CN206219451U - Heat-insulating, fire-preventing type energy saving building sheet material - Google Patents

Abstract

The utility model discloses a heat-insulating and fire-proof energy-saving building plate, which comprises an outer reflective layer, an inner fire-proof layer and a middle heat-insulating layer covered between the outer reflective layer and the inner fire-proof layer, wherein the inner wall of the outer reflective layer is sunken An inner concave cavity is formed, and the outer wall of the inner fireproof layer is depressed to form an outer concave cavity. The positions of the outer concave cavity and the inner concave cavity correspond to each other and are combined to form an accommodating space corresponding to the shape of the middle heat insulation layer to accommodate the middle heat insulation layer, and, The periphery of the outer reflection layer and the periphery of the inner fireproof layer are respectively provided with at least two through holes, so that at least two fasteners respectively pass through at least two through holes to connect the outer reflection layer, the middle heat insulation layer and the inner The fireproof layer is fixed as a whole. The heat-insulating and fire-proof energy-saving building plate of the utility model not only has excellent heat-insulating and fire-proof effects, but also has high safety in use.

Description

Heat-insulating and fire-proof energy-saving building panels

technical field

The utility model relates to a building board, in particular to an energy-saving building board.

Background technique

With the gradual coming of the energy crisis and the enhancement of people's awareness of environmental protection and energy conservation, energy-saving technology has made great progress. Due to the unprecedented development of China's real estate industry in recent years, the market demand for energy-saving buildings that closely revolve around real estate has also gradually increased. Including demand for energy efficient building panels.

Building panels are mainly widely used on the surface of exterior walls, interior walls, ceilings, partitions, etc. of buildings. In addition to decoration, building panels also have functions such as wall protection, heat preservation, moisture resistance, and sound insulation. Currently, expanded polystyrene board (EPS), extruded polystyrene board (XPS), spray polyurethane (SPU), polycarbonate, etc. The compressive strength is about 0.294 MPa, and it takes a period of maturity for the board to ensure its quality after leaving the factory. The polyurethane material is not resistant to acid and alkali, easy to age, and prone to detachment. More importantly, the flammability of building panels made of organic materials has become its fatal shortcoming. For example, XPS and EPS are easy to catch fire, and PU will release toxins when exposed to high temperatures.

In addition, in order to avoid the change of the internal and external ambient temperature of the building, and to avoid indoor overheating or overcooling, it is necessary to use building panels with thermal insulation effects. However, the building panels with heat insulation function currently used are always unsatisfactory in heat insulation effect.

For example, Chinese patent application No. 201510876788.7 discloses a moisture-proof and heat-insulating building board. The raw material components are composed as follows in parts by weight: inner coating: 25-30 parts of cement, 12-15 parts of steelmaking waste residue, 6-8 parts of perlite powder 12-15 parts of fly ash, 2-3 parts of expanded vitrified microbeads, 0.6-0.8 parts of vegetable protein glue, 3-5 parts of EVA redispersible rubber powder; outer coating: 4-6 parts of bentonite, plant 0.3-0.5 parts of protein glue, 2-4 parts of latex powder, 5-8 parts of sepiolite, 4-6 parts of bentonite, 0.8-1 part of superplasticizer, 3-4 parts of silicon dioxide, 2-3 parts of moisture-proof agent parts, alkali-resistant glass fiber 0.6-0.8 parts. However, the building board disclosed in this patent is a kind of building material with paint properties, which not only has a long period of construction, but also has complicated procedures, and the building board does not have a fireproof function.

Another example is Chinese patent application 201210040398.2, which discloses a method for making a non-combustible, heat-insulating, sound-insulating, light-weight, heat-insulating and decorative integrated building board, which weighs 35%-45% of rock foam material and 30%-35% of cement according to the percentage of the total weight of the product. , Methyl hydroxyethyl cellulose 0.2%-0.3%, redispersible latex 3.0-3.5%, lignocellulose 0.2%-0.3%, waste plastic micropowder abrasive 15-25%, mixed to make non-combustible heat insulation sound insulation light After mixing the non-combustible, heat-insulating, sound-insulating, and light-weight material with water in proportion, inject it into the frame of the prefabricated part of the tiles and press the ceramic tile insulation board or the painted surface insulation board. However, the building boards disclosed in this patent need to press ceramic insulation boards or painted surface insulation boards on non-combustible, heat-insulating and sound-insulating light materials. This pressing process has certain safety hazards. It has not yet achieved good results in terms of isolating solar radiant heat and isolating the impact of outdoor high temperature in summer.

