CN206418808U - One kind is applied to the decoration integrated module of cold district container construction inside holding - Google Patents

Abstract

An integrated thermal insulation and decoration module used in container buildings in cold regions, consisting of a transverse wall module, a longitudinal wall module, a floor module and a ceiling module; the transverse wall module is arranged along the length direction of the container, and the longitudinal wall module is arranged along the width direction of the container , the floor module is set at the bottom of the container, and the ceiling module is set along the top of the container; the transverse wall module is composed of the first light steel keel frame, the second light steel keel frame, protective layer, insulation layer and inner wall panels, and the transverse wall module One end of the module is provided with a first light steel keel frame, and the other end of the transverse wall module is provided with a second light steel keel frame. The first light steel keel frame and the second light steel keel frame are placed in the protective layer and the insulation layer. The module is provided with a protective layer, an insulating layer and an inner wall panel in sequence from the outside to the inside; the first light steel keel frame is evenly dislocated with openings. The utility model can realize the flexible disassembly and quick assembly of the inner wall modules of the container building, adopts factory production, assembly construction, waterproof, fireproof, weather-resistant and durable prefabricated modules to meet the heat preservation requirements of the container building in cold regions, and reduces the energy consumption of the building.

Description

An integrated module for thermal insulation and decoration in container buildings in cold regions

technical field

The utility model relates to an integrated thermal insulation and decoration module used in container buildings in cold regions.

Background technique

In recent years, container construction has gradually developed. The so-called container buildings are mostly transformed from containers, which have the characteristics of low cost, strong adaptability, mobility and easy assembly. Due to the needs of transportation and the pursuit of personalized building facades, container buildings mostly use internal insulation. Conventional methods of thermal insulation in container buildings require multiple processing of the interior of the container, and the volatilization of paint and putty during the processing will seriously pollute the indoor environment. At the same time, the traditional production method needs to carry out the finishing process after bonding the thermal insulation material. The production period is long, and the materials are not conducive to recycling. Features suitable for container construction. In addition, when the container building adopts the internal insulation method in cold regions, the interior of the container is generally filled with insulation materials first. Such a construction method is likely to cause condensation between the box body and the insulation material, resulting in short service life of the material and increased building energy consumption. . Therefore, there is a need for a new integrated module with high integration, short production period, easy assembly, easy disassembly, and recycling, so that it meets the energy-saving design standards for buildings in cold regions and is suitable for industrialized construction.

Utility model content

The purpose of the utility model is to provide an integrated construction method for interior insulation and decoration of container buildings suitable for cold climates. It adopts factory production, assembly construction, waterproof, fireproof, weather-resistant and durable prefabricated modules to meet the insulation requirements of container buildings in cold areas, and improve the building quality. High production efficiency, reducing building energy consumption, while ensuring the recycling of modules. The invention provides an integrated module for thermal insulation and decoration in container buildings in cold regions.

The utility model is an integrated thermal insulation and decoration module used in container buildings in cold regions, which is composed of a horizontal wall module, a vertical wall module, a floor module and a ceiling module; the horizontal wall module is arranged along the length direction of the container, and the vertical wall module Arranged along the width direction of the container, the floor module is arranged at the bottom of the container, and the ceiling module is arranged along the top of the container; the transverse wall module is composed of a first light steel keel frame, a second light steel keel frame, a protective layer , thermal insulation layer and inner wall panels, one end of the transverse wall module is provided with a first light steel keel frame, the other end of the transverse wall module is provided with a second light steel keel frame, and the first light steel keel frame and the second light steel keel frame are placed in the protective layer and the thermal insulation layer, and the protective layer, thermal insulation layer and inner wall panels are sequentially arranged on the transverse wall module from the outside to the inside; the first light steel keel frame is evenly dislocated with opening The hole part, the cross section of the first light steel keel frame consists of the first tail, the second tail, the first bend, the second bend, the third bend, the fourth bend, the fifth bend, the sixth The upper end of the first tail is connected with the left end of the first skeleton through the first bend, the first skeleton The right end is connected with the upper end of the second skeleton through the second bend, the lower end of the second skeleton is connected with the right end of the third skeleton through the third bend, and the left end of the third skeleton is connected with the fourth skeleton through the fourth bend The upper end of the fourth skeleton is connected with the upper end of the fifth skeleton through the fifth bend, the left end of the fifth skeleton is connected with the lower end of the second tail through the sixth bend; the first light steel keel The center of the frame and the second light steel keel frame is arranged symmetrically; the structures of the transverse wall module, the longitudinal wall module, the floor module and the ceiling module are the same; the first light steel keel frame of one of the two adjacent transverse wall modules The second light steel keel frame of the other transverse wall module of the adjacent two transverse wall modules is overlapped, and the N-type suspension is fixed to the first light steel keel frame of one of the two adjacent transverse wall modules by fixing bolts on the inner wall On the second light steel keel frame of the other transverse wall module of the adjacent two transverse wall modules, the N-type suspension is suspended in the socket of the inner wall fixing part of the inner wall of the container, and the inner wall fixing part passes through the outer wall The fixing bolts are connected with the outer wall fixtures arranged on the outer wall of the container, the first light steel keel frame of one of the two adjacent transverse wall modules is connected with the second light steel frame of the other transverse wall module of the two adjacent transverse wall modules A foam rubber layer is provided at the fitting position of the keel frame, and a sealant layer is provided at the joint of the inner wall panels of two adjacent transverse wall modules.

