CN218861818U - A vitrified microbead thermal insulation and energy-saving building wall - Google Patents

Abstract

This application relates to a vitrified microbead thermal insulation and energy-saving building wall, which includes two building wall bodies and a pressure plate. The building wall body is mainly composed of the first interface mortar and the first vitrified microbead thermal insulation mortar. , alkali-resistant grid cloth and anti-cracking mortar are stacked in sequence, and the two sides of the building wall bodies close to each other are provided with an assembly structure, and the assembly structure includes a first assembly block and a second assembly block, and the first The sides of the assembly block and the second assembly block which are far away from each other are respectively fixedly connected with the two building wall bodies. This application can prefabricate the building wall body, and install the building wall body by using the assembly structure by connecting the first assembly block and the second assembly block, so as to heat and insulate the building more quickly and conveniently deal with.

Description

A vitrified microbead thermal insulation and energy-saving building wall

technical field

The utility model relates to the field of thermal insulation and energy-saving buildings, in particular to a vitrified microbead thermal insulation and energy-saving building wall.

Background technique

With the modernization of urban development, the energy-saving and environmental protection-related capabilities of buildings have gradually entered people's field of vision, and more and more materials related to energy-saving and emission reduction have been applied to the field of building construction. Among them, vitrified microbead thermal insulation mortar, because of its excellent thermal insulation performance, stable material, and excellent fire resistance, is often used on the inner side of the building's outer wall to heat and insulate the interior of the building to a certain extent. Reduce electricity consumption for maintaining a suitable indoor temperature in summer and winter.

In the current state of the art, when the operator needs to use vitrified microbead thermal insulation mortar to heat-insulate the building, it is usually first to apply the interface mortar on the outside of the wall plaster layer as the base, and then apply the vitrified microbead thermal insulation The thermal mortar is used for thermal insulation, and finally the outer layer is coated with alkali-resistant mesh cloth and anti-cracking mortar for protection.

Although the above treatment method can better achieve the thermal insulation effect of the building, due to the layer-by-layer construction method, it needs a certain construction time and construction site, and it needs to be plastered and leveled in the later stage. When the operator When the target building that needs thermal insulation treatment is a building that has already been put into use, it is usually difficult to meet the above construction conditions because there are already relevant personnel working in the building. To sum up, in order to solve the above problems, the inventor proposes a thermal insulation and energy-saving building wall made of vitrified microbeads.

Utility model content

The utility model is to solve the problem that although the existing treatment method can better achieve the thermal insulation effect of the building, it needs a certain construction time and construction site due to the layer-by-layer construction method, and it needs to be plastered and leveled in the later stage. Work, when the target building that the operator needs to perform thermal insulation treatment is a building that has already been put into use, because there are already relevant personnel working in the building, it is usually difficult to meet the above construction conditions. A vitrified microbead thermal insulation is proposed. Energy-saving building walls.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a vitrified microbead thermal insulation and energy-saving building wall, including two building wall bodies and pressure plates, the building wall body is composed of the first interface mortar, the second A vitrified microbead thermal insulation mortar, alkali-resistant grid cloth and crack-resistant mortar are sequentially stacked, and the two building wall bodies are provided with an assembly structure on the side close to each other. The assembly structure includes a first assembly block and a The second assembly block, the sides of the first assembly block and the second assembly block that are far away from each other are fixedly connected to the two building wall bodies, and the inside of the first assembly block is provided with a mounting groove, and the inside of the mounting groove The top wall is threadedly connected with a screw rod, and one end of the screw rod inserted into the installation groove is rotatably connected with a rotating ring, and one end of the rotating ring is fixedly connected with a limiting block, and both ends of the limiting block are fixedly connected with a positioning column. The upper end of the positioning column slides through the first assembly block, and the inside of the second assembly block is provided with a sliding groove, the inner wall of the sliding groove is slidably connected with a sliding block, and the surface of the sliding block is fixedly connected with a control frame. One end of the control frame is slidingly connected with the second assembly block, the shape and size of the slide block are adapted to the screw rod and the positioning column, and one side of the pressure plate is fixedly connected with the first assembly block and the second assembly block by means of bolts.

The effect achieved by the above components is: when the target building that the operator needs to perform thermal insulation treatment is a building that has already been put into use, because there are already relevant personnel working in the building, it is usually difficult to meet the construction conditions of normal construction layer by layer , the building wall body can be prefabricated, and with the help of the assembly structure, the building wall body can be installed by connecting the first assembly block and the second assembly block, so that the building can be thermally insulated more quickly and conveniently , and when some thermal insulation materials are aging and the thermal insulation effect declines, it is also convenient to disassemble and replace the building wall body.

Preferably, the press plate includes a second interface mortar and a second vitrified bead thermal insulation mortar, and the press plate is composed of two second interface mortars and a second vitrified microsphere sandwiched between the two second interface mortars. Bead thermal insulation mortar composition.

