phen (film thickness of PE, PVC, PP 0.15 mm; thickness PS, GOMA and copolymer 3 mm) are listed in Table. four.

The range of quantitative content of the luminescent additive in the proposed polymer compositions is chosen empirically. The choice is due to the fact that when the content of the additive is below the specified limit value, the intensity of the glow decreases sharply (to 30-40%), and the increase in the content of the above limits for each polymer base leads to a decrease in light transmittance to 40-50%.

Example 73. A polymeric polyethylene coating containing an active chemical additive for Her (BTFA) x X Hairdryer is obtained by impregnating polyethylene granules with a 10% solution of an active chemical additive in acetone followed by evaporation of acetone. Thereafter, a film is produced from the obtained polyethylene granules by rolling. When the content of the components in the polymer coating is in the ratio of 99% by weight PE and 1% by weight to Eu (it absorbs 99% of the UV portion of the spectrum in the 350-380 nm region with a transformation of the absorbed UV light of 66% and film transparency in the 580 region -700 nm 77%.

Example 74. Similar to Example 1, except that the ratio of the active additive and PE is 0.01: 99.99. With the content of components in the polymer coating in this ratio, it absorbs 91% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 77% and film transparency in the region of 580–700 nm of 75%.

Example 75, similar to example 1, except that the ratio of active additive and PE is taken

five

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five

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0.05: 99.95. With the content of components in the polymer coating in this ratio, it absorbs 96% of the UV part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 71% and film transparency in the region of 580–700 nm of 81%.

Example 76 A polymer polyvinyl chloride coating is prepared analogously to example 1 by impregnating PVC granules with a 10% solution of an active chemical additive in acetone, followed by a film. When the content of components in the polymer coating in the ratio of PVC and the active chemical additive is 99.5: 0.5, it absorbs 99% of the UV portion of the spectrum in the region of 350-380 nm with a transformation value of the absorbed UV light of 76% and film transparency in the region of 580- 700 nm 77%.

Example 77. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.9: 0.1. It absorbs 92% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 88% and film transparency in the region of 580–700 nm of 78%.

Example 78. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.7: 0.3. It absorbs 96% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 82% and film transparency in the region of 580–700 nm of 81%.

Example 79. It is similar to Example I, except that a polymeric polystyrene polymer coating is obtained, containing PP and an active chemical additive in a ratio of 99.0:: 1.0. It absorbs 98% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 80% and film transparency in the region of 580-700 nm of 83%.

Example 80. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio of 99.99: 0.01. It absorbs 90% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 89% and a film transparency in the region of 580-700 nm of 82%.

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Example 81. It is similar to example 7, except that the polymer coating contains PP and the active chemical additive in a ratio of 99.94: 0.06. It absorbs 94% of the UV spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 85% and the film transparency in the region of 580–700 nm of 86%.

Example 82. A polystyrene coating containing an active chemical additive is obtained by dissolving the additive in the monomer and its subsequent polymerization. The polymer coating contains PS and the active chemical additive in the ratio of 99.9: 0.1. It absorbs 88% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 75% and film transparency in the region of 580-700 nm of 79%.

Example 83. Similar to example 10, except that the polymer coating contains PS and the active chemical additive in a ratio of 99.8: 0.2. It absorbs 93% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 71% and film transparency in the region of 580–700 nm of 84%.

Example 84. Similar to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.65: 0.35. It absorbs 97% of the UV spectrum in the region of 350-380 with a transformation of absorbed UV radiation of 68% and film transparency in the region of 580-700 nm 80%

Example 85. Similar to Example 10, with the exception that a polymer coating is obtained containing PMMA and an active chemical additive in a ratio of 99.95: 0.05. It absorbs 97% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 66% and film transparency in the region of 580-700 nm 80Z.

Example 86. Similar to Example 13, except that the polymer coating contains PMMA and ak. mud chemical additive in the ratio of 99.999: 0.001. It absorbs 88% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of the transformation of the absorbed UV radiation of 75% and

5 Q

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film transparency in the region of 580-700 nm 81%.

Example 87. It is similar to Example 13, except that the polymer coating contains PMMA and the active chemical additive in a ratio of 99.98: 0.02. It absorbs 93% of the UV part of the spectrum in the region of 350 ± 380 nm with a transformation of the absorbed UV radiation of 70% and a film brightness of 83% in the region of 580-700 nm.

Example 88. A polymer coating based on a copolymer (30% PS and 70% PMMA) containing an active chemical additive is prepared by dissolving the europium compound in a mixture of styrene and methyl methacrylate monomers, taken in a ratio of 3: 7, followed by polymerization. The resulting coating contains a copolymer (30% PS + 70% PMMA) and an active chemical additive in the ratio of 99.9:: 0.1. It absorbs 98% of the UV portion of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 66% and a translucency in the region of the red component (580–700 nm) of 81%.

Example 89. Similar to Example 16, except that the polymer coating contains copolymer and an active chemical additive in the ratio of 99.999: 0.001. It absorbs 86% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 76% and a translucency in the region of the red component (580-700 nm) of 81%.

