DE4108370A1 - System for storing latent heat - is container with thermally conducting base and top and divided vertically into stages containing plastic tube filled with eutectic mixt. - Google Patents

Abstract

A semi-dynamic latent heat store consists of a closed container with thermally conducting base and top contg. the heat-storing material and a heat-transporting liq. The latent heat storing material is in the heat store in parts of the container with flexible sides; bores for flow of heat-transfer liq. are between the heat transfer materials on the base and sides. The flexible sides are pref. made of polyetheylene, polypropylene or PVC. ADVANTAGE - Heat is transferred by boiling and condensing processes. Any known type of heat storage material can be used in principle. Halogen-hydrocarbons are not used for heat transfer.

Description

The invention relates to a quasi-dynamic latent heat memory for heat or cold storage under Use of the heat of fusion of selected substances is provided. It serves to bridge time differences between Heat generation and heat demand and to balance performance differences between heating systems and cooling systems. Preferential it is wise for the use of seizure and environmental heat for use in industry and household, e.g. B. Warm was preparation, heating, air conditioning etc. suitable.

For the storage of heat, substances such as Water or oil used because of their large speci thermal capacity technically relevant storage capacities surrender. Disadvantageous for memory based on tactile Warmth is that always larger temperature differences required are, which results in significant exergetic losses ren. To overcome these disadvantages, great efforts are being made Storage densities in the narrowest possible temperature ranges achieve. It is known that latent heat for this transitions from melting / solidification and lattice transformations of Salt hydrates, anhydrous salts and organic compounds can be exploited. In principle, these are Connections in static and dynamic latent heat storage applicable.

In static latent heat storage, the heat-storing connection is placed in containers with a large surface area in order to achieve high heat transfer rates. The most known are the memory sticks or memory balls [H. Hedmann, Energy Technology 1 (1986), 10] in which the latent heat storage material is located in airtight sealed polypropylene containers and the heat is transferred by air or oil via the container walls. Disadvantage of the static latent heat storage is that the heat transfer Stung during the entry or exit process due to the poor thermal conductivity of the latent heat storage materials drops very much and the change in phase caused by the phase change in the design of the container, z. B. by incomplete filling of this, must be taken into account. The permeation of volatile constituents, e.g. B. from water of the latent heat storage material or the heat transfer medium through the container walls, which lead to changes in the temperature of the latent point and loss of storage capacity. To overcome these disadvantages, various dynamic latent heat stores have been developed. According to US 41 54 292, the latent heat storage material is moved by rotating the storage container and the heat transfer is carried out over the container wall. Another solution is direct contact heat transfer, in which the latent heat storage material is in direct contact with the heat-transporting medium. According to F. Lindner and K. Scheunemann, research report DFVLR-FB 81-32, Stuttgart / FRG and AE Founda, GJG Despault, JP Tayler and CE Capes, Solar Energy 25 (1980) 437, heat transfer oils are passed through the latent heat storage material. Disadvantages here are the technical complexity, ensuring the operational safety of the internal oil circuit and the loss of energy due to the need for additional heat exchangers. The direct contact heat transfer to latent heat storage material by means of a low-boiling liquid and heat exchangers integrated in the storage tank is known according to WO 81/00 574 and DD-WP 2 25 857. This variant enables the simultaneous heat input and heat dissipation at high heat transfer capacities, but leads to a strong narrowing of the use of known latent heat storage materials, since a chemically stable, optimally crystallizing latent heat storage mixture must be present. The heat transfer liquid must not solve the latent heat storage material or only to a very limited extent and the density of the heat transport liquid must be greater than that of the latent heat storage material in the operating state of the store. Taking the necessary depot into account, only halogenated hydrocarbons, in particular freons, can therefore generally be used as heat transfer liquids. In the event of an accident, however, escaping halogenated hydrocarbons can lead to a considerable environmental impact.

The simultaneous heat input and heat output is in the Storage according to DD 1 47 405 and DD 2 07 758 realized by that the heat accumulator from two separate heat pressure transducers containing me exists, some of them are filled with a liquid heat transfer medium and the partition between the pressure chambers latent storage material rial contains. However, the disadvantage of these memories is that low heat transfer performance.

The invention is based on the technical object Develop latent heat storage in which the heat transfer takes place via boiling and condensation processes, in which all known latent heat storage materials in principle can be used and on the use of halogen carbons Hydrogen can be dispensed with as a heat transport medium can.

The technical problem is solved by a quasidynami latent heat storage, consisting of a closed Container, the bottom and top side with heat exchangers is provided, the latent heat storage material and one Contains heat transfer liquid, the latent heat mespeichermaterial in heat storage according to the invention in Be container parts with flexible walls and the store space is filled with these container parts so that between between the floor and ceiling heat transfers flow channels like to remain. The container parts with flexible walls are thin-walled plastic containers such as thin-walled capsules, thin-walled bags and in particular thin-walled plastic hose. Depending on the work  temperature of the storage are thermopla as materials plastic materials, such as polyethylene, polypropylene or Suitable for polyvinyl chloride. With large-volume storage it is expedient if between floor-side and ceiling-side according to the heat exchanger, storey-shaped internals are necessary to operate the memory Flow channels remain and the container parts with flexible walls not because of a too high packing height be heavily burdened that they will be destroyed.

To avoid high pressure loads on the heat accumulator should be the boiling point of the heat transfer rivers used liquid near the melting point or phase change point of the latent heat storage material used lie.

