阅读说明：本技术 一种节能型模块房房顶制作方法 (Energy-saving module house roof manufacturing method ) 是由 刘宝芳 于 2020-12-23 设计创作，主要内容包括：本发明是一种节能型模块房房顶制作方法,其步骤如下：(1)根据模块房房顶结构制作钢构架；(2)根据钢构架结构制作外顶板和内顶板；(3)将外顶板和内顶板固定在钢构架上；(4)对外顶板进行防水处理；(5)在外顶板上架设与房顶结构匹配的太阳能板支架,并将太阳能板铺设在支架上即可。本发明通过对外顶板进行防水处理,使得房顶防水效果好,且设置与房顶结构匹配的太阳能板,使得房顶白天便于储存电能,节约能源。(The invention relates to a method for manufacturing an energy-saving module house roof, which comprises the following steps: (1) manufacturing a steel framework according to the roof structure of the module house; (2) manufacturing an outer top plate and an inner top plate according to a steel framework structure; (3) fixing the outer top plate and the inner top plate on a steel framework; (4) carrying out waterproof treatment on the outer top plate; (5) the solar panel support matched with the roof structure is erected on the outer top plate, and the solar panel is laid on the support. According to the invention, the outer top plate is subjected to waterproof treatment, so that the roof has a good waterproof effect, and the solar panel matched with the roof structure is arranged, so that the roof is convenient to store electric energy in daytime, and the energy is saved.)

1. A method for manufacturing an energy-saving module house roof is characterized by comprising the following steps:

(1) manufacturing a steel framework according to the roof structure of the module house;

(2) make outer roof and roof according to steel framework structure:

preparing materials: the components are as follows according to the parts by weight: 55-65 parts of portland cement, 8-16 parts of straws, 12-22 parts of attapulgite clay, 10-12 parts of calcium oxide, 5-10 parts of wollastonite powder, 8-15 parts of marble, 5-10 parts of asbestos, 12-14 parts of magnesium oxide, 8-10 parts of magnesium chloride, 1-3 parts of a stabilizer, 2-3 parts of an adhesive and 2-4 parts of a thickening agent;

adding a proper amount of water into the raw materials, uniformly stirring, pouring into a corresponding mould, standing at room temperature for 13-16h, demoulding, taking out, and maintaining for 5-7 days;

(3) fixing the outer top plate and the inner top plate on a steel framework;

(4) and (3) carrying out waterproof treatment on the outer top plate:

coating a layer of waterproof paint on the outer top plate, naturally drying the outer top plate, and repairing the outer top plate to enable the surface of the outer top plate to be flat;

coating a base layer treating agent on the outer top plate, and paving a waterproof coiled material after the base layer treating agent is dried;

when the waterproof coiled material is laid, the unfolded part is unfolded after the coiled material is rolled for 1m, the heating spray gun is adopted to heat the hot melt adhesive surface and the base layer on the bottom surface of the waterproof coiled material until the hot melt adhesive layer has black luster and shines until micro bubbles appear, the coiled material is slowly laid down and laid on the base layer, and then the air exhaust roller is used for rolling the coiled material to ensure that the coiled material is firmly bonded with the base layer;

(5) the solar panel support matched with the roof structure is erected on the outer top plate, and the solar panel is laid on the support.

2. The method for manufacturing an energy-saving modular house roof as claimed in claim 1, wherein the thickness of the outer top plate in the step (2) is 15-18cm, and the thickness of the inner top plate is 12-16 cm.

3. The method for manufacturing an energy-saving modular roof as claimed in claim 1, wherein the stabilizer in step (2) is hydroxypropyl methylcellulose.

4. The method for manufacturing the energy-saving modular roof as claimed in claim 1, wherein the adhesive in the step (2) is composed of a modified polyurethane adhesive and an acrylic adhesive, and the mass ratio of the modified polyurethane adhesive to the acrylic adhesive is (6-7): (3-4).

5. The method as claimed in claim 1, wherein the thickening agent in step (2) is polyacrylamide.

6. The method for manufacturing the energy-saving module house roof according to claim 1, wherein the waterproof roll in the step (4) is an asphalt waterproof roll or a polymer waterproof roll.

Technical Field

The invention relates to the field of module rooms, in particular to a method for manufacturing a roof of an energy-saving module room.

Background

Modular houses have begun to gradually come into the field of vision of people, the modular houses differentiate the components of houses into different functional modules, factory manufacturing is realized by standardized, modular and universal production, and the houses are convenient and quick to assemble. One module of the modular house is a roof module which is mostly in a simple plate shape, has a simple structure and a general waterproof effect and does not have an energy-saving effect.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a method for manufacturing an energy-saving module house roof.