Example 90. Similar to npir-measure 16, except that the polymer coating contains a copolymer and an active chemical additive in a ratio of 99.96: 0.04. It absorbs 93% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 70% and a translucency in the region of the red component (580-700 nm) of 84%.

The Europium Eu (BTAA) compound used as an active additive is xxXFen absorbs UV radiation intensively, does not violate the transparency of the polymer in the visible region, and intensely luminesces in the nm region.

Optical properties of polymer films activated by Her (BTFA)} x

211X Hair dryer (film thickness of PE, PVC, PI 0.15 mm, thickness PS, 1GMMA and copolymer 3 mm) are listed in Table. five.

Example 91. A polymeric polyethylene coating containing the active chemical additive Eu (DBM) X 2DGSO is prepared by impregnating polyethylene granules with a 10% solution of the active chemical additive in acetone followed by evaporation of the acetone. After that, a film is obtained from the resulting polyethylene granules. rolling When the content of the components in the polymer coating is in a ratio of 99 PE and 1 wt.% She (DBM) 5-2 DGSO, it absorbs 98% of the UV part of the spectrum in the region Z. 0 - 380 nm with a transformation value of 181 absorbed UV light and the light transmittance of the film in the region of 580-700 nm is 77%.

Example 92. It is similar to Example 1, except that the ratio of the active additive and PE is 0.01: 99.99. With the content of components in the polymer coating in this ratio, it absorbs 89% of the UV spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 78% and translucency of the film in the region of 580–700 nm of 78%.

Example 93. It is similar to Example 1, except that the ratio of the active additive and PE is 0.6: 99.4. With the content of components in the polymer coating in this ratio, it absorbs 96% of the UV part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 71% and film transparency in the region of 580–700 nm of 81%.

Example 94. A polymer polyvinyl chloride coating is prepared analogously to example I by impregnating PVC granules with a 10% solution of an active chemical additive in acetone, followed by the preparation of a film. When the content of components in the polymer coating in the ratio of PVC to the active chemical additive is 99.5: 0.5, it absorbs 99% of the UV portion of the spectrum in the region of 350-380 nm with a transformation value of absorbed UV light of 70% and film transparency in the region of 580- 700 nm 79%.

Example 95. Similar to Example 4, with the exception that poly

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2822

dimensional coating contains PVC and active additive in the ratio of 99.8: 0.2. It absorbs 96% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 72% and film transparency in the region of 580–700 nm of 82%.

Example 96. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.95: 0.05. It absorbs 91% of the UV part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 76% and a film transparency in the region of 580–700 nm of 78%.

Example 97. It is similar to Example 1, except that a polymeric polypropylene coating is obtained containing PP and an active chemical additive in a ratio of 99.0: 1.0. It absorbs 99% of the UV portion of the spectrum in the region of 350–380 nm with the magnitude of the transformation of the absorbed Y (1 radiation of 67% and film translucency in the region of 580–700 nm, 79%.

Example 98. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio of 99.99: 0.01. It absorbs 92% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 77% and film transparency in the region of 580–700 nm of 79%.

Example 99. Similar to Example 7 with the exception that the polymer coating contains PP and a chemical additive in the ratio of 99.5: 0.5. It absorbs 97 / part of the spectrum in the region of nm with a transformation of the absorbed UV radiation of 72% and a film translucency in the region of 580-700 nm of 83%.

Example 100. A polystyrene coating containing an active chemical additive is obtained by dissolving the additive in the monomer and then polymerizing it. The polymer coating contains PS and an active chemical additive in the ratio of 99.99: 0.01. It absorbs 90% of the UV part of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 78% and a film translucency in the region of 580–700 nm, 79%.

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Example 101. Similar to example 10, except that the polymer coating contains PS and an active chemical additive in the ratio of 99.84: 0.16. It absorbs 95% of the UV spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 73% and film transparency in the region of 580–700 nm of 83%.

Example 102. Similar to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.7: 0.3. It absorbs 98% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 70% and a film transparency in the region of 580-700 nm of 80%.

Example 103. It is similar to example 10, except that a polymer coating is obtained containing PMMA and an active chemical additive in a ratio of 99.95: 0.05. It absorbs 99% of the U 1 part of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 71% and a translucency of the film in the region of 580–700 nm, 81%.

Example 104. Similar to example 13, except that the polymer coating contains PMMA and the active chemical additive in the ratio of 99.999: 0.001. It absorbs 9 1% of the UCh of the spectrum in the region of 350 - 380 nm with a magnitude of transformation of the absorbed UV radiation of 78% and the luminosity of the film in the region of 580-700 nm of 82%.

Example 105. Similar to example 13, except that the polymer coating contains PMMA and the active chemical additive in the ratio of 99.974: 0.026. It absorbs 96% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 74% and film transparency in the region of 580-700 nm of 86%.

Example 106. A polymer coating based on a copolymer (30% PS and 70% PMMA) containing an active chemical additive is prepared by dissolving the europium compound in a mixture of styrene and methyl methacrylate monomers, taken in a ratio of 3: 7, followed by polymerization. The resulting coating contains a copolymer (30% PS + 70% PMMA) and active chi

28

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formula additive in the ratio of 99.9:: 0.1. It absorbs 99% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 70% and a translucency in the region of the red component (580-700 nm) of 80%.

