EP0041244A2 - Apparatuses for the energy-saving recovery of useful ambient heat or of waste heat - Google Patents

Abstract

A process for the energy-saving recovery of useful heat from the environment or from waste heat with the use of a reversible chemical reaction comprising, charging and discharging alternatingly and successively by pressure variation with hydrogen two vessels which are interconnected by lines and filled with a metal hydride and the hydride-forming metal and removing as useful heat the heat of compression and of hydride formation thereby liberated by heat exchange and replacing consumed heat of expansion and hydrogen evolution of the hydride by heat exchange with the environment or by waste heat.

Description

The present invention relates to a method for the energy-saving production of useful heat from the environment or from waste heat using a reversible chemical reaction. The invention further relates to a device for performing this method.

A number of heat pumps are already known which operate according to the compression or absorption principle. Easily vaporizable liquids with low vapor pressure, such as halogenated hydrocarbons or ammonia, are mechanically or thermally compressed until liquefaction begins, the heat of condensation of the respective working materials being obtained as heating energy or waste heat. The useful heat consists of the enthalpy of vaporization, which is denied by environmental energy, and the heat of compression, which comes from the mechanical or thermal drive. Thus, only changes in the state of matter take place, chemical changes are deliberately avoided.

Eistungszahlen the _L, the ratio of emitted ie _N utzwärme to the expended power supply, are in electrically operated compression heat pumps is between 2 to 4. In absorption heat pumps, which are generally operated with fossil fuels, this figure is about 1.3. In comparison, an oil or gas boiler has a coefficient of performance of around 0.8.

• 1. Volle Reversibilität der chemischen Reaktion, was gleichbedeutend mit hoher Zykluslebensdauer der Arbeitsstoffe ist.
• 2. Möglichst hohe Reaktionsenthalpie, verbunden mit der Zusatzforderung, daß der energieaufnehmende Prozeß bei möglichst tiefer Temperatur abläuft (Nutzung von Umweltenergie niedriger Energiestufe) und der energieliefernde Prozeß Wärmeenergie auf einem Temperaturniveau liefert, welches ausreicht, um zumindest Gebäudeheizungen betreiben zu können.
• 3. Der reaktionskinetische Ablauf muß den gestellten Anforderungen voll genügen; d.h. das System darf nicht zu langsam arbeiten.
• 4. Gute Wärmeleitfähigkeit der Arbeitsstoffe, um den Wärmeaustauschprozeß möglichst wenig zu behindern.
• 5. Ungiftigkeit der Arbeitsstoffe, um bei etwaigen Leckagen des an sich voll verkapselten Wärmepumpensystems keine gesundheitlichen Gefahren heraufzubeschwören.
• 6. Vertretbarer Preis der Arbeitsstoffe.

Due to the general shortage of energy, thermochemical heat pumps have recently become interesting, in which attempts are made to exploit the absorption or dissipation of energy in a reversible chemical reaction. The advantage of thermochemical heat pumps over the Hitherto used heat pumps consist in that far smaller amounts of auxiliary energy are generally required to maintain the enthalpy of a chemical reaction than for pure compression and / or condensation processes. In theory, this means that thermo-chemical heat pump at higher _L eistungszahlen should be able than the known working on a purely physical base heat pumps. So far, in particular the alkaline earth metal chloride hydrates or ammonia have been investigated as reversible chemical reactions. These systems appeared particularly interesting in connection with the storage of heat, for example solar energy; see. DE-OS 27 58 727 and DE-OS 28 10 360. These systems have practically no significance, since a number of requirements have to be met that are not or only partially fulfilled by these chemical systems:

• 1. Full reversibility of the chemical reaction, which is synonymous with a long cycle life of the working materials.
• 2. The highest possible enthalpy of reaction, combined with the additional requirement that the energy-absorbing process takes place at the lowest possible temperature (use of environmental energy at a low energy level) and the energy-supplying process delivers thermal energy at a temperature level which is sufficient to at least be able to operate building heating systems.
• 3. The reaction kinetic process must fully meet the requirements; ie the system must not work too slowly.
• 4. Good thermal conductivity of the working materials in order to hinder the heat exchange process as little as possible.
• 5. Non-toxicity of the working materials, in order not to pose any health risks in the event of any leaks in the fully encapsulated heat pump system.
• 6. Reasonable price of the working materials.

