DE2619514A1 - Heat pump thermal storage system - has salt or salt mixture heat storage mass of exothermic crystallisation character - Google Patents

Abstract

A heat storage system for heat pumps, having a storage mass in the form of salt or salt mixture, uses a mixture whose density is greater than that of water when in place in the heat storage device. The melting point of the storage mass is at temp. level lower than that which can be reached with a conventional heat pump. Devices are provided by means of which heat can be transformed to or extracted from the storage as are devices for deliberate prolongation of the exothermic crystallisation of the salt paste to follow preselected programme.

Description

jr. Werding 2

29. U. 1976 Pf / Th

Attachment to

Patent registration

Winfried Werding. CH 1000 Lausanne U. Case 128 Heat storage for heat pumps

The invention relates to a heat accumulator according to the patent

(Patent application P 25 51 379 · 5) with a latent heat storage mass. This heat accumulator is characterized in that a vessel is filled with the storage mass, which is as liquid as possible Condition is that the vessel is sealed, that means are provided to prevent any increases in pressure and volume that may be inside the Vessel emerge, turn off or dismantle that means are provided to the heat from the walls of the vessel to its interior conduct and vice versa, with means being provided for heating or cooling the vessel arbitrarily or according to a predetermined program .

There are numerous solutions for storing heat in a salt or water known in salt mixtures. The main purpose of these is to store heat that is supplied by cheap electric night-time electricity and the mass used to temperatures between about 200 C and 850 C, whereby this heat is immediately used for various purposes

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is needed. It is obvious that when using the electric Current for heating a salt to its melting point for the purpose of heat storage is interested in a salt whose melting point is high, because apart from the energy that is consumed during the phase change, the thermal energy that is necessary to reach the melting point, which is very high in this case, is also stored to reach.

The heat accumulator has, when it is used for this purpose, the heat with help of cheap night-time electricity, not in the form of a single storage tank for a whole house, but that of radiators for use

borrowed forms, the volume and radiant surface of which are based on the space they are supposed to warm up. Therefore, it is not possible to heat the heat radiator to a temperature above 70 ⁰ C in order to avoid burns can be caused, with the preferred temperature is about 60 C.

Furthermore, the heat accumulator is primarily intended to Collect heat from sources whose heat emission only includes temperatures between 60 and 120 ° C, such as simple heat pumps, Storage of solar energy and alcohol burners that heat the water to its boiling point.

The main patent describes the fact that the amount of heat absorbed is directly proportional to the amount of salt used and that the salt volume can be reduced to its smallest value, if you bring the salt into the most liquid state possible during the production of such a heat storage device, in short: that with the least possible Salt volume the greatest density is reached. The manufacture of a memory is relatively easy due to the fact that the used salt, e.g. sodium acetate, already becomes very liquid at 85 C. - Handling it is therefore significantly less dangerous than handling a salt whose melting point is, for example, 800 C, without the To speak energy that is necessary to liquefy such a salt for the purpose of compression.

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The patent also mentions the fact that the exothermic crystallization process can be delayed if the pressure inside of the sealed vessel is created as soon as the storage mass reaches a temperature that exceeds the boiling temperature, not absorbed or is dismantled. It describes means of eliminating this delay. It is also mentioned in the same way that the delay in crystallization can also be used to store heat. - Experiments show that you can have a memory that is under pressure - can cool down completely, e.g. in a refrigerator, and then after a few hours, the exothermic crystallization can be caused simply by breaking the tightness of the storage tank, i.e. by the surrounding air is allowed to penetrate. - So it's possible, means to provide through which the exothermic crystallization can be programmed as required. This is very important for the use of the storage tank, be it in the storage of heat of a cheap energy like that of the electric night current, be it for storing solar radiation, which is sometimes important even in winter.

The present invention therefore has as an object a heat accumulator that contains a storage mass in the form of salt or a salt mixture, and is characterized by the fact that the density of the storage mass, once in the memory, is greater than that of water that the melting point of the storage mass is at a temperature lower than that achieved by one of the usual Heat pumps can be achieved that means are provided to use the same heat pump to both heat in said memory store as well as remove heat from the same that means are provided to delay the exothermic crystallization, means are provided to bring about said exothermic crystallization according to a predetermined program. One such memory that is special equipped, can be exposed to the sun instead of inside a house and used directly as a sun sleeper.

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Sun buyers are known. Vessels with thermally insulating walls contain water containers, the surface of the container facing the sun being black in color and located behind a glass, through which the sun's rays hit this black surface. The water heats up under the heat radiation of the Sun. In order to achieve a sufficient effectiveness of the collector, one must use extensive black areas, from which a aesthetic impairment of the environment, because in order to meet the need for hot water of 3 people for 8 months a year,

2 you need a black area of about 10 m, and for heating

2 of a house with 5 rooms, the black area must be larger than 100 m

The experiments show that the sodium acetate stores about 8 times as much energy as the water as soon as the sodium acetate reaches a temperature above 65 ° C with the same volume, with the same heating time and at the same temperature. A known solar energy collector exposed to the sun can reach a temperature that sometimes exceeds 100ºC. Thus, the conditions for good storage in sodium acetate are fully met after the boiling point of this product is 122 ° C, i.e. at a temperature that a solar energy collector in our latitudes could not reach, whereby the risk of destruction of the material due to this fact is eliminated .

As mentioned, the known solar energy collectors have a black surface which is protected by a glass, and this represents the aesthetic impairment mentioned Hard rubber. Run , the hard rubber can be shaped in such a way that it looks like bricks or roof tiles, for example, and thus blends in with the environment in the best possible way .

The present invention therefore proposes a heat accumulator, which has the characteristics already indicated and which is characterized by the fact that it is equipped so that he can be exposed to the sun that the sun-facing side of the store is also equipped with a glass cover, which for the thermal radiation is permeable, e.g. made of hard rubber, whereby this

Covering can have the most varied of shapes and colors so that the Storage fits in as best as possible into the environment in which it is used will.

The drawings show, as an example, some embodiments of the Invention according to the subject matter.

Fig. 1 shows a cross section through a memory.

Fig. 2 shows a perspective view, especially as a cross section one embodiment of a memory.

Fig. 3 shows a memory on the roof of a family house. Fig. K shows a memory which forms a canopy.

Fig. 5 shows the use of the memory according to the invention in a Meadow near a swimming pool.

The memory according to FIG. 1 consists of a vessel 1 which contains a salt 2, for example sodium acetate. This salt is more preferred than caustic soda, for example, because on the one hand it is not toxic and because its melting point is between 57 and 6U ⁰ C, depending on the purity, i.e. at temperatures that can be achieved by simple heat pumps or by the fact that the memory of the Exposed to the sun. In addition, the price of sodium acetate is low. Immersed in the salt 2 is a coil 3 in which a coolant of a heat pump (not shown) circulates. The vessel 1 is closed by a lid U which carries the snake 3. Connections, possibly welds, are provided in order to seal the vessel 1. - To produce the memory, the sodium acetate 2 is heated to 110 ° C, which makes it very "liquid" on the one hand and any excess moisture on the other.

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speed in which salts 2 is removed. The liquid salt 2 is poured into the vessel 1 in which the snake 3 is already attached. The vessel 1 is filled as full as possible; remains liquid, the screwing of the lid causes no difficulties even though the snake 3 is firmly connected to the lid h . The snake that is rotated with the lid h rotates easily in the molten salt 2. The lid k is equipped with a connection Ua. which ensures the seal. Finally, at Ub, the snake 3 is soldered so that the vessel 1 is sealed in the same way at the outlet of the snake 3. In the middle of the lid k there is an automatic slide _5S which consists of a coil 6 and a ferritic core 7, one end of which has the shape of a cone, 8. The ferritic core carries a pin 9 »which ends in a disk 10 and thereby attaches itself to the deck with a soft connection 11 el k propped up. The cone 8 is held in place by a spring 12. The electrical lines of a thermostat 13, which is mounted in a tight projection of the disk 10, go through the unit 7, 8, 9 and 10. The vessel 1 is located in a vessel 1U, the space between the walls of the two vessels being filled with a thermal insulation material 15, for example with high density sodium acetate. In the same way, one could imagine insulation in the manner of thermos flasks. The salt 2 forms an intermediate space 16 by cooling. The thermostat 13, which was previously immersed in the liquid salt 2, is covered by crystallized salt 2.

The heat pump, not shown, heats the snake 3, its Passes heat on to the salt 2, which, depending on the temperature, heats it above its melting point. If the memory is in the described Shape exposed to the sun, gives the vessel 1, which is preferably should consist of aluminum or copper, the sun's heat to the salt 2, whose temperature is also due to this process May exceed the melting point. As a result of this, the space 16 is filled again and the air contained therein is warmed, which their volume increases. The reduction of the gap 16 and the

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An increase in the volume of air results in the formation of pressure inside the vessel 1. The more the temperature of the salt 2 exceeds the melting point, the more the volume of the salt 2 increases and the more the gap 16 is reduced, ie the more the said pressure is increased. This pressure pushes the salt 2 against the wall of the vessel 1 after the end of the heating and causes a very high density of the salt 2 there, which for this reason becomes an excellent thermal insulator, so that the exothermic crystallization does not occur even if the volume changes 2 salt decreased. Due to the fact that the salt is retreating, the thermostat 13 is no longer immersed and the salt 2 crystallizes there. This crystallized salt 2 is in the sequence to inoculate the molten salt 2, thereby finally enters the expected exothermic crystallization. - As long as this reaction does not occur, the vessel 1 has the temperature of the surroundings, although the salt 2 inside is in a molten state. It is evident that all of the salt 2 eventually crystallizes through the loss of the stored heat, albeit a very slow one. Here a delay in crystallization of a whole week could be determined without the storage tank having been thermally insulated. Crystallization was brought about after one week by breaking the tightness of the vessel 1. This full week delay in response is long enough to benefit from. The memory is thus equipped so that the exothermic crystallization can be delayed on the one hand and that it can be triggered on the other hand at a suitable moment selected by the user or determined by a reguliergares programming device, e.g. by a thermostat, whereby it goes without saying that this suitable moment must be in the period in which the exothermic crystallization is still possible. As soon as the crystallization begins in the vessel 1, tension is applied to the coil $ , which thereby presses the ferrite core T against the inside of the vessel 1 . ; The cone θ moves away from its seat and presses on the spring 12 as long as the coil 6 remains under tension: The tightness of the vessel is therefore lifted . By shifting de · ferritic §. ■ - ■■; ' Kernt? If Mn occurs, the displacement of the pin 9 of the disk and the thermostat 13 against the surface of the salt 2 and the crystallized salt 2, among other things , causes the thermostat 13 to come into contact with the upper

area of the molten salt 2 an inoculation of the latter thing together with the air entering the vessel 1, the exothermic Causes crystallization. As soon as the thermostat 13 perceives an increase in the temperature that was released by this crystallization, he switches off the coil 6 and the spring 12 presses the cone of the ferritic core 7 onto its seat and the connection 11 of the disk 10 against the inside of the lid U, whereby the vessel 1 is sealed again for a further storage cycle.

If the molten salt 2, despite inoculation and contact with does not react to the surrounding air, the thermostat senses this fact. In this case one could, controlled by a delay relay, provide that a second delay relay, if the exothermic crystallization does not occur in due time, the coil switches on and off with a corresponding frequency and during a certain time which is regulated beforehand. The resulting Back and forth movement of the unit 7 »8,9» 10 and 13 caused Vibrations in the vessel 1, causing the desired exothermic crystallization triggers.

The heat released by the exothermic crystallization is carried through the heat pump, not shown, transported to the place where it should be used, e.g. to prepare warm water.

Fig. 2 shows another embodiment of the memory according to the invention The memory 17 with the properties described above is placed in the vessel 18, which has thermally insulated walls and its The wall 19 exposed to the sun consists of glass, so that the radiant heat can only penetrate into the interior of the vessel 18. The memory 17 is therefore protected against weather influences. To unity in the best possible way To insert into the environment, the glass 19 is covered with hard rubber 20, which here has the shape of Roman bricks. It will be apparent that the hard rubber 20 may or ever be given the shape of other bricks by color can give the appearance of slate or other materials used to cover the roofs of houses. With the help of

Pipelines 21 and 22 entering the queue, not shown or emerge from the same, you can combine different memories according to FIG. 2 to form a battery.

