DE10043533A1 - Heat store for solar energy has wall round inner container enclosing cavity filled with latent heat storage material - Google Patents

Abstract

The heat store has thermal insulation, at least one access in the upper (a) and lower (b) regions for input and output of the heat carrier and possibly with a heat exchanger and layer systems for the heat carrier. The wall (h) round the inner container (g) and spaced out from it encloses a cavity which is filled with latent heat storage material (c),

Description

The invention relates to a heat store according to the preamble of patent claim 1.

The increasing use of solar energy for building air conditioning is essential for the need large heat capacities. The heat or cold is usually stored in a sensitive manner. Larger heat capacities can only be achieved through the use of latent heat storage materials Achieve utilization of the enthalpy of fusion. So far, however, there is a general spread of this technology the lack of functionality and the high costs.

State of the art

In the developed by the company ST Speicher-Technologie, Gewerbeparkring 17, 15517 Fürstenwalde Latent heat storage devices are in direct contact with the storage material and heat transfer medium. So that Heat transfer medium, both in the solidified and in the liquid state, add heat to the storage material. or can lead away, a complex construction inside the container is required.

From DE 27 41 829 a solution is known in which the latent heat storage is implemented as a separate unit. The latent storage material floats in the form of plastic-coated paraffin particles in one separate heat storage filled with heat transfer fluid. The energy is applied via a heat exchanger transfer the medium to be tempered. This requires pumps and additional energy.

DE 198 15 521 shows a pressureless container which is filled with a storage liquid as a heat carrier. By installing latent storage elements in Zone B, an increase in Heat storage capacity achieved. However, in Zone B there is only slow heat transfer to or possible from the latent storage elements into the storage liquid. The design effort of the container is big.

From DE 198 13 562 a latent heat store is known in which a plurality of latent heat bodies are arranged vertically hanging. Air or water can flow through the latent heat store. As a result, heat is stored in the latent heat body or, as a result, when it flows through Relatively colder heat transfer medium released again. In practice, this is where the Solve latent heat body. Furthermore, the construction with increasing number of Latent heat body complex and costly.

DE 198 07 657 shows a latent heat storage combined with a water storage. By a defined Arrangement of the heat exchangers and a low-temperature latent heat storage in the lower storage area should as deep as possible cooling of the solar return or preheating the Fresh water can be reached. In addition, a high temperature  Latent heat storage provided. If hot water is drawn through the hot water pipe, it cools down Existing water in the reservoir from such that the stratification in the container due to turbulent flows gets destroyed. In areas of calcareous water, there is a slight risk of this heat exchanger Calcification due to calcification. It is not possible to replace the heat exchanger without the tank cut open. The arrangement of water and latent heat storage and the piping, leave none rational large-scale production, which ultimately has a cost disadvantage.

The object of the present invention is to provide a heat store which, on the one hand, is used in heating provides very responsive warm water in the upper area of the storage tank and on the other hand has a high heat capacity.

The invention is described in claim 1. The dependent claims contain advantageous ones Refinements and developments of the invention.

The invention provides the advantages of heat storage in water and latent heat storage materials to integrate in one system. The invention enables rapid heating of water in one Storage to a certain usable target temperature, for example 60 ° C. Is more energy for storage available, for example due to solar radiation by means of solar collectors, the storage temperature should do not increase due to the energy storage in the container. Can the temperature in the store despite Energy supply can be kept at the target temperature, the energy losses resulting from increased Storage temperature would set, saved. According to the invention, there is a memory area for this for latent heat storage materials arranged around the actual water storage.

Further important features and advantageous effects result from the following description of Embodiments that are shown in the accompanying drawings. On these embodiments the invention is in no way limited, because they serve only for better understanding and as an aid to Interpretation.

According to FIG. 1 and FIG. 3 (horizontal section through the container) it is provided according to the invention to fill a container (g) under pressure or without pressure with heat transfer medium (d), for example water. The container (g) is advantageously slim and tall in its geometry and has at least one upper (a) and at least one lower (b) access. Furthermore, heat exchanger systems and single-layer devices can also be integrated in the lower and upper storage area. The room filled with water is surrounded by a second jacket (h). The volume thus resulting between the container wall (g) and the jacket wall (h) is filled according to the invention with latent heat storage material (c). The entire system is surrounded by thermal insulation. The storage volume with the latent heat storage material (c) can be open at the top, or can be closed off with a lid to the surroundings. The memory can have a cylindrical shape or an arbitrary basic geometry, for example a square shape. Furthermore, the storage space for the latent heat storage material (c) can be so pronounced that the latent heat storage material (c) also encloses the surfaces (f) and (e).