The alkaline earth metal chloride hydrates no longer dissociate and evaporate sufficiently at temperatures below freezing. They can therefore only be operated with the aid of heat from the ground, from running water or groundwater, which considerably limits the area of application. In any case, the ambient air available to everyone cannot serve as an energy source below. the freezing point.

Furthermore, the thermal conductivity of the previously proposed working materials is low, so that there are considerable problems in the heat exchange processes. At least one needs very large heat exchange surfaces with the previously proposed working materials, which leads to undesirably large-volume aggregates.

Material and energy transport pose further significant difficulties. The reaction speed in proportion as water or salts ammoniäkfreie be enveloped with layers of salt hydrate or ammoniate - then the _Ge slowed. For this reason too, a large distribution of the working materials is unavoidable.

In recent years, some metal hydrides have been investigated in more detail, in order to be able to use them for the production and storage of hydrogen, which in principle can be used as an alternative energy for both engines and heating. The hydride or Hydridspaltung is _ver with a significant enthalpy - bound, which leads to considerable difficulties and disadvantages in the planned uses of these metal hydrides. It has therefore already been proposed in the test vehicles to use the waste heat from the engine and the exhaust gases to heat the hydride stores. In the summer months, air conditioning can be carried out directly by exchanging heat with the hydride storage. On the other hand, there are great difficulties in the start-up phase, since even at low temperatures there must be sufficient hydrogen pressure to start the engine and to bridge the time until the exhaust gases are warm enough to be used to heat the hydride storage. It has therefore been proposed already a combined hydrogen storage system, are connected to each other in the refueling of the vehicle and heating the house, while the energy released amounts of _H ydridbildung be exploited sense; see. H. Buchner, The Hydrogen-Hydride Energy Concept, Chemie Technik 7 (1978), pages 371 to 377. Accordingly, around 30% of the heat content of hydrogen at room temperature can be converted into useful heat at a higher temperature through the formation of hydrides. It is therefore recommended that hydrogen and heat recovery are always coupled with one another in these processes.

In reverse of this concept, it has also been proposed to store solar heat for indoor air conditioning with the help of metal hydrides. As a Primärenergieguelle F'lachsolarkollektor is assumed to be around 100 ° C, as Hilfswärmebad the earth serve at a temperature level of around 10 ° C, as a heat storage and heat transformation, two metal hydride with CaNi ₅ - and Fe _0.5 Ti _0.5 powder, between which hydrogen gas can be exchanged by opening a valve. Heat exchangers also couple the two hydride tanks to the primary energy source, to the auxiliary heating bath or to the consumer, a house; see. H. Wenzl, Hydrogen in Metals: Outstanding Properties and Examples of Their Use, Nuclear _{Research sanla} g _{e Jü l} i _{ch GmbH} , January 1980, pages 66, 67 and Figure 13. However, a rough _calculation shows that this concept is none There is a prospect of realization, since the hydride storage would have to be dimensioned too large to be able to be used for the storage of solar energy in profitable dimensions.

The object of the invention is to develop a method and a device for the energy-saving production of useful heat from the environment or from waste heat using a reversible chemical reaction.

This object is achieved in that two containers connected to one another by lines - which are roughly equally filled with a metal hydride and the hydride-forming metal or the hydride-forming alloy - are alternately loaded and unloaded with hydrogen by changing the pressure, thereby releasing the released ones Dissipates heat of compression and hydride formation through heat exchange as useful heat and replaces spent heat of relaxation and hydrogen release of the hydride with heat exchange with the environment or with waste heat.

The metal hydrides are divided into the low-temperature hydrides and high-temperature hydrides based on their property of decomposing at low or high temperatures. Especially when it comes to heating houses with the warmth of the surroundings, only the low-temperature hydrides can be used. If, on the other hand, waste heat from power plants or industrial plants is to be used, the high-temperature hydrides are ideal. For the heating of Iron titanium hydride is particularly suitable for residential buildings. This hydride can be formed quickly in the range -20 to +70 ⁰ C and are split again, with the pressure range of 0.1 to 12 bar is quite sufficient to control formation and cleavage. The high speed of the reaction, the high metallic thermal conductivity of the metal hydrides and the long cycle life of metal / metal hydride, the high energy density enable the use of this metal hydride if the system can be hermetically sealed and in particular to prevent the entry of oxygen. This problem is significantly alleviated if the heat pump process is carried out according to the absorption principle and there is no need for a leak-sensitive suction / pressure pump. The price of this alloy has already dropped to DM 10 / kg when large quantities are purchased, so that the investment costs for household heating based on this metal hydride can be significantly lower compared to conventional heat pumps.