Example 107. Similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in the ratio of 99.999: 0.001. It absorbs 91% of the Us-part of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 76% and a translucency in the region of the red component (580–700 nm) of 81%.

Example 108. Similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in the ratio of 99.94: 0.06. It absorbs 95% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 73% and translucency in the red component (580-700 nm) of 84%. The compound of europium ( DBM) x X 2 DGSO intensively absorbs UV radiation, does not violate the transparency of the polymer in the visible region and intensely luminesces in the region of 580-700 nm.

The optical properties of polymer films activated by Her (DBM) x X DGSO (film thickness of PE, PVC, W1 0.15 mm; thickness of PS, PMMA and copolymer 3 mm) are listed in Table. 6. The interval of the quantitative content of the luminescent additive in the proposed polymer compositions is chosen empirically. The choice is due to the fact that when the content of the additive is below the specified limit value, the intensity of the glow decreases sharply (to 30-40%), and an increase in the content of these limits for each polymer base leads to a decrease in translucency to AO-50%.

Example 109. Polymer polyethylene coating containing active chemical additive Eu (m6z) eX X ZTBP, is obtained by impregnating polyethylene granules with 10% ns-1 solution of active chemical additive in aceto

25

not followed by evaporation of the acetone. After that, a film is produced from the obtained polyethylene granules by rolling. When the content of the components in the polymer coating is in a ratio of 99% by weight of PE and 1% by weight of Eu (NO3) s STBP, it absorbs 97% of the UV portion of the spectrum in the range 350 - 380 nm with the transformation value of absorbed UV light A0% and The depth of the film in the region of 580 - 700 nm is 71%.

Sample software. Similar to Example I, except that the ratio of the active additive and PE is taken from 0.01: 99.99. When the content of the components in the polymer coating in this ratio is, it absorbs 88% of the UV part of the spectrum in the region of 350–380 nm, with the magnitude of the transformation D1 and absorbed UV light of 54% and the transparency of the film in the region of 580–700 nm 70%.

Example 111. Similar to example 1, except that the ratio of the active additive and PE is taken 0.06: 99.94. With the content of components in the polymer coating in this ratio, it absorbs 94% of the UV part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 45% and the luminosity of the film in the region of 580–700 nm, 73%.

Example 112. A polymer livinyl chloride coating is prepared analogously to the example) by impregnation

PVC granules 10% asset solution

Noah chemical additives in acetone, followed by obtaining a film. When the content of components in the polymer coating in the ratio of PVC and the active chemical additive is 99.5iO, 5, it absorbs 94% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV light of 44% and film transparency in the region of 580-700 nm 72%.

Example 113, similar to example 4 with the exception that the polymer coating contains PVC and the active additive in a ratio of 99.9: 0. It absorbs 90% of the UV part of the spectrum in the 350-380 nm region with a transformation of the absorbed UV light of 48% and the transparency of the film in the region of 580-700 nm is 69%.

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2826

Example 114. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.0: 1.0. It absorbs 98% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 40% and film transparency in the region of 580–700 nm of 68%.

Example 115. Similar to Example 1, except that a polymeric polypropylene coating is prepared that contains GSH and an active chemical additive in a ratio of 99.0: 1.0. - It absorbs 98% of the UV part of the spectrum in the region of 350–380 nm with a magnitude of transformation of absorbed UV radiation of 39% and a translucency (in the region of 580–700 nm) of the film 68%.

Example 116. A similar measure 7, except that the polymer coating contains W1 and active chemical additive in the ratio of 99.99: 0.01. It absorbs 85% of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 51% and a film translucency in the region of 580–700 nm, 67%.

Example 117, similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio of 99.96: 0.04. It absorbs 93% of the UV portion of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 43% and film transparency in the region of 580–700 nm of 71%.

Example 118. A polystyrene coating containing an active chemical additive is obtained by dissolving the additive in the monomer and its subsequent polymerization. The polymer coating contains PS and an active chemical additive in the ratio of 99.9: O, 1. It absorbs 90% of the UV portion of the spectrum in the region of 350-380 nm, with a magnitude of transformation of the absorbed UV radiation of 45% and film transparency in the region of 580-700 nm of 68%.

Example 119. Analogous to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.3: 0.7. It absorbs 93% of the UV spectrum in the region of 350-380 nm with

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the magnitude of the transformation of the absorbed UV-T1 radiation of 42% and the translucency of the film in the region of 580-700 nm

Example 120. It is similar to example 10, except that the polymer coating contains PS and an active chemical additive in the ratio of 99.0: 1.0. It absorbs 96% of the UV portion of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 37Z and film transparency in the region of 580–700 nm of 69%.

Example 121. Analogous to example 10, except that a polymer coating is obtained containing PMMA and an active chemical additive in the ratio of 99.9: 0.1. It absorbs 84% of the UV portion of the spectrum in the 350-380 range with a transformation value absorbed by UV radiation 46% and film transparency in the region of 580-700 to 66%.

