CH641542A5 - Heat accumulator - Google Patents

Description

The invention relates to a heat accumulator, in particular for use with a heat pump, at least one heat exchanger being provided, which is surrounded by the storage medium, and the storage medium being at least in part such that it changes from the liquid to the solid state during at least part of the operating time transforms.

It is known that the usable heat capacity of a heat store, in which water is used as a storage medium, can be increased considerably if one also uses the latent heat, which is released during the phase change from the liquid to the solid state or with the phase change from the solid to the liquid state is stored. In such systems, however, difficulties arise due to the fact that ice formation occurs on the heat transfer surfaces of the heat exchanger extracting heat from the store, as a result of which the heat transfer is severely impaired. In order to avoid this disadvantage, it is known to carry out the ice formation on a large number of heat exchanger units, each of which has a heat transfer lamella which is connected to two lines in a thermally conductive manner. One line serves as the evaporator tube of a heat pump. A heat-extracting refrigerant flows in this evaporator tube, which can lead to ice formation on the heat transfer fin. The second line serves a heat-carrying heat transport medium, through which the ice can be defrosted after ice formation. Such a heat store is operated intermittently, the heat supply continuing before each ice formation period until the ice has thawed from the heat exchanger units and has been removed from the volume range of the heat exchanger units by its buoyancy in the specifically heavier water (EPA-OS 0 004552) .

The heat accumulator described has the disadvantage that the heat transfer deteriorates immediately after the formation of ice and therefore relatively large lengths of evaporator tube are necessary. The performance is further deteriorated by the fact that heating cycles are repeatedly necessary to melt the ice. It is also disadvantageous here that heat must be returned to the heat accumulator for melting. Furthermore, the intermittent operation requires additional control means. If the control should fail, there is a risk of extensive ice formation. The resulting change in volume could then result in such pressure on the storage walls that the storage is destroyed.

It is therefore an object of the present invention to provide a heat store of the type mentioned at the outset, which can be operated in such a way that the heat exchanger is not iced up and thus does not require the supply of heat for deicing, but nevertheless allows the increased storage capacity to be exploited, which result from the phase change.

According to the present invention, this is achieved in the case of a heat store of the type mentioned at the outset by providing a multiplicity of containers which contain part of the storage medium, while the rest of the storage medium at least partially surrounds the containers and has a freezing point which is lower than that of the storage medium contained in the containers. This ensures that no ice forms on the heat exchanger when the temperature of the storage medium which surrounds the heat exchanger drops below 0 ° C. However, if the temperature of the storage medium mentioned is reduced below 0 ° C as a result of the heat removal, the water in the individual containers begins to freeze. As long as not all of the water in the containers is frozen, the temperature in the storage medium outside of these containers cannot drop significantly below 0 ° C and there is therefore no risk of the heat exchanger icing up. The heat accumulator according to the invention therefore has a usable heat capacity which is at least as large or larger than in known heat accumulators which use the water / ice phase change

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do. However, it does not require large heat exchange surfaces in the heat exchanger and no control devices for periodically melting ice on the heat exchange surfaces. There is therefore no need for complex piping with large and specially designed heat transfer fins, as is the case with the subject matter of the published patent application. It is also advantageous that in the area of the water / ice phase change, quick access to the entire heat capacity of the storage is ensured because the containers are washed around on all sides, and thus there is a large total area for heat transfer during ice formation. The maximum ice thickness is no more than about 10-20 cm. It is also advantageous that the relatively small containers can be easily inserted into storage tanks of any shape. In this way, existing memories can easily be converted to make use of the invention.

The storage medium in the containers can be water, and the remaining storage medium can consist of water mixed with antifreeze. The freezing point of the storage medium can be greatly reduced using antifreeze agents, such as those used for automotive engines.

The storage medium contained in the containers can also be made of a material, e.g. Wax or paraffin, which has a higher melting point than ice. When using wax, you get a latent storage with a high storage capacity at around 50-60 ° C. Such a heat store can e.g. serve as a day storage for a heater that is operated with night power.

The containers are advantageously spherical. Spherical containers can be filled with water outside the heat accumulator and filled into the accumulator without great difficulty. When using spherical containers, around 80% of the storage medium is in the balls, so that only around 20% of the storage medium with a lower freezing point than water is required.

This also means that up to 80 ° o of the memory content can be iced up without difficulty.

It is possible to produce the spherical containers from two hemispherical shells welded together. The shells can be welded at the location of the heat accumulator. Since the hemispherical shells can be stacked easily, transporting them to the place of use is easy. It is obvious to the person skilled in the art that, in addition to hemispherical shells, other shell shapes can also be used, but attention should be paid to their stackability.

However, it is also possible to make the containers tubular, for example. In this case, however, the containers cannot simply be thrown into the memory if the highest possible ratio between the container contents and the surrounding storage medium is to be achieved.

When containers in the form of corrugated tubes are used, better circulation of the storage medium around the containers is ensured.

The containers advantageously consist of an elastically stretchable plastic. In this case, the containers can be filled completely without the risk of them breaking apart when ice forms.

The containers can also be made from a stretchable bladder, e.g. made of natural rubber or synthetic rubber.

Such containers can also be filled on the spot and placed in the tank, which is already partially filled with storage medium.

The containers advantageously have about 10 to 201 contents. This gives a favorable heat transfer ratio between surface and content and relatively low ice thickness. Containers of this size can also be easily filled and filled into the tank.

In order to prevent the containers from being buoyed by the ice formation, they can be partially filled with a material of high specific weight. Sand of high specific weight is advantageously suitable as such material.