Another advantage of the metal hydrides is that they have proven to be extremely safe and non-toxic, so that no complex safety measures have to be taken. For a house heating system, for example, it should be entirely sufficient to connect the system with a safety valve and a line leading to the outside, so that, for example, in the event of a fire and the associated overheating of the system, the hydrogen can be safely vented to the outside, where it can be due to the low specific density immediately distributed upwards in the atmosphere and no longer represents a further source of danger.

When using the metal hydrides according to the invention, however, a number of other problems have to be considered. For example, traces of oxygen already lead to inactivation of the metal hydrides, so that the reversible hydride formation is considerably impaired or even comes to a standstill by even small amounts of oxygen. It is therefore absolutely necessary to hermetically seal the entire system from the two containers (1), (2), the switchable piping system (3) and the suction / pressure pump (4) from the environment. Since most metal hydrides can be reactivated with pure hydrogen at elevated temperatures, this part of the device according to the invention should be easy to remove and transport, so that it can be replaced and regenerated in the event of a malfunction due to oxygen. If necessary, the metal hydride could also be protected by upstream oxygen-binding media. These include on carrier material such as silica gel, chrome trioxide in cartridges (Oxisorb, Messer Griesheim).

In order to carry out the heat exchange on the metal hydride containers quickly and with little loss, extensive contact with the two exchanger systems (5), (6), (7) and (8) should be possible. On the other hand, the mass of the casing and the heat exchanger should be kept small, since otherwise the heat capacity of these parts would become unnecessarily large and considerable delays and heat losses would occur when the system was switched over. The containers (1) and (2) are therefore preferably designed as batteries of pipes which are connected to the pipeline system (3). In order to enable rapid entry and rapid removal of the hydrogen from the metal hydrides in the interior of the tubes, it can be sensible in certain cases to insert spider-shaped tube inserts with sieve-like holes in the metal hydride tubes. Since the metal hydrides are generally present as fine-grained powders with a large surface area after the usual activation by hydrogen, smaller ones can Tubes can also be dispensed with such additional installations.

In the simplest case, the heat exchange on the metal hydride containers (1) and (2) can take place with air. In the case of house heating, warm air would be drawn directly from the system, which could be used directly to heat a house. If desired, this warm air flow can be dosed via a mixing valve and a thermostat so that the room temperature remains constant.

• a) Wasserstoff wird vom Behälter (1) zum Behälter (2) gepumpt. Aus dem Hydrid im Behälter (1) bildet sich wieder Metall, während sich im Behälter.(2) Hydrid bildet. Die freiwerdende Wärme im Behälter (2) wird durch den Wärmeaustausch direkt als Nutzwärme abgeführt. Sobald sich praktisch alles Hydrid im Behälter (1) ins Metall und das Metall im Behälter (2) zum Hydrid umgewandelt hat, wird keine weitere Wärme im Behälter (2) mehr frei, so daß das System jetzt umgeschaltet werden muß.
• b) Durch das Rückpumpen des Wasserstoffs vom Behälter (2) in den Behälter (1) kehrt sich die Reaktion der Hydridbildung um, so daß jetzt im Behälter (1) Wärme frei wird. Selbstverständlich wird kurz nach dem Umschalten zunächst keine Nutzwärme anfallen, da der Behälter (1) durch Wärmeaustausch mit der Umgebung maximal die Umgebungstemperatur besitzen wird und erst durch Hydridbildung der Behälter (1) entsprechend erwärmt werden muß, bis die Temperatur auf die gewünschte Höhe angestiegen ist. Diese Umschaltphase wird umso länger sein, je größer die Wärmekapazität des Systems ist und je größer die Differenz zwischen der Temperatur der _Nutz- wärme und der Umgebungswärme ist. Erst wenn der Be--hälter (1) die Temperatur der Nutzwärme erreicht oder überstiegen hat, sollte die Nutzwärme entnommen werden. Um die im Umschaltzeitpunkt im Behälter (2) vorhandene Speicherwärme sinnvoll zu nutzen, sollte sie entweder dazu verwendet werden, Brauchwarmwasser zu bereiten oder den Behälter (1) durch Wärmeaustausch mit Behälter (2) bis zur Einstellung der Gleichgewichtstemperatur vorzuwärmen.