Example 122. Similar to example 13, except that the polymer coating contains PMMA and the active chemical additive in the ratio of 99.6: 0.4. It absorbs 91% of the UV portion of the spectrum in the region of 350 - 380 nm with a transform of the absorbed UV radiation of 40% and a film transparency in the region of 580-700 nm of 70%.

Example 123. Similar to example 13, except that the polymer coating contains PMMA and the active chemical additive in the ratio of 99.0: 1.0. Oio absorbs 96% of the UV portion of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 37% and film transparency in the region of 580–700 nm of 67%.

Example 124. A polymer coating based on a copolymer (30% PS and 70% PMMA) containing an active chemical additive is prepared by dissolving a europium compound in a mixture of styrene and methyl methacrylate monomers, taken in a ratio of 3: 7, followed by polymerization. The resulting coating contains a copolymer (30% PS + 70% PMMA) and active chem-. 99.9: 0 ratio. It absorbs 87% of the Us1 -part of the spectrum in the region of 350-380 nm with a magnitude of the transformation of the absorbed UV radiation of 44% and translucency in the region of

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2828

the red component (580-700 nm) is 68%.

Example 125. Similar to example 16, except that the polymer coating contains a copolymer and a chemical additive in the ratio of 99.5: 0.5. It absorbs 92% of the UV portion of the spectrum in the region of 350 - 380 nm with a transformation of the absorbed UV radiation of 41% and a light transparency in the region of the red component (580-7 EO nm) of 71%.

Example 126. Similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in the ratio of 99.0: 1.0. It absorbs 97% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 37% and translucency in the region of the red component (580-700 nm) 67%.

The europium compound Eu (NO.) X i X STBP used as an active additive intensively absorbs UV radiation, does not violate the transparency of the polymer in the visible region, and intensely luminesces in the region of 580–700 nm.

The optical properties of the polymer films activated by Eu (NO,), ZTBP (film thickness of PE, PVC, PP 0.15 mm, thickness of PS, PMMA and copolymer 3 mm) are listed in Table. 7

The range of quantitative content of the luminescent additive in the proposed polymer compositions is chosen empirically. The choice is due to the fact that when the content of the additive is below the specified limit value, the intensity of the glow decreases sharply (to 30-40%), and the increase in the content of the above limits for each polymer base is 1; n1; it leads to a decrease in light transmittance to 40-50%.

Example 127. Polymer polyethylene coating containing the active chemical additive EuCl x X STOPO is obtained by impregnating polyethylene granules with a 10% solution of the active chemical additive in acetone with subsequent evaporation of acetone. Thereafter, a film is obtained from the obtained polyethylene granules by val tsevani. When the content of the components in the polymer coating in the ratio of 99 wt.% PE and 1 wt.% EuCl, ZTFO it absorbs 97% of the UV part of the spectrum

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in the ZZO-ZvO nm region with a transformation of the absorbed UV light of 35% and film transparency in the region of 580-700 nm 75%.

Example 128. It is similar to Example I, except that the ratio of active additive and PE is 0.1: 99.9. When the content of the components in the polymer coating in this ratio is, it absorbs 86% of the UV part of the spectrum in the region of 350–380 with a trace of absorption of UV light of 44% and translucency} of the film in the region of 580–700 nm of 76%,

Example 129. It is similar to Example I, with the exception that the ratio of the active additive and PE is taken as O, 4–99.6. With the content of components in the polymer coating in this ratio, it absorbs 91% of the UV part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 38% and the light transmittance of the film in the region of 580–700 nm of 79%.

Example 130. A polymer polyvinyl chloride coating is prepared analogously to example I by impregnating PVC granules with a 10% solution of an active chemical additive in acetone, followed by a film. With

the content of components in the polymer coating in the ratio of PVC to the active chemical additive of 99.0: 1.0, it absorbs 97% of the UV portion of the spectrum in the region of 350-380 nm with a transformation value of the absorbed UV light of 37% and film transparency in the region of 580-700 nm 75%.

Example 131. Analogous to Example 4, except that the polymer coating contains PVC and the active additive in a ratio of 99.9: 0.1. It absorbs 82% of the UV part of the spectrum in the region of 350–380 nm, with a different transformation of the absorbing UV light of 46% and a film translucency in the region of 580–700 nm of 77%.

Example 132. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.6: 0.4. It absorbs 915 UV parts of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV light of 40% and film translucency in the region of 580–700 nm of 79%.

Example 133. It is similar to Example 1, with the exception that

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ABOUT

five

five

0

A polymeric polypropylene coating containing PP and an active chemical additive in a ratio of 99.0:: 1.0 is prepared. It absorbs 98% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 34% and film transparency in the region of 580-700 nm of 74%.

Example 134. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio of 99.5: 0.5. It absorbs 92% of the UV portion of the spectrum in the region of 350-380 nm, with a magnitude of transformation of the absorbed UV radiation of 39% and a film transparency in the region of 580-700 nm of 77%. ,

Example 135. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio of 99.9: 0.1. It absorbs 85% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 43% and a translucency of film B in the region of 580-700 nm of 74%.