FIG. 3 shows a battery of accumulators 23 on the roof of a house 2k, while FIG. K shows a battery of accumulators 25 which forms the canopy of a villa 26.

Fig. 5 shows a battery of accumulators 27 under the cover a frosted glass are hidden, which allows the radiant energy to pass in only one direction, namely from the side with the Color of the raw glass of the covering to the other side of the glass that on the side of the storage tank is coated with a very black iodine solution in carbon disulfide, which is completely for the radiant heat is permeable, imitates a paving and is on the edge of a Swimming pool 28 is located, the water of which could be heated with the help of a heat pump by the captured solar heat.

The invention is of course not restricted to the embodiments presented here. You can use the non-translucent, but the Radiant heat-permeable coverings give the colors, profiles and reliefs of the materials a building is usually made of, preferably in the form of foils that are as small as possible and easily adapt to the shapes required by the environment let, such as imitation of mansards, porches, balconies, etc. The memory according to the invention can be supplied so that they can be combined to form batteries.

The use of the mentioned covers can also be used independently of the memory according to the invention for any other known system of the Collecting solar energy can be used.

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Claims (1)

- 1o - Expectations ί1.Jheat storage for heat pumps, which has a wetness in the form of Contains salt or a salt mixture, characterized in that the Density of the storage mass as soon as it is in the storage tank, is higher than that of water that the melting point of the storage mass is at a temperature that is lower than that achieved by a Conventional heat pump can be achieved that means are provided with the help of which the same heat pump heat both in said Store memory as well as withdraw it from the fact that means are provided with the help of which the exothermic crystallization arbitrarily can be delayed, means being provided to cause said exothermic crystallization according to a predetermined program. 2. Heat accumulator according to claim 1, characterized in that it is so is equipped so that it can be exposed to the sun, that the side of the memory facing the sun, except with a glass for protection is provided with a cover to protect against the effects of the weather Lets heat radiation through, this covering being of various kinds and / or can be of different color so that it can adapt to the surroundings together with the memory in the best possible way, in the memory is needed. 3. Heat accumulator according to claim 1, characterized in that the wall or the walls of the housing of the memory are made of thermal insulation material if the memory is not directly used as a collector of Solar energy is needed, and that additional thermal insulation means are provided which surround the housing. - 11 - 609847/0912 28195U k. Heat accumulator according to claim 2, characterized in that when the accumulator is used as a collector of solar energy, at least that wall of the housing of the accumulator which faces the radiant heat consists of a material of high thermal conductivity, for example copper or aluminum, and that this wall is black in color. 5 · Heat accumulator according to one of the preceding claims, characterized in that that a coil of a heat pump is installed in the storage mass of the storage tank, with the input and output of the coil are equipped so that different memories can be connected in series and / or that means are provided to the same to merge in parallel. 6. Heat accumulator according to claim 1, characterized in that the housing of the memory is sealed and that means are provided with the help of which the tightness of the memory arbitrarily and / or after a predetermined program can be canceled and restored. 7. Heat accumulator according to claim 6, characterized in that the cancellation and restoring the tightness is accomplished with the help of a solenoid valve. 8. Heat accumulator according to claim 6, characterized in that the predetermined Program is controlled by a thermostat that is located outside of the memory. - 12 - 9. Heat accumulator according to claim 1, characterized in that means are provided siod ₃ with the help of which the storage mass can be brought into contact with a same mass arbitrarily or according to a predetermined program to melt _s , said same mass being crystallized and an inoculation of the molten mass causes, this inoculation s can take place without the tightness is necessarily canceled. 10. Heat accumulator according to claim 1 or 2 _S, characterized in that a thermostat is provided in the interior of the memory ₉ and that means are provided to arbitrarily bring the thermostat into contact with the storage mass. 11. Heat accumulator according to claim 1 or 2, characterized in that at least one delay relay is provided. 12. Heat accumulator according to claim 1, characterized in that means are intended to cause vibrations. 13. Heat accumulator according to claim 2, characterized in that the cover made of hard rubber. ΐίί. Heat accumulator according to Claim 2, characterized in that said cover consists of a frosted glass which allows the radiant heat to pass through only in one direction. 15. Heat storage device according to claim ili, characterized in that the frosted glass painted with a very black iodine solution in carbon disulfide is. 609847/0912 Blank page