DE2911552A1 - Latent heat storage brick - is hollow and of impermele material and filled with heat storage material - Google Patents

Abstract

The latent heat storage brick is intended for heating and cooling, and consists of an impermeable hollow filled with material storing latent heat. The hollow brick can be of glass, ceramic material or plastics, with two flat parallel outer faces (1) joined by a peripheral concave rounded face (2). It can be selectively coated on one flat outer face with material giving high absorption of short-wave radiation and low emission of long-wave radiation. It may have through channel pipes retaining pipelines with heat medium.

Description

Latent heat storage stone and its

Use The invention relates to latent heat storage stones as well their use for heating and cooling.

Wall and floor heating based on ceramic plates. under or in which lines for hot water or steam are performed are known. Even solar collectors have already been used, consisting of glass insulating cells of the type made of glass bricks, among which 'ie water pipes for the treatment of domestic water run through the sun. In a separate, older proposal, latent heat storage containers described, in which the latent heat storage means receiving chemical container with one through which a heat transfer medium can flow Pressure vessel part connected is.

Latent heat storage systems are used to store heat in conjunction with solar technology, by means of a heat pump or directly converted electrical Energy in the low tariff range (night power) or

other waste heat suitable. The latent heat storage means can store the latently stored energy, i.e. through phase transformation, for any length of time and can be unloaded if necessary. The one saved with a small temperature difference Energy is very large compared to storage without phase change.

The invention is based on the object of a latent heat storage stone to create that delivers high energy usage, accessible without difficulty is easy to use and simple and effective to build Heating or cooling systems is suitable.

The invention relates to a latent heat storage stone through the combination of a regularly formed impermeable hollow brick and a filling made of latent heat storage medium which is introduced into the cavity of the hollow brick.

Particularly preferred is a latent heat storage stone in which the Hollow brick two flat, parallel outer surfaces 1 connected by a circumferential Has concave round profile 2. The hollow brick is expediently made of glass.

The invention also relates to the use of such latent heat storage stones for the construction of latent heat storage for heating and cooling.

The latent heat storage stone according to the invention consists of a regular formed impermeable hollow brick. The hollow brick can be made from any impermeable materials such as glass, ceramic, plastic, e.g.

Acrylic glass, with glass being the preferred material. The term "impermeable" refers to impermeability to gases and liquids, while the material can be translucent. It turns out to be particularly favorable a hollow stone with two parallel, preferably flat outer surfaces, for example are rectangular and are connected by a circumferential concave round profile. Ever after application, the outer surfaces can e.g.

also be arched. A suitable one is placed in the cavity of the building block Latent heat storage means introduced. The filling of the latent heat storage medium can enter the cavity through a closable opening made in the building block take place.

Any commonly used ones can be used as the heat storage means Storage materials are used.

Basically, the storage materials must have a melting point in the have the desired temperature range and have a high storage capacity. Both organic and inorganic latent heat storage agents are suitable.

For example, inorganic salts such as CaCl2 6tf20, hF-4fi20, lia2SO4-10IS20 or Na2EPO4-12EI20 or organic compounds such as paraffins, Polyglycol, stearic acid and the like can be used. Are particularly suitable the inorganic salt hydrates.

The hollow brick filled with the latent heat storage means can to larger units, for example to a wall, can be built up either serves directly as a passive heating system or in combination with a heating surface e.g. heat exchangers through which heat medium flows, a cheap storage heating supplies.

When building the latent heat storage stones into a passive heating system For example, these can be stacked on top of one another with flat surfaces facing outwards to form a wall and the cavities formed by the circumferential concave round profile can may be mortared.

This wall can be arranged inside a house so that it is exposed to solar radiation, so that the latent heat storage means in solar radiation in the building blocks melts and when cooling down, the crystallization of the latent heat storage medium begins with the release of heat that can be used to heat rooms. During the heating phase, however, the room is not heated up as much (cooling effect) like without latent heat storage stones. If there is a risk of frost and the storage substance If you are sensitive or you want better insulation, it is advisable to use it built in this way from the latent heat storage stones as a passive heating system To protect the wall from the outside with a protruding glass wall.

In order to capture as much of the solar radiation as possible, the side of the stones facing the sun can be selectively coated with agents which have a large absorption for the spectral range of short-wave radiation and bring about low emissions for long-wave heat radiation.