Therefore, it is an urgent problem to be solved in the industry to provide an energy-saving building board with high safety and good heat insulation and fire prevention effect.

Contents of the invention

The purpose of the utility model is to provide a heat-insulating and fire-proof energy-saving building plate with high safety, good heat insulation effect, fire prevention effect and easy installation.

In order to achieve the above purpose, the utility model provides a heat-insulating and fire-proof energy-saving building board, which includes an external reflective layer, an internal fire-proof layer, and a middle heat-insulating layer wrapped between the external reflective layer and the internal fire-proof layer, wherein, The inner wall of the external reflective layer is recessed to form an inner cavity, and the outer wall of the inner fireproof layer is recessed to form an outer cavity. The positions of the outer cavity and the inner cavity correspond to each other and are combined to form an accommodating space corresponding to the shape of the middle heat insulation layer to accommodate the middle part. The heat insulation layer, and at least two through holes are respectively provided on the periphery of the outer reflection layer and the periphery of the inner fireproof layer, so that at least two fasteners respectively pass through at least two through holes to connect the outer reflection layer, The middle heat insulation layer and the inner fireproof layer are fixed as one.

Optionally, the fasteners are bolts, screws, rivets and other mechanical parts with fastening and connection functions.

Alternatively, the through holes may be threaded bolt holes.

Preferably, several longitudinal hollow passages spaced apart from each other are provided on the middle heat insulation layer.

Optionally, at least five longitudinal hollow passages arranged at equal intervals may be provided on the middle heat insulating layer; A longitudinal hollow channel; or, a hollow area, such as a cuboid hollow area, is provided inside the middle heat insulation layer.

Preferably, the volume of the longitudinal hollow channel accounts for 30%-45% of the volume of the middle insulation layer.

Preferably, one through hole is respectively provided at the four corners of the outer reflective layer and the inner fireproof layer.

Preferably, the raw material components of the external reflection layer include by weight: 40-45 parts of cement, 15-25 parts of water, 16-18 parts of filler, and 6-10 parts of reflective agent.

Preferably, the reflector includes 1 to 3 parts by weight of monocrystalline silicon powder and 5 to 7 parts of aluminum silicate, wherein the monocrystalline silicon powder has the function of reflecting sunlight, while the aluminum silicate has the function of reflecting sunlight at the same time. Sunlight and the effect of blocking heat transfer.

Preferably, the raw material components of the middle insulation layer include, by weight, 20-25 parts of cement, 7-12 parts of water, 6-8 parts of glass powder, and 3-4 parts of antimony oxide.

Preferably, the particle size of the glass powder is 0.3-0.5 mm.

Preferably, the raw material components of the inner fireproof layer include, by weight, 25-30 parts of cement, 12-20 parts of water, 5-8 parts of filler, and 6-8 parts of perlite powder.

Preferably, the filler is alumina ceramic balls with a particle size of 2-4 mm.

Another object of the present utility model is to provide a method for preparing heat-insulating and fire-proof energy-saving building panels, which includes: (1) mixing 40-45 parts of cement, 15-25 parts of water, 16-18 parts of filler, and reflective After mixing 6 to 10 parts of the agent evenly, place it in the external reflective layer mold and let it stand for 3 to 5 hours, demould to obtain the external reflective layer; (2), mix 25 to 30 parts of cement, 12 to 20 parts of water, filler After mixing 5-8 parts and 6-8 parts of perlite powder evenly, place them in the mold of the internal fireproof layer and let it stand for 3-5 hours, demould, and make the internal fireproof layer; (3), mix 20-25 parts of cement , 7 to 12 parts of water, 6 to 8 parts of glass powder, and 3 to 4 parts of antimony oxide are mixed evenly, placed in the middle heat insulation layer mold and left to stand for 2 to 3 hours, demolded, and the middle heat insulation layer is obtained; (4) Place the middle heat insulation layer in the outer concave cavity of the inner fireproof layer, correspond the inner concave cavity of the outer reflective layer to the outer concave cavity, cover it on the inner fireproof layer, and pass at least two fasteners Pass through at least two through holes at corresponding positions around the outer reflective layer and the inner fireproof layer respectively, so as to fix the outer reflective layer, the middle heat insulation layer and the inner fireproof layer into one body, and obtain a heat-insulating and fireproof energy-saving building board.

