DE102007047693A1 - Façade or roof element for attachment to a building and use thereof - Google Patents

Abstract

The invention relates to a facade or roof element for attachment to a building, with an outer wall, with an inner wall (10) and with a between the outer and the inner wall (10) arranged, thermal latent memory (14), wherein the outer wall as transparent thermal insulation (TWD) is formed and wherein in the latent memory, a fluid-carrying line (26) is arranged. To create a facade or roof element with a low temperature gradient in the latent memory, is achieved in that the latent memory at least one thermally conductive, open-cell lightweight board (24), in which a storage medium (28), preferably a phase change material (PCM) held is and that the lightweight board (24) has thermal contact with the fluid-carrying line (26).

Description

The The present invention relates to a facade or roof element according to the The preamble of claim 1 and a use thereof according to claim 8.

From the EP 1 248 932 B1 is a building exterior wall replacement facade element is known in which between two glass panes a PCM (phase change material, in particular paraffin, calcium chloride hexahydrally or the like) containing latent memory is provided. On one of the outside facing side of the facade element of the latent memory bounding glass is a prism-like glass pane spaced upstream, wherein the gap is filled with a standard in insulating glass gas. This creates a transparent thermal insulation that isolates the building well and yet allows sunlight to pass through the latent memory. The prisms are adjusted so that the heat radiation of the sunlight is at least partially reflected in the high sun in summer, while the heat radiation is transmitted in low sun in winter. This avoids overheating in the summer and supplies solar energy to the latent storage in winter.

With the facade element according to EP 1 248 932 B1 Thus, the heating in winter should be supported by the use of solar energy, while the prisms should avoid overheating in summer. To protect the environment, it would be desirable if the existing solar energy could be used even more intensively.

in the Inside the latent memory is a fluid-carrying pipe provided, which is connected to a heater, so that the latent memory supplied with additional heat energy in winter can, if the solar energy for heating the facade element should not be sufficient at room temperature. In latent memory is located a part of the storage medium PCM directly to the pipes, so that the heat carried by the fluid over the Pipes to the storage medium located in the immediate vicinity of the pipes can be discharged and only then in more remote areas of the Latent storage wanders. PCM has a poor thermal conductivity which has the consequence that in the latent memory a temperature gradient arises and that in the area of the tube a higher temperature prevails, as in more remote areas, allowing the heat transfer from the tube to the storage medium is difficult. this leads to to a high energy input, on the side facing the room the facade element to provide a sufficient temperature.

From that The present invention is based on the object, a façade or roof element of the type mentioned with a small To create temperature gradient in the latent memory.

When technical solution to this problem is inventively a Façade or roof element with the features of claim 1. Advantageous developments this façade or roof element are the dependent claims refer to.

One trained according to this technical teaching facade or roof element has the advantage that the thermally conductive lightweight board, in thermal contact with the fluid-carrying line stands, the heat stored in the latent memory very quickly transported to the fluid-carrying line and vice versa, that provided by the fluid-carrying line Heat can be distributed very quickly in the latent storage. Another advantage is that in the open pores of the lightweight board held storage medium has a large contact area to the lightweight board possesses, so that over this large contact surface Heat can be transferred in a very short time. The result is through the thermally conductive, open-pored lightweight board created with the storage medium stored therein a latent storage, due in part to the good conductivity of the Lightweight panel a very even temperature distribution owns and in which the existing latent heat over the lightweight board very quickly to the fluid-carrying line emits. It is understood that in the opposite direction the Heat emitted by the fluid-carrying line very fast and evenly through the lightweight board is distributed in the latent memory. As a result, this leads to the advantage that the façade according to the invention or roof element stored heat quickly and with low loss can deliver to the fluid-carrying line, for example in order to operate a heat pump.

One Another advantage is that the occurring solar heat through the thermally conductive, open-pored lightweight board is distributed very quickly throughout the entire memory, so that local overheating be avoided.

there It has proved to be advantageous, the open-pored lightweight panel as a matrix of expanded, preferably highly porous Natural graphite or from an open-pored, foamed metal manufacture. Both materials have a high thermal conductivity, can be designed porous and are available in sufficient Quantity and inexpensive available.

In a preferred embodiment, the outer wall comprises two parallel arranged Glass panes, between which a vacuum is formed. Due to this vacuum, the façade or roof element achieves a very high insulating effect, so that the heat stored in the latent storage is only lost to the outside wall again to a very small percentage.

In An advantageous development are between the glass panes a number of spacers arranged. This has the advantage that by the vacuum on the glass panes acting forces not lead to a cracking or breaking of the glass panes.