Example 136. A polystyrene coating containing an active chemical additive is obtained by dissolving the additive in the monomer and its subsequent polymerization. The polymer coating contains PS and an active chemical additive in the ratio of 99.5: 0.5. It absorbs 98% of the UV part of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 37% and film transparency in the region of 580-700 nm of 77%.

Example 137. Similar to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.75: 0.25. It absorbs 91% of the UV part of the spectrum in the region of 350 ± 380 nm with a magnitude of transformation of the absorbed UV radiation of 40% and film opacity in the region of 580-700 nm and 81%.

Example 138. Similar to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.95: 0.05. It absorbs 86% of the UV part of the spectrum in the region of 350 ± 380 nm with a transformation of the absorbed UV radiation of 43% and a luminosity of the film in the region of 580-700 nm of 76%.

Example 139. Similar to example 10, with the exception that a polymer coating is prepared containing ITMMA and an active chemical additive in the ratio of 99.99: 0.01. It absorbs 87% of the UV portion of the spectrum in the region of 350–380 nm, with a transformation of the absorbed UV radiation of 44% and film opacity in the region of 580–700 nm of 77%.

Example 140. Similar to example 13, except that the polymer coating contains PMMA and the active chemical additive in the ratio 99.77: 0.23. It absorbs 92% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 39% and the light transparency of the film in the region of 580-700 nm of 80%.

Example 141. Similar to Example 13, except that the polymer coating contains PMMA and the active chemical additive in a ratio of 99.5: 0.5. It absorbs 98% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 37% and a film opacity in the region of 580-700 nm of 77%.

Example 142. A polymer coating based on a copolymer (30% PS and 70% PMMA) containing an active chemical additive is prepared by dissolving a europium compound in a mixture of styrene and methyl methacrylate monomers, taken in a ratio of 3: 7, followed by polymerization. The resulting coating contains a copolymer (30% PS + 70% PMMA) and an active chemical additive in the ratio of 99.99:: 0.01. It absorbs 87% of the UV part of the spectrum in the region of 350–380 nm with a led ;. The transformation of absorbed UV radiation by 43% and the film transparency in the red region (580-700 nm) were 77%.

Example 143. Similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in the ratio of 99.7: 0.3. It absorbs 92% of the UV part of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 39% and translucency in the region of the red component (580-700 nm) 80%.

50

5 o

Q 5

five

five

Example 144. Similar to pri-r-iepy 16, with the exception that the polymer coating contains a copolymer and an active chemical additive in a ratio of 99.5: 0.5. It absorbs 98% of the UV part of the spectrum in the 35P - 380 nm region with a transformation of the absorbed UV radiation of 36% and light-transparency in the red component (580-700 nm) 76%.

The European & iClj x X ZTFOO used as an active additive intensively absorbs UV radiation, does not violate the transparency of the polymer in the visible region, and intensely luminescence in the region of 580-700 nm.

The optical properties of polymer films activated by EuClj STOFO (film thickness of PE, PVC, PP 0.15 mm; thickness of PS, PMMA and copolymer 3 mm) are listed in Table. eight.

The range of quantitative content of the luminescent additive in the proposed polymer compositions is chosen empirically. The choice is due to the fact that when the content of the additive is below the specified limit value, the intensity of the glow decreases sharply (to 30-40%), and an increase in the content of these limits for each polymer base leads to a decrease in translucency to 40-50%.

Example 145. Polymer polyethylene coating containing an active chemical additive ,, x X GHS, is obtained by impregnating polyethylene granules with a 10% solution of an active chemical additive in acetone followed by evaporation of acetone. Thereafter, a film is produced from the obtained polyethylene granules by rolling. When the content of the components in the polymer coating is in a ratio of 99% by weight of PE and 1% by weight of & C1, ZDGSO, it absorbs 99% of the UV portion of the spectrum in the region of 350-380% with a transformation of the absorbed UV set of 33% and film transparency in the region of 580-700 nm 75%.

Example 146. Similar to Example 1, except that the ratio of the active additive and FROM is 0.1: 99.9. When the content of components in the polymer coating in this ratio, it absorbs 86% Y (3 parts

331

spectrum in the region of nm with a magnitude of the transformation of the absorbed UV light of 39% and film transparency in the area of 580-700 nm 76%

Example 147. Similar to example 1, except that the ratio of the active additive to PE is 0.6: 99.4. With the content of components in the polymer coating in this ratio, it absorbs 93% of the UV part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 36% and film transparency in the region of 580–700 nm of 78%.

Example 148. Polymer polyvinyl chloride coating is prepared analogously to example 1 by impregnating a granule; PVC 10% solution of the active chemical additive in acetone, followed by the film. When the content of the components in the polymer coating in the ratio of PVC to the active chemical additive is 99.5: 0.3, it absorbs 95% of the UV portion of the spectrum in the region of 350-380 nm with a transformation value of the absorbed UV light of 38% and the luminance of the film in the region of 580- 700 nm 78%.

Example 149. Similar to example 4, except that the polymer coating contains PVC and the active additive in the ratio of 99.9: 0.1. It absorbs 89% of the UV part of the spectrum in the region of 350-380 with a transformation of absorbed UV light of 43% and film transparency in the region of 580-700 nm of 76%.

