CN209637176U - A kind of multilayered structure antistatic environment-friendly epoxy resin terrace - Google Patents

Abstract

The utility model relates to building ground floor materials, also relate to the other technologies field of this kind of terrace used in connection with, specifically, are related to a kind of multilayered structure antistatic environment-friendly epoxy resin terrace.The utility model discloses a kind of multilayered structure antistatic environment-friendly epoxy resin terrace, the epoxy floor successively includes the first nano-graphene epoxy resin layer, the first epoxy resin priming coat, graphene oxide layer, the second epoxy resin priming coat, the second nano-graphene epoxy resin layer, third epoxy resin priming coat, basal layer.The outer surface of epoxy floor provided by the utility model has more excellent wear-resisting property, the utility model uses sandwich structure simultaneously, intermediate oxidation graphene layer can give full play to the characteristic of terrace antistatic, for having stronger adaptability to the demanding application places of antistatic.

Description

A kind of multilayered structure antistatic environment-friendly epoxy resin terrace

Technical field

The utility model relates to building ground floor materials, also relate to the other technologies neck of this kind of terrace used in connection with Domain is specifically related to a kind of multilayered structure antistatic environment-friendly epoxy resin terrace.

Background technique

With the development of science and technology the terrace industry in China has rapid development at present, have been widely used for multiple Loophole perfusion and repairing, room between being put between specific field, such as the plastic cement race track of sports ground, building concrete crack repairing, beam building Interior ground surface finishing etc..

So far, the development of floor material the relevant technologies is very mature, is generally broadly divided into three classes, i.e. ring This three big resin system of oxygen, acrylic compounds and polyurethane.In these Main Systems, matrix resin is generally amorphous sticky Liquid does not have apparent fusing point, is heated and easily softens, then gradually melts stickness, and not soluble in water.By in the matrix resin It is middle that suitable curing agent or initiator is added, there can be the physical and mechanical property that can be actually used after cured, answer extensively For in real life production.It is different according to specific demand, it usually can also be a variety of other by adding into matrix resin The materials such as ingredient, such as cement, mortar, plasticizer make its application more to further strengthen its particular characteristic in a certain respect With specific aim and purpose, its bigger economic value is added.

Terrace is suitable for communication simultaneously, electronics, microelectronics, computer, precision instrument, weaving, printing, powder, chemistry, has Solvent, gas etc. all need the metope of antistatic factory, terrace etc..And terrace more commonly used at present, antistatic, The performances such as wear-resisting are all relatively low, are unable to satisfy the demand of the following this respect.Therefore, there is antistatic environment-friendly type terrace to have for exploitation Actual application value.

Utility model content

In order to solve the above-mentioned technical problem, the utility model provides a kind of multilayered structure antistatic environment-friendly epoxy resin Terrace, the epoxy floor successively include the first nano-graphene epoxy resin layer, the first epoxy resin priming coat, oxidation Graphene layer, the second epoxy resin priming coat, the second nano-graphene epoxy resin layer, third epoxy resin priming coat, substrate Layer.

As a kind of perferred technical scheme, the basal layer is selected from calcium carbonate plate, floor tile, marble, steel plate, calcium silicates The combination of plate, cement plate one or more.

As a kind of perferred technical scheme, the first epoxy resin priming coat, the second epoxy resin priming coat, Three epoxy resin bottom coating layers are each independently selected from bisphenol A type epoxy resin, polyglycidyl ether type epoxy resin, ethylene oxidic ester At least one of type epoxy resin, bisphenol f type epoxy resin, united phenol-type epoxy resin.

As a kind of perferred technical scheme, the first epoxy resin priming coat, the second epoxy resin priming coat, third The thickness of epoxy resin priming coat respectively stands alone as 0.05-0.08mm.

As a kind of perferred technical scheme, the first epoxy resin priming coat, the second epoxy resin priming coat, third The thickness of epoxy resin priming coat respectively stands alone as 0.05-0.06mm.

As a kind of perferred technical scheme, the first nano-graphene epoxy resin layer thickness are 0.5-1.5mm, the Two nano-graphene epoxy resin layers with a thickness of 1.5-2.5mm.

As a kind of perferred technical scheme, the first nano-graphene epoxy resin layer thickness are 1-1.5mm, second Nano-graphene epoxy resin layer with a thickness of 1.5-2mm.

As a kind of perferred technical scheme, the graphene oxide layer with a thickness of 0.01-0.05mm.

As a kind of perferred technical scheme, the graphene oxide layer with a thickness of 0.02-0.03mm.

