CN110863580A - Wall unit and wall structure - Google Patents

Abstract

The invention provides a wall unit and a wall structure, wherein the wall unit comprises: the connecting plates are symmetrically distributed in parallel; the two isolation frames comprise two side walls, and the side walls are respectively connected to the connecting plate; and the pair of peripheral plates are respectively connected to the isolation frames, and hollow cavities are respectively arranged between the peripheral plates and the two isolation frames. The formed wall structure is convenient for the arrangement of pipelines and the formation of a fresh air system, has good sound insulation capability and variable structure, and meets the rapid pace of life of modern people.

Description

Wall unit and wall structure

Technical Field

The invention relates to the technical field of buildings, in particular to a wall unit and a wall structure.

Background

Wall structures are important components of buildings and function to support, enclose or partition spaces. The wall body can be divided into an outer wall body structure and an inner wall body structure, and the inner wall body structure is arranged inside a building and surrounded by the outer wall body structure so as to separate the inner space of the building.

Because interior wall structure sets up in the inside of building, when interior wall structure is used for separating different rooms, interior wall structure need have better syllable-dividing, heat retaining effect, just can satisfy contemporary people's life needs, simultaneously along with the acceleration of people's life rhythm, also is diversified to the needs of wall structure, and quick life rhythm can not be satisfied to single wall structure.

However, the interior wall structure formed in the prior art is generally formed by pouring concrete and reinforcing steel bars, when a building is decorated, the interior wall structure needs to be additionally provided with pipelines to arrange water and electricity pipelines, on one hand, the damage to the wall structure is large, on the other hand, more manpower and material resources are needed, the cost is increased, the sound insulation effect is poor, and the comfort level of the internal environment of the building is reduced.

Disclosure of Invention

The invention solves the problem of providing a wall unit and a wall structure, so that the formed wall structure is convenient for the arrangement of pipelines and the formation of a fresh air system, has good sound insulation capability and variable structure, and meets the rapid rhythm of life of modern people.

To solve the above problems, the present invention provides a wall unit, comprising: the connecting plates are symmetrically distributed in parallel; the two isolation frames comprise two side walls, and the side walls are connected to the connecting plate; and the pair of peripheral plates are respectively connected to the isolation frames, and hollow cavities are respectively arranged between the peripheral plates and the two isolation frames.

Optionally, the method further includes: and the filling layer is positioned between the two isolation frames.

Optionally, the isolation frame further includes isolation surfaces, and the number of the isolation surfaces is one or two.

Optionally, when the number of the isolation surfaces is two, a rectangular cavity structure is formed between the isolation surfaces and the side walls.

Optionally, when the number of the isolation surfaces is one, a U-shaped cavity structure is formed between the isolation surface and the side wall.

Optionally, the side wall includes a side portion, a bending portion and a folding portion, the side portion is connected to the connecting plate, the bending portion extends along a side away from the side portion, and the folding portion is respectively overlapped with the side portion and the bending portion.

Optionally, the isolation surface is further provided with a plurality of hole structures.

Optionally, the distance from the joint of the bending part and the side part to the edge of the connecting plate is 1-5 cm.

Optionally, the connecting plate is made of carbonized wood or a wood-plastic plate.

Optionally, the material of the isolation frame includes: stainless steel materials, magnesium alloy materials, aluminum alloy materials and manganese alloy materials.

Optionally, the method further includes: the connecting layer, the connecting layer is located the connecting plate with between the peripheral board, the material of connecting layer is diatom mud.

Correspondingly, the invention also provides a wall structure which comprises a plurality of wall units.

Compared with the prior art, the technical scheme of the invention has the following advantages:

the pair of connecting plates are symmetrically distributed in parallel, the two isolating frames are connected to the pair of connecting plates, the pair of peripheral plates are respectively connected to the isolating frames, the number of the formed hollow cavities is two, and therefore by utilizing the space of the hollow cavities, on one hand, water and electricity pipelines can be directly laid in the middle of the hollow cavities and installation channels of fresh air pipelines can be formed, extra passages do not need to be formed, the difficulty of laying the water and electricity pipelines is simplified, and the formed wall units are not damaged; on the other hand, because the quantity of the hollow cavities is two, one hollow cavity is outside the environment formed by the building, and the other hollow cavity is inside the environment formed by the building, the hollow cavities can not only isolate the outside sound, but also isolate the inside sound, so that the formed wall unit has a good sound insulation effect, a heat insulation layer or a reinforcing rib and the like can be filled in the hollow cavities, the structure of the wall unit is changed, the formed wall unit has flexible structure variability, and because of the existence of the hollow cavities, the formed wall unit can have good waterproof and moistureproof capabilities, and the comfort level of the internal environment of the building is improved.