The effect achieved by the above components is: after the installation of the building wall body is completed, the assembly part is covered with a pressing plate to obtain a better thermal insulation effect.

Preferably, both sides of the inner wall of the installation groove are respectively fixedly connected with limiting rails, and the entrances of the limiting rails are opened at 30°.

The effect achieved by the above components is: the sliding block is limited, and the slightly opened limiting rail at the entrance can make the sliding block slide into the limiting rail more easily.

Preferably, the position of the inner top wall of the installation groove corresponding to the screw rod is fixedly connected to the limit frame, and one end of the screw rod is threaded through the limit frame.

The effect achieved by the above components is: the effect of limiting the position of the screw rod is achieved, so that the operation of the assembly structure is more reliable.

Preferably, a handle is fixedly connected to one end of the screw, and the cross section of the handle is rectangular.

The effect achieved by the above components is: it is easier for the operator to turn the screw rod, so as to facilitate the operation of the assembly structure to install the building wall body.

Preferably, a limiting groove is provided on the lower surface of the sliding block, the limiting groove matches the shape and size of the limiting block, and the inner wall of the limiting groove engages with the limiting block.

The effect achieved by the above components is: the effect of limiting the position of the limit block is achieved, so that the assembly of the building wall body is more firm.

Preferably, two card slots are provided on the side of the first assembly block close to the second assembly block, and two card slots are fixedly connected to the side of the second assembly block close to the first assembly block. The size of the shape of the block is suitable, and the inner wall of the slot is engaged with the block.

The effect achieved by the above components is: after the first assembly block and the second assembly block are connected, the effect of limiting the first assembly block and the second assembly block is achieved.

Preferably, grooves are formed on the side of the first assembly block and the second assembly block close to the pressure plate, the grooves match the thickness of the pressure plate, and the pressure plate is located in the grooves.

The effect achieved by the above-mentioned components is: the pressure plate is stored, so that the surface of the building wall body remains flat after the pressure plate is installed, so that it is more convenient to use.

In summary, the beneficial effects of the utility model are:

When the target building that the operator needs to carry out thermal insulation treatment is a building that has already been put into use, because there are already relevant personnel working in the building, it is usually difficult to meet the construction conditions of normal construction layer by layer, the building wall body can be prefabricated, and with the help of assembly Structure, by using the method of connecting the first assembly block and the second assembly block, the building wall body is installed, so that it is faster and more convenient to conduct thermal insulation treatment on the building, and some thermal insulation materials will be aging later. , when the thermal insulation effect declines, it can also facilitate the disassembly and replacement of the building wall body.

Description of drawings

Fig. 1 is a three-dimensional structure schematic diagram of the utility model.

Fig. 2 is a perspective view of the rear side of Fig. 1 of the utility model.

Fig. 3 is a schematic cross-sectional structure diagram of the disassembled state shown in Fig. 1 of the utility model.

Fig. 4 is a schematic cross-sectional structural view of the first assembly block of the utility model.

Fig. 5 is a schematic diagram of the three-dimensional structure of the limit block of the utility model.

Fig. 6 is a schematic diagram of a disassembled structure at the second assembly block of the utility model.

Fig. 7 is a schematic diagram of the lower structure of the sliding block of the utility model.

Explanation of reference signs:

1. Building wall body; 11. The first interface mortar; 12. The first vitrified microbead thermal insulation mortar; 13. Alkali-resistant mesh cloth; 14. Crack-resistant mortar; 2. Assembly structure; 201. The first Assembly block; 202, second assembly block; 203, mounting groove; 204, screw rod; 205, rotating ring; 206, limit block; 207, positioning column; 208, sliding groove; 209, sliding block; 210, control frame; 211, pressing plate; 2111, second interface mortar; 2112, second vitrified bead thermal insulation mortar; 212, limit rail; 213, limit frame; 214, handle; 215, limit groove; 216, card slot ; 217, block; 218, groove.

Detailed ways

Referring to Fig. 1 and Fig. 2 and Fig. 3, this embodiment discloses a vitrified microbead thermal insulation and energy-saving building wall, which includes two building wall bodies 1 and pressing plates 211, and the building wall body 1 consists of a first The interface mortar 11, the first vitrified microbead thermal insulation mortar 12, the alkali-resistant grid cloth 13 and the anti-crack mortar 14 are sequentially stacked, and the two building wall bodies 1 are provided with an assembly structure 2 on the side close to each other.