The utility model has the advantages that the outer surface of epoxy floor provided by the utility model has more excellent wear-resisting property, The utility model uses sandwich structure simultaneously, and intermediate graphene layer can give full play to the characteristic of terrace antistatic, for right The demanding application places of antistatic have stronger adaptability.Solve existing epoxy floor antistatic, wear-resisting property The characteristics such as difference.

Detailed description of the invention

Fig. 1 is multilayered structure antistatic environmental-protection epoxy resin floor structure schematic diagram；

Fig. 2 is ordinary epoxy resin floor structure schematic diagram.

Symbol description:

10: nano-graphene epoxy resin layer, wherein 101 be the first nano-graphene epoxy resin layer, 102 receive for second Rice graphene epoxy resin layer；

20: epoxy resin priming coat, wherein 201 be the first epoxy resin priming coat, 202 be the second epoxy resin primary coat Layer, 203 be third epoxy resin priming coat；

30: graphene oxide layer；

40: basal layer；

50: epoxy resin layer.

Specific embodiment

To solve the above-mentioned problems, the first aspect of the utility model provides a kind of multilayered structure antistatic environment-friendly type Epoxy floor, the epoxy floor successively include the first nano-graphene epoxy resin layer, the first epoxy resin bottom Coating, graphene oxide layer, the second epoxy resin priming coat, the second nano-graphene epoxy resin layer, third epoxy resin bottom Coating, basal layer.

Basal layer

As a preferred embodiment, the basal layer is selected from calcium carbonate plate, floor tile, marble, steel plate, calcium silicates The combination of plate, cement plate one or more.

Epoxy resin priming coat

As a preferred embodiment, the first epoxy resin priming coat, the second epoxy resin priming coat, third The thickness of epoxy resin priming coat respectively stands alone as 0.05-0.08mm.

As a preferred embodiment, the first epoxy resin priming coat, the second epoxy resin priming coat, third The thickness of epoxy resin priming coat respectively stands alone as 0.05-0.06mm.

As a preferred embodiment, the first epoxy resin priming coat, the second epoxy resin priming coat, Three epoxy resin bottom coating layers are each independently selected from bisphenol A type epoxy resin, polyglycidyl ether type epoxy resin, ethylene oxidic ester At least one of type epoxy resin, bisphenol f type epoxy resin, united phenol-type epoxy resin.

Preferably, the first epoxy resin priming coat, the second epoxy resin priming coat, third epoxy resin priming coat It is bisphenol A type epoxy resin.

Nano-graphene epoxy resin layer

As a preferred embodiment, the first nano-graphene epoxy resin layer thickness are 0.5-1.5mm, the Two nano-graphene epoxy resin layers with a thickness of 1.5-2.5mm.

As a preferred embodiment, the first nano-graphene epoxy resin layer thickness are 1-1.5mm, second Nano-graphene epoxy resin layer with a thickness of 1.5-2mm.

As a preferred embodiment, during the preparation process, the first nano-graphene epoxy resin layer and Second nano-graphene epoxy resin layer is first configured to coating fluid, then brushes on epoxy resin priming coat.

As a preferred embodiment, the first nano-graphene epoxy resin layer and the second nano-graphene Epoxy resin layer coating fluid is grouped as by two groups of A, B, and by weight, the component A includes following raw material: epoxy resin 40-60 parts, 5-15 parts of mill base, 4-10 parts of graphene oxide, 2-6 parts of diluent, 5-10 parts of silicon powder, 1-2 parts of defoaming agent, levelling agent 0.1-1 parts, 10-30 parts of resin color sand；The B component is curing agent 40-60 parts.

Preferably, the first nano-graphene epoxy resin layer and the second nano-graphene epoxy resin layer coating fluid It is grouped as by two groups of A, B, by weight, the component A includes following raw material: 50 parts of epoxy resin, 8 parts of mill base, oxidation 7 parts of graphene, 4 parts of diluent, 7 parts of silicon powder, 1.5 parts of defoaming agent, 0.5 part of levelling agent, 20 parts of resin color sand；The B component is 50 parts of curing agent.

As a preferred embodiment, the first nano-graphene epoxy resin layer and the second nano-graphene Epoxy resin in epoxy resin layer coating fluid is sweet selected from bisphenol A type epoxy resin, polyglycidyl ether type epoxy resin, shrink At least one of oily ester type epoxy resin, bisphenol f type epoxy resin, united phenol-type epoxy resin.

Preferably, the first nano-graphene epoxy resin layer and the second nano-graphene epoxy resin layer coating fluid In epoxy resin be bisphenol A type epoxy resin.

It is highly preferred that the bisphenol A type epoxy resin is polyimide modified bisphenol A type epoxy resin.

