SE528110C2 - Double glazed window containing sunlight absorbing film, contains thermally insulating sheet between film and inner pane - Google Patents

Abstract

A preferably transparent sheet of thermally insulating material is placed between the film and the inner pane and is designed to reduce heat radiating from the film to the room inside the building via the inner pane. A thin film with a light absorption which can be altered via an electrical voltage connectable to the film is located between the inner and outer panes.

Description

528 110 2 by limiting the heating of the thin film during sunlight absorption. This has been achieved according to a preferred embodiment of the invention in that the heat-insulating wall divides the inner space of the windows into an inner gap and an outer gap communicating therewith, through which a gaseous fluid, such as air, circulates from a cold end of a thermal energy storage, through the inner gap, and the outer gap, in which the circulating fluid coats the tower film and thereby absorbs heat from the thin film, when it has been subjected to a higher temperature than the circulating fluid by incident sunlight, and again to a hot end of the energy storage.

Buildings of a type suitable for an application of the invention are known by e.g. EP0102987, sometimes also the walls, like the windows, are provided with inner and outer gaps separated by a heat-insulating wall and interspersed with a circulating fluid for tanning the building, as shown e.g. and SE46073l. Such an embodiment in combination with a per se known thermal energy store with a hot and a cold end means that in external cooling a relatively low temperature of the supplied circulating fluid is required for heating the interior of the building, namely about 23 ° C, and in external heat a relatively high temperature of the supplied circulating fluid is required for keeping the building cool, namely about 18 ° C. A device of this known type for tanning a building has the advantage that the energy needed - low energy energy - can be obtained at low cost in many different ways anywhere in the world in the form of, for example, waste heat or district heating return, as seasonally stored solar heat and winter cooling or short-term stored solar heat and night cooling.

When a thin film according to the invention is arranged in the outer gap of the window, the thin film is heated by incident sunlight as soon as it begins to absorb sunlight, but a large part of the friend is taken care of by cooler circulation fluid which flows into the outer gap and coats the thin film. the heat to the thermal energy storage.

The arrangement of the thin film in the outer gap thus entails, in addition to the window obstructing or dampening the solar radiation, partly that solar heat is absorbed in the window and supplied with an energy store, partly that the thin film is cooled and prevented from heating internal rooms by heat radiation.

The thin film can be placed on the outside of the heat-insulating wall or on the inside of the outer window. Most effective, however, is if the thin film is located substantially in the central plane of the outer gap with both sides affected by the circulating fluid.

Furthermore, of course, at least a part of the outer gap may contain a second thin film, which is coated with the circulating fluid and which is of the type which is preferably transparent and which, depending on incident solar energy, generates electrical energy. Such a thin film has the property that the efficiency deteriorates at elevated temperature, which is thus counteracted by the cooling effect which, according to the above, the circulating fluid exerts on the thin film.

An optimum energy saving is achieved with the device according to the preferred embodiment of the invention in that the thermal energy storage contains a circulating liquid, and comprises one branch of a counterflow fan exchanger, which is arranged to be re-irradiated by the liquid, while the other branch is permeated by the gaseous fluid transfer medium. absorbed energy to the hot end of the energy storage. Exactly that the energy store contains a circulating liquid instead of gas or air, the energy store has an ability to in any case be able to receive and deliver energy from or to the said other branch. The Terznian energy stockpile is advantageously a stockpile, e.g. of the type shown in EPl483538 but can in smaller plants with tin storage e.g. between day and night be arranged above ground in a container with water and pipe loops located in different tin temperature layers in the traditional way.

The invention is further elucidated in the following with reference to the accompanying drawing, which schematically shows an embodiment example of a device according to the invention, and in which figure 1 is a cross section through a thin film and figure 2 is a vertical section through an exterior wall of a building with a window containing a thin film and with a ground energy storage under the building.

The thin film shown in Fig. 1 consists in a known embodiment of at least two polyester sheets 1 and inside these two conductive layers 2 of interior thermoxide and inside a laminate 3 which on one side joins a layer 4 of tungsten oxide, and on the other side a layer 5 of nickel oxide with the laminate 3. The conductive layers 2 have conductors 6 for two electrical connections, which on short-term supply of a voltage causes the thin film to absorb light, ie darken, to a degree depending on the duration of the voltage. The thin film remains in that state until a voltage of opposite polarity is applied, whereby the absorption decreases, ie the thin film lightens.

