FI83135B - Method for charging and discharging heat energy from storage water heaters - Google Patents

Description

1 83135

METHOD OF CHARGING AND DISCHARGING HEAT ENERGY IN RESERVE WATER HEATERS - FÖRFARANDE FÖR ATT LADDA OCH URLADDA VÄRME-ENERGI FRAN ACKUMULERANDEN WATTENVÄRMAREN

The invention relates to a method by means of which large amounts of thermal energy can be stored in a small space, the storage can be loaded and, in particular, the heat storage can be unloaded by a new self-adjusting method.

10 Domestic hot water is usually stored in pressure-resistant hot water tanks. This solution is widespread, especially when water is heated by electricity. The tank is needed to balance consumption and heating output. In detached houses, which are typical applications for water heaters, in order to reduce the electrical power required for water heating, it is almost necessary to use a tank of a certain size to equalize the water consumption peak and at the same time the heating power peak. In addition, in connection with night electric heating, domestic hot water accumulators are used, which are dimensioned in such a volume that their amount of water is generally sufficient during daytime use and the tank water is heated at night during a more favorable electricity tariff. Domestic water heaters are also generally heated by gas, heat pumps and, to some extent, solar and wind energy.

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The water-containing accumulators described above have several drawbacks. The space required by the accumulator is rather large, because the thermal energy is stored in water, which must be as much as the desired capacity of the tank. In addition, the water tank must have a pressure-resistant and non-corrosive structure. Typical domestic hot water tanks have a volume of 100 to 500 liters and are heated by electric heaters or heating elements located close to the bottom of the storage tank. Domestic water is taken from the tank through a pipe connection 35 located close to its top and the cold water entering it is led to the bottom of the tank. The hot water to be used with this typical solution is always old standing water in the tank and due to the absence of 2 83135 for a few days when the water is not used, the whole tank is full of old standing water. An electrically heated domestic hot water tank is fitted with a heating element or an electric heater at the bottom of the tank. However, the heating element or resistor cannot be installed so low on the bottom of the tank that about 10% of the water volume of the tank is below the element or resistance, so that this portion of water does not reach the regulated temperature of at least + 55 ° C due to water deposition properties. The water remaining at the bottom of the tank at a temperature of about + 15 ° -10 + 45 ° C is very advantageous for the bacterial population in the water, which increases the quality of the water even more the longer the water tank is not used. In addition, a tank with a large amount of water still has the disadvantage of a long time, which takes a long time to obtain water of satisfactory temperature, if the tank has been able to drain all its hot water due to the use of a large amount of water.

The solution according to the invention avoids the above-mentioned drawbacks and these features of the invention are set out in the claims of patent-20. The storage water heater according to the invention is constructed in such a way that the heat energy accumulator is not water but a mass capable of storing a corresponding amount of heat energy of a suitable preferred material, e.g. zinc. If zinc is used to store thermal energy and the maximum temperature of the storage mass is raised to + 450 ° C, then a conventional 200 liter water heater is equivalent to 160 kg of zinc with a volume of only 20 liters. The material of the thermal energy storage must have such properties that it can be heated with electric resistors preferably to a temperature of up to -30 ° C and that the temperature is raised above the melting point of the material, whereby the melting heat can also be used for energy storage. In the solution according to the invention, a heat exchanger is placed above the thermal energy storage, which is, for example, a double pipe structure. The cold incoming water heats up in the above-mentioned heat exchanger after passing through it very quickly when hot water is needed. The heat energy is fed to the heat exchanger in the solution according to the invention. a 83135 1 i

from the thermal energy storage using the heat pipe principle

I do not. In this solution, the hermetically sealed piping passes from the thermal energy storage to the heat exchanger above and the heat is transferred very efficiently in the pipe upwards by means of the intermediate. The properties of the medium used in the heat pipe must be such that it is both a liquid and a gas in the heat pipe at least in the temperature range 0 <> - +100 <> C.

In this case, energy is transferred from the storage to the heat exchanger so that the medium evaporates at the heat energy storage temperature and rises as steam to the heat exchanger and condenses there into a liquid and flows back into the heat storage, where heat transfer is efficient if hot water is desired. However, the temperature of the energy storage must then be always higher than the required hot water temperature.

15 Since it is advantageous to raise the temperature of the energy storage to very high up to +450 <> c and the hot water heater would not be allowed to heat the hot water above +120 <> c, the heat transfer efficiency of the heat pipe is limited in the solution according to the invention substance / with a critical temperature below + 120 ° C. At and above the critical temperature, the heat pipe principle ceases to operate because the density of the medium as liquid and gas becomes the same and the heat transfer from the bottom up in the heat pipe then decisively decreases. In this case, in a stable situation 5, the temperature of the low-lying thermal energy storage can be e.g. + 450 ° C, whereby the medium in the heat pipe leaving the storage upwards is above the critical temperature and pressure, but no upward flow of said medium takes place. The heat exchanger depends on the loss power and insulation at a temperature of only about +120 <> C. However, if the heat transfer in this case becomes harmfully high from the heat energy storage to the heat exchanger / so that the temperature of the heat exchanger I

la rises above +120 <> C / the heat pipe can be equipped with flow shut-off valves placed in the thermal energy storage and; 5 to the pipe sections between the heat exchanger. The valves may be thermostatic flow control valves.