In an alternative embodiment is the outer wall formed as two or three panes having insulating glazing. Such insulating glazings are known in the art and have also good insulation values, so that here in the latent memory existing heat only to a small percentage again get lost.

In the facade element according to EP 1 248 932 B1 The lead through the latent storage line is used to supply heat to the latent storage in winter, so that the space behind it is sufficiently heated. In this façade element, the solar energy is used only to support the winter heating. However, in order to be able to use the solar energy even more effectively, the invention proposes to remove excess solar energy via the fluid-carrying line, and to supply it to a heat pump, especially in the summer and during the transitional period, a transparent thermal insulation and a latent storage. About this heat pump can then be heated, for example, hot water or a heater can be supported.

there It has proved to be advantageous to a storage medium with a Phase change temperature between 18 ° C and 26 ° C, preferably between 21 ° C and 22 ° C, wherein advantageously the latent storage so much heat is removed, that this always a temperature between 18 ° C and 26 ° C, preferably between 21 ° C and 22 ° C has. Such a latent memory thus has the the people in the room have an ideal temperature, which As a result, the room temperature will also be at least is located almost in this area. In summer causes such a temperature that the occupants of the facade element as an area, from which a pleasant coolness emanates. In winter, the façade element is pleasant perceived low-temperature radiant heat. In the result Thus, the selected phase change temperature is year-round created a very pleasant room climate.

Further Advantages of the invention facade or Roof element will be apparent from the accompanying drawings and the embodiments described below. As well may be the ones mentioned above and the others Features according to the invention in each case individually or be used in any combination with each other. The mentioned Embodiments are not exhaustive Enumerating to understand, but rather have exemplary Character. Show it:

1 a schematic representation of a section of a facade or roof element according to the invention in a sectional view, taken along line II in 2 ;

2 a schematic representation of the section of the facade or roof element according to 1 in a sectional view, cut along line II-II in 1 ;

3 an enlarged detail of the façade or roof element according to 1 according to line 111 in 1 ;

4 a schematic representation of a section of a second embodiment of a facade or roof element according to the invention in a sectional view.

In the 1 to 3 a section of a facade or roof element according to the invention is shown, which has an inner wall 10 , an exterior wall 12 and a thermal latent accumulator disposed between the outer and inner walls 14 includes. The outer wall 12 consists of a first, 6 mm thick glass pane 16 and a second, also 6 mm thick glass pane 18 , Between the first glass pane 16 and the second glass pane 18 are a number of spacers 20 arranged the two glass panes 16 . 18 Keep apart from each other. Between the first glass pane 16 and the second glass pane 18 is a vacuum 20 designed to provide good thermal insulation of the outer wall 12 to reach. The spacers 20 cause the glass panes 16 . 18 do not bend and break due to the forces created by the vacuum. The glass panes 16 . 18 have a high heat radiation passage coefficient, so that the incident on the outside of the facade or the roof element solar radiation well in the latent memory 14 arrives. At the same time, the outer wall has 12 a good insulation value, so that in latent storage 14 existing heat is not lost uncontrollably again.

The inner wall 10 is also made of a 6 mm thick glass pane. This interior wall 10 can be printed or painted according to taste or be made of a glass opaque to the human eye. This interior wall 10 serves as a room wall in the finished building, so that its decorative design is reserved for the individual tastes of the residents.

In the latent memory 14 is a good heat-conducting, open-pore lightweight board 24 formed from a matrix of expanded, highly porous natural graphite. In the open pores of the lightweight board 24 is a storage medium 28 , in this case a PCM (Phase Change Material) stored. This PCM can be a paraffin or a calcium chloride hexahydral. In about the middle of the latent memory 14 is a fluid-carrying line 26 provided with the lightweight board 24 is in thermal contact. About this line 26 can the latent memory 14 Heat withdrawn or supplied. The administration 26 is ideally laid meandering and runs through the latent memory 14 a large area. The administration 26 is connected to a heat pump not shown here, so that the guided heat in the heat from the heat pump can be energetically used.

The storage medium 28 has a phase change temperature between 21 ° C and 22 ° C, allowing the storage medium 28 can absorb most of the energy in this temperature range.

It is understood that in the 1 to 3 shown element can be used both as a facade element in a building, as well as a roof element of a building.

following the operation of such a facade or roof element is detailed described.

The façade or roof element is attached to a building as a replacement for a normal house wall, with the outer wall 12 facing the sun and being the inner wall 10 facing the interior of the building. Here, the inner wall is used 10 at the same time as a room closure and can be decorated according to the wishes of the resident decorative, in particular by imprints, by using certain glass materials or the like.