Such a heater would have the following cycles:

• a) Hydrogen is pumped from the container (1) to the container (2). Metal forms again from the hydride in the container (1), while hydride forms in the container (2). The heat released in the container (2) is dissipated directly as useful heat by the heat exchange. As soon as practically all the hydride in the container (1) has converted to metal and the metal in the container (2) to the hydride, no further heat is released in the container (2), so that the system must now be switched over.
• b) By pumping back the hydrogen from the container (2) into the container (1), the reaction of the hydride formation is reversed, so that heat is now released in the container (1). Of course, shortly after the switchover, there will initially be no useful heat, since the container (1) will have a maximum of the ambient temperature due to heat exchange with the surroundings, and the container (1) must first be heated accordingly until the temperature has risen to the desired level . This switchover phase will be longer, the greater the heat capacity of the system and ever greater the difference between the temperature of _heat-N supporting and the ambient heat is. The useful heat should only be removed when the container (1) has reached or exceeded the temperature of the useful heat. In order to make sensible use of the storage heat in the tank (2) at the time of the switchover, it should either be used to prepare domestic hot water or preheat the tank (1) by exchanging heat with the tank (2) until the equilibrium temperature is reached.

Since most heating systems work with circulating water, the heat exchange of the useful heat can also be carried out directly with water. However, since the tanks drop to temperatures below 0 ° C during the hydrogen release phase, this would lead to freezing of the water. If you want to carry out the heat exchange with water, this would have to be done by trickling water over the tubular batteries. The correspondingly heated water would then have to be reintroduced into the circuit by an additional pump. During the switchover phase, heat exchange between the tanks (1) and (2) could take place or useful water could be preheated. The heat exchange with the environment would have to take place through air or a liquid system with antifreeze. When exchanging heat with air, it must always be taken into account that the cooling of the air leads to condensation and ice formation, which significantly affects the efficiency of the system. The latent heat of melting and evaporating water undesirably increases the thermal capacity of the system, which leads to loss of time and energy in the switchover phase. These disadvantages are noticeable when using water and aq coolants with anti-freeze are avoided, but the outlay on equipment is correspondingly greater.

A preferred variant of the method according to the invention therefore uses so-called heat pipes for heat exchange (heat pipes; see P. Dunn and D.A. Reay, Heat Pipes, Pergamon Press, 1976). These are hermetically sealed metal pipes, some of which are filled with an easily evaporable liquid. The heat transfer takes place by evaporating the liquid at the lower end and giving off the heat of vaporization by recondensing the liquid at the upper end of the tube. These heat pipes act as diodes because heat can only be transferred in one direction, namely from bottom to top. If the amount of heat at the lower end is no longer sufficient to evaporate the liquid, steam can no longer rise and condense at the top. As soon as the upper end is warmer than the lower end, heat is no longer transported. These heat pipes also have the advantage that the thermal conductivity is 3 orders of magnitude higher than that of copper.

When using such heat pipes in the method according to the invention, there is also no need to switch over the heat exchanger systems, since the heat pipes can always only transport the heat in the one desired direction. In such a case, only the direction of the hydrogen flow through the pump (4) has to be reversed. This can be done by using appropriate valves or by reversing the direction of pump rotation. With the absorption heat pump, the direction of flow of the hydrogen is reversed by simply switching the fossil heating source on and off in accordance with the working cycle time.

