RU216002U1 - HYBRID WALL PANEL - Google Patents

Abstract

The utility model relates to a modular prefabricated hybrid wall panel for residential and commercial buildings that collectively performs heating, ventilating and air conditioning tasks for both interior and exterior walls, and a method for manufacturing the same. The utility model provides a hybrid wall panel comprising an inner wall layer, an outer wall layer, and a heat exchanger system located between said inner and outer wall layers. Said heat exchanger system has a series of tubes serving as conduits for heating or cooling fluid, and said hybrid wall panel further comprises an insulation layer having air cavities in its construction.

Description

Field of technology to which the utility model belongs

The utility model relates to a modular prefabricated hybrid wall panel for residential and commercial buildings that collectively performs heating, ventilating and air conditioning tasks for both interior and exterior walls, and a method for manufacturing the same.

Utility model background

Efficient control of the ambient temperature in the interior of buildings is an important problem for which many methods have been proposed over the years. Embedding pipes in floors, ceilings and walls is an approach to keep rooms warm and/or cool with large heat exchange surfaces. Previously, the method was applied using rigid flow paths, including concrete or metal pipes embedded in the walls, and covering them with alum or gypsum during the construction of the building wall. The problem with this approach is the high cost of repairing leaks and the formation of moisture on the wall, which can only be remedied by costly demolition. More practical solutions later emerged in the industry, such as modular panels with pre-installed piping, or installing and plastering heating mats or pipes on existing walls. Examples of such panels can be found in AT405429-A and EP 2397322-A2. This approach helps with the installation of heating/cooling systems on an existing wall, but still does not support obtaining a flexible and convenient installation of the radiant panel along with the construction of supporting structural elements such as ventilation systems. In addition, the proposed modular panels do not offer solutions to prevent/reduce the formation of moisture on said panels.

When calculating the rate of heat transfer and the insulation characteristics of a panel, which are directly affected by any accumulation of moisture inside the panel, significant parameters such as insulation type, insulation thickness and pipe spacing must be taken into account, however, commercially available panels are offered only in a few standard types instead of designing according to important variables such as several structural details and climatic conditions. This leads to inappropriate adjustment and insufficient optimization of energy, cost and comfort between panels and existing building structure properties.

Prefabricated wall panels are commercially available, however none of them perform the tasks of heating, ventilation and air conditioning in an integrated manner, and furthermore, the formation of moisture on and/or inside the wall panels is an unresolved issue in panel wall technology.

Therefore, the utility model provides a complete hybrid wall that provides a compact design having radiant heating/cooling and ventilation (HVAC) systems along with a new insulation layer having improved insulating capacity, reducing moisture buildup on and/or within the proposed wall. In addition, the disclosed hybrid wall according to the utility model speeds up the installation of the HVAC system according to different geographic conditions and environmental conditions by saving time, labor as well as installation and thereby low cost.

The purpose of the utility model is to provide an improvement in energy efficiency as a power transmission system.

This object can be understood more clearly by considering the following description of the utility model and the detailed descriptions throughout the text.

Brief Description of the Utility Model

The utility model provides a hybrid wall panel comprising an inner wall layer, an outer wall layer, and a heat exchanger system located between said inner and outer wall layers. Said heat exchanger system has a series of tubes serving as conduits for heating or cooling fluid, and said hybrid wall panel further comprises an insulation layer having air cavities in its construction.

According to a preferred embodiment of the utility model, said insulation layer (40) has at least 70% air cavities by volume.

According to a preferred embodiment of the utility model, said insulation layer is made of foam concrete, airgel, or a mixture thereof. In addition, said insulation layer is preferably made of foam concrete, the air cavity content of which is between 70 and 80% by volume. Alternatively, said insulation layer may be made from aerogels having air cavities.

According to another embodiment of the utility model, said outer wall layer and/or said inner wall layer (10) is made of glass-reinforced concrete.

According to another embodiment of the utility model, the pipes of said heat exchanger system are made of cross-linked polyethylene.

According to another embodiment of the utility model, the disclosed hybrid wall panel further comprises a ventilation system with internal air ducts located between said inner wall layer and said outer wall layer.