Drawings

Fig. 1 to 2 are schematic structural views of a wall unit according to a first embodiment of the present invention;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a schematic structural view of an isolation frame according to a first embodiment of the present invention;

FIG. 4 is a schematic structural view of an isolation frame according to another embodiment of the present invention;

FIG. 5 is a schematic structural view of an isolation frame according to still another embodiment of the present invention;

FIG. 6 is a schematic structural view of a wall element after a connecting layer is formed in accordance with a first embodiment of the present invention;

FIG. 7 is a schematic structural diagram of a wall structure according to an embodiment of the present invention;

fig. 8 is a schematic structural view of a wall element according to a second embodiment of the invention.

Detailed Description

Currently, in the field of construction, the most widely used wall structure includes a concrete layer on which an insulation board is formed and a decorative board is formed on the insulation board.

The inventor finds that firstly, because the wall structure is of a solid structure, when the hydropower pipeline is laid in the wall structure, a passage needs to be additionally arranged in the wall structure to lay the hydropower pipeline, so that the hydropower pipeline is difficult to lay and high in cost; when the second wall structure is used as an inner wall, the wall structure is a solid structure, so that the sound insulation effect is poor, and the comfort of the internal environment of a building is reduced; in the third wall structure, the structure of the wall needs to be damaged when the wall structure is decorated for the second time, which is difficult to decorate, and has the disadvantages of great labor and high cost.

The inventor finds that the two isolation frames are respectively connected to the pair of connecting plates, the pair of peripheral plates are respectively connected to the isolation frames, and hollow cavities are respectively arranged between the two isolation frames, so that on one hand, the formed hollow cavities are used for directly arranging water and pipeline lines and forming an installation path of a fresh air system, the difficulty of arranging the water and pipeline lines and the formation of the installation path of the fresh air system are simplified, the cost is saved, and the formed wall body unit is not damaged secondarily; meanwhile, due to the existence of the hollow cavity, the formed wall unit has good sound insulation capability; on the other hand, when secondary decoration is needed, only the peripheral plate needs to be replaced, other materials can be used subsequently, the integral structure of the wall unit does not need to be damaged, waste materials are few, the cost is saved, and meanwhile, the secondary decoration process is simplified.

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

First embodiment

Referring first to fig. 1-2, a wall unit 100 comprises: a connecting plate 110, a spacer 120, a peripheral plate 130, and a hollow chamber 140.

Fig. 2 is a top view of fig. 1.

The connecting plates 110 are a pair, and the connecting plates 110 are symmetrically distributed in parallel;

the number of the isolation frames 120 is two, each isolation frame comprises two side walls 121, and the side walls 121 are respectively connected to the connecting plate 110;

the peripheral plates 130 are coupled to the isolation frames 120, and the hollow cavities 140 are formed between the two isolation frames 120.

In this embodiment, two hollow cavities 140 are formed between the peripheral plate 130 and the isolation frame 120.

In this embodiment, since the wall unit 100 is provided with the hollow cavity 140, the hollow cavity 140 provides a space for arrangement of water and power pipelines and formation of an installation channel of a fresh air system, and an additional passage does not need to be arranged in the wall unit 100, so that manpower and material resources are saved, and damage to the formed wall unit 100 is reduced; meanwhile, due to the existence of the hollow cavities 140, the sound propagation medium is changed from the previous solid propagation medium into an air propagation medium, the sound propagation speed is slowed down, the wall unit 100 formed by the sound propagation medium has good sound insulation and sound insulation capabilities, meanwhile, the hollow cavities 140 are respectively located between the peripheral plate 130 and the isolation frame 120, when the wall unit 100 is utilized to form a wall structure, one of the hollow cavities is located in the external environment of a building, and the other hollow cavity is located in the internal environment of the building, so that the external sound can be isolated, the internal sound can also be isolated, the double sound insulation effect is achieved, and the comfort level of the internal environment of the building is improved.

In this embodiment, the hollow cavity 140 is not filled with an insulating layer or a reinforcing rib; in other embodiments, an insulating layer or a reinforcing rib may be further filled in the hollow cavity 140 to improve the insulating capability and strength of the formed wall unit 100, so that the structure of the wall unit 100 is flexible and variable, and the requirements of different areas on the wall unit are met.