The latent heat storage stones according to the invention can also be used in buildings in the double function as a "stone" component and at the same time as a storage heater be applied. For example, a wall in a building can be built from these stones which is followed by a heating surface, which in the building blocks Contained latent heat storage means through night power, collector heat or other Waste heat is melted and the latent heat storage medium gives off heat to the room to be heated when it cools with crystallization.

This end of heating can be compared to the previous night storage heaters A more favorable indoor climate can be created, since the main part of the heat does not come through Convection but is transmitted by radiation.

The latent heat storage stones according to the invention can also be used as desired large latent heat accumulators can be arranged in combination with heat exchangers. The latent heat storage stones are stacked on top of one another. The flat outer surface a flat heat exchanger, for example a conventional panel radiator, closes tightly through which a heat transfer medium, e.g. water, can flow, and this arrangement can be repeated in any size to form a multilayer structure. the The resulting overall arrangement is expediently enclosed by a thermal insulation material. It is beneficial to clear the gaps between the heat exchanger plates and the latent heat storage bricks pour with a medium that conducts heat well. This creates direct contact between heat exchanger plates and building blocks. Preference is given to between the hollow brick layers Launching devices, e.g. in the form of thin launch tubes, inserted. At the beginning of the Crystallization of the latent heat storage medium in all latent heat storage stones cold liquid is introduced through the launch tubes for a short period of time or gas passed through.

The stones are locally strongly cooled, and it occurs spontaneously Crystallization.

When warm heat transfer medium is passed through, e.g. water or another liquid or gaseous heat transfer medium, through the heat exchanger this is transferred to the The latent heat storage medium contained in hollow blocks is melted, the memory is charging. As soon as the temperature of the latent heat storage means during discharging dropped below that of its melting point is, becomes appropriate the crystallization initiated by the fact that through the launch tubes during a cold liquid or gas flows for a short period of time.

The latent heat storage stones are locally strongly cooled and it spontaneous crystallization occurs.

The good heat transfer from and to the heat transfer medium can thereby be increased that the spaces between the heat exchanger plates and hollow blocks with are poured into a medium that conducts heat well.

The heat exchanger plates can be used as a one-circuit system or as a two-circuit system be constructed. A two-circuit system can also be achieved in that the Heating only every second plate is traversed by the heat transfer medium and when unloading the remaining plates, which increases the loading and unloading times somewhat.

According to a further embodiment of the latent heat storage stone according to the invention this has continuous sewer pipes for receiving heat transfer medium flowing through it Lines on.

The latent heat storage stone according to the invention can also be used on the edge or Contain recesses in the surface area that are used to accommodate heat transfer media flowed through lines serve. By stacking latent heat storage stones with corresponding recesses in the edge or surface area are sewer pipes formed, through which you can, for example, elastic hoses to pass through the Heat carrier sets. As a result, the heat is flowed through directly by the heat transfer medium Hose transported in and out of the stone without the need for special heat exchangers.

The invention is described below with reference to the drawings, in which Fig. 1 is a perspective view of a latent heat storage stone according to the invention, FIG. 2 shows a side view of the latent heat storage stone according to FIG. 1, FIG. 3 shows a perspective view of a latent heat storage stone having continuous duct tubes, 4 shows a plan view of a continuous channel tube comprising two of two Halves assembled latent heat storage stone, Fig. 5 is a schematic representation, which the structure of a latent heat storage from latent heat storage stones according to 3 and 4 with hose lines passed through, FIG. 6 shows a section of a Recesses in the surface area having latent heat storage stone, Fig. 7 a latent heat accumulator constructed from the latent heat accumulator stones according to FIG. 6, 8 shows a schematic representation of one of the latent heat storage stones according to the invention constructed passive heating or cooling system, FIG. 9 is a schematic representation one built up from latent heat storage stones including a heating surface Latent heat storage wall for heating rooms and Fig. 10 a schematic representation of a vertical section through one of the latent heat storage stones and heat exchangers constructed latent heat storage.

Fig. 1 shows a latent heat storage stone according to the invention, the made of a hollow glass brick with right-angled flat outer surfaces 1 and circumferential concave round profile 2 is constructed and with any suitable latent heat storage means, for example an inorganic salt hydrate, via an opening (not shown) is filled. Fig. 2 shows a side view of the latent heat storage stone according to Fig. 1.