Example 150. Similar to Example 4, except that the polymer coating contains PVC and the active additive in a ratio of 99.0:: 1.0. It absorbs 99% of the UV part of the spectrum in the region of 350–380 km with a transformation of the absorbed UV light of 34% and film transparency in the region of 580–700 nm.73%.

Example 151. Analogous to Example 1, with the exception that a polymeric polypropylene coating is obtained that contains III and an active chemical additive in the ratio of 99.0: 1.0. It absorbs 99% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of a transformation of the absorbed UV radiation of 34% and a film translucency in the region of 580–700 nm of 74%.

Example 152. Similar to Example 7, with the exception that poly-

0 j

0 5

about

.

five

five

0

2834

dimensional coating contains PP and active chemical additive in the ratio of 99.5: 0.5. It absorbs 94% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 37% and a film transparency in the region of 580-700 nm of 77%.

Example 153. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio of 99.9: 0.1. It absorbs 89% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 39% and film transparency in the region of 580-700 nm of 75%.

Example 154. A polystyrene coating is prepared containing the active chemical additive by dissolving the additive in the monomer and then polymerizing it. The polymer coating contains PS and an active chemical additive in the ratio of 99.9: 0.1. It absorbs 90% of the UV portion of the spectrum in the region of 350–380 nm, with a transformation of the absorbed UV radiation of 39% and film transparency in the region of 580–700 nm of 78%.

Example 155. Similar to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.2-0.8. It absorbs 94% of the UV part of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 37% and film transparency in the region of 580–700 nm and 81%.

Example 156. Similar to example 10, except that the polymer coating contains PS and an active chemical additive in the ratio of 98.0: 2.0. It absorbs 99% of the UV portion of the spectrum in the region of 3–50–380 nm with a transformation of the absorbed UV radiation of 34% and film transparency in the region of 380–700 km 77%.

Example 157. Similar to example 10, with the exception that a polymer coating is prepared containing PMMA and an active x and a trace additive in a ratio of 99.9: 0.1. It absorbs 89% of the UV portion of the spectrum in the region of 350-380 nm, with a magnitude of transformation of the absorbed UV radiation of 39% and a film transparency in the region of 580-700 nm of 78%.

3513

Example 158. Similar to example 13, except that the polymer coating contains PMMA and the active chemical additive in the ratio of 99.1: 0.9. It absorbs 95% of the UV portion of the spectrum in the region of 350–380 nm, with a magnitude of transformation of the absorbed UV radiation of 36% and a translucency of the film in the region of 580–700 nm of 81%.

Example 159 Similar to Example 13, except that the polymer coating contains PMMA and the active chemical additive in COOTIIO is 98.0: 2.0. It absorbs 99% of the UV portion of the spectrum in the region of 350–380 pm with a transformation of the absorbed UV radiation of 33% and the luminosity of the film in the region of 580– 700 nm of 78%.

Example 160. A polymer coating based on a copolymer (30% PS and 70% PMMA) containing an active chemical additive is prepared by dissolving the europium compound in a mixture of styrene and methyl methacrylate monomers, taken in a 3: 7 ratio, followed by polymerization. The resulting coating contains a copolymer (30% PS + 70% PMMA) - and an active chemical additive in the ratio of 99.9:: 0.1. It absorbs 89% of the UV portion of the spectrum in the region of 350-380 nm, with a magnitude of transformation of the absorbed UV radiation of 38% and a film translucency in the region of the red component (580-700 nm) of 77%.

Example 161. Similar

Example 16, except that the polymer coating contains a copolymer and a chemical additive in the ratio of 99.0: 1.0. It absorbs 94% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 36% and a translucency in the region of the red component (580-700 nm) of 81%.

Example 162. Similar to Example 16, except that the polymer coating contains a copolymer and a chemical additive in a ratio of 98.0: 2.0. It absorbs 99% of the 1 part of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 33% and a transmittance in the region of the red component (580–700 nm) of 76%.

28

36

50

five

Used as an active additive, the europium EiiCl compound, x X ZDGSO intensively absorbs UV radiation, does not violate the transparency of the polymer in the visible region, and intensely luminesces in the 580-

700 nm.

Optical properties of polymeric

films activated by EuCl ZDGSO

(film thickness PE, PVC, PI 0.15 mm;

thickness PS, PMMA and copolymer 3 mm),

are given in table. 9.

The interval of quantitative content of the lu- (the inhaling additive in the proposed polymer compositions is chosen empirically. The choice is due to the fact that when the content of the additive is below the specified limit, the intensity of the glow decreases sharply (to 30-40%) basis leads to a decrease in translucency to 40-50%.

Example 163. A polymeric polyethylene coating containing the active chemical additive EuClj x X ZNSO is prepared by impregnating polyethylene granules with a 10% solution of the active chemical additive in acetone followed by evaporation of acetone. After that, a film is obtained from the obtained polyethylene granules by means of a shaft. When the content of components in the polymer coating in the ratio

99% by weight PE and 1% by weight E-aCl3HCO

it absorbs 99% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV light of 37% and film translucency in the region of 580–700 nm of 71%.