The beneficial effects of the utility model are: (1) Utilize three-layer boards with reflection, heat insulation and fireproof effects respectively and rationally construct the arrangement among the three-layer boards, so that the formed building boards have excellent fireproof and heat insulation effects ; (2), the setting of the longitudinal hollow channel in the middle heat insulation layer can not only effectively reduce the weight of the building board, but also has a certain sound insulation effect; (3), the middle heat insulation layer is set between the outer reflective layer and the inner fireproof layer In the cavity formed between the outer reflective layer and the inner fireproof layer are connected by fasteners, so that the connection of the three-layer board is fastened, and the use safety of the building board is high.

Description of drawings

Fig. 1 is a schematic diagram of the external structure of the heat-insulating and fire-proof energy-saving building board of the present invention.

Fig. 2 is a structural schematic diagram of the D-D section in Fig. 1 of the present utility model.

Fig. 3 is a three-dimensional structural schematic diagram of the external reflective layer and the internal fireproof layer of the present invention.

detailed description

Embodiments of the present application are described in detail below, and examples of the embodiments are shown in the drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below by referring to the figures are exemplary, and are intended to explain the present application, and should not be construed as limiting the present application.

First of all, please refer to Fig. 1 and Fig. 2, according to a non-limiting embodiment of the present invention, the heat-insulating and fire-proof energy-saving building board of the present invention includes an external reflective layer A, an internal fire-proof layer B and a reflective layer coated on the external Intermediate insulation layer C between layer A and inner fire protection layer B.

Wherein, as shown in Figure 3, the inner wall of the external reflective layer A is recessed to form an inner cavity V, and in order to accommodate the middle heat insulation layer C, correspondingly, the outer wall of the inner fireproof layer is recessed to form an outer cavity (not shown in the figure shown), and the positions of the outer concave cavity and the inner concave cavity correspond to each other, thereby forming a combined accommodating space, which corresponds to the shape of the middle heat insulation layer, so that the middle heat insulation layer can be accommodated in the in this accommodation space. At the same time, a bolt hole H is respectively provided at the four corners and longitudinal midpoints of the outer reflective layer A and the inner fireproof layer B, and the outer reflective layer A and the middle heat insulation layer are connected by six bolts passing through the bolt holes H respectively. C and the inner fireproof layer B are fixed as one.

As an alternative embodiment, as shown in Figure 2, five longitudinal hollow passages P are arranged on the middle insulation layer C, and the volume of the longitudinal hollow passages P accounts for 40% of the volume of the middle insulation layer C. Therefore, not only can the weight of building panels be effectively reduced to facilitate construction, but also have the effect of sound insulation and moisture resistance.

The preparation methods of the outer reflective layer A, the inner fireproof layer B and the middle heat insulation layer C will be further described in detail below in conjunction with specific examples.

Example 1

In parts by weight, 40 parts of cement, 15 parts of water, 16 parts of alumina ceramic balls with a particle size of 3 mm, 2 parts of monocrystalline silicon powder and 6 parts of aluminum silicate are placed in the external reflective layer mold and let stand After 3 hours, the outer reflective layer was obtained after demoulding.

Then, in parts by weight, after mixing 20 parts of cement, 8 parts of water, 6 parts of glass powder with a particle size of 0.4 mm, and 4 parts of antimony oxide, they were placed in the middle heat insulation layer mold and stood for 2 hours. After demoulding, the middle insulation layer is obtained.

Then, continue to mix 30 parts of cement, 20 parts of water, 8 parts of alumina ceramic balls with a particle size of 2 mm, and 8 parts of perlite powder in parts by weight, and then place them in the inner fireproof layer mold and let it stand After 5 hours, the inner fireproof layer was obtained after demoulding.