According to another embodiment of the utility model, the disclosed hybrid wall panel further comprises at least one ventilation duct connected to said air ducts of the ventilation system and located on the inner layer of the wall.

According to another embodiment of the utility model, the disclosed hybrid wall panel further comprises a tie frame located between said inner wall layer and said outer wall layer. Said tie frame is preferably made from load-bearing structural elements. Optionally, said tie frame further comprises anchor rods for securing the outer layer of the wall to the tie frame. Additionally, said tie frame may further comprise side reinforcement provided on the outer sides of the tie frame to secure the hybrid wall panel to the building reinforcement.

According to another embodiment of the utility model, the hybrid wall panel according to the utility model may further comprise at least one recess and a protrusion at its horizontal ends extending along the horizontal (x) direction for interlocking one panel to another to form a modular structure.

The utility model further discloses a method for manufacturing a hybrid wall panel according to any of the preceding claims, comprising the following steps:

a) pouring the glass-reinforced concrete mixture in the liquid phase into the mold and removing it from the mold after complete hardening to obtain the outer layer (60) of the wall,

b) placing the tie frame (50) in the resulting outer layer (60) of the wall,

c) pouring the liquid mixture both on said outer layer (60) of the wall and on the placed tie frame (50) to provide the layer (40) of insulation,

d) arrangement of pipes of the system (30) of the heat exchanger, internal air ducts (20) and the ventilation duct (21) of the ventilation system on a fully hardened mixture of the insulation layer (40),

e) pouring the fiberglass-reinforced concrete mixture onto the insulation layer (40) to form the inner layer (10) of the wall.

The figure, of which a brief explanation is herewith provided, is intended solely to provide a better understanding of the utility model and, thus, is not intended to determine the scope of legal protection or the context in which the specified scope should be interpreted in the absence of a description.

In FIG. 1 is an exploded view of an exemplary modular finished hybrid wall panel.

The utility model is described below in conjunction with the accompanying figure and specific embodiments. It is to be understood that the following specific embodiments are used to illustrate the utility model only and are not used to limit the scope of the utility model. It should be noted that the term "vertical" used in the description below refers to the direction (y) and the term "horizontal" refers to the direction ( x ), which are based on the position of the outer wall layer (60) shown in FIG. 1.

The utility model discloses a finished hybrid wall panel (100) made in one piece with a fluid heating and cooling system. Said hybrid wall panel (100) comprises an inner wall layer (10), an outer wall layer (60) and a heat exchanger system (30) located between said inner and outer wall layers. The disclosed heat exchanger system (30) has a number of tubes that function as conduits for the heating or cooling fluid. In addition, said hybrid wall panel (100) contains an insulation layer (40) having air cavities in its construction.

According to one embodiment of the utility model, said insulation layer (40) has at least 70% air cavities by volume. Optionally, said air cavities may be in the form of small pockets which contain trapped air.

According to a preferred embodiment of the utility model, as shown in FIG. 1, the pipes of the heat exchanger system (30) are distributed between the insulation layer (40) and the inner layer (10) of the wall to prevent heat transfer between the outer layer (60) of the wall and the pipes, and the geometry of the pipes and the distances between them can be considered as functions of the thermal load on the building and properties of several elements used in the hybrid wall panel (100) and calculated and designed according to variables such as structural details and climate conditions to apply proper energy regulation and optimization. Thus, the inventive hybrid wall panel (100) is extremely flexible according to the environmental conditions and the desired performance.

The pipe material of the heat exchanger system (30) is preferably selected from plastic derivatives. More preferably, the pipes of the heat exchanger system (30) are made of cross-linked polyethylene.

The fluid that flows through the pipes of the heat exchanger system (30) may be water or any other liquid fluid that contains oil and liquid refrigerants.

The utility modellers have found that the void space of the insulation material provides additional thermal insulation properties and further prevents/significantly reduces the formation of moisture in the hybrid wall panel as disclosed herein and/or improves the moisture optimization of the insulation layer (40). Thus, the insulation layer (40) of the disclosed hybrid wall panel (100) according to the utility model mainly contains air cavities in its construction. Thus, said insulation layer (40) may be made from any suitable material having air pockets in its construction, as disclosed above.

According to a preferred embodiment of the utility model, said insulation layer (40) contains air cavities that form at least 70% of the insulation layer (40) by volume.