In this embodiment, a gap 150 is formed between the two isolation frames 120; in other embodiments, the gap 150 may not be formed between two of the spacers 120.

In this embodiment, the material of the connecting plate 110 is carbonized wood; in other embodiments, the material of the connecting plate 110 may also be wood-plastic plate.

In this embodiment, the connection plate 110 can block the problem of conduction of hot and cold bridges in the building because: the connecting plate 110 is made of carbonized wood, and the wood is a low-thermal-conductivity material, so that the problem of low conduction of a heat bridge and a cold bridge can be solved.

In this embodiment, the connection plates 110 connected to the sidewalls of the isolation frames 120 can block the conduction problem of the heat bridge and the cold bridge in the building, and on the other hand, the adjacent isolation frames 120 are connected together through the connection plates 110, and the connection plates 110 are made of wood, so that the connection plates 110 are sandwiched in the middle when extreme conditions such as earthquake occur, and the friction between the connection plates 110 is large, thereby alleviating the earthquake, reducing the friction damage between the steel and the steel caused by the earthquake, and improving the stability and reliability of the formed building.

In this embodiment, the number of the isolation frames 120 is two, and the two isolation frames are respectively a first isolation frame 122 and a second isolation frame 123; in other embodiments, the number of the isolation frames 120 may also be 3, 4, or other numbers.

In this embodiment, the first isolation frame 122 and the second isolation frame 123 are symmetrically distributed; in other embodiments, the first isolation frame 122 and the second isolation frame 123 may also be asymmetrically distributed.

In this embodiment, the peripheral plate 130 is a decorative plate, and the peripheral plate 130 has a laminated structure and includes a first decorative plate 131 and a second decorative plate 132; in other embodiments, the peripheral plate 130 may have a single-layer structure.

In this embodiment, the first decorative plate 131 is made of cement (concrete), and on one hand, the isolation frame 120 is connected with the second decorative plate 132, so that toxic gas polluting the environment is not generated, and the environment is protected; on the other hand, the strength of the formed wall unit 100 is also improved due to the high strength of the concrete.

In this embodiment, the second decorative plate 132 is made of wood, and is used for decorating the formed wall unit 100, so as to achieve the functions of beauty and decoration.

In this embodiment, the connecting plate 110 is connected to the sidewall 121 of the isolation frame 120 by a screw; in other embodiments, the connecting plate 110 and the sidewall 121 of the isolation frame 120 may be riveted.

Referring to fig. 3, the isolation frame 120 includes a sidewall 121 and an isolation surface 122, and the sidewall 121 includes a side portion 1211, a bent portion 1212, and a folded portion 1213.

In this embodiment, the number of the isolation surfaces 122 is one; in other embodiments, the number of isolation surfaces 112 may also be two.

In this embodiment, a U-shaped cavity structure is formed between the isolation surface 122 and the sidewall 121.

In this embodiment, the isolation surface 122 and the two sidewalls 121 form a U-shaped cavity structure.

The width of the spacer 120 is 300mm, 450mm and 600mm, and the width is the distance between the two sidewalls 121.

In this embodiment, the isolation surface 122 is provided with a plurality of hole structures 1221.

In this embodiment, the hole structure 1221 functions as a connection hole, so as to connect the isolation frame 120 with a subsequently filled insulating layer or other layers.

In this embodiment, the isolation surface 122 and the sidewall 121 are integrally formed; in other embodiments, the isolation surface 122 and the sidewall 121 are not integrally formed.

In this embodiment, the bent portion 1212 extends along a side away from the connecting plate 110.

In this embodiment, the bent portion 1212 is provided on the side wall 121 for the purpose of, on one hand, due to the existence of the bent portion 1212, when the peripheral plate 130 is installed, the bent portion 1212 functions to block the peripheral plate 130 so that the peripheral plate 130 is not too close to the isolation surface 122, so that the hollow cavity 140 between the peripheral plate 130 and the isolation frame 120 is not too small, thereby enabling the hollow cavity 140 to play a sound insulation role well and providing enough space for the arrangement of pipeline and the formation of installation pipeline of fresh air system; on the other hand, due to the existence of the bent portion 1212, it is also convenient when the peripheral plate 130 is mounted, because it is only necessary to ensure that the peripheral plate 130 is closely attached to the bent portion 1212, and it is not necessary to consider the mounting position of the peripheral plate 130, so that the construction difficulty of the peripheral plate 130 is simplified, and the production efficiency is improved.