Solar radiation causes solar heat through the outer wall 12 in the latent memory 14 , The incoming solar energy is through the lightweight board 24 and its high thermal conductivity quickly throughout the latent storage 14 distributed. Due to the large contact surface between the lightweight board 24 and the storage medium 28 The solar heat is released quickly to the PCM. Because the PCM has a phase change temperature between 21 ° C and 22 ° C, has the latent memory 14 usually also a temperature between 21 ° C and 22 ° C on.

Through the line 26 For example, a fluid, such as water or glycol, flows at a lower temperature, which causes the fluid to heat on its way through the cladding or roof element. Again, there is a rapid heat transfer from the storage medium PCM to the fluid instead, because the lightweight board 24 has a good thermal conductivity and thus the heat can be transported quickly from the PCM to the fluid.

The removal of heat from the latent storage 14 is controlled so that the latent storage ideally always has a temperature between 21 ° C and 22 ° C. In exceptional cases, the temperature of the latent accumulator can also drop to 18 ° C or rise to 26 ° C. In summer, a tempered to 21 ° C to 22 ° C façade or roof element to a pleasant cooling of the building, while in winter tempered to 21 ° C to 22 ° C façade or roof element avoids cold radiation, so that all year round a very pleasant indoor climate is created, whereby at the same time excess solar energy can be used via the heat pump.

This in 4 Facade element shown differs from that in 1 to 3 Facade element shown only in that the outer wall 112 consists of a three-pane insulating glazing according to the prior art. Incidentally, this second embodiment corresponds to the in the 1 to 3 illustrated embodiments with all its advantages.

10

inner wall

12 112

outer wall

14

latent storage

16

pane

18

pane

20

spacer

22

vacuum

24

lightweight panel

26

management

28

storage medium

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 1248932 B1 [0002, 0003, 0013]

Claims (10)

Façade or roof element for attachment to a building, with an outer wall ( 12 . 112 ), with an inner wall ( 10 ) and with one between the outside ( 12 . 112 ) and the inner wall ( 10 ), thermal latent memory ( 14 ), the outer wall ( 10 . 112 ) is designed as transparent thermal insulation (TWD) and wherein in the latent memory a fluid-carrying line ( 26 ), characterized in that the latent memory ( 14 ) at least one thermally conductive, open-pore lightweight building board ( 24 ) in which a storage medium ( 28 ), preferably a phase change material (PCM), is held and that the lightweight board ( 24 ) thermal contact with the fluid-carrying line ( 26 ) Has. Façade or roof element according to claim 1, characterized in that the open-pore lightweight building board ( 24 ) is formed as a matrix of expanded, preferably highly porous, natural graphite. Façade or roof element according to claim 1, characterized characterized in that the open-pored lightweight board made of a foamed Metal is formed. Façade or roof element according to one of the preceding claims, characterized in that the outer wall ( 12 ) two parallel glass panes ( 16 . 18 ), between which a vacuum ( 22 ) is trained. Façade or roof element according to claim 4, characterized in that between the glass panes ( 16 . 18 ) a number of spacers ( 20 ) are arranged. Façade or roof element according to one of claims 1 to 3, characterized in that the outer wall ( 112 ) is formed as two or three sheets of glass having insulating glazing. Façade or roof element according to one of the preceding claims, characterized in that the storage medium ( 28 ) has a phase change temperature between 18 ° C and 25 ° C, preferably between 21 ° C and 22 ° C. Use of a facade or roof element for attachment to a building, with an outer wall ( 12 . 112 ), with an inner wall ( 10 ) and with one between the outside ( 12 . 112 ) and the inner wall ( 10 ), thermal latent memory ( 14 ), the outer wall ( 12 . 112 ) is designed as a transparent thermal insulation (TWD) and wherein in the latent memory ( 14 ) a fluid-carrying line ( 26 ) is arranged, in particular according to one of the preceding claims, for receiving solar energy in the latent memory ( 14 ), characterized in that excess solar energy via the fluid-carrying line ( 26 ) is supplied to a heat pump. Use of a facade or roof element according to claim 8, characterized in that outside the heating period from the latent memory ( 14 ) so much energy via the fluid-carrying line ( 26 ) is supplied to a heat pump that the located behind the facade or roof element rooms are cooled. Use of a facade or roof element according to one of claims 8 or 9, characterized in that the latent memory ( 14 ) is maintained year-round at a temperature level of 18 ° C to 25 ° C, preferably 21 ° C to 22 ° C.