In Fig. 3, a latent heat storage stone according to the invention is the same Structure as shown in Fig.1, but the continuous sewer tubes 3, through which lines can be passed by the heat transfer medium are flowed through. FIG. 4 shows a plan view of a sewer pipe traversed by it Latent heat storage stone, which is composed of two glass building hollow stone halves. In Fig. 5 is a built up of latent heat storage stones with continuous duct tubes Latent heat storage with hose lines 5 laid through the sewer pipes for flowing through heat transfer medium visible.

In Fig. 6 a latent heat storage stone according to the invention is shown, the recesses 4 in the surface areas to accommodate lines for the Has heat carrier.

Fig. 7 shows the structure of a latent heat store from the in Fig. 6 explained latent heat storage stones, whereby through the assembly corresponding groove-shaped recesses 4 in the surface areas of the latent heat storage stones Form tubular passages into which hose lines 5 are inserted through the the Heat transfer medium can be flowed through. The build will held together by a bracket 6.

8 shows the use of latent heat storage stones according to the invention for direct heating or cooling of rooms. A wall 7 made of latent heat storage stones is exposed to solar radiation behind a glass wall 8. By exposure to the sun the substance in the stones melts and after cooling down, crystallization begins. The room is heated by radiation and convection. If necessary, this is the Sun-facing side of the stones, as with good solar collectors, selectively coated, the absorption for the spectral range of short-wave radiation with low emission for the area of thermal radiation to enlarge.

9 shows a further application of the latent heat storage stones according to the invention, a partition wall made up of two walls 7 of latent heat storage stones with between them arranged heating surface 9 is established. The heating surface is, for example using night power, collector heat or other waste heat, the latent heat storage means melted in the building blocks and is used for room heating during crystallization usable heat, Fig. 10 shows a further application of the latent heat storage stones according to the invention a latent heat storage system of the following structure. Alternating is a wall 7 made of latent heat storage stones and a heat transfer medium 10 designed as a flat radiator is arranged adjacent to it. This multilayer structure of a latent heat accumulator is made of a thermal insulation material il enclosed. Gaps between heat exchanger plates and latent heat storage stones can be filled with a medium that conducts heat well to ensure direct contact between heat exchanger plates and building blocks and thus good heat transfer to ensure.

Claims (10)

Claims 1 1. Latent heat storage stone, g e k e n n z e i c h n e t d u r c h the combination of a regularly trained impermeable 3auhohlsteins and a filling introduced into the cavity of the vauhohlsteins from latent heat storage means. 2. Latent heat storage stone according to claim 1, d a d u r c h g e k It is noted that the hollow stone is made of glass, ceramic or plastic. 3. Latent heat storage stone according to claim 1 or 2, d a -d u r c it is noted that the hollow stone has two flat, parallel outer surfaces (1) connected by a circumferential concave round profile (2). 4. Latent heat storage stone according to claim 1 to 3, d a -d u r c h it is not indicated that it should be achieved on a smooth outer surface high absorption for short-wave radiation and low emission of long-wave thermal radiation is selectively coated. 5. Latent heat storage stone according to claim 1 to 4, d a -d u r c h it is not indicated that it has continuous sewer tubes (3) for receiving having lines through which heat transfer medium flows. 6. Latent heat storage stone according to claim 5, d a d u r c h g e k It is noted that in the surface area of the Hollow brick Recesses (4) are made to accommodate lines through which the heat transfer medium flows are. 7. Use of latent heat storage stones according to claims 1 to 6 for the construction of latent heat storage for heating and cooling. 8. Use according to claim 7, d a d u r ch g e -k e n n z e i c h n e t, that the latent heat storage stones are constructed as a wall (7) that absorbs solar radiation is exposed. 9. Use of latent heat storage stones according to claim 7, d a D u r c h e k e n n n n e i c h n e t that the latent heat storage stones become one Wall (7) are built up, which is closely followed by a heating surface (9) and if necessary this structure is repeated. 10. Use of latent heat storage stones according to claim 1 to 4, that the latent heat storage stones are closed larger latent heat storage units are stacked to which closely adjoining a flat heat exchanger (10) through which the heat transfer medium flows, this arrangement is possibly repeated and the overall arrangement of one Thermal insulation material (11) is surrounded.