ES1237114U - POWER WALL (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

1. Energy collecting wall of the type comprising: - an outer face intended to receive solar radiation; - an inner face opposite said outer face facing a passenger compartment; characterized in that said energy capturing wall comprises between said exterior and interior faces a PCM layer that has PCM material and an air circuit, said air circuit providing an air outlet towards the passenger compartment and the energy capturing wall being equipped with means thermal conduction between the air circuit and the PCM layer.

Description

POWER WALL

DESCRIPTION

Field of the Invention

The present invention relates to an energy capturing wall, in particular, the present invention relates to a wall capable of capturing energy, said wall being a constructive element with passively capturing energy.

Background of the invention

In recent times, society, through informative programs, has become aware of the need to save energy and make efficient use of it. In this sense the growth of the use of renewable energies is evident.

In this sense, there are several projects to improve energy consumption, for example, in buildings with the aim of having an energy consumption in heating and cooling is almost nil.

Passive conditioning systems have always been present in the behavior of both humans and most animals. From the most elementary attitude of seeking protection in caves against climatic factors, to the more evolved to reproduce what nature provided in the place, with the desired dimensions and shape. These simple constructive facts gave rise to the experience transmitted from generation to generation, which, based on popular architecture, became passive and bioclimatic architecture.

Passive solar architecture has systems that allow the necessary energy savings in a society that is increasingly aware of the importance of caring for our planet. For example, elements such as the Trombe Wall are known.

The Trombe Wall, disclosed in US Patent US246626, is a wall in which solar radiation is absorbed on the outer face and this is transferred through a conductive wall to the inner face of the wall.

The present invention relates to a solar air collector. The solar air collector is a simple passive solar system that involves the capture of energy from the sun by a glazed surface that are sized for each orientation and depending on the heat needs of the building or premises to be heated, to later be accumulated in an air absorption circuit and transferred to the interior

To date, researchers and universities, seeing the potential of the subject have wanted to focus on solar collectors, as well as phase change materials worked from engineering. Among the most recent and significant studies we find a series of articles published in two of the journals with the greatest international impact between 2000 and today, Energy and Building and Renewable & Sustainable and Energible. Highlights the Massachusetts Institute of Technology, sometimes supported by relevant entities such as King Fahd University of Petroleum and Minerals in Saudi Arabia and Departments of Mechanical Engineering of several Indian Colleges, such as Anna, Chennai and Sri Venkateswara in Sriperumpudur or the Scientific and Technical Center of Construction in, Saint-Martin-Heres, France and the Joseph Fourier University in France.

It is important to highlight in the light of the previous articles that solar air collectors are a novel topic that until now has mostly had a treatment from engineering to develop collectors that we already find commercially. The application in architecture of these, necessary and fundamental, has been practically neglected when it is understood as a posteriori addition in sunny facades.

An example of a solar air collector is the "Solar Wall", applied at the US military base of Ft. Drum, north of New York State. This collector consists of a fully perforated metallic cladding placed on the outer face of a building In this case, years of research have eradicated the need to cover it with glass, improving the ability to integrate into commercial, industrial or institutional buildings, by eliminating said coating, costs are reduced and the time frame of the return on investment is shortened .

Solar radiation heats the metal cladding while the fans create a negative pressure in the air cavity, which allows the air heated by solar energy to be extracted through the perforations of the panels.

The problems of the prior art collectors are, among others, their difficult incorporation into existing walls and the possibility of their incorporation as an architectural element.

The present invention solves the problems of the prior art by means of an innovative structure. Specifically, the present invention discloses an energy sensing wall of the type comprising:

• an outer face intended to receive solar radiation;

• an inner face opposite said outer face facing a passenger compartment;

said energy collecting wall between said outer and inner faces a PCM layer having PCM material and an air circuit said air circuit having an air outlet to the passenger compartment and the energy collecting wall being provided with thermal conduction means between the air circuit and the PCM layer.

Preferably, the thermal conduction means comprise a reinforcement plate between the PCM layer and the air circuit said reinforcement plate being a thermally conductive plate.

In addition, the reinforcing plate functions as a stiffening plate and can be, for example, an aluminum plate or plate.

In the case of buildings without external ventilation, the air circuit may comprise an air inlet from the passenger compartment. In the case of tertiary buildings, the air inlet to the air circuit can be connected to a source or an air supply circuit external to the passenger compartment.

In order to provide the wall with greater heating capacity, the wall may comprise an absorber thermally connected to the air circuit. Said absorber will preferably be thermally in contact with the PCM layer in order to be able to conduct heat to said PCM layer.