Finally, place the middle insulation layer in the outer concave cavity of the inner fireproof layer, match the inner concave cavity of the outer reflective layer with the outer concave cavity, cover it on the inner fireproof layer, and pass through the two fasteners respectively. Two through holes at the corresponding positions on the outer reflective layer and the inner fireproof layer are used to fix the outer reflective layer, the middle heat insulation layer and the inner fireproof layer into one body to obtain a heat-insulating and fireproof energy-saving building board.

Example 2

In parts by weight, 45 parts of cement, 25 parts of water, 18 parts of alumina ceramic balls with a particle size of 4 mm, 1 part of monocrystalline silicon powder and 7 parts of aluminum silicate are placed in the external reflective layer mold and allowed to stand After 5 hours, the external reflective layer was obtained after demoulding.

Then, in parts by weight, after mixing 25 parts of cement, 12 parts of water, 8 parts of glass powder with a particle size of 0.3 mm, and 3 parts of antimony oxide, they were placed in the middle heat insulation layer mold and left to stand for 3 hours. After demoulding, the middle insulation layer is obtained.

Then, continue to mix 25 parts of cement, 12 parts of water, 5 parts of alumina ceramic balls with a particle size of 3 mm, and 6 parts of perlite powder in parts by weight, then place them in the inner fireproof layer mold and let it stand After 3 hours, the inner fireproof layer was obtained after demoulding.

Finally, place the middle heat insulation layer in the outer concave cavity of the inner fireproof layer, match the inner concave cavity of the outer reflective layer with the outer concave cavity, cover it on the inner fireproof layer, and pass through the four fasteners respectively. The four through holes at the corresponding positions on the periphery of the outer reflective layer and the inner fireproof layer fix the outer reflective layer, the middle heat insulation layer and the inner fireproof layer into one body to obtain a heat-insulating and fireproof energy-saving building board.

Example 3

In parts by weight, 42 parts of cement, 20 parts of water, 17 parts of alumina ceramic balls with a particle size of 2 mm, 3 parts of monocrystalline silicon powder and 5 parts of aluminum silicate are placed in the external reflective layer mold and let stand After 4 hours, the outer reflective layer was obtained after demoulding.

Then, in parts by weight, after mixing 22 parts of cement, 10 parts of water, 7 parts of glass powder with a particle size of 0.5 mm, and 3 parts of antimony oxide, they were placed in the middle heat insulation layer mold and left to stand for 2 hours. After demoulding, the middle insulation layer is obtained.

Then, continue to mix 28 parts of cement, 15 parts of water, 6 parts of alumina ceramic balls with a particle size of 4 mm, and 7 parts of perlite powder in parts by weight, then place them in the inner fireproof layer mold and let it stand After 4 hours, the inner fireproof layer was obtained after demoulding.

Finally, place the middle heat insulation layer in the outer concave cavity of the inner fireproof layer, match the inner concave cavity of the outer reflective layer with the outer concave cavity, cover it on the inner fireproof layer, and pass through the four fasteners respectively. The four through holes at the corresponding positions on the periphery of the outer reflective layer and the inner fireproof layer fix the outer reflective layer, the middle heat insulation layer and the inner fireproof layer into one body to obtain a heat-insulating and fireproof energy-saving building board.

Example 4

In parts by weight, 43 parts of cement, 18 parts of water, 18 parts of alumina ceramic balls with a particle size of 3 mm, 2 parts of monocrystalline silicon powder and 6 parts of aluminum silicate are placed in the external reflective layer mold and let stand After 5 hours, the external reflective layer was obtained after demoulding.

Then, in parts by weight, after mixing 24 parts of cement, 12 parts of water, 8 parts of glass powder with a particle size of 0.3 mm, and 4 parts of antimony oxide, they were placed in the middle heat insulation layer mold and left to stand for 3 hours. After demoulding, the middle insulation layer is obtained.

Then, continue to mix 27 parts of cement, 13 parts of water, 5 parts of alumina ceramic balls with a particle size of 4 mm, and 6 parts of perlite powder in parts by weight, and then place them in the inner fireproof layer mold and let it stand After 5 hours, the inner fireproof layer was obtained after demoulding.

Finally, place the middle heat insulation layer in the outer concave cavity of the inner fireproof layer, match the inner concave cavity of the outer reflective layer with the outer concave cavity, cover it on the inner fireproof layer, and pass through the four fasteners respectively. The four through holes at the corresponding positions on the periphery of the outer reflective layer and the inner fireproof layer fix the outer reflective layer, the middle heat insulation layer and the inner fireproof layer into one body to obtain a heat-insulating and fireproof energy-saving building board.