The polyimide modified bisphenol A type epoxy resin, preparation method include the following steps:

(1) triethylamine of 2, the 4- dihydroxy metaphenylene diamine hydrochloride of 2.13g and 1mL is dissolved in 25mL N- methylpyrrole In alkanone, diphenyl ether tetrabasic carboxylic acid dicarboxylic anhydride, the toluene of 10mL and the glacial acetic acid of 1.0g of 3.1g is added, is then warming up to 180 DEG C 5h is kept the temperature, is precipitated in methyl alcohol after completion of the reaction, filtering, vacuum drying obtain the polyimides of hydroxyl.

(2) by weight part ratio be the bisphenol A type epoxy resin of 100:40:90:1, step (1) obtain polyimides, drop Bornylene dicarboxylic anhydride, 2,4,6- tri- (dimethylamino methyl) phenol are mixed, and are heated while stirring uniformly, heating schedule is After 120 DEG C of heating 1h, be continuously heating to 150 DEG C of heating 3h to get.

As a preferred embodiment, the first nano-graphene epoxy resin layer and the second nano-graphene The preparation method of graphene oxide in epoxy resin layer coating fluid, comprising the following steps:

(1) reaction flask of 500mL is assembled in ice-water bath, and the solid mixing of 1g graphite powder and 0.75g sodium nitrate is added Object；

(2) the addition 45mL concentrated sulfuric acid and 5mL concentrated phosphoric acid in the mixture in step (1), magnetic agitation, during which in three batches 4.5g potassium permanganate is added；

(3) after potassium permanganate is completely dissolved in step (2), 60 DEG C are warming up to, continues to stir 10h；

(4) after cooling, 100mL deionized water is added into the mixed liquor of step (3), continues to be warming up to 95 DEG C, continues to stir Mix 1h；

(5) temperature, which drops to 60 DEG C and 15mL hydrogen peroxide is added, dissolves remaining insoluble Mn oxide, after being cooled to room temperature, from The heart collects sediment；50mL deionized water is added into sediment, and the dense HCl of 5mL is added to remove some non-soluble oxides, from Sediment is washed with deionized after collecting sediment in the heart, is freeze-dried spare；

(6) it disperses sediment made from above-mentioned steps (5) in deionized water, suspension is made.Add into suspension The concentrated sulfuric acid for entering 5mL, after being warming up to 110 DEG C, to reactor be added 5mL malonic acid, reaction time 4min, vacuum filtration, Washing and be dried to get.

As a preferred embodiment, the first nano-graphene epoxy resin layer and the second nano-graphene Diluent in epoxy resin layer coating fluid is reactive diluent.

Further, the reactive diluent is monocycle oxygroup glycidol ethers reactive diluent and/or bicyclic oxygroup Glycidol ethers reactive diluent.

Further, the reactive diluent contains hydroxyl reactive group.

Further, the reactive diluent also contains carbon-carbon double bond active group.

Preferably, the reactive diluent is compound a, and compound a structural formula (1) is as follows:

The synthetic method of the compound a includes the following steps:

(1) it in the four-hole boiling flask equipped with reflux condensing tube, constant pressure funnel, blender and thermometer, sequentially adds 8.81g1,4- butylene glycol, 8.42g KOH solid, 0.40g tetrabutylammonium bromide and 100mL volume ratio are the toluene and water of 2:1 Mixed solution, stir evenly；

(2) 18.50g epoxychloropropane is slowly added dropwise in 40 DEG C, reacts 6h.Revolving removes organic solvent, obtained aqueous solution It is washed with 50mL hexamethylene, solvent is evaporated off in methylene chloride extraction to obtain the final product.

As a preferred embodiment, the first nano-graphene epoxy resin layer and the second nano-graphene The granularity of silicon powder in epoxy resin layer coating fluid is 1200 mesh.

As a preferred embodiment, the first nano-graphene epoxy resin layer and the second nano-graphene The diameter of color sand in epoxy resin layer coating fluid is 1mm.

As a preferred embodiment, the first nano-graphene epoxy resin layer and the second nano-graphene Defoaming agent in epoxy resin layer coating fluid is polyoxyethylene polyoxypropylene pentaerythrite ether.

As a preferred embodiment, the first nano-graphene epoxy resin layer and the second nano-graphene Levelling agent in epoxy resin layer coating fluid is BYK-333 organosilicon.