So while everyone exchanges heat with air, water, frost-proof water or other liquids Phase reversal, the corresponding heat exchanger must also be switched, which requires considerable equipment and appropriate control devices, this can be dispensed with when using heat pipes. The reversal of the pumping direction of the hydrogen can be done in this preferred embodiment of the invention by thermostats or even by a simple timer. The useful heat obtained can only flow in the desired direction due to the diode effect of the heat pipes, so that a phase-reversed switching can never occur. Of course, even when using heat pipes, it cannot be avoided that useful heat cannot be removed for a certain period of time after switching, since the cooled container must first be brought to the temperature of the useful energy to be removed by hydride formation and possibly heat exchange.

In a further embodiment of the invention, the pressure change is brought about thermally. This eliminates the suction / pressure pump, but it is necessary to use two different metal hydrides. The two metal hydrides must differ by different hydrogen absorption or desorption energy and thus absorb or release the hydrogen at different temperatures. The metal hydride with the lower hydrogen desorption energy is able to utilize ambient heat or waste heat, while the second metal hydride with higher hydrogen desorption energy has to be fed with heat, as can be obtained, for example, from the combustion of fossil fuels.

A typical combination of two different metal hydrides is a titanium-iron-manganese hydride and a titanium-zirconium-chromium-manganese hydride. The chemical composition of these hydrides is TiFe _0.8 Mn _0.2 H ₂ and Ti _0.9 Zr _0.1 CrMnH ₃ .

The absorption and desorption temperatures of these two metal hydrides are + 65 ^° C and + 121 ^° _C and - 6 ^° C and + 50 C. From this, a theoretical system coefficient of performance of 1.6 can be calculated.

A device for carrying out this variant of the method also consists of two containers (1), (2), each filled with approximately half the metal hydride and the hydride-forming metal of the two different metal hydrides, a connecting pipe (3), mutually switchable heat exchangers (5), (6), for the dissipation of the useful heat and mutually switchable heat exchangers (7), (8) for the supply of heat to the environment or waste heat or the fossil heat as well as line (13), (14) and switchable shut-off valves (11), (12).

The use of heat pipes is also particularly advantageous for this. While the heat pipe (7) is still fed with heat from the environment or waste heat, the heat pipe (8) is fed intermittently with heat which has been produced by burning fossil fuels. The additional line (13), (14) and switchable shut-off valves (11), (12) are necessary to prevent direct transmission of the fossil-generated heat to the useful heat flow. This would be prevented by putting the heat exchanger of the heat pipe (6) out of operation by bypassing the useful heat flow during the period of hydrogen desorption. This is done by operating the shut-off valve (11) accordingly.

During the shutdown of the heat pipe (6) comes there is a build-up of heat in the portion of the current that leads to useful heat and is held in the heat exchanger. This has the desired result that the heat-transfer medium in the heat pipe _- overheated and almost merges with poor thermal conductivity vapor without condensation possibility. As a result, the heat transport to the heat exchanger at the head of the heat pipe is greatly reduced. In principle, it would also be possible to install a second shut-off valve in the bypass line, which in turn opens or closes the bypass line. However, such an arrangement requires additional control effort.

It is also necessary to install a bypass line (14) and a shut-off valve (12) in the supply line for fossil heat to the heat pipe (8). However, if you do not use the heat generated by the combustion of fossil fuels through a liquid medium, you can do without it entirely if you use intermittent direct heating. In practice, this is particularly easy to achieve with an appropriately switched oil or gas burner. In this case, one would get by with three heat pipes, namely (5), (6) and (7).

If the respective intended use of the useful heat makes it necessary to be able to remove it continuously, it is necessary either to partially transfer the useful heat in a heat store, for example Glauber's salt heat store, or to use two devices according to the invention in parallel and to take the useful heat out of phase from them. The cycle of such a double system would then run according to the rhythm (1), (1 '), (2), (2'), (1) etc. For the normal heating of a house, however, it is readily acceptable that each after switching over, no useful heat for a certain period of time can be taken, especially if these phases are relatively short without providing useful heat.

The dimensioning of the device according to the invention and the length of the respective phases depends to a considerable extent on the amounts of useful heat required, the amount of environmental heat or waste heat and the investment costs. If the ambient air were to be used, it would certainly make sense to only run one cycle per day, since the warmer day air would then be used. Here, however, the investment costs of the plant and the required amounts of metal hydride would be considerably higher. According to the invention, it is possible and extremely advantageous to make the cycles significantly shorter, for example in 30 minutes to 3 hours, and thereby to significantly reduce the size and investment amount of the system. In theory, it is quite possible to shorten the cycles even more, e.g. B. to 10 minutes, however, this would reduce the investment costs proportionally no longer as much. In addition, the kinetics of hydride formation would have a disruptive effect even with even shorter cycles.