Optionally, the insulation layer (40) may be made of foam concrete, aerogels, or mixtures thereof.

The inventors of the utility model have found that the thermal conductivity coefficient (λ) of a material is low if the density of said material in its solid state is also low. In addition, the results of their experiments show that an insulating material made of foam concrete, having at least 70% air cavities in its volume, has a density of 200-350 kg/m ³ with a lambda value (λ) of 0.055-0.077 W/m⋅ TO. Thus, in order to provide an effective thermal insulation property, as well as to prevent/reduce the formation of moisture on the proposed wall, said insulation layer is preferably made of foam concrete having at least 70% air cavities by volume. As will be appreciated by one skilled in the art, foam concrete is a lightweight material having a Portland cement paste or grout with a uniform hollow or porous structure created by introducing air in the form of small bubbles.

According to another preferred embodiment, the insulation layer (40) is made of foam concrete, the air content of which is from 70 to 80% of the total volume. In addition, due to the low density and highly porous structure, foam concrete has good functional properties such as fire resistance and acoustic performance. Alternatively, the insulation layer (40) may be made from airgels having air cavities.

According to an embodiment of the utility model, said outer layer (60) of the wall is made of glass-reinforced concrete. In addition, said inner layer (10) of the wall can be made of fiberglass-reinforced concrete. Optionally, both the outer layer (60) of the wall and the inner layer (10) of the wall are made of fiberglass reinforced concrete.

By taking into account the environmental conditions and the desired technical characteristics, the hybrid wall panel (100) according to the utility model may optionally contain a ventilation system with internal air ducts (20) located between said inner wall layer (10) and said outer wall layer (60). Said internal air ducts (20) are preferably located between the inner layer (10) of the wall and the pipes of the heat exchanger system (30). Moreover, the ventilation system and hence the hybrid wall panel (100) comprise at least one ventilation duct (21) connected to said air ducts of the ventilation system (20) to adequately supply fresh air to the inside of the building.

The proposed hybrid wall panel (100) according to the utility model has a large surface in the x -direction and y -direction plane and a thickness in the z -direction, as shown in the exploded view shown in FIG. 1. The inner layer (10) of the wall of the hybrid wall panel (100), which is predominantly superimposed in the plane of the x direction and the y direction, further accommodates said at least one ventilation duct (21), but preferably several ventilation ducts (21).

The hybrid wall panel (100) according to the utility model further comprises a tie frame (50) located between said inner wall layer (10) and said outer wall layer (60). Said tie frame (50) is preferably located between the insulation layer (40) and the outer layer (60) of the wall for application predominantly in the x -direction and y -direction plane. According to a preferred embodiment, said tie frame (50) is made of load-bearing structural elements, i.e. steel, iron, aluminum, composite materials, alloys, etc., and optionally has anchor rods (51) for fixing the outer layer (60) of the wall on the tie frame (50) and / or side reinforcement provided on the outer sides of the tie frame (50) for attaching the hybrid wall panel (100) to the reinforcement of the building.

For structural purposes, the hybrid wall panel (100) according to the utility model may further comprise at least one notch and projection (not shown) at its horizontal ends extending along the horizontal direction ( x direction) to interlock one panel to another to form a modular structure. . This advantageous design of the hybrid wall panel (100) allows them to be connected effortlessly.

The height ( y direction) and width ( x direction) of the hybrid wall panel (100) vary according to the floor height and room dimensions of the architecture object. The thickness of the inner wall layer (10), outer wall layer (60) and insulation layer (40) also vary according to the requirements of the architectural object and can be considered as functions of the thermal load on the building and the properties of several materials used in the hybrid wall panel (100). In addition to the thermal insulation capacity of the insulation layer (40), it is also used as a moisture-proof layer to provide a more uniform temperature distribution over the wall surface and additionally create a bad smell and appearance of said panel.

The materials to be used in the inventive hybrid wall panel (100), their location and thickness, pipe spacings, wall panel dimensions and embodiments may vary according to the needs of structural, thermal and economic optimization of the associated objects. By means of the inventive hybrid wall panel (100) discussed above, a separation of spaces within buildings and external wall structures is achieved along with a fluid heating/cooling system. This hybrid wall panel represents a complete solution to technical challenges including moisture generation, air conditioning, construction and insulation, and strong bonding between individual wall panels (100).