As a preferred embodiment, the first nano-graphene epoxy resin layer and the second nano-graphene Curing agent in epoxy resin layer coating fluid is selected from benzyl dimethylamine, 2- (dimethylaminomethyl) phenol, 2-methylimidazole, 4, 4'- diaminodiphenyl-methane, 2- ethyl imidazol(e), 2-ethyl-4-methylimidazole, two ring of 3,3'- dimethyl -4,4'- diamino Hexyl methane, methyl ring pentanediamine, 5- amino -1,3,3- 3-methyl cyclohexanol methylamine, 4,4'- diaminodiphenyl-methane, 1,2- At least one of cyclohexanediamine, 4,4'- diamino bicyclic hexyl methane.

Preferably, the curing agent is 4,4'- diaminodiphenyl-methane.

Applicants have discovered that the wear-resisting property of terrace is improved when the terrace contains nano-graphene epoxy resin； Conjecture the possible reason is, nano-graphene and epoxy resin mutually cooperate with, make the nano-graphene epoxy resin have it is excellent Different wear-resisting property.

Graphene oxide layer

As a preferred embodiment, the graphene oxide layer with a thickness of 0.01-0.05mm.

As a preferred embodiment, the graphene oxide layer with a thickness of 0.02-0.03mm.

As a preferred embodiment, during the preparation process, the graphene oxide layer is first configured to coating fluid, It is brushed on the second epoxy resin priming coat again.

The preparation method of graphene oxide in the graphene oxide layer, comprising the following steps:

(1) reaction flask of 500mL is assembled in ice-water bath, and the solid mixing of 1g graphite powder and 0.75g sodium nitrate is added Object；

(2) the addition 45mL concentrated sulfuric acid and 5mL concentrated phosphoric acid in the mixture in step (1), magnetic agitation, during which in three batches 4.5g potassium permanganate is added；

(3) after potassium permanganate is completely dissolved in step (2), 60 DEG C are warming up to, continues to stir 10h；

(4) after cooling, 100mL deionized water is added into the mixed liquor of step (3), continues to be warming up to 95 DEG C, continues to stir Mix 1h；

(5) temperature, which drops to 60 DEG C and 15mL hydrogen peroxide is added, dissolves remaining insoluble Mn oxide, after being cooled to room temperature, from The heart collects sediment；50mL deionized water is added into sediment, and the dense HCl of 5mL is added to remove some non-soluble oxides, from Sediment is washed with deionized after collecting sediment in the heart, is freeze-dried spare；

(6) it disperses sediment made from above-mentioned steps (5) in deionized water, suspension is made.Add into suspension The concentrated sulfuric acid for entering 5mL, after being warming up to 110 DEG C, to reactor be added 5mL malonic acid, reaction time 4min, vacuum filtration, Washing and be dried to get.

As a preferred embodiment, the preparation method of the graphene oxide coating fluid are as follows: take 5mg graphite oxide Alkene adds 10mL water, is configured to graphene oxide coating fluid.

Applicants have discovered that the anti-static ability of terrace can be improved using sandwich structure.Conjecture the possible reason is in Between the characteristic of terrace antistatic can be given full play to using graphene oxide layer, with further increasing nano-graphene epoxy resin The anti-static ability on level ground improves the reliability of product.

Further, the first epoxy resin priming coat, the second epoxy resin priming coat, third epoxy resin priming coat Thickness respectively stand alone as 0.05-0.08mm, the first nano-graphene epoxy resin layer thickness are 0.5-1.5mm, second nanometer Graphene epoxy resin layer with a thickness of 1.5-2.5mm, graphene oxide layer with a thickness of 0.01-0.05mm.

Further, the first epoxy resin priming coat, the second epoxy resin priming coat, third epoxy resin priming coat Thickness respectively stand alone as 0.05-0.06mm, the first nano-graphene epoxy resin layer thickness are 1-1.5mm, second nanometer of stone Black alkene epoxy resin layer with a thickness of 1.5-2mm, graphene oxide layer with a thickness of 0.02-0.03mm.

Further, the first epoxy resin priming coat, the second epoxy resin priming coat, third epoxy resin primary coat The thickness of layer respectively stands alone as 0.05mm, and the first nano-graphene epoxy resin layer thickness are 1.5mm, the second nano-graphene ring Oxygen resin layer with a thickness of 1.5mm, graphene oxide layer with a thickness of 0.03mm.

Applicants have discovered that passing through the first epoxy resin priming coat of different-thickness, the first nano-graphene epoxy resin Layer, the second epoxy resin priming coat, graphene oxide layer, third epoxy resin priming coat, the second nano-graphene epoxy resin Layer interaction, improve the antistatic of multilayered structure antistatic environment-friendly epoxy resin terrace, wear-resisting property, impact resistance, Chemical resistance.Epoxy resin priming coat is used simultaneously, the binding force between each layer can be further increased, so that terrace be made to make Be not in the process peel off.