Example 164. Analogous to example 1, except that the ratio of the active additive and PE is taken 0.1: 99.9. When the content of components in the polymer coating in this ratio, it absorbs 93% of the UV part of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV light of 42% and film transparency in the region of 580-700 nm 70%.

Example 165. Similar to example 1, except that the ratio of the active additive and PE is 0.5: 99.5. When the content of components in the polymer coating in this ratio is, it absorbs 97% of the UV portion of the spectrum in the region of 350–380 nm with a height of 3713

The transformation of the absorbed UV light is D0% and the film translucency in the range of 58– 700 nm is 72%.

Example 166. Polymer polyvinyl chloride coating is prepared analogously to example 1 by P {feeding PVC granules with a 10% solution of an active chemical additive in acetone, followed by film preparation. 0.5 it absorbs 97% of the UV part of the spectrum in the region of 350 ± 380 nm with a transformation of the absorbed UV light of 37% and light transmission of the film in the region of 580-700 nm and 73%.

Example 167. Similar to example 4, except that the polymer coating contains PVC and the active additive in a ratio of 99.9: 0.1. It absorbs 92% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV light of 42% and a film transparency in the region of 580–700 nm of 70%.

Example 168. Similar to Example 4, except that the polymer coating contains PVC and the active additive in a ratio of 99.0: 1.0. It absorbs 99% of 1 part of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV light of 35% and film transparency in the region of 580-700 nm 67%.

Example 169. Similar to example 1, except that receive polymeric polypropylene coating containing PP and active chemical additive in the ratio of 99.0: 1.0. It absorbs 99% of the UV portion of the spectrum in the region of 350-380 nm with a transformation of the absorbed UV radiation of 36% and film transparency in the region of 580-700 nm of 67%.

Example 170. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio of 99.5: 0.5. It absorbs 98% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 38% and a film transparency in the region of 580-700 nm of 71%.

Example 171. Similar to example 7, except that the polymer coating contains PP and an active chemical additive in the ratio

about ,

0 25

," five

five

0

five

2838

99.9: 0.1. It absorbs 95%. The UV part of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV radiation of 44% and the film transparency in the region of 580–700 nm of 68%.

Example 172. A polystyrene coating is obtained containing the active chemical additive by dissolving the additive in the monomer and subsequent polymerization. The polymer coating contains PS and an active chemical additive in the ratio of 99.9: 0.1. It absorbs 93% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 44% and a light intensity of the film in the region of 580-700 nm of 70% ..

Example 173. Analogous to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.4: 0.6. It absorbs 98% of the UV portion of the spectrum in the region of 350-380 nm with a magnitude of transformation of the absorbed UV radiation of 39% and a film transparency in the region of 580-700 nm of 73%.

Example 174. Analogous to example 10, except that the polymer coating contains PS and the active chemical additive in the ratio of 99.0: 1.0. It absorbs 99% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 35% and light emission with the film in the region of 580–700 nm and 68%.

Example 175. It is similar when measure 10, except that a polymer coating is obtained containing PMMA n active chemical additive in a ratio of 99.9: 0.1. It absorbs 94% of the UV part of the spectrum in the region of 330–380 nm with a magnitude of transformation of the absorbed UV radiation of 45% and film opacity in the region of 580–700 nm of 72%.

Example 176. Similar to Example 13, except that the polymer coating contains PMMA and the active chemical additive in a ratio of 99.3: 0.7. It absorbs 98% of the UV portion of the spectrum in the region of 350–380 nm with a magnitude of transformation of the absorbed UV radiation of 40% and film transparency in the region of 580–700 nm of 76%.

Example 177. Similar to example 13, except that the polymer coating contains PMMA

3913

and an active chemical additive in the ratio of 99.0: 1.0. It absorbs 99% of the UV portion of the spectrum in the ZZO- 380 region with a magnitude of 36% absorbed UV radiation and a film opacity of 580-700 nm 66%,

Example 178, A polymer copolymer based coating (PPS and 70% PMMA) containing an active chemical additive, is prepared by dissolving the europium compound in a mixture of styrene and methyl methacrylate monomers, taken in a ratio of 3: 7, followed by polymerization. The resulting coating contains a copolymer (30% PS + 70% PMMA) and an active chemical additive in the ratio of 99.9:: 0.1. It absorbs 94% of the UV portion of the spectrum in the region of 350–380 nm with a transformation of the absorbed UV radiation of 43% and a translucency in the region of the red component (580–700 nm) of 71%.

Example 179. Similar to measure 16, except that the polymer coating contains a copolymer and an active chemical additive in a ratio of 99.4: 0.6. It absorbs 98% of the UV portion of the spectrum in the nm region with a magnitude of transformation of the absorbed UV radiation of 39% and a translucency in the region of the red component (580-700 nm) of 74%,

Example 180, similar to example 16, except that the polymer coating contains a copolymer and an active chemical additive in a ratio of 99.0: 1.0. It absorbs 99% of the UV portion of the spectrum in the 350-380 nm region with the magnitude of the transformation of absorbed UV 37% and the luminous flux in the red region was and (580-700 nm) 70%. -

The europium compound EuClj x X ZNSO used as an active additive intensively absorbs UV radiation, does not violate the transparency of the polymer in the visible region, and intensely luminesces in the region of 580-700 nm

The optical properties of polymer films activated with EuCl ZNSO (film thickness of PE, PVC, PP 0.15 mm; thickness of PS, PMMA and copolymer 3 mm) are listed in Table 10.