In order to achieve the purpose, the invention adopts the following technical scheme:

a method for manufacturing an energy-saving module house roof comprises the following steps:

(1) manufacturing a steel framework according to the roof structure of the module house;

(2) make outer roof and roof according to steel framework structure:

preparing materials: the components are as follows according to the parts by weight: 55-65 parts of portland cement, 8-16 parts of straws, 12-22 parts of attapulgite clay, 10-12 parts of calcium oxide, 5-10 parts of wollastonite powder, 8-15 parts of marble, 5-10 parts of asbestos, 12-14 parts of magnesium oxide, 8-10 parts of magnesium chloride, 1-3 parts of a stabilizer, 2-3 parts of an adhesive and 2-4 parts of a thickening agent;

adding a proper amount of water into the raw materials, uniformly stirring, pouring into a corresponding mould, standing at room temperature for 13-16h, demoulding, taking out, and maintaining for 5-7 days;

(3) fixing the outer top plate and the inner top plate on a steel framework;

(4) and (3) carrying out waterproof treatment on the outer top plate:

coating a layer of waterproof paint on the outer top plate, naturally drying the outer top plate, and repairing the outer top plate to enable the surface of the outer top plate to be flat;

coating a base layer treating agent on the outer top plate, and paving a waterproof coiled material after the base layer treating agent is dried;

when the waterproof coiled material is laid, the unfolded part is unfolded after the coiled material is rolled for 1m, the heating spray gun is adopted to heat the hot melt adhesive surface and the base layer on the bottom surface of the waterproof coiled material until the hot melt adhesive layer has black luster and shines until micro bubbles appear, the coiled material is slowly laid down and laid on the base layer, and then the air exhaust roller is used for rolling the coiled material to ensure that the coiled material is firmly bonded with the base layer;

(5) the solar panel support matched with the roof structure is erected on the outer top plate, and the solar panel is laid on the support.

Particularly, in the step (2), the thickness of the outer top plate is 15-18cm, and the thickness of the inner top plate is 12-16 cm.

In particular, the stabilizer in the step (2) is hydroxypropyl methyl cellulose.

Specifically, the adhesive in the step (2) is composed of a modified polyurethane adhesive and an acrylic adhesive, and the mass ratio of the modified polyurethane adhesive to the acrylic adhesive is (6-7): (3-4).

In particular, the thickening agent in the step (2) is polyacrylamide.

Particularly, the waterproof roll in the step (4) is an asphalt waterproof roll or a polymer waterproof roll.

The invention has the beneficial effects that: according to the invention, the outer top plate is subjected to waterproof treatment, so that the roof has a good waterproof effect, and the solar panel matched with the roof structure is arranged, so that the roof is convenient to store electric energy in daytime, and the energy is saved.

Detailed Description

The invention is further illustrated by the following examples:

example 1

A method for manufacturing an energy-saving module house roof comprises the following steps:

(1) manufacturing a steel framework according to the roof structure of the module house;

(2) make outer roof and roof according to steel framework structure:

preparing materials: the components are as follows according to the parts by weight: 55 parts of portland cement, 8 parts of straw, 12 parts of attapulgite clay, 10 parts of calcium oxide, 5 parts of wollastonite powder, 8 parts of marble, 5 parts of asbestos, 12 parts of magnesium oxide, 8 parts of magnesium chloride, 1 part of a stabilizer, 2 parts of an adhesive and 2 parts of a thickening agent;

adding a proper amount of water into the raw materials, uniformly stirring, pouring into a corresponding mould, standing at room temperature for 13h, demoulding, taking out, and curing for 5 days;

(3) fixing the outer top plate and the inner top plate on a steel framework;

(4) and (3) carrying out waterproof treatment on the outer top plate:

coating a layer of waterproof paint on the outer top plate, naturally drying the outer top plate, and repairing the outer top plate to enable the surface of the outer top plate to be flat;

coating a base layer treating agent on the outer top plate, and paving a waterproof coiled material after the base layer treating agent is dried;

when the waterproof coiled material is laid, the unfolded part is unfolded after the coiled material is rolled for 1m, the heating spray gun is adopted to heat the hot melt adhesive surface and the base layer on the bottom surface of the waterproof coiled material until the hot melt adhesive layer has black luster and shines until micro bubbles appear, the coiled material is slowly laid down and laid on the base layer, and then the air exhaust roller is used for rolling the coiled material to ensure that the coiled material is firmly bonded with the base layer;

(5) the solar panel support matched with the roof structure is erected on the outer top plate, and the solar panel is laid on the support.

Particularly, in the step (2), the thickness of the outer top plate is 15cm, and the thickness of the inner top plate is 12 cm.

In particular, the stabilizer in the step (2) is hydroxypropyl methyl cellulose.

Specifically, the adhesive in the step (2) is composed of a modified polyurethane adhesive and an acrylic adhesive, and the mass ratio of the modified polyurethane adhesive to the acrylic adhesive is 2: 1.

in particular, the thickening agent in the step (2) is polyacrylamide.

Particularly, the waterproof coiled material in the step (4) is an asphalt waterproof coiled material.