The multilayered structure antistatic environmental-protection epoxy resin terrace preparation method, comprising the following steps:

(1) it is polished with sander and removes substrate weaker zone and laitance layer, while preparing the first epoxy resin primary coat liquid, first Nano-graphene epoxy resin masking liquid, the second epoxy resin primary coat liquid, graphene oxide masking liquid, third epoxy resin primary coat liquid, Second nano-graphene epoxy resin masking liquid；

(2) brushing third epoxy resin primary coat liquid on the base layer forms third epoxy resin priming coat；

(3) the second nano-graphene epoxy resin masking liquid is brushed on third epoxy resin priming coat, forms second nanometer Graphene epoxy resin layer；

(4) the second epoxy resin primary coat liquid is brushed on the second nano-graphene epoxy resin layer, forms the second asphalt mixtures modified by epoxy resin Rouge priming coat；

(5) the brushing graphene oxide masking liquid on the second epoxy resin priming coat forms graphene oxide layer；

(6) the first epoxy resin primary coat liquid is brushed in graphene oxide layer, forms the first epoxy resin priming coat；

(7) the first nano-graphene epoxy resin masking liquid is brushed on the first epoxy resin priming coat, forms first nanometer Graphene epoxy resin layer, curing time are 10~48h, complete the production of this terrace.

The utility model is specifically described below by embodiment.It is necessarily pointed out that following embodiment It is served only for that the utility model is described in further detail, should not be understood as the limitation to scope of protection of the utility model, the field Some nonessential modifications and adaptations that professional technician makes according to the content of above-mentioned the utility model are still fallen within practical Novel protection scope.

In addition, if without other explanations, it is raw materials used to be all commercially available.

Embodiment

The basal layer of Examples 1 to 8 and comparative example 1~4,6~9, the first epoxy resin priming coat, the first nano-graphene Epoxy resin layer, the second epoxy resin priming coat, graphene oxide layer, third epoxy resin priming coat, the second nano-graphene Each layer raw material is as follows in epoxy resin layer:

Basal layer: the basal layer is marble；

Epoxy resin priming coat: the first epoxy resin priming coat, the second epoxy resin priming coat, third asphalt mixtures modified by epoxy resin Rouge priming coat is bisphenol A type epoxy resin；

Nano-graphene epoxy resin layer: the first nano-graphene epoxy resin layer and the second nano-graphene ring Oxygen resin layer coating fluid is grouped as by two groups of A, B, and by weight, the component A includes following raw material: epoxy resin 50 Part, 8 parts of mill base, 7 parts of graphene oxide, 4 parts of diluent, 7 parts of silicon powder, 1.5 parts of polyoxyethylene polyoxypropylene pentaerythrite ether, 0.5 part of BYK-333 organosilicon levelling agent, 20 parts of resin color sand；The B component is 50 parts of curing agent.

The epoxy resin is polyimide modified bisphenol A type epoxy resin, and preparation method includes the following steps:

(1) triethylamine of 2, the 4- dihydroxy metaphenylene diamine hydrochloride of 2.13g and 1mL is dissolved in 25mL N- methylpyrrole In alkanone, diphenyl ether tetrabasic carboxylic acid dicarboxylic anhydride, the toluene of 10mL and the glacial acetic acid of 1.0g of 3.1g is added, is then warming up to 180 DEG C 5h is kept the temperature, is precipitated in methyl alcohol after completion of the reaction, filtering, vacuum drying obtain the polyimides of hydroxyl.

(2) polyamides obtained weight part ratio for the raw materials bisphenol A type epoxy resin of 100:40:90:1, step (1) is sub- Amine, carbic anhydride, 2,4,6- tri- (dimethylamino methyl) phenol are mixed, and are heated while stirring uniformly, are heated journey After sequence is 120 DEG C of heating 1h, be continuously heating to 150 DEG C of heating 3h to get.

The preparation method of the graphene oxide, comprising the following steps:

(1) reaction flask of 500mL is assembled in ice-water bath, and the solid mixing of 1g graphite powder and 0.75g sodium nitrate is added Object；

(2) the addition 45mL concentrated sulfuric acid and 5mL concentrated phosphoric acid in the mixture in step (1), magnetic agitation, during which in three batches 4.5g potassium permanganate is added；

(3) after potassium permanganate is completely dissolved in step (2), 60 DEG C are warming up to, continues to stir 10h；

(4) after cooling, 100mL deionized water is added into the mixed liquor of step (3), continues to be warming up to 95 DEG C, continues to stir Mix 1h；

(5) temperature, which drops to 60 DEG C and 15mL hydrogen peroxide is added, dissolves remaining insoluble Mn oxide, after being cooled to room temperature, from The heart collects sediment；50mL deionized water is added into sediment, and the dense HCl of 5mL is added to remove some non-soluble oxides, from Sediment is washed with deionized after collecting sediment in the heart, is freeze-dried spare；

(6) it disperses sediment made from above-mentioned steps (5) in deionized water, suspension is made.Add into suspension The concentrated sulfuric acid for entering 5mL, after being warming up to 110 DEG C, to reactor be added 5mL malonic acid, reaction time 4min, vacuum filtration, Washing and be dried to get.