In this embodiment, the folding portion 1213 is provided on the side wall 121 for the purpose of forming the folding portion 1213 by folding the side wall 121 for a plurality of times, wherein a portion of the folding portion 1213 overlaps the bending portion 1212, and a portion of the folding portion 1213 overlaps the side portion 1211, and during the use of the isolation frame 120, the folding portion 1213 not only increases the thickness of the bending portion 1212 and the side portion 1211, but also increases the stress capacity of the bending portion 1212 and the side portion 1211, thereby improving the strength and usability of the isolation frame 120.

In other embodiments, referring to fig. 4, the isolation frame 120 includes a sidewall 121 and an isolation surface 122, and the sidewall 121 has no bending portion.

In other embodiments, referring to fig. 5, the isolation frame 120 includes two side walls 121 and two isolation surfaces 122, where the number of the isolation surfaces 122 is two, the number of the side walls 121 is two, and a rectangular cavity structure is defined by the two isolation surfaces 122 and the two side walls 121. The hollow cavity of this structure is directly the space between the two isolation surfaces 122, but the cost of forming the isolation frame 120 is high.

In this embodiment, the isolation frame 120 is made of stainless steel; in other embodiments, the material of the isolation frame 120 may also be a magnesium alloy material, an aluminum alloy material, a manganese alloy material, or the like, but is not limited to these materials.

In this embodiment, the purpose of the isolation frame 120 is adopted, so that on one hand, the process of forming the hollow cavity 140 becomes simple, and the size of the formed hollow cavity 140 is well controlled; on the other hand, the isolation frame 120 is used to improve the strength and structural stability of the formed wall unit 100, and the wall structure formed by the wall unit meets the national production safety regulations.

In this embodiment, the bent portion 1212 extends along a side away from the connecting plate 110.

In this embodiment, the side 1211 is connected to the connection plate 110.

With continued reference to fig. 1, the distance from the connection point of the bending portion 1212 and the side portion 1211 to the edge of the connecting plate 110 is 1 cm to 5 cm (i.e. d in the figure).

In this embodiment, a distance of 1 cm to 5 cm is left between the connection portion of the bending portion 1212 and the side portion 1211 and the edge of the connection plate 110, so that after the peripheral plate 130 is installed, a groove can be formed among the peripheral plate 130, the connection plate 110 and the side portion 1211, and the formed groove is filled with diatom ooze and other materials.

In this embodiment, when the distance from the connection portion of the bent portion 1212 and the side portion 1211 to the edge of the connecting plate 110 is less than 1 cm, at this time, since the distance from the connection portion of the side portion 1211 and the bent portion 1212 to the edge of the connecting plate 110 is too small, the groove space formed between the peripheral plate 130, the connecting plate 110 and the side portion 1211 is too small, and the amount of the diatom ooze and other materials which can be filled subsequently is too small, so that the excellent fireproof and soundproof effects cannot be achieved; when the distance from the connection portion between the bent portion 1212 and the side portion 1211 to the edge of the connecting plate 110 is greater than 5 cm, since the distance from the connection portion between the side portion 1212 and the bent portion 1211 to the edge of the connecting plate 110 is too large, on one hand, the thickness of the wall structure is increased, and the area inside the building is reduced, on the other hand, the groove space formed between the peripheral plate 130, the connecting plate 110, and the side portion 1211 is too large, and the amount of the diatom ooze and other materials to be filled subsequently is too large, which can achieve good fireproof and soundproof effects, but the cost is increased.

Referring to fig. 6, a connection layer 160 is further included, and the connection layer 160 is located between the connection plate 110 and the peripheral plate 140.

In this embodiment, the connection layer 160 is made of diatom ooze; in other embodiments, the material of the connecting layer 160 may also be concrete, wood, or the like.

In this embodiment, since the connection portion between the bent portion 1212 and the side portion 1211 protrudes from the edge of the connecting plate 110, when the peripheral plate 130 is mounted, there is a groove (refer to fig. 2) formed among the side portion 1211, the connecting plate 110 and the peripheral plate 130, and at this time, the groove is filled with diatom ooze, so as to enhance the fire-proof and sound-proof capabilities of the wall unit 100.

Referring to fig. 7, a wall structure 200, the wall structure 200 is formed using the wall unit 100 described above.