Referring to Fig. 3, Fig. 4 and Fig. 5 and Fig. 6, the present embodiment discloses that the assembly structure 2 includes a first assembly block 201 and a second assembly block 202, and the first assembly block 201 and the second assembly block 202 are far away from each other. One side is fixedly connected with two building wall bodies 1 respectively, and the inside of the first assembly block 201 is provided with a mounting groove 203, and the inner top wall of the mounting groove 203 is threadedly connected with a screw rod 204, and one end of the screw rod 204 inserted into the mounting groove 203 is rotatably connected with a Rotating ring 205, one end of rotating ring 205 is fixedly connected with limiting block 206, both ends of limiting block 206 are fixedly connected with positioning column 207, the upper end of positioning column 207 slides through the first assembly block 201, the second assembly block 202 The inside is provided with a sliding groove 208, the inner wall of the sliding groove 208 is slidably connected with a sliding block 209, the surface of the sliding block 209 is fixedly connected with a control frame 210, and one end of the control frame 210 is slidably connected with the second assembly block 202, and the shape of the sliding block 209 is The size is suitable for the screw rod 204 and the positioning column 207 , and one side of the pressure plate 211 is fixedly connected with the first assembly block 201 and the second assembly block 202 by means of bolts. When the target building that the operator needs to carry out thermal insulation treatment is a building that has already been put into use, because there are already relevant personnel working in the building, it is usually difficult to meet the construction conditions of normal construction layer by layer, the building wall body can be prefabricated 1 , with the help of the assembly structure 2, the building wall body 1 is installed by using the method of connecting the first assembly block 201 and the second assembly block 202, so that the building wall body 1 is installed more quickly and conveniently, and the subsequent When part of the thermal insulation material is aging and the thermal insulation effect decreases, it is also convenient to disassemble and replace the building wall body 1 .

Referring to Fig. 3, the present embodiment discloses that the pressing plate 211 includes the second interface mortar 2111 and the second vitrified bead thermal insulation mortar 2112, and the pressing plate 211 is composed of two second interface mortars 2111 and sandwiched between the two second interface The second vitrified bead thermal insulation mortar 2112 between the mortar 2111 is formed. After the installation of the building wall body 1 is completed, the pressing plate 211 is used to cover the assembly part to obtain better thermal insulation effect.

4 and 5, this embodiment discloses that both sides of the inner wall of the installation groove 203 are respectively fixedly connected with the limit rail 212, and the entrance of the limit rail 212 is opened at 30°. The sliding block 209 is limited, and the slightly stretched limiting rail 212 at the entrance can make the sliding block 209 slide into the limiting rail 212 more easily, and the position of the inner top wall of the installation groove 203 corresponding to the screw rod 204 is fixedly connected to the limiting frame 213 , one end of the screw rod 204 threads through the limit frame 213 . This achieves the effect of limiting the position of the screw rod 204, thereby making the operation of the assembly structure 2 more reliable. One end of the screw rod 204 is fixedly connected with a handle 214, and the cross section of the handle 214 is rectangular. This achieves the effect of making it easier for the operator to rotate the screw rod 204 , thereby facilitating the installation of the building wall body 1 by operating the assembly structure 2 .

Referring to Fig. 3 and Fig. 7, the present embodiment discloses that the lower surface of the sliding block 209 is provided with a limit groove 215, the limit groove 215 is adapted to the size of the shape of the limit block 206, and the inner wall of the limit groove 215 is compatible with the limit The bit blocks 206 snap together. Reached limit block 206 is carried out limit, thereby the effect that makes the assembly of building wall body 1 more firm, the first assembly block 201 is provided with two draw-in grooves 216 on one side close to the second assembly block 202, and the second assembly block The side of 202 close to the first assembly block 201 is fixedly connected with two clamping blocks 217 , the clamping groove 216 is adapted to the shape and size of the clamping blocks 217 , and the inner wall of the clamping groove 216 is engaged with the clamping blocks 217 . After the first assembly block 201 and the second assembly block 202 are connected, the effect of limiting the first assembly block 201 and the second assembly block 202 is achieved, and the first assembly block 201 and the second assembly block 202 are close to the pressure plate 211 A groove 218 is formed on one side, and the groove 218 is adapted to the thickness of the pressure plate 211 , and the pressure plate 211 is located in the groove 218 . The pressure plate 211 is accommodated, so that the surface of the building wall body 1 remains flat after the pressure plate 211 is installed, thereby making it more convenient to use.