The beneficial effects of the utility model are:

The utility model can realize the flexible disassembly and quick assembly of the inner wall modules of the container building. The structure of the module itself is simple, the number of components is small, and there is only one type of light steel keel frame. The module has strong applicability, and the integration of heat preservation and decoration is adopted to avoid secondary decoration inside the container building, improve production efficiency and reduce decoration pollution. The module has good thermal insulation performance, fire prevention and waterproof, longer service life and convenient recycling.

Description of drawings

Figure 1 is a schematic diagram of the assembly of an integrated thermal insulation and decoration module used in container buildings in cold regions;

Fig. 2 is a schematic diagram of overlapping of two adjacent transverse wall modules;

Fig. 3 is the structural representation of the first light steel keel frame;

Fig. 4 is the structural representation of the cross-section of the first light steel keel frame;

Fig. 5 is a structural schematic diagram of two adjacent transverse wall modules fixed in the container;

Fig. 6 is a schematic diagram of the structure of the N-type suspension suspended in the inner wall fixture;

Figure 7 is a schematic diagram of the connection between the transverse wall module and the ceiling module;

Fig. 8 is a schematic diagram of the connection between the transverse wall module and the floor module.

detailed description

Specific Embodiment 1: As shown in Figure 1, an integrated thermal insulation and decoration module applied to container buildings in cold regions in this embodiment is composed of a transverse wall module 1a, a vertical wall module 1b, a floor module 1c and a ceiling module 1d; The transverse wall module 1a is arranged along the length direction of the container 9, the longitudinal wall module 1b is arranged along the width direction of the container 9, the bottom plate module 1c is arranged at the bottom of the container 9, and the ceiling module 1d is arranged along the top of the container 9 The transverse wall module 1a is composed of a first light steel keel frame 11a, a second light steel keel frame 11b, a protective layer 12, an insulating layer 13 and an inner wall panel 14, and one end of the transverse wall module 1a is provided with a first The light steel keel frame 11a, the other end of the transverse wall module 1a is provided with a second light steel keel frame 11b, and the first light steel keel frame 11a and the second light steel keel frame 11b are placed on the protective layer 12 and the insulation layer 13, the horizontal wall module 1a is sequentially provided with a protective layer 12, an insulating layer 13 and an inner wall panel 14 from the outside to the inside; the first light steel keel frame 11a is evenly dislocated with openings 112, and the first The cross section of the light steel keel frame 11a consists of the first tail portion 111a, the second tail portion 111b, the first bend portion 112a, the second bend portion 112b, the third bend portion 112c, the fourth bend portion 112d, the fifth bend portion 112e, the Six curved parts 112f, a first frame 113a, a second frame 113b, a third frame 113c, a fourth frame 113d and a fifth frame 113e, the upper end of the first tail part 111a connects with the first frame 113a through the first bend 112a The left end of the first frame 113a is connected to the left end, the right end of the first frame 113a is connected to the upper end of the second frame 113b through the second bend 112b, and the lower end of the second frame 113b is connected to the right end of the third frame 113c through the third bend 112c, The left end of the third frame 113c is connected to the upper end of the fourth frame 113d through the fourth bend 112d, and the lower end of the fourth frame 113d is connected to the right end of the fifth frame 113e through the fifth bend 112e. The left end of the skeleton 113e is connected to the lower end of the second tail part 111b through the sixth bent part 112f; the first light steel keel frame 11a and the second light steel keel frame 11b are arranged symmetrically; the horizontal wall module 1a and the vertical wall module 1b , the floor module 1c and the ceiling module 1d have the same structure; the first light steel keel frame 11a of one of the two adjacent transverse wall modules 1a is the same as the first light steel keel frame 11a of the other transverse wall module 1a of the two adjacent transverse wall modules 1a The two light steel keel frames 11b are overlapped, and the N-type suspension 31 is fixed on the first light steel keel frame 11a of one of the two adjacent transverse wall modules 1a and the adjacent two transverse wall modules 1a through the inner wall fixing bolts 32 On the second light steel keel frame 11b of another transverse wall module 1a, the N-shaped suspension part 31 is suspended in the socket of the inner wall fixing part 23 on the inner wall of the container 9, and the inner wall fixing part 23 is fixed by the outer wall fixing bolt 22 and the outer wall set on the outer wall of the container 9 The fixing part 21 is connected, and the first light steel keel frame 11a of one of the two adjacent transverse wall modules 1a is attached to the second light steel keel frame 11b of the other transverse wall module 1a of the two adjacent transverse wall modules 1a A foam glue layer 5 is arranged at the joint position, and a sealant glue layer 6 is arranged at the junction of the interior wall panels 14 of two adjacent transverse wall modules 1a.