More preferably, the wall may comprise a wall of inertia that defines the inner face of the energy collecting wall. Said wall of inertia can be constituted by a material with a high level of inertia such as platelets of mud or refractory brick and, in addition, it can have an additional frame.

As for the PCM material, the present invention contemplates that it is, for example, a material that changes from a solid to a liquid state in the presence of heat such as waxes and / or paraffins.

Additionally, the wall may comprise a glass that defines the outer face of the energy collecting wall, preferably, said glass is a glass with anti-reflective capacity.

Brief description of the figures

Examples of embodiment of the system according to the present invention are shown in the accompanying figures, in which:

- Figure 1 shows an example of a cabin inside a building that incorporates a wall according to the present invention.

- Figure 2 shows a mechanical exploded view of an embodiment of a wall according to the present invention.

- Figures 3A and 3B show longitudinal sections of the example wall of Figure 2.

- Figure 3 shows schematically the layers that make up a wall according to the present invention.

Detailed description of one embodiment

The present invention discloses an energy capture wall in which said energy collection is carried out by using phase change materials, known in the art as PCM (acronym for the English expression "phase change materials"). Phase change materials (PCM) have the ability to store heat (latent heat storage units), high heat of fusion and phase transition point in the environment of the operating temperature. Energy capture wall is to prevent heat loss by absorbing or releasing it.

Figure 1 shows a first embodiment in which an energy sensor wall (1) is arranged adjacent to a conventional wall (3). Preferably, the energy sensing wall (1) of the present invention can be arranged under a window (2).

Figure 1 shows the inner face of the energy collecting wall (1), that is, the face oriented towards the inside of the receptacle. The energy capture wall (1) of Figure 1 is intended for use in buildings and has a circulating air inlet, at the less partially, through the wall of energy capture and recirculated into the interior of the cabin after passing through elements intended to modify the air temperature.

Figure 2 shows an example wall according to the present invention. In the exploded view of Figure 2 an example of a wall is seen comprising a frame (16) whose function is to support the other layers of the energy collecting wall (1). In an exemplary embodiment, the frame (16) can be an angle frame 500 mm 200 mm carbon steel (iron) 3 mm thick. These measures would be especially suitable for an energy sensor wall (1) of 1000 mm x 1000 mm.

The frame (16) can be a one-piece frame, manufactured by folding. In this way, the frame (16) excessively supports the weight of all the layers. This type of preparation and choice of materials allows the energy collecting wall (1) of the present invention to be a supporting structure.

Additionally, the energy collecting wall (1) comprises a glass (14) which is preferably a selective glass that can have an anti-reflective coating in order to allow the greatest amount of solar energy to pass through it to heat the absorbent elements and / or PCM that will be explained in more detail below. Alternatively, a wall according to the present invention can have a simple glass (ESG) to reduce manufacturing costs with which a lower energy collection would be achieved but which may be sufficient in certain applications.

In particular embodiments of the present invention, the energy collecting wall (1) can have an insulating layer (20) that has a double function of preventing heat losses towards the frame (16) and acting as a fireproof element. An example of the type of insulating layer (20) according to the present invention is a panel of mineral wool, for example, the one manufactured by Knauf. Said panel is fireproof, thermal insulating, acoustic insulating, dimensionally stable and unalterable in time which makes it particularly suitable for the energy collecting wall (1) of the present invention.

The solar collector wall (1) further comprises an air circuit (13) comprising an air inlet (130), for example, from the inside of the wall the air is circulated through the air circuit comprising, for example, a coil (132) and then circulated again in the direction of the inner face through an air outlet (131).

The heating of the air that passes through the air circuit (13) to heat the interior exposed to the inner face of the energy collecting wall (1) can be carried out, for example, by two complementary heating methods: The arrangement of a solar energy absorber between the glass (14) and the air circuit (13) and / or the arrangement of a layer of PCM with thermal conduction capacity towards the air circuit (13).

As for the absorber, an absorber of the known type and commonly used in photovoltaic generators can be arranged, such as, for example, a double-flow bitubular absorber or any other material capable of absorbing photons of solar radiation in the form of heat for transfer, in this case, to the air circuit (13).

On the other hand, the air circuit (13) is heated by the action of a layer of PCM (12). The PCM layer has a series of receptacles that have materials that are capable of phase change, such as paraffins or waxes.

The PCM used will find its phase change, preferably, at about 40 ° C, which is the temperature that could be reached in the PCM layer (12) when receiving energy from the Sun. Organic materials, such as waxes, paraffins and other PCMs Easy access in the market are preferred.