The dimensioning results from the following rough calculation: With a maximum heat requirement per heating day in a single-family house of 100 kWatt, a reaction container should contain at least 3000 kg of metal or metal hydride. If the individual phases are shortened to one hour, the hydride requirement drops to 125 kg per container. With the already mentioned price of about 10 DM per kg, the investment sum under conventional heat pumps is reduced, whereby the higher efficiency and the more problem-free use of environmental heat enable an almost universal use, at least in the latitudes where the outside temperatures rarely fall below -10 ° C decrease.

The method according to the invention and the device according to the invention can be used particularly advantageously where larger amounts of waste heat are available at a relatively low temperature level, for example cooling water or condensates from power plants, steelworks, coking plants, chemical plants etc. These amounts of heat can be transferred relatively easily and with little loss transport longer distances and can be converted according to the invention into useful heat of higher temperature at the respective consumer points. Only in this way is it conceivable, for example, to operate district heating lines at relatively low temperatures and to only extract heat from the desired higher temperature in households or at the consumer points. The device according to the invention is thus used like a heat transformer. In contrast to electrical energy, which can only be transferred over long distances with low losses if the voltage is high, heat can be transported in a line system with low losses if the temperature differences to the surroundings are low.

It is clear from the explanations that there is no need for further differentiation that the heat pump variants according to the invention can also be used for cooling. The absorption heat pump in particular would be suitable for solar cooling, since the upper temperature level for the process control when appropriate metal hydrides are selected is already in the range of the conductivity of non-concentrating solar collectors.

• Figur 1 zeigt schematisch die einfachste Ausführungsform der erfindungsgemäßen Vorrichtung.
• Figur 2 zeigt eine Ausführungsform, bei der zusätzlich nach der Umschaltung ein Wärmeaustausch zwischen den Behältern (1) und (2) durch die Vorrichtung (9) möglich ist sowie gewünschtenfalls noch Wärmeaustauscher (10) vorgesehen sind, welche die Abführung von Nutzwärme geringer Temperatur beispielsweise zum Vorwärmen von Nutzwasser ermöglichen.
• Figur 3 zeigt eine bevorzugte Ausführungsform unter Verwendung von Wärmerohren sowohl für die Zuführung der Umweltwärme als auch zur Abführung der Nutzwärme, bei der aufgrund der Diodenwirkung keine Umschaltungen notwendig sind.
• Figur 4 zeigt eine weitere Ausführungsform unter Verwendung von Wärmerohren, bei der die Druckveränderung thermisch erfolgt.

The principle and preferred embodiments of the device according to the invention are explained in more detail in the following figures.

• Figure 1 shows schematically the simplest embodiment of the device according to the invention.
• Figure 2 shows an embodiment in which, after the switchover, a heat exchange between the containers (1) and (2) by the device (9) is possible and, if desired, heat exchangers (10) are also provided which dissipate useful heat at low temperature, for example enable to preheat industrial water.
• FIG. 3 shows a preferred embodiment using heat pipes both for supplying the environmental heat and for dissipating the useful heat, in which no switchovers are necessary due to the diode effect.
• FIG. 4 shows a further embodiment using heat pipes, in which the pressure change takes place thermally.

• (3) das umschaltbare Rohrleitungssystem für Wasserstoff,
• (4) die ggf. umschaltbare Pumpe für den Wasserstoff,
• (5) und (6) die umschaltbaren Wärmeaustauscher für die Nutzwärme
• (7) und (8) die umschaltbaren Wärmeaustauscher für die Umgebungswärme bzw. Abfallwärme,
• (9) ein Wärmeaustauscher zwischen den beiden Behältern (1) und (2), welcher nach dem Umschalten zum Einsatz kommen kann,
• (10) zusätzlich Wärmeaustauscher zur Abführung von Nutzenergie geringerer Temperatur, beispielsweise zur Vorwärmung von Nutzwasser,
• (11) und (12) Absperrventile,durch die die Abnahme von Nutzwärme bzw. die Zufuhr von fossiler Wärme intermittierend unterbrochen werden kann,
• (13) und (14) bypass-Leitungen für die Abnahme von Nutzwärme bzw. die Zufuhr von fossiler Wärme, die gegebenenfalls durch weitere nicht eingezeichnete Absperrventile im Wechselrhythmus mit den Absperrventilen (11) und (12) geschaltet werden können.