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When it is then desired to take hot hot water, the temperature of the heat exchanger drops immediately below the critical temperature of the medium and the heat pipe principle begins to operate efficiently and tends to keep the temperature of the heat exchanger close to the critical temperature of the medium. One preferred medium is the refrigerant R 12 used in the refrigeration technology for the solution according to the invention.

The invention will now be described in more detail with reference to an embodiment shown in the accompanying drawing, in which Figure 1 shows a storage water heater according to the invention with a thermal energy storage, a heat pipe and a heat exchanger.

At the bottom of the charging water heater (1), a heat-storing zinc mass (4) in the tank (3), which is heated by an electric resistor (2), is placed. Due to the high temperatures, the zinc mass (4) is well insulated with the insulating material (5). At the top of the charging water heater there is a heat exchanger (6) into which the cold water comes from direction C and the hot water leaves in direction D. The inner tube of the heat exchanger (6) is a part (8) of the heat pipe (7). The heat pipe is evacuated and then filled with a suitable amount of refrigerant R 12 and hermetically sealed.

The electric resistor (2) is controlled so as to tend to keep the temperature of the charging zinc mass at a controlled maximum value, which may be slightly above +419 <> C, which is the melting temperature of zinc. In the case where hot water is taken in via the heat exchanger (6), the temperature of the heating pipe part (8) also drops well below the critical temperature of the medium and immediately causes the medium 35 in the pipe section (8) to condense and transfer heat from the medium to the heat exchanger. . The medium condensed from the pipe section (8) flows through the direction B into the heat pipe part (9) in the thermal energy storage (4), where it evaporates again due to the higher temperature and flows back to the heat exchanger via the direction λ.

83135 A circulation process by means of a medium is created in the heat pipe (7), in which the heat energy storage (4) transfers heat to the heat exchanger (6). The circulation process continues as long as cold water flows into the heat exchanger, causing the medium 5 to condense in the heat pipe section (8), or until the temperature of the thermal energy storage has dropped close to the temperature of the cold water entering the heat exchanger (6).

When the flow of cold water to the heat exchanger is stopped, the flow and circulation of the medium in the heat pipe continues until the heat exchanger temperature has risen close to the critical temperature of the medium, whereby the medium circulation in the heat pipe stops almost completely because the density of the medium as liquid and gas is the same. down through the direction B of the heat pipe (7) to the pipe end (9) ends. Thereafter, a supercritical state is reached at each point in the heat pipe if the temperature of the thermal energy storage is in the most efficient operating range, i.e. between + 130 ° and + 450 ° C. In this case too, heat transfer from the storage (4) to the heat exchanger (6) takes place, which is not desirable. Heat transfer occurs in part through conduction along the heat pipe and in part through the transport of supercritical medium, which movement is caused by the temperature difference of the supercritical medium between parts (8) and (9) of the heat pipe. In the case shown, when no hot water is taken in, the temperature of the heat exchanger may become harmfully high due to the natural convection of the medium in the heat pipe and the conduction through the pipe wall of the heat pipe. To overcome this drawback, the heat pipe is equipped with thermostatic control valves (10) and (11), which operate in such a way that their valves close when the heat exchanger (6) has reached a temperature of e.g. + 120 ° C and prevent heat transfer through between the heat pipe parts (8) and (9). Valves (10) and 35 (11) open respectively when the heat exchanger temperature drops below + 120 ° C.

In particular, it should be noted that the method according to the invention can also be used to heat air. In this case, air is blown through the heat exchanger 6 83135 instead of water, and the device acts as a storage air heating device, such as a room heater. The charging mass can also be placed separately from the heat exchanger at a distance of several meters, whereby they are connected to each other by 5 heat pipes. The invention may, of course, be modified in other ways within the scope of the inventive idea defined by the following claims.

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Claims (3)

7 83135 A method for charging and discharging thermal energy in storage water heaters or heat accumulators, comprising a container (3) containing a storage substance (4) insulated with an insulating material (5), said substance being heated by a heating element (2) to a temperature of at least + 3000C and discharging thermal energy 3) for the heat exchanger (6) at a substantially lower temperature, the heat pipe (7) is characterized in that a heat transfer medium is used in the heat pipe (7), the critical temperature of which is at most the highest desired temperature of the heat exchanger (6). when the heat exchanger reaches a critical temperature of said medium. 2. A patent according to claim 1 for the preparation and extraction of energy-energy fractions, the color transfer (7) being provided with a fan (10) and (11), which comprises a color transfer genome. Method for charging and discharging thermal energy according to Claim 1, characterized in that the heat pipe (7) is provided with valves (10) and (11) which limit the transfer of heat along the heat pipe. Method for staining and discharging thermal energy according to Claim 1 or 2, characterized in that the thermal energy is transferred from the tank (3) via a heat pipe (7) to a heat exchanger (6) located above the tank. β 83135 For the purpose of charging and discharging the color of a battery, including the color of the battery (5), the color of the battery (3), the color of the battery (4) element (2) up to a temperature of + 300 ° C and a temperature of the energy of the energy (3) up to a temperature of 6 °, with a minimum temperature, the temperature of the color (7) 7) användes ett värmeväxlingsmedium, vars Kritis-ka temperatur är högst samma som den högsta ommade tempera-turen av värmeväxlaren (6) för att väsentligt stoppa eller gränsa enlig värmerörprincipen händande värmeväxling när värmeväxlaren uppenär temperpurär 3. A patent according to claim 1 or 2 for the use and application of the color energy to the energy, the color energy (3) of the genome and the color (7) account for the energy of the color (6). I: