CN116065756A

CN116065756A - Assembled building element

Info

Publication number: CN116065756A
Application number: CN202310181952.7A
Authority: CN
Inventors: 白为洁; 于嵌; 钱俊杰
Original assignee: Individual
Current assignee: Individual
Priority date: 2023-02-28
Filing date: 2023-02-28
Publication date: 2023-05-05

Abstract

The invention belongs to the technical field of assembly plates, in particular to an assembly type building component, which comprises a matrix, wherein the matrix is a prefabricated plate with a heat insulation material filled in the middle; the building assembly is mounted on the base body and is used for splicing a plurality of base bodies; the bridge assembly is arranged between the substrates and used for communicating the outer frame and the inner frame, and the bridge assembly is used for changing the heat conduction efficiency between the inner frame and the outer frame.

Description

Assembled building element

Technical Field

The invention belongs to the technical field of assembly plates, and particularly relates to an assembly type building member.

Background

The assembled integrated building is a brand new building system which is produced by assembling and integrating building components into a market to provide a final perfect product in a production mode of specialized large factories and socialization cooperation, most of components are manufactured in factories when the assembled integrated building is built, and only prefabricated components are required to be built and connected when the assembled integrated building is built, so that the construction period can be effectively shortened, the labor output is greatly reduced, and the material waste is reduced.

When the assembled integrated building accessory is produced, most of main components, such as a wall body, a floor slab and the like, are prefabricated in factories, and are directly assembled in construction, along with the prevalence of energy-saving and environment-friendly concepts, the traditional assembled building component has good heat preservation performance in production for enhancing the temperature regulation effect in a building, however, when the building is in actual use, the building is found to have good heat preservation performance, when the temperature inside and outside the building has great difference and the temperature inside and outside the building is required to be balanced with the outside temperature, when the temperature regulation is carried out by adopting a room temperature regulating device such as an air conditioner and the like, the energy consumption is high, such as hot summer, the building is subjected to the daytime and the evening of daytime conversion, the indoor temperature is far higher than the outdoor temperature after the building is subjected to the insolation by sunlight, or the indoor temperature is higher than the indoor temperature in cold winter, or the room temperature is excessively cool at the noon, the strong heat preservation performance of the building can prevent the balance regulation of the indoor temperature and the outdoor temperature, the temperature is directly regulated by the temperature regulating device, and the energy consumption is high, and the temperature regulation equipment is greatly burdened.

In the related art, in order to enhance the rapid balance between a building with good heat preservation performance and the outside temperature, the indoor and outdoor air flows are exchanged by adopting structures such as doors and windows, so that the temperature adjusting equipment is assisted to adjust the temperature, but when the environment where the building is located has larger outside dust and the ventilation efficiency of the doors and windows is poor, the implementation effect is not ideal.

The information disclosed in this background section is only for enhancement of understanding of the general background of the invention and should not be taken as an acknowledgement or any form of suggestion that this information forms the prior art that is known to a person skilled in the art.

Disclosure of Invention

In order to overcome the defects in the prior art and solve the technical problems, the invention provides an assembled building component.

The technical scheme adopted for solving the technical problems is as follows: according to the invention, by arranging the bypass assembly and utilizing the injection and discharge of external water flow, the connection and blocking of the outer frame and the inner frame are realized, so that the heat conduction performance of the inner side and the outer side of the member is effectively adjusted, and when in actual use, the heat conduction performance of the member can be flexibly adjusted according to the specific conditions of the environment and the indoor environment, so that the use comfort and the energy conservation of the built assembled building are enhanced.

The invention relates to an assembled building component, which comprises a matrix, wherein the matrix is a prefabricated plate with a middle part filled with a heat insulation material;

the building assembly is mounted on the base body and is used for splicing a plurality of base bodies;

the building assembly comprises an outer frame and an inner frame, wherein the outer frame and the inner frame are of lightweight steel structures, the outer frame and the inner frame are respectively and fixedly arranged on the inner side and the outer side of a base body, and the inner frame and the outer frame are used for connecting a plurality of base bodies;

the heat insulation frame is fixedly arranged on the outer wall of the matrix and used for isolating heat conduction between the outer frame and the inner frame;

filling sponge, wherein the heat insulation frames are of C-shaped design, the heat insulation frames between the matrixes are opposite to each other, and the filling sponge is fixedly arranged in the inner cavity of the heat insulation frame;

the bypass assembly is arranged between the substrates and used for communicating the outer frame and the inner frame, and the bypass assembly is used for changing heat conduction efficiency between the inner frame and the outer frame.

Preferably, the bridging component comprises a connecting piece, wherein the side, close to each other, of the outer frame and the inner frame is provided with a splicing groove, and the connecting piece is slidably arranged in the splicing groove;

the flexible pipes are fixedly connected between the two corresponding connecting pieces, and two adjacent flexible pipes are connected in a conducting manner through the connectors;

the extension pipe, the extension pipe is connected with the joint is dismantled, the external water supply pipeline of extension pipe.

Preferably, the two ends of the flexible pipe are fixedly connected with plugs, and the plugs are in threaded connection with the connectors; the connector is characterized in that the connector adopts a four-way pipe, the opening of the connector is of a step-shaped design, and the inside of the connector is elastically connected with a blocking plate through a spring.

Preferably, the elastic sealing ring is fixedly arranged at the joint step corresponding to the blocking plate.

Preferably, the connecting piece comprises connection piece, conducting strip and spliced pole, the conducting strip is in flexible intraductal and external both sides with connection piece symmetric distribution, spliced pole fixed connection is on the conducting strip, the spliced pole runs through flexible pipe to with connection piece fixed connection.

Preferably, the connecting sheet is of a C-shaped design, and the connecting sheet extends into the two corresponding inserting grooves respectively.

Preferably, the connecting column penetrates through the inner frame and the outer frame respectively, the connecting column is far away from the bolt type design on one side of the heat conducting fin, and the connecting column is connected with a nut in a threaded manner.

Preferably, the outer frame and the inner frame are fixedly connected with uniformly distributed supporting rods, and the supporting rods are used for enhancing the connection stability among the outer frame, the inner frame and the matrix.

Preferably, the supporting rods are hollow steel tubes, and the inner cavities of the supporting rods are all in conduction design.

The beneficial effects of the invention are as follows:

1. according to the assembled building component, the prefabricated base body is spliced by the aid of the building component, gaps between the base bodies are filled by adopting materials such as the heat insulation frames and the filling sponge in the splicing process, gaps between the outer frames and the inner frames used for supporting and connecting are filled at the same time, and then a stable heat insulation layer is formed by matching with the base bodies, so that the overall heat insulation performance of the component is enhanced.

2. According to the assembled building component, the bypass assembly is arranged, the connection and blocking of the outer frame and the inner frame are realized by injecting and discharging external water flow, so that the heat conduction performance of the inner side and the outer side of the component is effectively adjusted, and when the assembled building component is in actual use, the heat conduction performance of the component can be flexibly adjusted according to the specific conditions of the environment and the indoor environment, and the use comfort and the energy conservation of the built assembled building are further enhanced.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a partial construction view of the present invention;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

FIG. 4 is a connection diagram of a plug and a connector;

FIG. 5 is a partial cross-sectional view of the present application;

in the figure: 1. a base; 2. an outer frame; 21. an inner frame; 22. a heat insulating frame; 23. filling a sponge; 24. a plug-in groove; 25. a flexible tube; 26. an extension tube; 3. a plug; 31. a joint; 32. a closure plate; 33. an elastic sealing ring; 4. a connecting piece; 41. a connecting sheet; 42. a heat conductive sheet; 43. a connecting column; 5. a nut; 6. and (5) supporting the rod.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1 to 5, the fabricated building element according to the present invention includes a base 1, wherein the base 1 is a prefabricated plate material with a middle part filled with a heat insulation material;

the building assembly is mounted on the base body 1 and is used for splicing a plurality of base bodies 1;

the building assembly comprises an outer frame 2 and an inner frame 21, wherein the outer frame 2 and the inner frame 21 are of light steel structures, the outer frame 2 and the inner frame 21 are respectively and fixedly installed on the inner side and the outer side of a base body 1, and the inner frame 21 and the outer frame 2 are used for connecting a plurality of base bodies 1;

a heat insulation frame 22, wherein the heat insulation frame 22 is fixedly arranged on the outer wall of the base body 1, and the heat insulation frame 22 is used for isolating heat conduction between the outer frame 2 and the inner frame 21;

the filling sponge 23, wherein the heat insulation frames 22 are of C-shaped design, the heat insulation frames 22 between the substrates 1 are opposite to each other, and the filling sponge 23 is fixedly arranged in the inner cavity of the heat insulation frames 22;

the bypass assembly is arranged between the base bodies 1 and used for communicating the outer frame 2 and the inner frame 21, and the bypass assembly is used for changing the heat conduction efficiency between the inner frame 21 and the outer frame 2;

when the prefabricated building is built, the prefabricated components are spliced and assembled to quickly finish the assembly of the building, after the building is finished, the heat insulation performance of the prefabricated external wall boards has great influence on the heat exchange capability between the inside of the prefabricated building and the external environment, certain differences exist in the heat insulation performance requirements of the external wall boards in different living environments, for example, when the building is positioned in a shade, the indoor environment is cool and moist all the year round, when the heat exchange capability of the external wall boards is stronger, the indoor temperature can be effectively promoted to rise when the external environment temperature is higher than the indoor temperature, and great benefits exist for heating and dehumidifying, so the invention enhances the selectivity and the flexibility of the components when the assembled building is built by manufacturing the assembled building components with variable heat conduction effects, the adaptability of the assembled building to the environment is enhanced, specifically, when the assembled component is prefabricated, a base body 1 is cast and manufactured by adopting a mode of wrapping a heat insulation material and a steel skeleton by concrete, when the base body 1 is subjected to working procedures such as maintenance and the like, the base body 1, a building assembly and a bridging assembly are assembled, when the assembly is carried out, a heat insulation frame 22 is fixedly arranged on the side wall of the base body 1 by adopting modes such as bolts, cement nails and the like, the filling sponge 23 with better heat insulation performance is then cut and fixed in the heat insulation frame 22, at this time, the outer frame 2, the inner frame 21 and the base body 1 are fixedly connected, preferably in a threaded connection, welding or the like, and then assembled into a basic unit after the fixing is completed, and then a plurality of basic units are spliced, and when the basic units are spliced, the outer frames 2 and the inner frames 21 of two adjacent components are aligned and attached to each other, in the process, the filling sponge 23 on the heat insulating frame 22 in the adjacent members are mutually extruded and deformed to fill the gap between the adjacent two matrixes 1, and then the outer frame 2 and the inner frame 21 between the adjacent basic units are welded to form a whole body, so that the basic units are assembled to the building according to a specific assembly process of the assembled building.

According to the invention, the prefabricated base body 1 is spliced by the building assembly, and in the splicing process, the gaps between the

base bodies

1 and 1 are filled by adopting the materials such as the heat insulation frame 22, the filling sponge 23 and the like, and the gaps between the outer frame 2 and the inner frame 21 which are used for supporting and connecting are filled at the same time, so that a stable heat insulation layer is formed by matching with the base body 1, and the overall heat insulation performance of the component is enhanced.

As a preferred embodiment of the present invention, the bypass assembly includes a connecting member 4, the side of the outer frame 2 and the side of the inner frame 21, which are close to each other, are provided with inserting grooves 24, and the connecting members 4 are slidably mounted in the inserting grooves 24;

the flexible pipes 25 are fixedly connected between the two corresponding connecting pieces 4, and the two adjacent flexible pipes 25 are connected in a conducting way through the joint 31;

an extension pipe 26, wherein the extension pipe 26 is detachably connected with a joint 31, and the extension pipe 26 is externally connected with a water supply pipeline;

when the plurality of basic units are spliced and assembled, after the adjacent two basic units are aligned, the connecting piece 4 is inserted into the inserting groove 24, and as the connecting piece 4 is respectively positioned at two sides of the flexible pipe 25, and the inserting groove 24 is respectively symmetrically arranged on the inner frame 21 and the outer frame 2, during the process of inserting the connecting piece 4 into the inserting groove 24, the flexible pipe 25 synchronously presses the filling sponge 23 and enters into a gap of the filling sponge 23, then, after the flexible pipe 25 arranged among the plurality of basic units is butted and conducted through the joint 31, the extending pipe 26 is detachably connected with one joint 31, specifically, the connecting mode is preferably threaded connection, clamping connection and the like, when the component formed by the plurality of basic units is assembled on the assembled building, in an initial state, the flexible pipe 25 is pressed by the filling sponge 23 at two sides, the flexible pipe 25 is used for exhausting the air in the flexible pipe 25 to form a sheet-shaped structure, the heat conduction efficiency between the connecting pieces 4 at the two sides of the flexible pipe 25 is lower, the heat insulation effect of the filling sponge 23 is matched, the heat insulation performance of the component formed by a plurality of basic units is better, when the heat insulation performance of the component is required to be changed, the extending pipe 26 is connected with an external water supply pipeline, the water in the water supply pipeline flows into the extending pipe 26 and the flexible pipe 25 by manually opening the water supply pipeline, the strength of the flexible pipe 25 extruded by the filling sponge 23 is increased under the action of water pressure, the shape of the flexible pipe 25 is restored, then the connecting pieces 4 at the two sides of the flexible pipe 25 have better heat conduction effect due to the existence of water in the flexible pipe 25, the connecting pieces 4 are respectively connected with the outer frame 2 and the inner frame 21 in a sliding way, the outer frame 2, the inner frame 21 and the connecting piece 4 are both made of metal materials with good heat conducting performance, so when the indoor temperature and the outdoor temperature are greatly different, for example, when the indoor environment is relatively cool and the outdoor environment is relatively hot in a building, heat conduction is carried out between the external air and the outer frame 2, heat is transferred to the inner frame 21 under the action of the outer frame 2, the connecting piece 4 and water, a heat bridge is formed between the inner frame 21 and the outer frame 2, heat exchange is formed between the outside and the building under the action of the heat bridge, the cool environment in the building is effectively heated, the environment comfort is improved, when the outside environment is unsuitable, or when equipment such as an air conditioner is required to be started, the water flow in the flexible pipe 25 is discharged, the flexible pipe 25 is extruded again under the elastic action of the filling sponge 23, and at the moment, the bridge connection between the outer frame 2 and the inner frame 21 is disconnected, and indoor cold air or outward diffusion can be effectively avoided.

As a preferred embodiment of the present invention, two ends of the flexible tube 25 are fixedly connected with plugs 3, and the plugs 3 are in threaded connection with the joint 31; the connector 31 is a four-way pipe, the opening of the connector 31 is of a step-shaped design, and a blocking plate 32 is elastically connected inside the connector 31 through a spring;

when the flexible pipe 25 is connected, firstly, the two ends of the flexible pipe 25 are fixedly connected with the plug 3 through hot melt adhesive, then, the plug 3 is in threaded connection with the connector 31, in the threaded connection process, the plug 3 moves towards the inside of the connector 31 and pushes the blocking plate 32 to move towards the inside of the connector 31, so that the plug 3 is communicated with the inner cavity of the connector 31, then, the joint of the connector 31 and the plug 3 is in sealed connection through sealant or hot melt adhesive, and the blocking plate 32 is not inserted into the inner cavity of the connector 31 of the plug 3, and blocks the opening of the connector 31 under the action of a spring, so that the occurrence probability of water flow exudation, leakage and other problems in the later period can be effectively avoided.

As a preferred embodiment of the invention, an elastic sealing ring 33 is fixedly arranged at the step of the joint 31 corresponding to the plugging plate 32;

by fixedly mounting the elastic sealing ring 33 at the step of the inner cavity of the joint 31, the sealing effect of the blocking plate 32 on the opening of the joint 31 is effectively enhanced by utilizing the elastic sealing ring 33.

As a preferred embodiment of the present invention, the connecting piece 4 is composed of a connecting piece 41, a heat conducting piece 42 and a connecting post 43, the heat conducting piece 42 and the connecting piece 41 are symmetrically distributed on the inner side and the outer side of the flexible pipe 25, the connecting post 43 is fixedly connected to the heat conducting piece 42, and the connecting post 43 penetrates through the flexible pipe 25 and is fixedly connected with the connecting piece 41;

the connecting piece 4 comprises a connecting piece 41, a heat conducting fin 42 and a connecting column 43, so when the flexible pipe 25 is connected with the connecting piece 4, the heat conducting fin 42 and the connecting column 43 are integrated through casting or welding and other technologies, then the heat conducting fin 42 and the connecting column 43 are placed in an inner cavity of the flexible pipe 25 through an opening of the flexible pipe 25, the connecting column 43 is extended to the outside of the flexible pipe 25 through perforating the outer wall of the flexible pipe 25, when the flexible pipe 25 is perforated, the size of the perforating hole is smaller than the diameter of the connecting column 43, then the connecting piece 41 is inserted on the connecting column 43, the heat conducting fin 42 and the connecting piece 41 are extruded and fixed, so that the heat conducting fin 42 and the connecting piece 41 form stable clamping on the flexible pipe 25, sealing glue is coated at the junction of the flexible pipe 25 and the connecting column 43 in the pressurizing process, then the heat conducting fin 42 and the connecting column 41 are matched, the leakage probability of the flexible pipe 25 is reduced, when the outer frame 2 or the inner frame 21 and the connecting piece 41 are subjected to heat exchange, the heat conduction between the connecting column 43 and the connecting column 42 is fast, the heat conduction between the connecting piece 41 and the inner frame and the connecting frame and the heat conducting frame is accelerated, the heat conduction efficiency of the inner frame 21 is increased, and the heat conduction efficiency of the heat conduction efficiency is further increased, and the heat conduction efficiency is further increased.

As a preferred embodiment of the invention, the connecting piece 41 is of C-shaped design, and the connecting piece 41 extends into the two corresponding inserting grooves 24 respectively;

through setting up the connection piece 41 to the C shape to in extending its two adjacent jack-in grooves 24, after the connection piece 41 is installed in jack-in groove 24, utilize connection piece 41 to carry out preliminary fixation to adjacent outer frame 2, adjacent inner frame 21, strengthen the inseparable laminating effect of adjacent outer frame 2, inner frame 21, and then pass through the assistance for subsequent processes such as welding, fixing between outer frame 2, between inner frame 21, strengthen the joint strength of a plurality of basic units.

As a preferred embodiment of the present invention, the connecting posts 43 penetrate through the inner frame 21 and the outer frame 2, respectively, the connecting posts 43 are designed as bolts on the side far away from the heat conducting fins 42, and nuts 5 are screwed on the connecting posts 43;

after the connecting piece 41 is inserted into the inserting groove 24, the connecting column 43 extends to the outside along the holes formed in the inner frame 21 and the outer frame 2 in advance, then the connecting column 43 is tightened and fixed through the nut 5, in the process, the connecting piece 41 is connected with the outer frame 2 and the inner frame 21 more stably, meanwhile, the attaching degree is increased, the distance and the gap are reduced, and the heat conduction efficiency is effectively enhanced.

As a preferred embodiment of the present invention, the outer frame 2 and the inner frame 21 are fixedly connected with uniformly distributed supporting rods 6, and the supporting rods 6 are used for enhancing the connection stability between the outer frame 2, the inner frame 21 and the base 1;

through adopting bracing piece 6 to be connected with outer frame 2, internal frame 21, carry out the joint through the recess of seting up in advance between bracing piece 6 and the base member 1, after the equipment is accomplished, the joint strength between outer frame 2, internal frame 21 and the base member 1 can be strengthened to the existence of bracing piece 6, simultaneously because bracing piece 6 and outer frame 2, internal frame 21 lug connection, after outer frame 2 and internal frame 21 bypass, heat synchronous to the bracing piece 6 on transfer, dispersion, further strengthen heat conduction efficiency, the reinforcing is to the effect of building inside and outside heat exchange.

As a preferred embodiment of the invention, the supporting rods 6 are hollow steel tubes, and the inner cavities of the supporting rods 6 are all in a conduction design;

the supporting rod 6 arranged on the hollow steel pipe can effectively enhance the heat exchange effect with the environment due to the increase of the contact area with the outside air, so that the heat exchange effect between the internal environment and the external environment of the building is further promoted, and the improvement of the indoor environment is quickened.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The assembled building component comprises a base body (1), wherein the base body (1) is a prefabricated plate with a heat insulation material filled in the middle;

the method is characterized in that: the building assembly is mounted on the base body (1) and is used for splicing a plurality of base bodies (1);

the building assembly comprises an outer frame (2) and an inner frame (21), wherein the outer frame (2) and the inner frame (21) are of light steel structures, the outer frame (2) and the inner frame (21) are respectively and fixedly arranged on the inner side and the outer side of the base body (1), and the inner frame (21) and the outer frame (2) are used for connecting a plurality of base bodies (1);

the heat insulation frame (22) is fixedly arranged on the outer wall of the base body (1), and the heat insulation frame (22) is used for isolating heat conduction between the outer frame (2) and the inner frame (21);

the heat insulation frames (22) are of C-shaped design, the heat insulation frames (22) between the substrates (1) are opposite to each other, and the filling sponge (23) is fixedly arranged in the inner cavity of each heat insulation frame (22);

the bypass assembly is arranged between the base bodies (1) and used for communicating the outer frame (2) with the inner frame (21), and the bypass assembly is used for changing heat conduction efficiency between the inner frame (21) and the outer frame (2).

2. A fabricated building element according to claim 1, wherein: the bridging component comprises a connecting piece (4), wherein inserting grooves (24) are formed in one side, close to each other, of the outer frame (2) and the inner frame (21), and the connecting piece (4) is slidably arranged in the inserting grooves (24);

the flexible pipes (25) are fixedly connected between the two corresponding connecting pieces (4), and the two adjacent flexible pipes (25) are connected in a conducting way through the joint (31);

the extension pipe (26), extension pipe (26) are connected with joint (31) detachably, extension pipe (26) external water supply pipeline.

3. A fabricated building element according to claim 2, wherein: two ends of the flexible pipe (25) are fixedly connected with plugs (3), and the plugs (3) are in threaded connection with the connectors (31); the connector (31) adopts four-way pipes, the opening of the connector (31) is of a step-shaped design, and a blocking plate (32) is elastically connected inside the connector (31) through a spring.

4. A fabricated building element according to claim 3, wherein: an elastic sealing ring (33) is fixedly arranged at the step of the joint (31) corresponding to the blocking plate (32).

5. A fabricated building element according to claim 2 or 4, wherein: the connecting piece (4) comprises a connecting piece (41), a heat conducting fin (42) and connecting columns (43), wherein the heat conducting fin (42) and the connecting piece (41) are symmetrically distributed on the inner side and the outer side of the flexible pipe (25), the connecting columns (43) are fixedly connected to the heat conducting fin (42), and the connecting columns (43) penetrate through the flexible pipe (25) and are fixedly connected with the connecting pieces (41).

6. A fabricated building element according to claim 5, wherein: the connecting pieces (41) are of C-shaped design, and the connecting pieces (41) respectively extend into the two corresponding inserting grooves (24).

7. A fabricated building element according to claim 6, wherein: the connecting column (43) penetrates through the inner frame (21) and the outer frame (2) respectively, the connecting column (43) is far away from the bolt type design on one side of the heat conducting fin (42), and the connecting column (43) is connected with a nut (5) in a threaded mode.

8. A fabricated building element according to claim 7, wherein: the support rods (6) which are uniformly distributed are fixedly connected to the outer frame (2) and the inner frame (21), and the support rods (6) are used for enhancing the connection stability among the outer frame (2), the inner frame (21) and the matrix (1).

9. A fabricated building element according to claim 8, wherein: the supporting rods (6) are hollow steel pipes, and the inner cavities of the supporting rods (6) are all in conduction design.