The diluent is compound a, and compound a structural formula (1) is as follows:

The synthetic method of the compound a includes the following steps:

(1) it in the four-hole boiling flask equipped with reflux condensing tube, constant pressure funnel, blender and thermometer, sequentially adds 8.81g1,4- butylene glycol, 8.42g KOH solid, 0.40g tetrabutylammonium bromide and 100mL volume ratio are the toluene and water of 2:1 Mixed solution, stir evenly；

(2) 18.50g epoxychloropropane is slowly added dropwise in 40 DEG C, reacts 6h.Revolving removes organic solvent, obtained aqueous solution It is washed with 50mL hexamethylene, solvent is evaporated off in methylene chloride extraction to obtain the final product.

The granularity of the silicon powder is 1200 mesh；

The diameter of the color sand is 1mm.

Graphene oxide layer: the preparation method of the graphene oxide is the same as the oxidation stone in nano-graphene epoxy resin layer Black alkene.The preparation method of the graphene oxide coating fluid are as follows: take 5mg graphene oxide, add 10mL water, be configured to graphite oxide Alkene coating fluid.

The terrace preparation method of embodiment and comparative example, comprising the following steps:

(1) it is polished with sander and removes substrate weaker zone and laitance layer, while preparing the first epoxy resin primary coat liquid, first Nano-graphene epoxy resin masking liquid, the second epoxy resin primary coat liquid, graphene oxide masking liquid, third epoxy resin primary coat liquid, Second nano-graphene epoxy resin masking liquid；

(2) brushing third epoxy resin primary coat liquid on the base layer forms third epoxy resin priming coat；

(3) the second nano-graphene epoxy resin masking liquid is brushed on third epoxy resin priming coat, forms second nanometer Graphene epoxy resin layer；

(4) the second epoxy resin primary coat liquid is brushed on the second nano-graphene epoxy resin layer, forms the second asphalt mixtures modified by epoxy resin Rouge priming coat；

(5) the brushing graphene oxide masking liquid on the second epoxy resin priming coat forms graphene oxide layer；

(6) the first epoxy resin primary coat liquid is brushed in graphene oxide layer, forms the first epoxy resin priming coat；

(7) the first nano-graphene epoxy resin masking liquid is brushed on the first epoxy resin priming coat, forms first nanometer Graphene epoxy resin layer, curing time are for 24 hours, to complete the production of this terrace.

Embodiment 1

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.05mm, graphene oxide layer 30 with a thickness of 0.01mm, the second epoxy resin priming coat 202 with a thickness of 0.05mm, the second nano-graphene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 is with a thickness of 5mm.

Embodiment 2

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.06mm, graphene oxide layer 30 with a thickness of 0.01mm, the second epoxy resin priming coat 202 with a thickness of 0.06mm, the second nano-graphene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0.06mm, basal layer 40 is with a thickness of 5mm.

Embodiment 3

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.08mm, graphene oxide layer 30 with a thickness of 0.01mm, the second epoxy resin priming coat 202 with a thickness of 0.08mm, the second nano-graphene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0.08mm, basal layer 40 is with a thickness of 5mm.

Embodiment 4

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.05mm, graphene oxide layer 30 with a thickness of 0.02mm, the second epoxy resin priming coat 202 with a thickness of 0.05mm, the second nano-graphene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 is with a thickness of 5mm.

Embodiment 5

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.05mm, graphene oxide layer 30 with a thickness of 0.03mm, the second epoxy resin priming coat 202 with a thickness of 0.05mm, the second nano-graphene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 is with a thickness of 5mm.

Embodiment 6

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.05mm, graphene oxide layer 30 with a thickness of 0.05mm, the second epoxy resin priming coat 202 with a thickness of 0.05mm, the second nano-graphene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 is with a thickness of 5mm.

Embodiment 7

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 0.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.05mm, graphene oxide layer 30 with a thickness of 0.03mm, the second epoxy resin priming coat 202 with a thickness of 0.05mm, the second nano-graphene epoxy resin layer 102 with a thickness of 2.5mm, third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 is with a thickness of 5mm.

Embodiment 8

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 1mm, the first epoxy resin primary coat Layer 201 with a thickness of 0.05mm, graphene oxide layer 30 with a thickness of 0.03mm, the second epoxy resin priming coat 202 with a thickness of 0.05mm, the second nano-graphene epoxy resin layer 102 with a thickness of 2mm, third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 is with a thickness of 5mm.

Embodiment 9

With reference to Fig. 1.With embodiment 5, difference exists for each thickness degree of terrace and each layer raw material concrete component and parts by weight In epoxy resin is in the first nano-graphene epoxy resin layer and the second nano-graphene epoxy resin layer coating fluid Bisphenol A type epoxy resin.

Embodiment 10

With reference to Fig. 1.With embodiment 5, difference exists for each thickness degree of terrace and each layer raw material concrete component and parts by weight In the first nano-graphene epoxy resin layer and the second nano-graphene epoxy resin layer coating fluid are by two groups of A, B It is grouped as, by weight, the component A includes following raw material: 40 parts of epoxy resin, 5 parts of mill base, 4 parts of graphene oxide, dilute Release 2 parts of agent, 5 parts of silicon powder, 1 part of polyoxyethylene polyoxypropylene pentaerythrite ether, 0.1 part of BYK-333 organosilicon levelling agent, resin coloured silk 10 parts of sand；The B component is 40 parts of curing agent.

Embodiment 11

With reference to Fig. 1.With embodiment 5, difference exists for each thickness degree of terrace and each layer raw material concrete component and parts by weight In the first nano-graphene epoxy resin layer and the second nano-graphene epoxy resin layer coating fluid are by two groups of A, B Be grouped as, by weight, the component A includes following raw material: 60 parts of epoxy resin, 15 parts of mill base, 10 parts of graphene oxide, 6 parts of diluent, 10 parts of silicon powder, 2 parts of polyoxyethylene polyoxypropylene pentaerythrite ether, 1 part of BYK-333 organosilicon levelling agent, resin 30 parts of color sand；The B component is 60 parts of curing agent.

Comparative example 1

The first nano-graphene of this comparative example epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin priming coat 201 With a thickness of 0mm, graphene oxide layer 30 is with a thickness of 0.03mm, and the second epoxy resin priming coat 202 is with a thickness of 0mm, and second nanometer Graphene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0mm, basal layer 40 with a thickness of 5mm。

Comparative example 2

The first nano-graphene of this comparative example epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin priming coat 201 With a thickness of 0mm, graphene oxide layer 30 is with a thickness of 0.03mm, and the second epoxy resin priming coat 202 is with a thickness of 0mm, and second nanometer Graphene epoxy resin layer 102 is with a thickness of 1.5mm, and third epoxy resin priming coat 203 is with a thickness of 0.05mm, 40 thickness of basal layer For 5mm.

Comparative example 3

The first nano-graphene of this comparative example epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin priming coat 201 With a thickness of 0mm, graphene oxide layer 30 is received with a thickness of 0.03mm, the second epoxy resin priming coat 202 with a thickness of 0.05mm, second Rice graphene epoxy resin layer 102 is with a thickness of 1.5mm, and for third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 is thick Degree is 5mm.

Comparative example 4

The first nano-graphene of this comparative example epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin priming coat 201 With a thickness of 0mm, graphene oxide layer 30 is with a thickness of 0mm, and the second epoxy resin priming coat 202 is with a thickness of 0mm, the second nano-graphite Alkene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 with a thickness of 5mm。

Comparative example 5

With reference to Fig. 2.Epoxy resin layer 50 is with a thickness of 3mm, and third epoxy resin priming coat 203 is with a thickness of 0.05mm, substrate Layer 40 is with a thickness of 5mm.

Epoxy resin coating fluid used in this comparative example includes two groups of A, B and is grouped as, by weight, the component A Including following raw material: 50 parts of bisphenol A type epoxy resin, 8 parts of mill base, 4 parts of diluent, 7 parts of silicon powder, polyoxyethylene polyoxypropylene season Penta 4 1.5 parts of alcohol ethers, 0.5 part of BYK-333 organosilicon levelling agent, 20 parts of resin color sand.The B component is 4,4'- diamino two 50 parts of phenylmethane.

Comparative example 6

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.03mm, graphene oxide layer 30 with a thickness of 0.01mm, the second epoxy resin priming coat 202 with a thickness of 0.03mm, the second nano-graphene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0.03mm, basal layer 40 is with a thickness of 5mm.

