DE3033014A1 - HEAT STORAGE - Google Patents

Abstract

The heat accumulator (10) comprises a tank (19) containing water-filled spherical receptacles made of an elastically extensible synthetic material. These receptacles are surrounded by a storage medium which contains an antifreeze agent and therefore has a lower freezing point than the water contained in the receptacles. If, therefore, the heat pump (11) is in operation, for example for heating the water contained in the water storage tank (17) for central heating, and the temperature in the accumulator drops below the zero point, no ice forms on the evaporator (13), so that its functioning is not impaired by ice formation. However, the water in the receptacles (21) freezes, so that the latent heat being released in the liquid/solid phase transition is utilised. <IMAGE>

Description

DR. BERÖ DiPLv-ING. STAPF DIPL.-ING. SCHWABE: DR. DR.SANDMAIR 3033014

PATENTANWÄLTE PO Box 860245 8000 Munich 86

• fc.

? Sep 1980

Attorney's file: 31 141 ^cents

_PAL0MAR ELEKTRONIK AG

In the instep

8903 Birmensdorf / SWITZERLAND

Heat storage

130 026/0341

. '(089) 988272 Telegrams: Bank accounts: Hypo-Bank Munich 4410122850

988273 BERGSTAPFPATENT Munich {BLZ 70020011) Swifl Code: HYPO DE MM

'' 8 82 74 TELEX: Bayet Vereinsbank MOnchen 453100 (BLZ 700202 70)

'83310 052456OBERGd Postscheck Munich 65343-808 (BLZ 70010080)

30330H

Attorney's file: 31 141

Heat storage

The invention relates to a heat accumulator, in particular for use with a heat pump, wherein a heat exchanger is provided at least, which is surrounded by the storage medium and the storage medium is at least designed in part such that it fixed during at least part of the _t operation time from liquid to State passes.

It is known that the usable heat capacity of a heat accumulator · in which water is used as a storage medium can be increased considerably if one also uses the latent heat generated during the phase change from liquid to solid state becomes free or when the phase changes from solid is stored to the liquid state. In such systems, however, difficulties arise in that the Heat transfer surfaces of the heat exchanger which extracts heat from the storage device causes ice to form, as a result of which the heat transfer is severely impaired. To avoid this disadvantage, it is known to prevent the formation of ice on a

130026/0341

Perform a plurality of heat transfer units, each of which has a heat transfer lamella that is metallically thermally conductive is connected to two lines. One line serves as an evaporator tube. Heat pump. In this evaporator tube A heat-extracting refrigerant flows, which can lead to the formation of ice on the heat transfer lamella. The second Line serves a heat-carrying heat transport medium, through that the ice can be defrosted after the ice has formed. The operation of such a heat storage is intermittent, the supply of heat is continued before each ice formation period until the ice is removed from the heat exchanger units defrosted and due to its buoyancy in the specifically heavier water from the volume area of the heat exchanger units removed (EPA-OS 0 004 552).

The heat accumulator described has the disadvantage that the heat transfer is impaired immediately after the ice has formed and soir.it still requires relatively large evaporator tube lengths are. The performance is further deteriorated by the fact that repeatedly heating cycles are necessary to the ice melt away. It is also disadvantageous here that heat has to be fed back into the heat storage device in order to melt it. Further Intermittent operation requires additional control means. Should the control fail, so there is a risk of extensive ice formation. The resulting change in volume could then be a such pressure is applied to the storage walls that the storage facility is destroyed.

It is therefore the object of the present invention to provide a heat store of the type mentioned at the beginning, which can be operated in such a way that no icing of the heat exchanger takes place and therefore does not require the supply of heat for de-icing, but still allows the increased storage capacity to be used, which result from the phase aw; echsel.

130026/0341

30330H

According to the present invention, this is the case with a heat accumulator of the type mentioned achieved in that a plurality of containers is provided, which a part of the storage medium, while the remaining storage medium at least partially surrounds the container and a freezing point has, which is lower than that of the storage medium contained in the containers. This achieves that no ice forms on the heat exchanger if the temperature of the storage medium surrounding the heat exchanger drops below 0 C. But if the temperature is reduced by the heat extraction of the storage medium mentioned is lowered below 0 C, the water in the individual containers begins to freeze. So long If not all of the water in the containers is frozen, the temperature in the storage medium outside these containers can be does not sink significantly below 0 C and thus exists as long as it is there is also no risk of the heat exchanger icing up. The heat accumulator according to the invention therefore has a usable heat capacity that is at least as large or greater is the same as with known heat storage systems that make use of the water / ice phase change. However, it does not need any large ones Heat exchange surfaces at the heat exchanger and no control devices for the periodic melting of ice on the heat exchange surfaces. So there is no complex piping with large and specially designed heat transfer fins as necessary for the subject of the cited publication. It is also advantageous that in the area of the phase change Water / ice quick access to the entire heat capacity of the storage tank is guaranteed because the container be washed around on all sides, and thus a large total area for heat transfer during ice formation. The maximum ice thickness is no more than 10-20 cm. Advantageous is also that the relatively small containers can easily be placed in storage tanks of any shape. In this way, existing memories can also be easily converted to make use of the invention.