The interval of quantitative content of the luminescent additive in

28

40

5 0 5

d

Q 5

five

0

five

Lagged polymer compositions are selected empirically. The choice is due to the fact that when the content of the additive is below the specified limit value, the intensity of the glow decreases sharply (to 30-40%), and an increase in the content of the above limits for each polymer base leads to a decrease in the transparency to 40-50%,

The methods for preparing films from the proposed polymeric compositions differ from those known only by the introduction into the composition of the compounds EPOVI. The process of preparing the films does not differ from the known ones.

All the polymer films described above were used to grow crops.

Experiments on the alignment of agricultural crops was performed as follows.

Radishes, peas, dill, lettuce, spinach, orypi9 i, and tomatoes were planted in the open ground in two grams. Two greenhouses covered with polymer film were built above the sowing. The film covering the greenhouse No. 1 contained an active chemical additive. Greenhouse No. 2 (control experiment) was covered with a film that does not contain an activating additive. From the moment of planting, comparative observations were made of the development of plants in both greenhouses,

In par. No. 1 (activated), accelerated plant development was observed. So, for example, at the moment of the appearance of the 3rd leaf of radish in a controlled greenhouse, the fifth leaf in the experimental greenhouse was released; the pea plastika leaf in the experimental greenhouse was twice as wide as in the control greenhouse. By the time of bloom, the plant biomass was 1; 5–2 times the plant biomass of the control greenhouse. The flowering of plants in the greenhouse began on average a week earlier than in the control greenhouse. In the course of the observations, a comparative quantitative analysis of the chlorophyll content (a + B) with respect to magnesium was carried out on an atomic absorption spectrophotometer. An increase in the content of chlorophyll in the leaves in the experimental greenhouse was noted 1.8 times in radishes 1.5 times in peas. The average weight indicator of radish root crops in an experimental greenhouse is 1.5 times higher than that in the control greenhouse.

41138112842

The proposed polymer composite appears in the red component, which

films can produce films that absorb up to 99% of UV light in the region of 35– 380 nm, while 4– 80 percent of the absorbed ultraviolet

leads to the fact that the translucency in the region of the red component (58 CH700 nm) increases from 50 to 63-92%.

Table 1

table 2

Table

Tables, and 9

Claims (4)

1. A polymer composition for producing films based on a thermoplastic polymer containing a chemical additive, characterized in that, in order to increase the absorption of the UV part and increase the proportion of the red component of solar radiation, the composition contains a europium compound selected from the group as a chemical additive including Eu (NO _? ) j Hairdryer, where Hairdryer - 1,10phenanthroline, EuC1 ₃ 'ZTOFO, where TOFOtrioctylphosphine oxide, in the following ratio of components, wt.%: Polymer 99.00-99.99 Europium compound 0.01 - 1.00 2. A polymer composition for producing films based on a thermoplastic polymer containing a chemical additive, characterized in that, in order to increase the absorption of the UV part and increase the proportion of the red component of solar radiation, the composition contains a europium compound selected from the group as a chemical additive including Eu (HFAA) ₃ · Phen, where HFAA - hexafluoroacetylacetone, Phen - 1,10-phenanthroline, Eu (TTA) · DP, where TTA - tenoyl trifluoroacetone, CP - 2,2-dipyridyl, Eu (TTA) ₃ - A hair dryer, where TTA is tenoyltri-fluoroacetone, phen-1,10-phenanthroil, Eu ( BTFA) _e Phen, where BTFA is benzoyl trifluoroacetone, Phen is 1,10-phenanthroline, Eu (DBM) ₃ - 2DGS0, where DBM is di-benzoylmethane, DHSO is dihexyl sulfoxide, in the following ratio, wt.%: -Polymer 99,000-99,999 Europium Compound 0.001-1,000 3. Polymer composition for producing films Based on thermoplastic— SU 1381128 polymer containing a chemical additive, characterized in that, in order to increase the absorption of the UV part and increase the proportion of the red component of solar radiation, as a chemical additive, the composition contains a europium compound selected from the group consisting of Eu (NOj) ₃ · 3 TBP, where TBP is tributyl phosphate, EuCls' 3 NSO, where NSO are petroleum sulfoxides of the formula R _? SO, where R is a hydrocarbon radical, in the following ratio, May 7: Polymer 99.0-99.9 Europium compound 0.1-1.0 4. A polymer composition for producing films based on a thermoplastic polymer containing a chemical additive, characterized in that, in order to increase the absorption of the UV part and increase the proportion of the red component of solar radiation, as a chemical additive the composition contains a europium compound - EuCl3 · 3 DGSO, where DGSO - dihexyl sulfoxide, in the following ratio, May 7: Polymer 98.0—99.9 Europium compound 0.1-2.0