WO1987000569A1 - Energy-storing facade covering for controlling heat flow - Google Patents

Abstract

The facade covering is made from elements comprising an energy-accumulator (1) and insulation (2). The accumulator contains material with a large energy-storage capacity, which can accumulate energy by phase changes (solid-liquid or liquid-gas) or by changes in the property of the material (hard-soft). For charging the accumulator with solar radiation energy the accumulator and insulation adopt a mutual position which exposes the accumulator to the sun and thermally dissociates it from the interior of the building (3). For discharging, the insulation is arranged between the accumulator and surrrounding area (4), and the accumulator is then thermally linked with the building. The mutual movement of the acccumulation and insulation can be effected by a rotary movement. In each position, the insulation protects the building from heat losses or from unwanted solar radiation also. The effect can be enhanced by applying a reflective coating to the insulating surfaces (5, 6) as well as by providing the insulating surface facing the accumulator with a parabolic cross-section.

Description

description

Energy-storing facade cladding that controls heat flow

The invention relates to a facade cladding constructed from elements for retrofitting existing or installing in new buildings mainly in the non-residential sector. The purpose of the facade elements is, firstly, to adapt the heat flows through the facade to the needs of the building users, i.e. To use solar radiation for heating purposes, or to keep it away if it is undesirable. Secondly, the building is to be insulated against heat loss and thirdly, a storage facility is to be made available for the energy generated.

Facade claddings that adapt their heat transfer properties to the needs of building users are known, for example with the aid of foils, as set out in Swiss Patent 610 037. It is also known to use the building wall as an energy store, e.g. the Trombe wall, the Trombe wall may also contain a storage medium based on phase change, such as set out in Telkes M., DOE / ISES-AS 2nd Natl. Passive solar conf. 1978, vol. 2, p. 283.

However, the Trobe wall is a cumbersome component and has too little storage capacity even when using latent storage media. The task was to develop an industrially producible, flexible component which realizes the functions of passive energy generation, storage, insulation and sun protection in one and is easy to assemble and operate.

This object was achieved by integrating the storage medium in the form of a fixed or movable element in the facade cladding and with a movable insulation Combined layer that thermally shields the storage medium from the outside or from the inside as required. These elements can be manufactured in standard sizes or manufactured for individual dimensions. They can be attached to the outer wall, particularly in the case of existing buildings, or, in the case of new buildings, can be integrated directly into the wall. On the outside, they are preferably covered with single or double glazing, which on the one hand leads to the greenhouse effect and thus increases the passive energy yield, but on the other hand also offers protection from the weather.

According to claim 1, the insulation can shield the store from the inside of the building when the store is discharged and is to be charged by incoming solar radiation. The insulation is also in this position if the building is to be protected against undesired heating on hot days. If the memory is loaded, however, the insulation elements slide between it and the outside. This protects him from losing energy to the outside world and can instead release it to the interior of the building.

Claims 4 to 6 define possible storage media: conventional latent storage salts with solid-liquid conversion, media with evaporation in the temperature ranges of interest (for example refrigerants or plastics which soften with considerable energy absorption and which form the component directly, ie without wrapping) can.

A reflective coating on one or both sides of the insulation layer (claims 2 and 3) increases the effectiveness by also preventing energy influences that take place via radiation.

A preferred embodiment according to claim 7 consists in the formation of the isolation elements as semi-cylindrical Shells that can rotate around fixed, rod-shaped storage elements. If the inner surfaces, as claim 8 teaches, have a parabolic cross section with the storage rods in the focal point, the energy yield is particularly high because of the radiation beam.

The roundness of the insulation shells mentioned is also used according to claim 9 in order to transmit the drive moments for the displacement by means of a toothing.

Another embodiment describes claim 10: memory and insulation form a common element which, by tilting about an axis of rotation, enables the two positions prescribed by claim 1.

It shows:

Fig. 1 shows the cross section through two facade elements with fixed storage rods and semi-cylindrical, around the storage rods rotatable insulation shells.

2 shows the cross section through a facade element, the insulation shell of which has an inner surface which is parabolic in cross section. The memory stick is in the parabolic focus. The outer surface of the insulation shell is provided with teeth.

Fig. 3 shows the cross section through a tiltable combined storage-insulation element designed as a plate.

Identical functional components are provided with the same reference numbers in the three figures. 1 shows the embodiment with fixed storage rods 1 and insulation shells 2 which can be rotated about axis 8, in cross section, the facade elements in this case being attached to the outer wall 10 of a building behind glazing 11. The lateral attachment of the storage rods or storage of the insulation shells, not shown, is carried out in a conventional manner. The rotary movement can also be transmitted in a conventional manner, for example by means of chains, toothed racks, or else with a toothing 9 of the shell outer surface 6 shown in FIG. 2, which can also be limited to the two end faces. 2 also shows the design of the inner shell surfaces 5 as reflecting parabolic bodies with the storage rods at the focal point, the parabolic mirroring both bundling the radiation arriving from the sun and guiding the radiation emitted by the storage to the building , depending on the position of the insulation shells.

FIG. 3 shows another embodiment in which the storage and insulation together form a lamella-like component which can be tilted about the axis 8.

Claims

Claims 1. Energy-storing facade cladding that controls the heat flow, consisting of storage elements (i) that store energy in the form of enthalpy, and insulation elements (2) that know the energy flow that is possible in the form of convection or radiation heat , characterized in that the mutual position of the storage and insulation elements with respect to the inside of the building (3) and the outside of the building (4) can be changed such that the insulation either inhibits the flow of energy between storage and inside of the building, that between storage and the outside, on the other hand, is not hindered, or in contrast to that the insulation inhibits the energy flow between the storage and the outside, but not that between the storage and the inside. 2. facade cladding according to claim 1, characterized gekennzeich¬ net that the memory facing surface (5) of the insulation elements is coated reflective. 3. facade cladding according to claim 1, characterized gekennzeich¬ net that the surface facing away from the memory (6) of the insulation elements is coated reflective. 4. Facade elements according to claim 1, characterized in that the storage elements contain a storage medium which stores energy by passing from the solid to the liquid phase. 5. facade elements according to claim 1, characterized in that the storage elements contain a storage medium which stores energy by passing from the liquid to the gaseous phase. 6. Facade elements according to claim 1, characterized in that the storage elements consist of a storage medium which stores energy by changing its material properties in a manner which is characterized by a change in the strength properties. 7. facade cladding according to claim 1, characterized gekennzeich¬ net that the storage elements are stationary and rod-shaped and the insulation elements are designed as semi-cylindrical shells, the cylinders (7) intended by continuation of the shells enclosing the storage elements and the shells around the axis of rotation (8) the imaginary cylinder can be rotated. 8 .. facade cladding according to claims 2 and 7, characterized ge indicates that the inner surfaces of the shells have a parabolic cross-section "and the storage elements are arranged in the parabolic focus. 9. facade cladding according to claim 7, characterized gekennzeich¬ net that the shells are provided on the outer surface with a toothing (9) which enables transmission of the rotary movement. 10. facade cladding according to claim 1, characterized gekennzeich¬ net that memory and insulation form a common element which is rotatable about an axis. 11. facade cladding according to claim, characterized gekennzeich¬ net that the facade cladding is a facade element and is also translucent.