In all figures, (1) and (2) mean the containers filled with metal or metal hydride,

• (3) the switchable piping system for hydrogen,
• (4) the possibly switchable pump for the hydrogen,
• (5) and (6) the switchable heat exchanger for the useful heat
• (7) and (8) the switchable heat exchangers for the ambient heat or waste heat,
• (9) a heat exchanger between the two tanks (1) and (2), which can be used after switching,
• (10) additionally heat exchanger for dissipating useful energy at a lower temperature, for example for preheating useful water,
• (11) and (12) shut-off valves, through which the removal of useful heat or the supply of fossil heat can be interrupted intermittently,
• (13) and (14) bypass lines for the removal of useful heat or the supply of fossil heat, which can be switched alternately with the shut-off valves (11) and (12) if necessary by further shut-off valves (not shown).

Claims (14)

1. A method for the energy-saving production of useful heat from the environment or from waste heat using a reversible chemical reaction, characterized in that two containers connected to one another by lines, which are approximately equally divided with a metal hydride and the hydride-forming metal or the hydride-forming alloy are filled, alternately loaded and unloaded with hydrogen by changing the pressure, thereby dissipating the heat released by the compression and hydride formation by heat exchange as useful heat and replacing the heat used in relaxation and the hydrogen emission of the hydride by heat exchange with the environment or with waste heat. 2. The method according to claim 1, characterized in that a low-temperature hydride is used as the metal hydride and the pressure change is effected mechanically. 3. The method according to claim 1, characterized in that iron-titanium hydride is used as the metal hydride. 4. The method according to claim 1, characterized in that one uses two different metal hydrides and causes the pressure change thermally. 5. The method according to claim 4, characterized in that a titanium-iron-manganese hydride and a titanium-zirconium-chromium-manganese hydride are used as metal hydrides. 6. The method according to claim 1 to 5, characterized in that one carries out the heat exchange with air / air. 7. The method according to claims 1 to 6, characterized in that one carries out the heat exchange by trickling water through a battery of tubes and when switching the heat capacity of the system by trickling with cold fresh water for preheating warm useful water. 8. The method according to claims 1 to 7, characterized in that one carries out the heat exchange for removing the useful heat and / or the heat exchange for supplying the heat to the environment or the waste heat with heat pipes (heat pipcs). 9. The method according to claims 1 to 8, characterized in that two systems of the same size are connected in parallel and out of phase for the removal of useful heat. 10. Device for carrying out the method according to claims 1 to 3 consisting of two approximately equal containers (1), (2), each filled with about half metal hydride and the hydride-forming metal or the hydride-forming alloy, a switchable piping system (3) with a suction / pressure pump (4), mutually switchable heat exchangers (5), (6) for the dissipation of the useful heat and mutually switchable heat exchangers (7), (8) for the supply of heat to the environment or the waste heat. 11. Device for performing the method according to claims 4 and 5 consisting of two containers (1), (2), each filled with about half of metal hydride and the hydride-forming metal of two different metal hydrides, a connecting tube (3), mutually switchable heat exchangers (5 ), (6), for the dissipation of the useful heat and mutually switchable heat exchangers (7), (8) for the supply of heat to the environment or waste heat or the fossil heat as well as lines (13), (14) and switchable shut-off valves (11 ), (12). 12. The device according to claims 10 or 11, characterized in that the switchable heat exchanger (5), (6) and / or the switchable heat exchanger (7), (8) are replaced by heat pipes. 13. The apparatus according to claim 11, characterized in that the switchable heat exchanger (5), (6) and (7) are replaced by heat pipes and the heat exchanger (8) along with line (14) and shut-off valve (12) replaced by an intermittent direct heating is. 14. Device according to claims 10 to 13, characterized in that two systems of almost the same size are connected next to one another out of phase for dissipating the useful heat.

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