The working principle is:

When the target building that the operator needs to perform thermal insulation treatment is a building that has already been put into use, because there are already relevant personnel working in the building, it is usually difficult to meet the construction conditions of normal layer-by-layer coating, firstly, the handle 214 can be rotated to make the screw 204 move along the Rotate the limit frame 213, and drive the limit block 206 to move down through the rotating ring 205. At this time, the positioning column 207 limits the position of the limit block 206, and then the clamping blocks on the two building wall bodies 1 217 is aligned with the card slot 216 for assembly, and then the control frame 210 is moved to make the sliding block 209 slide into the installation groove 203 in the sliding groove 208. At this time, the limit rail 212 limits the sliding block 209, and the entrance is slightly open. The limit rail 212 can make the sliding block 209 slide into the limit rail 212 more easily, and then the handle 214 is reversely rotated, and the screw rod 204 drives the limit block 206 to snap into the limit groove 215, thereby limiting the position of the slide block 209, Then fix the first assembly block 201 and the second assembly block 202 in the connected state, then put the pressure plate 211 into the groove 218, and install it to the surface of the first assembly block 201 and the second assembly block 202 by means of bolts, that is, the alignment is completed. The assembly of building wall body body 1. By setting the assembly structure 2, it is faster and more convenient to carry out thermal insulation treatment on the building, and when some thermal insulation materials are aging later, and the thermal insulation effect declines, it is also convenient to disassemble and replace the building wall body 1 Effect.

Claims (8)

1. The utility model provides a thermal-insulated energy-conserving building wall of vitrified micro bubble heat preservation, includes two building wall bodies (1) and clamp plate (211), building wall body (1) is stacked gradually by first interface mortar (11), first vitrified micro bubble heat preservation heat insulation mortar (12), alkali-resisting net cloth (13) and anti-crack mortar (14) and is constituted, two building wall body (1) one side that is close to each other is equipped with assembly structure (2), its characterized in that: the assembly structure (2) comprises a first assembly block (201) and a second assembly block (202), one surfaces of the first assembling block (201) and the second assembling block (202) which are far away from each other are respectively fixedly connected with the two building wall bodies (1), the first assembling block (201) is internally provided with an installing groove (203), the inner top wall of the mounting groove (203) is connected with a screw rod (204) in a threaded manner, one end of the screw rod (204) inserted into the mounting groove (203) is rotationally connected with a rotating ring (205), one end of the rotating ring (205) is fixedly connected with a limit block (206), two ends of the limiting block (206) are fixedly connected with positioning columns (207), the upper end of the positioning column (207) penetrates through the first assembling block (201) in a sliding manner, a sliding groove (208) is arranged inside the second assembling block (202), the inner wall of the sliding groove (208) is connected with a sliding block (209) in a sliding way, the surface of the sliding block (209) is fixedly connected with a control frame (210), one end of the control frame (210) is connected with the second assembling block (202) in a sliding way, the size of the shape of the sliding block (209) is matched with that of the screw rod (204) and the positioning column (207), one surface of the pressure plate (211) is fixedly connected with the first assembly block (201) and the second assembly block (202) through bolts.

2. The vitrified micro bubble heat-insulation energy-saving building wall body of claim 1, which is characterized in that: the pressing plate (211) comprises second interface mortar (2111) and second vitrified micro bubble heat preservation and insulation mortar (2112), and the pressing plate (211) is composed of two second interface mortars (2111) and the second vitrified micro bubble heat preservation and insulation mortar (2112) clamped between the two second interface mortars (2111).

3. The vitrified microsphere heat-insulation energy-saving building wall body of claim 1, which is characterized in that: the both sides of mounting groove (203) inner wall are fixedly connected with spacing rail (212) respectively, the entrance of spacing rail (212) is 30 and opens.

4. The vitrified micro bubble heat-insulation energy-saving building wall body of claim 1, which is characterized in that: the position that the roof corresponds screw rod (204) in mounting groove (203) is connected with spacing (213) fixedly, the one end screw thread of screw rod (204) runs through spacing (213).

5. The vitrified microsphere heat-insulation energy-saving building wall body of claim 1, which is characterized in that: one end of the screw rod (204) is fixedly connected with a handle (214), and the cross section of the handle (214) is rectangular.

6. The vitrified micro bubble heat-insulation energy-saving building wall body of claim 1, which is characterized in that: the lower surface of the sliding block (209) is provided with a limiting groove (215), the limiting groove (215) is matched with the shape of the limiting block (206) in size, and the inner wall of the limiting groove (215) is clamped with the limiting block (206).

7. The vitrified micro bubble heat-insulation energy-saving building wall body of claim 1, which is characterized in that: two clamping grooves (216) are formed in one face, close to the second assembling block (202), of the first assembling block (201), two clamping blocks (217) are fixedly connected to one face, close to the first assembling block (201), of the second assembling block (202), the clamping grooves (216) are matched with the clamping blocks (217) in shape and size, and the inner wall of each clamping groove (216) is clamped with the clamping blocks (217).

8. The vitrified microsphere heat-insulation energy-saving building wall body of claim 1, which is characterized in that: one surfaces, close to the pressing plate (211), of the first assembling block (201) and the second assembling block (202) are provided with grooves (218), the grooves (218) are matched with the thickness of the pressing plate (211), and the pressing plate (211) is located in the grooves (218).

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