The opening 112 provided on the first light steel keel frame in this embodiment can effectively avoid the cold bridge effect, and at the same time, it is convenient to be fixed with the connecting parts by bolts.

The protection layer 12 in this embodiment is a waterproof aluminum film, which can avoid damage to the insulation layer due to cold bridge condensation.

The thermal insulation layer 13 in this embodiment is filled with polyurethane thermal insulation material, which has the advantages of good thermal insulation effect, fire resistance and impermeability.

The interior wallboard 14 in this embodiment adopts a paper-faced gypsum board or a decorative board with special requirements.

The curved part described in this embodiment has rounded corners, which ensures that no yield damage will be caused during the bending process of the light steel keel, and at the same time avoids the injury of the construction personnel to the sharp corner of the keel. The hole 112 is evenly dislocated on the light steel surface, which can effectively reduce the weight of the component, and at the same time effectively avoid the cold bridge effect due to the increased heat transfer path. The hole also facilitates the direct fixing of the N-type suspension by bolts. The tail part ensures the effective fixation of the light steel keel frame to the module, especially the insulation layer in the module.

In this embodiment, during the construction process of the adjacent modules, it is first necessary to set out the wires for positioning. On the outer wall of the container, the outer wall fixing parts are fixed by the outer wall fixing bolts, and at the same time, the inner wall fixing parts are connected. Before fixing the inner wall fixing parts, the inner wall of the container can optionally be filled with thermal insulation and fireproof materials such as polyurethane. The module is hung on the inner wall fixing parts by hanging, and the hanging parts are first fixed on the light steel keel frame of the module through fixing bolts. When installing two adjacent modules, you can choose to fill the insulation foam glue such as polyurethane foam glue between the two modules. Adjust the tightness and the mutual flatness of the two adjacent modules through the fixing bolts on the outer wall. After the installation is completed, the joints of the inner wall panels of the two modules can be filled with environmentally friendly sealant. When the inner wall panels are metal plates, seamless sealants can also be used. It is design, omit this step.

The bend of the N-shaped suspension part 31 in this embodiment is set in a circular arc shape, which can ensure that the module is inserted into the inner wall fixing part and ensure stability. At the same time, this design is easy to disassemble, and the modules can be disassembled and then applied to other container buildings.

Specific embodiment 2: As shown in Figure 7, the difference between this embodiment and specific embodiment 1 is that the ceiling module 1d is arranged in the gap between the transverse wall module 1a and the top plate of the container 9, and is fixed on the container by a fastener 9 On the top plate, internal corner lines 7 are provided at the angle between the transverse wall module 1a and the ceiling module 1d. Others are the same as the first embodiment.