130026/0341

30330H

The storage medium in the containers can be water, and the rest of the storage medium can consist of antifreeze mixed water. With 'antifreeze, such as those used for automobile engines, the freezing point of the storage medium can be lowered significantly.

The storage medium contained in the containers can also consist of a material, e.g. wax or paraffin, which has a has a higher melting point than ice. When using wax, you get a latent storage with high storage capacity at around 50 - 60 ° C. Such a heat storage tank can, for example, serve as a day storage tank for heating that uses night-time electricity is operated.

The containers are advantageously spherical. Spherical containers can be filled with water outside the heat storage tank and filled into the storage tank without great difficulty will. When using spherical containers, around 80% of the storage medium is in the spheres, see above that only about 20% storage medium with a lower freezing point than water is necessary. It also follows from this that Up to 80% of the storage capacity can be frozen without difficulty. .

It is possible to manufacture the spherical containers from two hemispherical shells welded to one another. The welding the shells can be made at the location of the heat storage tank. Because the hemispherical shells are easily stacked their transport to the place of use proves to be problem-free. It is evident to the person skilled in the art that, in addition to hemispherical shells, other shell shapes are also used can, but attention should be paid to their stackability.

130026/0341

But it is also possible to make the container tubular, for example. In this case, however, the containers cannot • can simply be thrown into the storage tank if you have as high a ratio as possible between the contents of the container and the surrounding area Wants to achieve storage medium.

If containers in the form of corrugated tubes are used, ensures better circulation of the storage medium around the container.

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

The containers can also consist of an expandable bladder, e.g. made of natural rubber or synthetic rubber. Also such Containers can be filled on the spot and placed in the tank, which is partially already filled with storage medium.

The containers advantageously have a volume of about 10 to 20 liters. This gives a ratio that is favorable for the heat transfer between surface and content and relatively thin ice. Containers of this size can also be easily filled and placed in the Tank to be filled.

To prevent / that the containers are buoyed by the ice formation obtained, they can be partially filled with a material of high specific gravity. As such material sand with a high specific weight is advantageous.

The water in the containers may contain tracers. Through surveillance the content of tracer in the rest of the storage medium can then be determined whether and how many containers are in operation have become leaky.

130026/0341

BATH ORIGINAL

30330U

> ίθ

At least one vibrator is advantageously provided, which at least when the storage medium is in the container is near the freezing point, the storage medium vibrates. In this way, hypothermia of the Storage medium can be prevented. The vibration causes ice to begin to form as soon as the freezing point is reached.

The vibrator is expediently an ultrasonic generator. An ultrasonic generator generates vibrations that cannot be heard. An infrasound generator also proves to be useful, which also generates vibrations that are inaudible. Infrasound has the advantage that it is in the storage medium spreads well even when there are obstacles such as those created by each container. It is also possible to use a sound generator if there is no risk of sound waves escaping to the heat accumulator and represent a noise immission. By suitable choice of Sound frequency, this can usually be avoided because the tank walls, especially if they are made of concrete, have a low one Own natural frequency.

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

Fig. 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

3 shows a corrugated tubular container for receiving storage medium.

130026/0341

.44-

The heat exchanger 10 shown in FIG. 1 is connected to a heat pump 11 connected, which is used, for example, to supply heat to a house. The reference number 13 is a heat exchanger provided, which normally acts as an evaporator of the heat pump 11. During the evaporation, the heat accumulator becomes energy withdrawn. With the reference number 15 is the condenser of the heat pump 11 shown. This is arranged in a buffer 17 and is used, for example, the water a Central heating system to heat. It is known that, through suitable switching, the heat pump 11 is also used for cooling can be, in which case, e.g. in summer, the storage 10 thermal energy is supplied.

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

In figure 2 such a container 21 is shown, e.g. has a content of about 10-20 liters. It consists of two hemispherical shells 23, each of which has a flange 25. The two flanges 25 are welded to one another in an airtight manner. A nozzle 27 is provided to fill in water, wherein then after filling the nozzle is closed, for example by welding. The hemispherical ones. Trays 23 are stackable. This allows the containers to be assembled in place and filled with water. The individual shells 23 · are required very little space during transport thanks to their stackability.