Fig. 2 shows an outer wall 10 of a building with a window 11 comprising an outer pane 12, an inner pane 13, and between these a transparent, heat-insulating wall 14, e.g. consisting of a gas-filled s.k. insulating glass, 528 110 4 which divides the space between the windows 12,13 in an inner slot 15 and an outer slot 16, which communicates through a passage at the upper edge of the wall 14.

Between the outer pane 12 and the wall 14, a thin film 17 is fixed in the central plane of the gap 16. The gap 15 is through a pipeline 18 and the gap 16 is through a pipeline 19 in communication with one branch of a rotary debris exchange. Air is circulated through the gaps 15 and 16 and the pipelines 18 and 19 by means of a thermostatically controlled fan 21, which supplies the gap 15 with air at a temperature of about 18 ° C, i.e. a few degrees below the desired room temperature, for cooling in summer the air inside the window. The tower film 17 is heated by incident sunlight and then coated with a cooling air stream, which absorbs heat and transfers the heat to the heat exchanger 20. This heat is transferred in a known manner to the second branch of the heat exchanger, which is connected to a pipeline circuit 22,23 in one example below. A ground-based pump 25 drives a liquid up through the line 23, which is provided with a friend-insulated housing 26, through the heat exchanger 20 and down through the line 22, which is in intimate thermal communication with the ground, in which it from the tower fin 17 the friend transferred via the friend changer is stored. The ground energy storage 24, shown in the drawing, in practice constitutes only a small part of a normal internal energy storage, the extent and operation of which in a larger manner for tempering a building are described in more detail in the said EPl483538.

Fig. 2 shows the thin film 17 located in the central plane of the outer gap 16.

Alternatively, it may be located on the inside of the outer pane 12 or on the outwardly facing side of the insulating wall 14. Furthermore, the thin film 17 in Fig. 2 can be supplemented with a smaller part 30 of a thin film of the kind which generates an electrical voltage when it is exposed to sunlight. This energy can be used for various energy-saving purposes, e.g. for driving the fan 21. the invention is of course not limited to the embodiments shown and described here, but can be modified in several ways within the scope of the invention defined by the claims.

Claims (5)

528 ETTÚ PATENTKRAV P265 1. 1. A device for saving energy in the cooling of a building, which is provided with a window (II), which in a space between an inner pane (13) and an outer pane (12) has a thin film (17) of the type which has an adjustable light absorption, which is controlled by means of an electrical voltage connectable to the thin film, in that a preferably completely transparent wall (14) of heat-insulating type is arranged between the thin film (17) and the inner pane (13) of the window and at a distance from the inner pane. Device according to claim 1, characterized in! in that the heat-insulating wall (14) divides the inner space of the windows into an inner gap (15) and an outer gap (16) communicating with it, the means by which a gaseous fluid, such as air, circulates from a cold end of a thermal energy storage (20). , 24) f through the inner gap (15), and the outer gap (16), in which the circulating fluid coats the thin film (17) and thereby absorbs heat from the thin film, when it has been subjected to a higher temperature than the circulating fluid by incident sunlight, and again to a hot end of the energy store (20,24). Device according to claim 1 or 2, in that the thin film (17) is located substantially in the central plane of the outer gap (16) with both sides affected by the circulating fluid. Device according to any one of claims 1 to 3, characterized in that at least a part of the outer gap (16) between said friend-insulating wall and the outer window contains a second thin film (30), which is coated with the circulating fluid, and is of the kind, which is preferably transparent, and which in dependence on incident solar energy generates electrical energy. Device according to one of Claims 2 to 4, characterized in that the thermal energy storage (20, 24) contains a circulating liquid, and comprises one branch of a countercurrent heat exchanger (20), which is arranged to be flowed through by the liquid, while the other branch is permeated by the gaseous fluid to transfer energy absorbed from the thin film (17) to the hot end of the energy storage.