DE2837091A1 - Thermal energy storage system - using heat pipes to transfer heat into and out of storage medium to improve efficiency - Google Patents

Abstract

Heat (or latent heat) storage system uses heat storage medium or media. It consists of a single vessel, or several vessels mounted side by side or in circular arrangement. Connection between the phase donating heat and the medium eventually heated together with the storage medium is by means of heat pipes. The three media can be separated by horizontal or vertical walls. Similarly the heat pipes can be horizontal, vertical or at an angle. Used esp. in solar heating systems. By giving faster heat transfer, a better thermal efficiency is achieved.

Description

Storage for storing heat and / or latent heat

In heating technology, especially in solar heating technology, it is often required heat and / or latent heat for shorter or longer periods of time save.

This purpose is used, among other things, memories that have a thermal storage medium or Heat storage media contain lind from a single container or from several containers exist, which are arranged next to one another, one above the other and / or in a ring to one another are.

In such hitherto known containers for storing heat Liquid and solid storage media are used, including those used for deeper Discharge temperatures are solid and only become liquid at higher charging temperatures. This is the known latent storage.

Difficulties arise from the fact that when charging heat accumulators because of the only possible heat exchanger surfaces for up to a limited size the heat transfer from the charging medium to the storage medium takes a considerable amount of time is required. In the case of a circuit-led charging meaium, such as e.g. in solar heating systems is the case, it can therefore happen that only part of the heat supplied transfers to the storage medium, while the remaining part remains in the loading medium. The same also applies to the discharging process of the memory when the heat is by means of a second heat exchanger transferred from the storage medium to a discharge medium must become.

The heat transfer from the charging medium to the storage medium is particularly difficult in the case of latent heat storage devices, if the storage medium is has passed into the solid state of aggregation.

The same applies to latent heat storage systems with direct contact of the loading medium with the storage medium.

In the containers of heat accumulators, one is therefore as quick as possible Heat transport and the best possible and therefore rapid heat transfer required, to achieve a high level of efficiency.

With the subject matter of the present application, the until now any difficulties that arise are eliminated.

This is done by the fact that the ',) eleller is a Wiirmotube or has several heat pipes that are known per se.

The heat pipes are arranged in the memory that the loading medium supplied heat is transferred to the storage medium in a very short time, whereby it It is irrelevant whether the storage medium is liquid or solid. Even with the aforementioned Latent heat storage with direct contact with the charging medium and the storage medium the use of heat pipes results in a considerably faster and better distribution the LRdewärme in the entire solid block of the storage medium created during the discharge, so that an accelerated dissolution into the liquid state is achieved This can increase the heat transfer surface area of the heat pipes be provided with longitudinal or transverse ribs in a manner known per se.

It is particularly useful if those equipped with heat pipes Heat storage built up from individual container rings of the same type or of the same height are.

This firstly achieves - that all requests for certain memory sizes can be easily met that, secondly, the transport and the introduction of the Storage in existing buildings is very simple that, thirdly, the container height without further can be adapted to the very different clear room heights, and Fourthly, in the event of heat pipe failure, individual heat pipes can be replaced quickly or a container ring is possible.

Also the optimal adaptation of the size of the surfaces of the heat exchangers in the memory of the respective surface of the collectors is in this design easy to reach. To achieve a high degree of efficiency, this adaptation is at Solar systems are crucial.

In Fig. 1, the first embodiment is a pressureless, so open memory from a single container shown schematically, which with a storage medium is filled and both a charging and a discharging heat exchanger having, the charge heat exchanger in the container below and the discharge heat exchanger is arranged above.

Immediately distribute vertical heat pipes with the liquefaction side up the supplied heat, they lead to the discharge heat exchanger and ensure that In the vicinity of the charge heat exchanger below, there are no warnings, but rather the lowest possible temperature level is constantly achieved.

In Fig. 2, as a second embodiment, a pressureless, so open memory from a single container shown schematically with a storage medium is filled and both a charging and a discharging heat exchanger having, wherein the charge heat exchanger arranged vertically in the center of the memory and surrounded by the discharge heat exchanger is horizontal (Fig. 2 left) or inclined with the release side, i.e. the side emitting the heat upwards Fig 2 right) arranged heat pipes form radial rays in several planes. she not only distribute the heat supplied by the heat exchanger of the charging medium in the shortest possible time Time in the entire contents of the memory, but also lead them immediately to the heat exchanger of the unloading medium.

In Fig. 3 is a third embodiment, a pressure accumulator shown schematically from three containers. The cylindrical inner container becomes encircled by the other two containers in a ring shape. The middle container will the charging medium, e.g. a liquid heated by solar collectors, is supplied. The domestic water to be heated flows through the inner container. In the outer container the heating water to be heated from a central heating system flows.

Heat pipes arranged horizontally form radial ones in several planes Jets0 The condensing sides of the inner heat pipes are in the cylindrical inner container. The liquefaction sides of the outer heat pipes are in in the outer liing container. The heat pipes thus distribute the from the charging medium heat supplied to the inner and outer containers in a very short time Container, and the loading medium contains when leaving the middle container at all no or only a very small excess of heat, in Fig. 4 is the fourth Exemplary embodiment composed of individual container rings of the same type Individual tank - memory shown schematically. On a foot disk that has the Forms container bottom and has tie rod connections, sit in sealing channels the individual container rings of the same type and a cover disk, which also have tie rod connections shows. In the case of pressureless, i.e. open containers, a cover plate is sufficient instead of a cover plate an upper end ring with tie rod connections.