The water in the containers can have tracers. By monitoring the tracer content in the rest of the storage medium, it can then be determined whether and how many containers have leaked in the company.

An embodiment of the invention is described in more detail below. For a better understanding of the explanations, reference can be made to the drawing. It shows:

1 is a schematic representation of a heat accumulator that is connected to a heat pump,

Fig. 2 shows a spherical container for receiving storage medium and

Fig. 3 shows a corrugated tube-shaped container for receiving storage medium.

The heat exchanger 10 shown in FIG. 1 is connected to a heat pump 11, which is used, for example, to supply heat to a house. A heat exchanger is provided with the reference number 13, which normally acts as an evaporator of the heat pump 11. Energy is extracted from the heat storage during evaporation. The condenser of the heat pump 11 is shown with the reference number 15. This is arranged in an intermediate store 17 and is used, for example, to heat the water of a central heating system. It is known that by suitable switching, the heat pump 11 can also be used for cooling, in which case, e.g. in summer, the store 10 thermal energy is supplied.

In the exemplary embodiment shown, the tank 19 is filled with a large number of spherical containers 21 which contain water as the storage medium. They are surrounded by another storage medium, which consists of water mixed with antifreeze. As already mentioned, the antifreeze prevents ice 13 from forming on the heat exchanger. However, ice can form in the containers 21.

Such a container 21 is shown in FIG. has a content of about 10-201. It consists of two hemispherical shells 23, each having a flange 25. The two flanges 25 are welded together in an airtight manner. A nozzle 27 is provided to fill in water, which is then closed, for example by welding, after the nozzle has been filled. The hemispherical shells 23 are stackable. This enables the containers to be assembled on site and filled with water. Thanks to their stackability, the individual trays 23 require very little space during transport.

An elastically stretchable plastic, e.g. Polypropylene or neoprene. However, it would also be possible to produce such containers from steel, for example. However, the volume expansion during ice formation must be taken into account. If the container is practically inextensible, it cannot be completely filled with water. In order to prevent such a container from being buoyed in the storage medium surrounding it, it can be partially coated with material of high specific weight, e.g. Sand, gravel or iron filings.

The containers can also be formed by a bladder made of natural rubber or synthetic rubber. Also

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such bubbles can be filled in place and placed in storage. They are not subjected to great stress, since they float in the rest of the storage medium. In order to avoid a buoyancy in the formation of ice, they can also be partially filled with material of high specific weight.

FIG. 3 shows a further embodiment of a container 21, this container is tubular. If it is in the form of a corrugated tube, the water circulation between such containers is facilitated. The containers shown in FIG. 3 are advantageously placed in the tank 19 in a vertical position, it being possible for them to remain open at the top. When the tank 19 is filled, water can flow into the container 21 from above and also fill it. After all the containers 21 have been filled, the water level in the tank 19 can then be lowered, wherein it must be taken into account that when the water in the container 21 freezes, water is still out

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this will flow out. However, before the storage tank is put into operation, the tank containing the tubular container 21 has antifreeze added to it. The storage medium containing the antifreeze then surrounds the tubular containers 21, but cannot penetrate them because the level in the tank has been lowered sufficiently beforehand.

Various configurations are still possible without deviating from the inventive concept. So the containers or bladders 21 e.g. be filled with a material that has a higher melting point than ice. Among other things, Wax, paraffin or other substances with relatively high latent heat. In this way e.g. a 15 heat storage can be built, which can be heated with cheap night electricity and can give off a lot of heat in the range of about 50-60 ° C during the day.

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1 sheet of drawings

Claims (14)

641 542 1. heat storage, in particular for use with a heat pump, at least one heat exchanger being provided, which is surrounded by the storage medium, and the storage medium being at least in part such that it changes from the liquid to the solid state during at least part of the operating time, characterized in that a plurality of containers (21) are provided which contain part of the storage medium, while the remaining storage medium at least partially surrounds the containers (21) and has a freezing point which is lower than that of the in the containers (21) contained storage medium. 2. Heat accumulator according to claim 1, characterized in that the storage medium contained in the containers is water and said remaining storage medium consists of water mixed with antifreeze. 2nd PATENT CLAIMS 3. Heat storage device according to claim 1, characterized in that the storage medium contained in the containers consists of a material which has a higher melting point than ice. 4. Heat storage device according to claim 3, characterized in that said material is wax or paraffin. 5. Heat accumulator according to one of claims 1 to 4, characterized in that the containers (21) are spherical. 6. Heat accumulator according to claim 5, characterized in that the spherical container (21) consist of two welded hemispherical shells (23). 7. Heat accumulator according to one of claims 1 to 4, characterized in that the containers (21) are tubular. 8. Heat accumulator according to claim 7, characterized in that they have the shape of a corrugated tube. 9. Heat storage device according to one of claims 1 to 8, characterized in that the containers (21) consist of elastically stretchable plastic. 10. Heat store according to one of claims 1 to 5, characterized in that the containers consist of an expandable bladder. 11. Heat storage device according to one of claims 1 to 9, characterized in that the containers each have 10 to 201 contents. 12. Heat accumulator according to one of claims 1 to 11, characterized in that the containers (21) are partially filled with a material of high specific weight. 13. Heat accumulator according to claim 12, characterized in that the containers (21) are partially filled with sand. 14. Heat storage device according to one of claims 2 and 5 to 13, wherein the storage medium is water, characterized in that the water in the containers (21) has a tracer.