Comparative example 7

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 1.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.04mm, graphene oxide layer 30 with a thickness of 0.01mm, the second epoxy resin priming coat 202 with a thickness of 0.04mm, the second nano-graphene epoxy resin layer 102 with a thickness of 1.5mm, third epoxy resin priming coat 203 with a thickness of 0.04mm, basal layer 40 is with a thickness of 5mm.

Comparative example 8

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 2mm, the first epoxy resin primary coat Layer 201 with a thickness of 0.05mm, graphene oxide layer 30 with a thickness of 0.03mm, the second epoxy resin priming coat 202 with a thickness of 0.05mm, the second nano-graphene epoxy resin layer 102 with a thickness of 1mm, third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 is with a thickness of 5mm.

Comparative example 9

With reference to Fig. 1.The first nano-graphene of the present embodiment epoxy resin layer 101 is with a thickness of 2.5mm, the first epoxy resin bottom Coating 201 with a thickness of 0.05mm, graphene oxide layer 30 with a thickness of 0.03mm, the second epoxy resin priming coat 202 with a thickness of 0.05mm, the second nano-graphene epoxy resin layer 102 with a thickness of 0.5mm, third epoxy resin priming coat 203 with a thickness of 0.05mm, basal layer 40 is with a thickness of 5mm.

Performance test

Antistatic test: referring to SJ/T11294-2003 antistatic floor coatings general specification.

Ageing-resistant performance test: referring to GB/T1865-2009 testing standard, the evaluation of ageing-resistant performance is referring to GB/ T1766-2008 evaluates extent of the destruction and quantity with 0 to 5 numerical grade, and 0 indicates no destruction, 5, which indicate serious, destroys.

Color and appearance, hardness, impact resistance, adhesive force, chemical resistance test: referring to GB/T 22374-2008 terrace Material.

1~3,6~7 lawn performance test of Examples 1 to 3 and comparative example

4~5 terrace performance test of embodiment 1,4~6 and comparative example

Embodiment 5, embodiment 7-11, the performance detection of 4,5,8,9 terrace of comparative example

In conclusion 5 multilayered structure antistatic environment-friendly epoxy resin terrace of embodiment belongs to the optimum embodiment of this case. Intermediate modified graphene layer can give full play to the characteristic of terrace antistatic, and application places demanding for antistatic have Stronger adaptability.

The above descriptions are merely preferred embodiments of the present invention, is not the limitation for making other forms to invention, Any person skilled in the art is changed or is changed to equivalent variations possibly also with the technology contents of the disclosure above Equivalent embodiment, but all without departing from the content of the technical scheme of the utility model, according to the technical essence of the utility model to Any simple modification made by upper embodiment, equivalent variations and remodeling, still fall within the protection scope of technical solutions of the utility model.

Claims (9)

1. a kind of multilayered structure antistatic environment-friendly epoxy resin terrace, which is characterized in that the epoxy floor is successively wrapped Include the first nano-graphene epoxy resin layer, the first epoxy resin priming coat, graphene oxide layer, the second epoxy resin primary coat Layer, the second nano-graphene epoxy resin layer, third epoxy resin priming coat, basal layer.

2. epoxy floor according to claim 1, which is characterized in that the basal layer be selected from calcium carbonate plate, floor tile, The combination of marble, steel plate, calcium silicate board, cement plate one or more.

3. epoxy floor according to claim 1, which is characterized in that the first epoxy resin priming coat, Diepoxy resin priming coat, third epoxy resin priming coat are each independently selected from bisphenol A type epoxy resin, poly epihydric alcohol ether type At least one of epoxy resin, glycidyl ester type epoxy resin, bisphenol f type epoxy resin, united phenol-type epoxy resin.

4. epoxy floor according to claim 1, which is characterized in that the first epoxy resin priming coat, second Epoxy resin priming coat, third epoxy resin priming coat thickness respectively stand alone as 0.05-0.08mm.

5. epoxy floor according to claim 4, which is characterized in that the first epoxy resin priming coat, second Epoxy resin priming coat, third epoxy resin priming coat thickness respectively stand alone as 0.05-0.06mm.

6. epoxy floor according to claim 1, which is characterized in that the first nano-graphene epoxy resin layer With a thickness of 0.5-1.5mm, the second nano-graphene epoxy resin layer with a thickness of 1.5-2.5mm.

7. epoxy floor according to claim 6, which is characterized in that the first nano-graphene epoxy resin layer With a thickness of 1-1.5mm, the second nano-graphene epoxy resin layer with a thickness of 1.5-2mm.

8. epoxy floor according to claim 1, which is characterized in that the graphene oxide layer with a thickness of 0.01-0.05mm。

9. epoxy floor according to claim 8, which is characterized in that the graphene oxide layer with a thickness of 0.02-0.03mm。