The heat pipes are arranged in this container as in the one in the embodiment shown in Fig. 2, that is, radial rays in several planes forming.

In Fig. 5 is a fifth embodiment of a single similar container rings composed memory with three ring-shaped to each other arranged containers shown schematically. On a foot disk, which is the lower one floor which forms three containers and has tie rod connections, sit in sealing gutters the container rings made up of three concentric cylinders through perpendicular radial Ribs are connected to each other. A cover plate with tie rod connections seals and locks the three containers at the top.

Horizontal and radial heating rolls are in every switch ring contain, namely they form an inner and an outer heat pipe ring. All Heat pipes with their heat-absorbing ends, the evaporation sides, are in the middle arranged annular container. The heat pipes of the inner ring are sufficient their liquefaction sides into the inner cylindrical container and the Heat pipes of the outer ring reach with their liquefaction sides in the outer one Ring container into it. The heat supplied to the middle container by the loading medium is immediately distributed to the other two containers by means of the heat pipes, so that the loading medium completely uses its excess heat when it leaves the central container or almost completely released into the media in the other two containers.

In Fig. 6 is a sixth embodiment of a single Storage tanks of the same height are composed of three storage tanks arranged one above the other Containers shown schematically. On a foot disk, which is also the lower one Forms container bottom of the lower container and has tie rod connections, sit the individual container rings and a cover plate with tie rod connections in sealing channels. Two container rings are provided with a bottom. These floors form the partition walls the container. However, the partitions can also be designed as parts between two container rings be clamped.

The size of the three containers in this store can be in any plant easily adapted in an optimal manner. For this it is only necessary for everyone Container to take the appropriate number of container rings.

Vertically arranged heat pipes are with their heat-emitting ends, the liquefaction sides, facing upwards, inserted in the partition walls. The heat pipes in the lower intermediate container wall immediately conduct the heat from the lower one Load medium container in the middle process water container. The heat pipes in the The upper intermediate tank wall conducts the heat into the upper heating water tank. The The size and number of heat pipes in the two partition walls were chosen.

Literature considered 1. German magazine "Umschau" 1967, issue 19 p. 634: "The heat pipe - a simple construction element for heat transfer", Dr.-Ing.

R. Pruschek.

2. USA magazine "maschine Design" March 11, 1976 p. 52 - 56: "The Heat Pipe: Hot New Way to Save Energy, "Robert B. Aronson.

3rd conference report basics of solar technology "of the German society for solar energy from October 22, 1976 pp. 205-235: "Physical, chemical and technological basics of latent heat storage ", Dipl. -Phys.

Friedrich Lindner.

4. Conference report "Teigen mit Sonne-3.Speicherung" of the German Society for solar energy from 8/9. November 1977 5. 199 - 208: "A new development for Realization of compact latent heat storage ", Dipl.-Phys. Friedrich Lindner.

5th conference report "2nd International Sun Forum" of the German Society for solar energy from July 12-14, 1978 pp. 137-148: "The influence of storage heat exchangers and flow rate on the collector efficiency of solar thermal systems ", P.A. Schoeck ; P. 149 - 159: "Direct - Contact - Heat Exchanger - Storage", Walter Loss.

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Claims (7)

Claims memory for storing heat and / or latent heat, which contains a heat storage medium or media and consists of a single container or consists of several containers side by side, one above the other and / or ring-shaped are arranged to one another, characterized. that the memory is a heat pipe or has multiple heat pipes. 2. Heat accumulator according to claim 1, characterized in that in one Single tank, the heat pipes are arranged vertically with the condensing side up are. 3. Heat accumulator according to claim 1, characterized in that in one Single tank the heat pipes horizontally or inclined with the condensing side are arranged upwards and form radial rays in several planes. 4. Heat accumulator according to claim 1, characterized in that. that in three annularly nested containers, the heat pipes horizontally or inclined are arranged with the liquefaction side up, in several radial planes Form jets and with the liquefaction side in the inner and in the outer Reach in the container. 5. Heat accumulator according to claim 1, characterized in that individual containers are composed of individual container rings of the same type with horizontal or inclined with the liquefaction side up and radial rays forming heat pipes are equipped, and that the container rings by tie rods be clamped together. 6. Heat accumulator according to claim 1, characterized in that three Containers arranged in a ring to one another from individual container rings of the same type are composed, the with horizontal or inclined with the condensing side are equipped with heat pipes pointing upwards and forming radial rays, which extend with the liquefaction side into the inner and outer container, and that the container rings are clamped together by tie rods. 7. Heat accumulator according to claim 1, characterized in that three Containers arranged one above the other made up of individual container rings of the same height and are composed of intermediate floors, which are perpendicular to the liquefaction side upwardly directed heat pipes are equipped with the condensing side reach into the middle and the upper container, and that the container rings and intermediate dead ends are clamped together by tie rods.