As section Fig. 4 shows a memory structure with improved dynamic properties. Surface-enlarging measures (c1) have been taken on the inner container (g). Here, good heat-conducting elements carry the heat both out and into the latent heat storage material. These can be metal lamellae, for example, which are connected to the container (g) with good thermal conductivity.

To increase the dynamic properties of the latent heat storage material, for example, that is also Steel scrap from metal cutting, for example, can be added.

Fig. 5 and the horizontal section through the exemplary cylindrical container Fig. 6 show another way to increase the heat storage capacity. One or more bodies that can be filled with latent heat storage material are provided in the interior of the store. The walls of these bodies are made of good heat-conducting material. The bodies can be filled from the outside, or already filled into the heat store.

Vertical temperature zoning can be achieved with subdivisions of the area in which the latent heat storage material (c) is introduced, as shown in FIG. 2. In this case, several separate areas are to be provided structurally, for example (c2) (c3) (c4), into which latent heat storage material with different melting points can be introduced. This enables thermal stratification supported by the latent heat storage material with a temperature that increases from bottom to top.

The strength of the resulting from the difference in radii between the inner container (g) and the surrounding jacket (h) Annular gap, which is filled with heat latent storage material over the height, can be arbitrary or dependent on the required heat storage capacity can be designed. This also applies analogously to other geometrical ones Tank basic shapes.

The container dimensions are arbitrary, ideally slim and tall, for example at least twice as much high as the width of the heat accumulator or at least twice as high as the diameter of one cylindrical heat storage. The water volume is, for example, more than 150 liters.

The advantages according to the invention are as follows: The latent heat storage material (c) is safe separated from the heat transfer medium (d). This means that the latent Heat transfer material (c) in downstream circles with heat sinks with a system-damaging effect occur. For heat exchange between heat transfer medium (d) and latent heat storage material (c) no additional units are required. This is done purely physically.

The system according to the invention enables rapid heating of the heat transfer medium (d) sensitive heat up to a defined target temperature, which corresponds to the melting point of the latent Heat storage material corresponds. Because the target temperature is now above a certain level despite the energy supply Range can be kept almost constant, are the energy losses compared to energy storage only significantly less in sensitive heat.

In terms of manufacturing technology, rational series production is possible according to the invention.

Claims (13)

1. Heat storage, in particular water and latent heat storage, with thermal insulation, with at least one access in the upper (a) and lower (b) area for the inlet and outlet of a heat transfer medium and optionally with heat exchangers and single-layer systems for the heat transfer medium (d) , characterized in that the wall (h) surrounding the inner container (g) at a distance encloses a space which is filled with latent heat storage material (c). 2. Heat accumulator according to claim 1 or in particular according thereto, characterized in that the Inner container (g) is designed as a pressure container. 3. Heat storage device according to one or more of the preceding claims or in particular according thereto, characterized in that between the inner container (g) and the surrounding wall (h) enclosed space is open at the top. 4. Heat storage device according to one or more of the preceding claims or in particular according thereto, characterized in that the inner container (g) is well heat-conducting and Has surface-enlarging structures. 5. Heat accumulator according to claim 4, characterized in that on the outside of the inner container (g) Steel fins are attached to conduct heat well. 6. Heat accumulator according to one or more of the preceding claims or in particular according thereto, characterized in that the latent heat storage material has good heat-conducting waste materials, for example from metal-cutting manufacturing processes. 7. Heat accumulator according to one or more of the preceding claims or in particular according thereto, characterized in that between the inner container (g) and the surrounding wall (h) enclosed space is divided vertically into several zones (c4) (c3) (c2) and with latent Heat storage material is filled with different melting points. 8. Heat storage device according to one or more of the preceding claims or in particular according thereto, characterized in that the memory is cylindrical or any basic geometry having. 9. Heat accumulator according to one or more of the preceding claims or in particular according to it, characterized in that the latent heat storage material completely encloses the inner container.   10. Heat storage device according to one or more of the preceding claims or in particular according thereto, characterized in that the heat accumulator as a whole is surrounded by thermal insulation. 11. Heat store according to one or more of the preceding claims or in particular according thereto, characterized in that the latent heat storage material (c) surrounding the inner container (g) can have any volume. 12. Heat storage device according to one or more of the preceding claims or in particular according thereto, characterized in that the water volume has at least 150 l. 13. Heat storage device according to one or more of the preceding claims or in particular according thereto, characterized in that one or more, with latent Heat storage material fillable body (c5), which consist of good heat-conducting material and of infested outside, or can already be infested in the heat storage, are.