In this embodiment, the wall structure 200 includes two wall units 100; in other embodiments, the wall structure 200 may further include three, four, etc. wall units 100.

In this embodiment, the two wall units 100 are connected by a screw thread; in other embodiments, two wall units 100 may be connected by riveting or the like.

In this embodiment, since the wall unit 100 has the hollow cavities 140, and the formed wall structure 200 also has the hollow cavities 140, the formed wall structure 200 is also convenient for laying of a water and electricity pipeline and forming of an installation channel of a fresh air system, and damage to the wall structure 200 is reduced; the formed wall structure 200 has good sound insulation capability, and the comfort level of the internal environment of the building is enhanced; meanwhile, due to the existence of the connecting layer 160, the formed wall structure 200 has good fireproof capacity, and the safety factor of the formed wall structure 200 is improved.

Second embodiment

The present embodiment is different from the first embodiment only in that a filling layer 170 is formed on both of the spacers 120.

Referring to fig. 8, a wall unit 100 includes: connecting plate 110, spacer 120, filler layer 170, peripheral plate 130, and hollow cavity 140.

The connecting plates 110 are a pair, and the connecting plates 110 are symmetrically distributed in parallel;

the number of the isolation frames 120 is two, each isolation frame comprises two side walls 121, and the side walls 121 are respectively connected to the connecting plate 110;

a filling layer 170 filled between the two isolation frames 120;

the peripheral plates 130 are coupled to the isolation frames 120, and the hollow cavities 140 are formed between the two isolation frames 120.

In this embodiment, the number of the hollow cavities 140 is two.

In this embodiment, the filling layer 170 is made of a thermal insulation material; in other embodiments, the material of the filling layer 170 may also be concrete or the like.

In this embodiment, the filling layer 170 is filled between the two isolation frames 120, so as to improve the heat insulation capability of the formed wall unit 100, and improve the comfort level of the internal environment of the building.

In this embodiment, the reason why the first isolation frame 122 and the second isolation frame 123 are symmetrically distributed is that: the filling layer 170 is filled between the two isolation frames 120 (i.e., between the first isolation frame 122 and the second isolation frame 123), and the filling layer 170 and the isolation frames 120 are in surface-to-surface contact, so that the contact area is large, the formed filling layer 170 is firmer, the filling layer 170 is easier to mount, and the process difficulty is simplified.

In this embodiment, since the isolation surface 122 is provided with a plurality of hole structures 1221, the hole structures 1221 may function as connection holes, so as to facilitate connection between the isolation frame 120 and the filling layer 170. This is because there is no need to additionally perforate the isolation surface 122, and the isolation frame 120 and the filling layer 170 are directly connected by glue, which is a simple process.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (12)

1. A wall element, comprising:

the connecting plates are symmetrically distributed in parallel;

the two isolation frames comprise two side walls, and the side walls are connected to the connecting plate;

and the pair of peripheral plates are respectively connected to the isolation frames, and hollow cavities are respectively arranged between the peripheral plates and the two isolation frames.

2. The wall element of claim 1, further comprising: and the filling layer is positioned between the two isolation frames, and the filling layer is made of a heat-insulating material.

3. The wall unit of claim 1, wherein the spacer frame further comprises one or two spacer surfaces.

4. The wall element of claim 3, wherein when the number of the isolation surfaces is two, a rectangular cavity structure is formed between the isolation surfaces and the side walls.

5. The wall unit according to claim 3, wherein when the number of the isolation surfaces is one, a U-shaped cavity structure is formed between the isolation surfaces and the side wall.

6. A wall element according to claim 1, wherein the side wall comprises side portions connected to the connection plate, bent portions extending along a side remote from the side portions, and folded portions coinciding with the side portions and the bent portions, respectively.

7. A wall element according to claim 3, wherein the insulation surface is further provided with a plurality of hole structures.

8. A wall element according to claim 6, wherein the distance from the connection of the bent portion and the side portion to the edge of the connection plate is 1-5 cm.

9. A wall element according to claim 1, wherein the web material is a carbonized wood or wood-plastic board.

10. The wall unit of claim 1, wherein the spacer frame material comprises: stainless steel materials, magnesium alloy materials, aluminum alloy materials and manganese alloy materials.

11. The wall element of claim 1, further comprising: the connecting layer, the connecting layer is located the connecting plate with between the peripheral board, the material of connecting layer is diatom mud.

12. A wall structure comprising a plurality of wall elements as claimed in any one of claims 1 to 11.

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