RU2036175C1 - Composition coating for preventing edges of articles of sheet glass against impact loads - Google Patents

Abstract

FIELD: production of composition coatings. SUBSTANCE: proposed coating contains (mass %): elasticator of 0.1-0.313 mm fraction 10-20, mineral filler of 0.01-0.07 mm fraction 2-4, dimethyl phthalate 1-2, epoxy adhesive the rest. EFFECT: improves quality of composition. 4 tbl

Description

 The invention relates to the glass industry and can be used in the manufacture of glass products from sheet glasses experiencing mechanical impact loads in the manufacture, transportation and operation, in particular in the manufacture of matrix glasses for the production of sheet polymethyl methacrylate.

 Known methods of protecting the surface of sheet glass from mechanical damage, in which a polymer layer is applied to the surface to be protected (polyurethane, polyethylene terephthalate, polyvinyl butyral, etc.) [1] However, when protecting the end surfaces of the glass, the polymer films quickly peel off during successive shock loads due to the relatively low adhesive strength connections.

 Epoxy resins have high adhesion strength to the glass surface [2] However, they do not have high impact strength, which leads to rapid destruction of the epoxy coating.

 Closest to the proposed are composite coatings, including epoxy resins and finely divided filler [3] In such composite materials, epoxy resins provide high adhesion to the glass surface, and filler a significant increase in the impact strength of the coating and, as a result, an increase in the impact resistance of glassware. However, the achieved impact strength does not satisfy the necessary requirements.

 The technical result of the invention is the creation of a composite coating for the protection of the ends of sheet glass products experiencing mechanical impact loads during manufacture, transportation and operation, a significant increase in the resistance of glassware with a composite protective coating applied to its ends to successive impact loads.

 This is achieved by the fact that the composite coating for protecting the ends of sheet glass products containing a polymeric binder and a finely divided filler contains epoxy adhesive as a polymeric binder, and a 0.100-0.313 mm fraction modifier powder and a 0.01- 0.07 mm and a plasticizer in the following ratio of components, wt. elasticizer powder 10-20, mineral filler powder 2-4, plasticizer 1-2, epoxy adhesive the rest. In this case, the preferred thickness of the composite coating is 1-3 mm

 The proposed composite coating has a high adhesive strength of the connection with the end surface of the sheet glass due to the use of epoxy adhesive as a binder. The particles of elasticizer form an elastomeric network in the composite coating, which gives the material elastic properties and the ability to elastic deformations. Particles of a mineral filler, having a size several times smaller than particles of an elasticizer, occupy a space in the composite material in the cells of the elastomeric network, increasing the strength of the polymer matrix formed by the binder, and at the same time plasticizing it.

 Tests were made on the impact strength of silicate glass samples having dimensions of 50x50x10 mm, the end of which was protected by various composite coatings. EKF-5 and EDP-5 epoxy adhesives were used as a binder in composite coatings; polyurethane powders (according to VTU VNIISS 1-60), rubber and high pressure polyethylene of various fractions were used as elasticizer powders. The composite material was prepared by jointly grinding the epoxy adhesive with filler powders, followed by the addition of a hardener and additional grinding. A protective coating was applied to the end surface of the glass samples with a spatula. Impact tests were carried out using a steel ball with a diameter of 28 mm and a mass of 121 g, which was thrown between the guide profiles on the end of the glass sample with a protective coating. The sample was placed under the guiding profiles so that the end surface was perpendicular to the direction of impact, and the impact itself was in the central part of the protected surface. The ball was thrown onto a glass sample repeatedly from the same height of 1 m until traces of destruction of the glass sample appeared (chips, cracks and other destruction or peeling of the protective coating).

 PRI me R 1. The thickness of the coating ranged from 0.8 to 5 mm It is noted that composite coatings with a thickness of less than 1 mm do not improve the impact strength of products, and with a thickness of more than 3 mm they tend to peel off with a small number of impacts.

 PRI me R 2. The influence of the composition of the composite coating on its protective properties.

 In the table. 1 shows the specific compositions of the protective coating with a thickness of 2 mm

 From the table. 1 shows that the greatest resistance has a composite coating containing components, wt. epoxy glue 74-87, powder polyurethane elasticizer 10-20, powder aluminum oxide 2-4, plasticizer dimethyl phthalate 1-2.

 In the table. Figures 2-4 show the average values from three parallel tests of samples with the same coatings.

 PRI me R 3. The influence of the type of epoxy binder on the protective properties of the composite coating is considered (table. 2).

 From the table. 2 shows that the type of epoxy adhesive does not significantly affect the resistance of the coating to impact loads.

 PRI me R 4. The influence of the composition of the fillers in the composite coating on its protective properties (Table 3).

 From the table. 3 it can be seen that the best protective properties are observed when using an elasticizer powder of a fraction of 0.100-0.313 mm and a powder of a mineral filler of a fraction of 0.01-0.07 mm.

 PRI me R 5. The influence of the type of elasticizer and mineral filler on the protective properties of the composite coating is considered (table. 4).

 From the table. Figure 4 shows that the best results are observed when alumina is used as a mineral filler and polyurethane as an elasticizer.

 Thus, the proposed composite coating can significantly increase the resistance of glass products to sequential shock loads.

Claims (1)

 COMPOSITE COATING FOR PROTECTING ENDS OF SHEET GLASS PRODUCTS FROM SHOCK LOADS, containing epoxy adhesive, characterized in that it additionally contains a fraction modifier 0.1 0.313 mm, a mineral filler fraction 0.01 0.017 mm and dimethyl phthalate in the following ratio, wt. . Elastifier fraction 0.1 0.313 mm 10 20
The mineral filler fractions of 0.01 0.07 mm 2 4
Dimethyl phthalate 1 2
Epoxy adhesive Else

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