Example 5

In parts by weight, 40 parts of cement, 15 parts of water, 17 parts of alumina ceramic balls with a particle size of 4 mm, 3 parts of monocrystalline silicon powder and 6 parts of aluminum silicate are placed in the external reflective layer mold and left to stand After 3 hours, the outer reflective layer was obtained after demoulding.

Then, in parts by weight, after mixing 20 parts of cement, 10 parts of water, 8 parts of glass powder with a particle size of 0.3 mm, and 4 parts of antimony oxide, they were placed in the middle heat insulation layer mold and left to stand for 3 hours. After demoulding, the middle insulation layer is obtained.

Then, continue to mix 30 parts of cement, 18 parts of water, 6 parts of alumina ceramic balls with a particle size of 4 mm, and 6 parts of perlite powder in parts by weight, then place them in the inner fireproof layer mold and let it stand After 5 hours, the inner fireproof layer was obtained after demoulding.

Finally, place the middle insulation layer in the outer concave cavity of the inner fireproof layer, match the inner concave cavity of the outer reflective layer with the outer concave cavity, cover it on the inner fireproof layer, and pass through the two fasteners respectively. Two through holes at the corresponding positions on the outer reflective layer and the inner fireproof layer are used to fix the outer reflective layer, the middle heat insulation layer and the inner fireproof layer into one body to obtain a heat-insulating and fireproof energy-saving building board.

It can be seen that the utility model uses three-layer boards with reflection, heat insulation and fireproof effects respectively and reasonably constructs the arrangement between the three-layer boards, so that the prepared building boards have excellent fireproof heat insulation and sound insulation effects, At the same time, the use safety of the building panels is effectively improved through the connection of the fasteners.

Although the preferred embodiment of the present utility model has been described in detail here, it should be understood that the present utility model is not limited to the specific structures and steps described and shown in detail here, without departing from the spirit and scope of the present utility model Other modifications and variations can be realized by those skilled in the art below.

Claims (8)

1. A heat-insulating and fire-proof energy-saving building board, characterized in that it comprises an external reflective layer, an internal fire-resistant layer, and a middle heat-insulating layer coated between the external reflective layer and the internal fire-resistant layer, wherein the The inner wall of the external reflective layer is recessed to form an inner concave cavity, the outer wall of the inner fireproof layer is concave to form an outer concave cavity, and the positions of the outer concave cavity and the inner concave cavity correspond to each other and are combined to form an inner cavity with the middle heat insulation layer. The accommodating space has a corresponding shape to accommodate the middle heat insulation layer, and at least two through holes are respectively provided at the corresponding positions of the periphery of the outer reflective layer and the periphery of the inner fireproof layer, so that at least two fastening Parts respectively pass through the at least two through holes to fix the outer reflective layer, the middle heat insulation layer and the inner fireproof layer into one body. 2. The heat-insulating and fire-proof energy-saving building board according to claim 1, characterized in that, several longitudinal hollow passages spaced apart from each other are provided on the middle heat-insulating layer. 3 . The heat-insulating and fire-proof energy-saving building board according to claim 2 , wherein the volume of the longitudinal hollow channel accounts for 30% to 45% of the volume of the middle insulation layer. 4 . 4 . The heat-insulating and fire-proof energy-saving building board according to claim 3 , wherein a through hole is respectively provided at the four corners of the external reflective layer and the internal fire-proof layer. 5. The heat-insulating and fire-proof energy-saving building board according to claim 4, wherein the fasteners are bolts, screws or rivets. 6. The heat-insulating and fire-proof energy-saving building board according to claim 5, wherein at least five longitudinal hollow passages arranged at equal intervals are arranged on the middle heat-insulating layer. 7. The heat-insulating and fire-proof energy-saving building board according to claim 5, wherein two rows of longitudinal hollow passages are arranged on the middle insulation layer, and each row of longitudinal hollow passages includes at least three longitudinal hollow passages arranged at equal intervals. aisle. 8. The heat-insulating and fire-proof energy-saving building board according to claim 1, wherein a hollow area is provided inside the middle heat-insulating layer.