When heat is introduced through the bottom heat exchanger evaporates the heat transfer fluid and gives its ver heat of vaporization via the flexible walls of the container parts the latent heat storage material therein, where through this melts. Conversely, when it comes to heat dissipation the heat exchanger in the steam room port liquid condensed. The dripping condensate ver steams on contact with those with latent heat storage material filled container parts again, as long as a temperature diff reference between heat transfer entrance and latent heat storage material exists. Under the conditions of the boil and condensation heat transfer occur in the heat storage Changes in pressure caused by the vapor pressure temperature Relationship of the heat transfer fluid. In the state of charge the pressure in the accumulator is higher than in the discharged one Condition before. The low pressure with latent heat Container material filled with flexible walls are increasingly merged with increasing state of charge expresses what an optimal thermal contact between the container wall and latent heat storage material results. So who the losses of the heat transfer performance of the latent heat memory due to the reduction in thermal conductivity  of the latent heat storage material in the molten against diminished above the solid state. In the course of ark and discharge cycles take place depending on the thickness of the flexible len walls of the container parts an the setting of Melting and solidification equilibrium favoring Bewe the latent heat storage material. The arrangement of the Latent heat storage material in the heat storage in one or the offers several container parts with flexible walls Possibility of easy exchange and installation several melting at different temperatures Latent heat storage materials. When using multiple at different temperatures melting latent heat large storage densities result in wide storage densities Temperature ranges. The problem of initiating the Crystallization is, as is common practice, by users formation of nucleating agents or by stocking kri stallisat solved.

Changes in concentration of the latent heat storage material, e.g. B. the water content of salt hydrates due to permeation 3 through the flexible container part walls, can be concluded from that a similar activity of the diffusing component through the flexible material in the heat transport liquid is set. For example, when using salt hydrates as latent heat storage material, water can be added to the heat transfer liquid.

The advantage of the quasi-dynamic latent according to the invention heat storage is that the heat transfer over Boiling and condensation processes take place, all known Latent heat storage materials can be used in principle and on the use of halocarbons as Heat transfer medium can be dispensed with.

The invention is illustrated by the following two examples are explained:  

example 1

Fig. 1 shows a quasi-dynamic latent heat storage, consisting of a closed container 1 , the bottom side with the heat exchanger 2 for heat input and cover is provided on the side with the heat exchanger 3 for heat discharge. The container volume is divided into floors 4-8 by multi-storey buildings. As a latent heat storage material, the eutectic melting mixture of 58.7% Mg (NO ₃ ) ₂ .6H ₂ O and 41.3% MgCl ₂ .6H ₂ O, melting point 59 ° C., is used, which is arranged in spiral-shaped thin-walled HD polyethylene tubes , Diameter 5 cm, located on floors 4-8 . Pentane that contains 2% water is used as the heat transfer liquid 9 . The heat transfer liquid 9 has contact with the latent heat storage container via the vapor and liquid phase by means of a riser pipe 10 . This latent heat storage is operated in the temperature range of 45-65 ° C.

When heat is introduced via the heat exchanger 2 , the heat transfer liquid 9 evaporates and gives off its heat of condensation via the HD polyethylene tube wall to the latent heat storage material, causing it to melt. Conversely, when the heat is discharged via the heat exchanger 3 steam of the heat transfer liquid is condensed. The condensate is evaporated to the polyethylene tube wall again, the Mg (NO _{3) 2} .6H ₂ O whereby - MgCl ₂ · 6H ₂ O mixture crystallized.

With the storage filling used, the quasi-dynamic latent heat storage has a working pressure range of 146 to 267 kPa. On average, the storage density is 245 MJ / m ³ salt hydrate mixture. The average heat transfer capacity is 10.5 kW / t salt hydrate at an inlet temperature at heat exchanger 2 of 70 ° C and at heat exchanger 3 of 35 ° C.

Example 2

In the quasi-dynamic latent heat storage device according to FIG. 1, the latent heat storage mass is one half each of a eutectic mixture of 58.7% Mg (NO _{3) 2} · 6H ₂ O and 41.3% MgCl ₂ · 6H ₂ O and 0.5% Na ₂ S ₂ O ₅ containing stabilized Na ₂ S ₂ O ₃ .5H ₂ O formed. The latent heat storage mass is in two separate thin-walled HD polyethylene tubes, diameter 5 cm. The filling with Na ₂ S ₂ O ₃ .5H ₂ O was carried out in the absence of air. Pentane is used as the heat transfer liquid that contains 2% water. Due to the different latent heat storage masses, the latent heat storage has two solidification ranges at 48 ° C and 59 ° C. In the working range from 45 to 65 ° C, the storage density is 330 MJ / m ³ latent heat storage mass. The average heat transfer capacity is 16 kW / t salt hydrate at an inlet temperature at the heat exchanger 2 of 70 ° C and at the heat exchanger 3 of 35 ° C.

Claims (5)

1. Quasi-dynamic latent heat storage, consisting of a closed container which is provided on the bottom and ceiling sides with heat exchangers and which contains latent heat storage material and a heat transfer liquid, characterized by the following features:

• - The latent heat storage material is in the heat storage in container parts with flexible walls,
• - The storage space is filled with these container parts so that flow channels remain between the bottom and the ceiling side heat exchanger.

2. Quasi-dynamic latent heat store according to claim 1, characterized in that the container parts with flexible len walls made of thermoplastic materials. 3. Quasi-dynamic latent heat store according to claim 1 and 2, characterized in that the container parts with flexible walls thin-walled plastic capsules, art cloth bag or a plastic tube or several Plastic hoses are. 4. Quasi-dynamic latent heat store according to claim 1 and 2, characterized in that the flexible walls of the Container parts made of polyethylene, polypropylene or polyvi nyl chloride exist. 5. Quasi-dynamic latent heat store according to claim 1, characterized in that between the bottom and ceiling-side heat exchanger, floor-level installation ten are arranged.