130026/0341

30330H

An elastically stretchable material is advantageous as the material for the container Plastic, e.g. polypropylene or neoprene. However, it would also be possible to manufacture such containers from steel, for example. However, the volume expansion during ice formation must then be taken into account. If the container is practically non-stretchable, so it cannot be completely filled with water. To prevent, that such a container receives buoyancy in the storage medium surrounding it, it can partly with material of high specific Weight, e.g. sand, gravel or iron filings, filled with ground.

The containers can also be formed by a bladder made of natural rubber or synthetic rubber. Such bubbles can also be filled on the spot and placed in the memory.

They are not subjected to any great stress because they float in the rest of the storage medium. To boost the ice formation To avoid this, they can also be partially filled with material of high specific gravity.

Another embodiment of a container 21 is shown in FIG shown. This container is tubular. If it is in the shape of a corrugated pipe, water will circulate between such containers made easier. The containers shown in FIG. 3 are advantageously placed in the tank 19 in a vertical position inserted, whereby they can remain open at the top. When the tank 19 is filled, water can flow into the container 21 from above and fill them too. After all the containers 21 have been filled, the water level in the tank 19 can then be lowered It must be taken into account that when the water in the container 21 freezes, water will still flow out of it. Before however, the memory is put into operation, the tank containing the tubular container 21 is antifreeze buried. The storage medium containing the antifreeze then surrounds the tubular container 21, but can do not penetrate into this, because the level in the tank was lowered sufficiently beforehand.

130026/0341

-Al.

A vibrator 20 is also provided on the tank 19, with which the storage medium can be set in vibration. at This vibrator can be an ultrasonic or infrasonic generator Act. But it is also possible to use a sound generator. The vibrator is beneficial in the middle of the tank 19, a vibrator member being provided which extends into the interior of the tank and into the storage medium, which is located outside the container 21, is immersed. This also means that the storage medium is inside the container vibrated to prevent hypothermia. In addition to vibrators, there are also other means conceivable, which are normally used. to prevent hypothermia and to ensure that ice formation certainly starts at freezing point.

Various configurations are still possible without deviating from the inventive concept. So can the containers or bladders 21 may be filled with, for example, a material which has a higher melting point than ice. Some of the possible options are Wax, paraffin or other substances with relatively high latent heat. In this way, e.g. a heat accumulator can be built that can be heated with cheap night electricity and a lot of heat during the day in the range of around 50 to 60 ° G can deliver.

130 0 26/0341

Claims (18)

30330H Attorney's file: 31 141 PATENT LAWYERS · Claims MONKS eo · MAUtRKlflCHeRSTR.46 Heat storage, especially for use with a heat pump, wherein at least one heat exchanger is provided, which is surrounded by the storage medium, and the storage medium; is at least in part such that it moves from the liquid to the solid state passes, characterized in that a plurality of containers (21) is provided, which one Contain part of the storage medium, while the remaining storage medium at least partially surrounds the container (21) and has a freezing point lower than that of the storage medium contained in the containers (21). 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. 3. Heat accumulator according to claim 1, characterized in that the storage medium contained in the containers consists of a Material. Consists that has a higher melting point than ice • having. 4. Heat accumulator 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 that the containers (21) are spherical. 130026/0341 BATH ORIGINAL 30330H 6. Heat accumulator according to claim 5, characterized in that the spherical container (21) of two welded together hemispherical shells (23) exist. 7. Heat accumulator according to one of claims 1 to 4,. Characterized / äjß.ss the container (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 that the container (21) are made of elastically stretchable plastic. 10. Heat accumulator according to one of claims 1 to 5, characterized in that that the containers consist of an expandable bladder. 11. Heat accumulator according to one of claims 1 to 9, characterized in that that the · containers each contain 10 to 20 liters. 12. Heat accumulator according to one of claims 1 to 11, characterized in that 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 accumulator according to one of claims 1 to 13, characterized characterized in that the water in the containers (21) has a tracer. 130026/0341 15. Heat accumulator according to one of claims 1 to 14, characterized in that at least one vibrator is provided, which at least when the storage medium is in the container in the vicinity of the freezing point
causes the storage medium to vibrate. 16. Heat accumulator according to claim 15, characterized in that the vibrator is an ultrasonic generator. 17. Heat accumulator according to claim 15, characterized in that the vibrator is an infrasonic generator '. 18. Heat accumulator according to claim 15, characterized in that the vibrator is a sound generator. 130 0 26/0341