Example 2

A method for manufacturing an energy-saving module house roof comprises the following steps:

(1) manufacturing a steel framework according to the roof structure of the module house;

(2) make outer roof and roof according to steel framework structure:

preparing materials: the components are as follows according to the parts by weight: 65 parts of Portland cement, 16 parts of straws, 22 parts of attapulgite clay, 12 parts of calcium oxide, 10 parts of wollastonite powder, 15 parts of marble, 10 parts of asbestos, 14 parts of magnesium oxide, 10 parts of magnesium chloride, 3 parts of a stabilizer, 3 parts of an adhesive and 4 parts of a thickening agent;

adding a proper amount of water into the raw materials, uniformly stirring, pouring into a corresponding mould, standing at room temperature for 16h, demoulding, taking out, and curing for 7 days;

(3) fixing the outer top plate and the inner top plate on a steel framework;

(4) and (3) carrying out waterproof treatment on the outer top plate:

coating a layer of waterproof paint on the outer top plate, naturally drying the outer top plate, and repairing the outer top plate to enable the surface of the outer top plate to be flat;

coating a base layer treating agent on the outer top plate, and paving a waterproof coiled material after the base layer treating agent is dried;

when the waterproof coiled material is laid, the unfolded part is unfolded after the coiled material is rolled for 1m, the heating spray gun is adopted to heat the hot melt adhesive surface and the base layer on the bottom surface of the waterproof coiled material until the hot melt adhesive layer has black luster and shines until micro bubbles appear, the coiled material is slowly laid down and laid on the base layer, and then the air exhaust roller is used for rolling the coiled material to ensure that the coiled material is firmly bonded with the base layer;

(5) the solar panel support matched with the roof structure is erected on the outer top plate, and the solar panel is laid on the support.

Particularly, in the step (2), the thickness of the outer top plate is 18cm, and the thickness of the inner top plate is 16 cm.

In particular, the stabilizer in the step (2) is hydroxypropyl methyl cellulose.

Specifically, the adhesive in the step (2) is composed of a modified polyurethane adhesive and an acrylic adhesive, and the mass ratio of the modified polyurethane adhesive to the acrylic adhesive is 7: 4.

in particular, the thickening agent in the step (2) is polyacrylamide.

Particularly, the waterproof roll in the step (4) is a high-molecular waterproof roll.

Example 3

A method for manufacturing an energy-saving module house roof comprises the following steps:

(1) manufacturing a steel framework according to the roof structure of the module house;

(2) make outer roof and roof according to steel framework structure:

preparing materials: the components are as follows according to the parts by weight: 60 parts of portland cement, 12 parts of straw, 17 parts of attapulgite clay, 11 parts of calcium oxide, 7 parts of wollastonite powder, 12 parts of marble, 7 parts of asbestos, 13 parts of magnesium oxide, 9 parts of magnesium chloride, 2 parts of a stabilizer, 2 parts of an adhesive and 3 parts of a thickening agent;

adding a proper amount of water into the raw materials, uniformly stirring, pouring into a corresponding mould, standing at room temperature for 14.5h, demoulding, taking out, and curing for 6 days;

(3) fixing the outer top plate and the inner top plate on a steel framework;

(4) and (3) carrying out waterproof treatment on the outer top plate:

coating a layer of waterproof paint on the outer top plate, naturally drying the outer top plate, and repairing the outer top plate to enable the surface of the outer top plate to be flat;

coating a base layer treating agent on the outer top plate, and paving a waterproof coiled material after the base layer treating agent is dried;

when the waterproof coiled material is laid, the unfolded part is unfolded after the coiled material is rolled for 1m, the heating spray gun is adopted to heat the hot melt adhesive surface and the base layer on the bottom surface of the waterproof coiled material until the hot melt adhesive layer has black luster and shines until micro bubbles appear, the coiled material is slowly laid down and laid on the base layer, and then the air exhaust roller is used for rolling the coiled material to ensure that the coiled material is firmly bonded with the base layer;

(5) the solar panel support matched with the roof structure is erected on the outer top plate, and the solar panel is laid on the support.

Particularly, in the step (2), the thickness of the outer top plate is 16cm, and the thickness of the inner top plate is 14 cm.

In particular, the stabilizer in the step (2) is hydroxypropyl methyl cellulose.

Specifically, the adhesive in the step (2) is composed of a modified polyurethane adhesive and an acrylic adhesive, and the mass ratio of the modified polyurethane adhesive to the acrylic adhesive is 13: 7.

In particular, the thickening agent in the step (2) is polyacrylamide.

Particularly, the waterproof coiled material in the step (4) is an asphalt waterproof coiled material.

The invention has been described in an illustrative manner, and it is to be understood that the invention is not limited to the specific embodiments described above, but is intended to cover various modifications, which may be made by the methods and technical solutions of the invention, or may be applied to other applications without modification.