Specific embodiment three: As shown in Figure 8, the difference between this embodiment and specific embodiment one or two is: the bottom plate module 1c is arranged in the gap between the transverse wall module 1a and the bottom plate of the container 9, and the transverse wall An anchor line 8 is provided at the angle between the module 1a and the baseboard module 1c. Others are the same as the first or second embodiment.

Claims (3)

1. An integrated thermal insulation and decoration module applied to container buildings in cold regions, characterized in that the integrated thermal insulation and decoration module applied to container buildings in cold regions consists of a transverse wall module (1a), a vertical wall module (1b), a floor module ( 1c) and a ceiling module (1d); the transverse wall module (1a) is arranged along the length direction of the container (9), the longitudinal wall module (1b) is arranged along the width direction of the container (9), and the bottom plate module (1c) is arranged on the bottom of the container (9), and the roof module (1d) is arranged on the top of the container (9); light steel keel frame (11b), protective layer (12), heat insulation layer (13) and inner wall board (14), and one end of the transverse wall module (1a) is provided with a first light steel keel frame (11a), The other end of the transverse wall module (1a) is provided with a second light steel keel frame (11b), and the first light steel keel frame (11a) and the second light steel keel frame (11b) are placed on the protective layer (12 ) and the thermal insulation layer (13), the transverse wall module (1a) is provided with a protective layer (12), thermal insulation layer (13) and inner wall panels (14) sequentially from outside to inside; the first light steel keel frame ( 11a) is evenly dislocated with openings (112), the cross-section of the first light steel keel frame (11a) consists of the first tail (111a), the second tail (111b), the first bend (112a) , the second bend (112b), the third bend (112c), the fourth bend (112d), the fifth bend (112e), the sixth bend (112f), the first skeleton (113a), the second frame (113b), third frame (113c), fourth frame (113d) and fifth frame (113e), the upper end of the first tail (111a) is connected to the first frame (112a) through the first bend (112a) 113a), the left end of the first frame (113a) is connected to the upper end of the second frame (113b) through the second bend (112b), and the lower end of the second frame (113b) is connected through the third bend (112c) is connected with the right end of the third skeleton (113c), and the left end of the third skeleton (113c) is connected with the upper end of the fourth skeleton (113d) through the fourth bend (112d), and the fourth skeleton (113d) ) is connected to the right end of the fifth skeleton (113e) through the fifth bend (112e), and the left end of the fifth skeleton (113e) is connected to the lower end of the second tail (111b) through the sixth bend (112f); The first light steel keel frame (11a) and the second light steel keel frame (11b) are centrally symmetrically arranged; the transverse wall module (1a), vertical wall module (1b), floor module (1c) and ceiling module ( The structure of 1d) is the same; the first light steel keel frame (11a) of one of the adjacent two transverse wall modules (1a) is the same as the other transverse wall module (1a) of the adjacent two transverse wall modules (1a) The second light steel keel frame (11b) is overlapped, and the N-type suspension (31) is fixed to the first light steel keel frame ( 11a) On the second light steel keel frame (11b) of another transverse wall module (1a) of the adjacent two transverse wall modules (1a), the N-type hanger (31) is suspended on the container (9) In the socket of the inner wall fixing part (23) of the inner wall, the inner wall fixing part (23) is connected with the outer wall fixing part (21) arranged on the outer wall of the container (9) through the outer wall fixing bolt (22), and the adjacent two The first light steel keel frame (11a) of one of the transverse wall modules (1a) is attached to the second light steel keel frame (11b) of another transverse wall module (1a) of two adjacent transverse wall modules (1a) A styrofoam layer (5) is provided at the closing position, and a sealant layer (6) is provided at the junction of the interior wall panels (14) of two adjacent transverse wall modules (1a). 2. An integrated thermal insulation and decoration module applied to container buildings in cold regions according to claim 1, characterized in that the ceiling module (1d) is arranged between the transverse wall module (1a) and the top plate of the container (9) In the gap, it is fixed on the roof of the container (9) by a fixing piece, and a corner line (7) is provided at the angle between the transverse wall module (1a) and the ceiling module (1d). 3. An integrated thermal insulation and decoration module applied to container buildings in cold regions according to claim 1, characterized in that the bottom plate module (1c) is arranged between the transverse wall module (1a) and the bottom plate of the container (9) In the gap, the angle between the transverse wall module (1a) and the floor module (1c) is provided with an anchor line (8).