Since, in the presence of heat energy, the PCM layer (12) can be substantially liquid, it is possible to incorporate a reinforcing plate (15) whose function is to maintain the PCM layer (12) in a certain way. In the case of Figure 2, the reinforcement plate (15) is disposed between the PCM layer (12) and the air circuit (13), so that the reinforcement plate (15) must be thermally conductive, by example, it can be an aluminum sheet.

Finally, a wall of inertia (11) is provided that gives the wall a rigidity sufficient to be a structural wall. In this case, we have opted for a stone solution of refractory brick 4 cm thick that will be left visible in the internal part of the house. A characteristic of the wall of inertia (11) is that, preferably, it should be composed of material with a high level of inertia such as clay platelets or refractory brick. Optionally, the inertia wall may have an additional frame (19) to hold the energy collection wall (1) together.

Figures 3A and 3B show two longitudinal sections of the collecting wall of Figure 2. Specifically, Figure 3A shows a longitudinal section that coincides with the air outlet (131) and Figure 3B shows a longitudinal section that coincides with a part longitudinal of the coil (132).

In said longitudinal sections, the arrangement of the energy collecting wall (1) is observed as an architectural element, preferably structural. In this example, the Energy collecting wall has its outer face towards the sunny facade of a structure, that is, oriented towards the sun (17) to receive solar radiation and its inner face towards a receptacle (18).

The solar energy received by the wall causes the PCM layer (12) to heat up, generating a phase change in the materials that compose it, for example, from a solid state to a liquid state, storing energy in the form of heat.

In the case that the structure is a building, the energy capture wall (1) has an air inlet coming from the receptacle (18) that is circulated along the air circuit, specifically, of the coil (132 ). The air circuit (13) is heated due to direct or indirect contact with the PCM layer (12) which, in turn, heats the air that circulates through said circuit.

In the case of tertiary buildings, since they must have ventilation, the air inlet (130) can be connected to a source of external ventilation to the passenger compartment.

Finally, the air is recirculated again to the receptacle (18) with a higher temperature.

The presence of the inertia wall (11) gives the energy-sensing wall (1) a rigidity that allows its use as a structural wall and, in addition, the use of refractory brick allows maintaining the internal temperature of the air circuit (13) and the PCM layer (12).

Figure 4 shows a diagram of the layers that can comprise an energy sensor wall (1) according to the present invention.

The energy collecting wall (1) comprises an outer layer that is disposed towards the Sun (17) and an inner layer that is disposed towards an internal receptacle (18). Between said outer and inner layers there is an air circuit (13) and a PCM layer with thermal conduction capacity towards the air circuit (13).

Optionally, additional means of heating the air circuit and / or the PCM layer may be available, for example, by arranging an absorber (133) thermally connected to the air circuit (13) and / or to the layer of PCM (12).

To provide the energy collecting wall (1) with a stiffness that allows it to support the typical loads of a structural wall, the addition of a frame (16) and an inertia wall (11) is contemplated.

Claims (13)

1. Energy sensor wall of the type comprising: • an outer face intended to receive solar radiation; • an inner face opposite said outer face facing a passenger compartment; characterized in that said energy collecting wall comprises between said outer and inner faces a layer of PCM having PCM material and an air circuit said air circuit having an air outlet towards the cabin and the energy collecting wall being provided with means of thermal conduction between the air circuit and the PCM layer. 2. Wall according to claim 1, characterized in that the thermal conduction means comprise a reinforcement plate between the PCM layer and the air circuit, said reinforcement plate being a thermally conductive plate. 3. Wall according to claim 2, characterized in that the reinforcing plate is an aluminum plate. 4. Wall according to any of the preceding claims, characterized in that the air circuit comprises an air inlet from the passenger compartment. 5. Wall according to any one of claims 1 to 4, characterized in that the air circuit comprises an air inlet from an air supply circuit. 6. Wall according to any of the preceding claims, characterized in that it comprises an absorber thermally connected to the air circuit. 7. Wall according to any of the preceding claims, characterized in that it comprises an absorber thermally connected to the PCM layer. 8. Wall, according to any of the preceding claims, characterized in that it comprises a wall of inertia that defines the inner face of the energy collecting wall. 9. Wall according to claim 9 characterized in that the inertia wall has an additional frame. 10. Wall according to claim 8, characterized in that the wall of inertia comprises a series of refractory bricks. 11. Wall according to any of the preceding claims, characterized in that the PCM material is a material that changes from a solid to a liquid state in the presence of heat. 12. Wall according to claim 11, characterized in that the PCM material is a wax and / or a paraffin. 13. Wall, according to any of the preceding claims, characterized in that it comprises a glass defining the outer face of the energy collecting wall.