The utility model further discloses a method for manufacturing a hybrid wall panel according to the utility model, said method comprising the following method steps:

a) pouring the glass-reinforced concrete mixture in the liquid phase into the mold and removing it from the mold after it has completely hardened to obtain the outer layer (60) of the wall,

b) placing the tie frame (50) in the resulting outer layer (60) of the wall,

c) pouring the liquid mixture both on said outer layer (60) of the wall and on the placed tie frame (50) to provide the layer (40) of insulation,

d) arrangement of pipes of the system (30) of the heat exchanger and / or internal air ducts (20) and the ventilation duct (21) of the ventilation system on a fully hardened mixture of the insulation layer (40),

e) pouring the fiberglass-reinforced concrete mixture onto the insulation layer (40) to form the inner layer (10) of the wall.

The method of manufacture proposed in the utility model is advantageous because a hybrid wall panel made according to the disclosed method steps will have a compact but layered internal structure, while these layers are completely adjacent to each other, since the layers are essentially connected to each other. the other, while at least one of them is also placed in the wall panel in a liquid or semi-liquid phase. Thus, the resulting hybrid wall panel has a "closed box as a block" structure, while the exposed layers bear the load of the adjacent layers. This technical effect can be called "block effect".

According to one embodiment of the utility model, instead of implementing step a) of the disclosed method, a preformed layer can be used as the outer layer (60) of the wall according to the utility model. In addition, the embodiments of the layers and/or systems disclosed above may be implemented in the method steps disclosed above.

Claims (13)

1. Hybrid wall panel (100), containing the inner layer (10) of the wall, the outer layer (60) of the wall and the system (30) of the heat exchanger located between the specified inner and outer layers of the wall, while the specified system (30) of the heat exchanger has a number of pipes , performing the function of channels for heating or cooling fluid, characterized in that said hybrid wall panel (100) further comprises an insulation layer (40) having air cavities in its design, while said insulation layer (40) has at least 70 % of air cavities by volume. 2. Hybrid wall panel (100) according to claim 1, characterized in that said insulation layer (40) is made of foam concrete, aerogels or mixtures thereof. 3. Hybrid wall panel (100) according to claim 2, characterized in that said insulation layer (40) is made of foam concrete, the content of air cavities of which is from 70 to 80% by volume. 4. Hybrid wall panel (100) according to claim 2, characterized in that said insulation layer (40) is made of airgels having air cavities. 5. Hybrid wall panel (100) according to any one of the preceding claims, characterized in that said outer wall layer (60) and/or said inner wall layer (10) is made of fiberglass reinforced concrete. 6. Hybrid wall panel (100) according to any one of the preceding claims, characterized in that the pipes of said heat exchanger system (30) are made of cross-linked polyethylene. 7. Hybrid wall panel (100) according to any one of the previous claims, characterized in that it further comprises a ventilation system with internal air ducts (20) located between said inner wall layer (10) and said outer wall layer (60). 8. Hybrid wall panel (100) according to claim 7, characterized in that it additionally contains at least one ventilation duct (21) connected to said air ducts of the ventilation system (20) and located on the inner layer (10) of the wall. 9. Hybrid wall panel (100) according to any one of the preceding claims, characterized in that it further comprises a tie frame (50) located between said inner wall layer (10) and said outer wall layer (60). 10. Hybrid wall panel (100) according to claim 9, characterized in that said tie frame (50) is made of load-bearing structural elements. 11. Hybrid wall panel (100) according to claim 10, characterized in that the specified tie frame (50) additionally contains anchor rods (51) for fixing the outer layer (60) of the wall on the tie frame (50). 12. Hybrid wall panel (100) according to any one of paragraphs. 10 or 11, characterized in that said tie frame (50) further comprises side reinforcement provided on the outer sides of the tie frame (50) for fixing the hybrid wall panel (100) to the building reinforcement. 13. Hybrid wall panel (100) according to any one of the preceding claims, characterized in that it further comprises at least one notch and protrusion at its horizontal ends extending along the horizontal direction ( x) for interlocking one panel to another to form a modular structure .

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