AT510685A4 - HEAT STORAGE DEVICE - Google Patents

Abstract

The invention relates to a heat storage device (1), in particular for a heating and / or service water system, with at least a first and a second memory (2, 3) for a liquid heat carrier, which memory (2, 3) arranged over several at different heights Connecting lines (4, 5, 6) are flow-connected to each other, wherein each connecting line (4, 5, 6) has a first end (4a, 5a, 6a) in the region of the first memory (2) and a second end (4b, 5b, 6b ) in the region of the second memory (3), and at least one first connecting line (4) in a lower region (7), at least one second connecting line (5) in a central region (8) and a third connecting conduit (6) in one the upper region (9) of the memory (2, 3) is arranged, and wherein the heat carrier in the first memory (2) by at least one heating device (10) is heated. In order to achieve a usable temperature level as quickly as possible, it is provided that the flow through the second connecting line (5) is temperature-dependent controllable via at least one first valve (13).

Description

15369

The invention relates to a heat storage device, in particular for a heating and / or process water system, with at least a first and a second memory for a liquid heat carrier, which memory are flow-connected to each other via a plurality of arranged at different heights connecting lines, wherein each connecting line has a first end in the area of the first memory and a second end in the region of the second memory, and at least a first connecting line in a lower region, at least a second connecting line in a central region and a third connecting line in an upper region of the memory is arranged, and wherein the heat carrier in first memory can be heated by at least one heating device. Furthermore, the invention relates to a method for operating this heat storage device.

From DE 44 18 737 Al an arrangement for hot water treatment with multiple storage for receiving water or other heat medium is known, wherein a first memory for heating its contents has a connection to a solar system. Within the first store, a storage tank for heated service water is arranged, which can be supplied separately from the rest of the storage contents and drained.

The system is connected to the flow and return of the radiator of a heating system and further has a flow-connected to the first memory second memory. Between the two accumulators, a plurality of connecting conduits, specifically an upper, a middle and a lower connecting conduit, are arranged, which interconnect the accumulators at different levels in order to allow a water exchange within a plurality of temperature layers between the accumulators. The upper connecting line has a check valve, which allows a flow from the second into the first memory and blocks the connecting line in the case of a flow from the first to the second memory. Heat is introduced into the first storage tank. Due to the resulting difference in density, water from the cooler second memory is forced through the lower connecting line into the first store, with a return flow via the central connecting line into the second store. As soon as a higher temperature is present in the first reservoir at the level of the central connecting line than in the second reservoir, water flows from the first reservoir into the second reservoir. There, the warmer water rises due to the lower density upwards and mixes with the upper layers in the second memory. If, for example, removal of hot process water causes the first store to cool down, cooler water from the first store into the second store and, as compensation, hot water via the upper line through the opening check valve from the second store are produced via the middle line pressed into the first memory. The disadvantage is that even at low temperature differences, a gravity circulation takes place, so that heat flows off early from the first memory into the second memory and thus the heating process of the first memory takes comparatively much time. The parallel loading and unloading of both stores results in relatively high radiation losses.

The object of the invention is to avoid these disadvantages and to achieve a usable temperature level as quickly as possible in a heat storage device with multiple storage.

According to the invention this is achieved in that the flow through the second connecting line via at least one first valve is temperature-dependent controllable, wherein preferably the first valve is formed by a thermostatic valve.

The first valve may be arranged in the region of the first end of the second connecting line. 2

The first valve has a temperature-dependent switching range between a closed position and an open position in the range of a defined threshold temperature, wherein preferably the Schwelitemperatur between about 40 ° C and about 60 ° C, preferably between about 45 ° C and 55 ° C.

Characterized in that only from a defined threshold temperature, the flow connection is released in the second connection line, a rapid warming of the first memory, and thus an early use of a high temperature level of the heat carrier is possible.

In order to enable a good gravity circulation when the first valve is open, it is advantageous if the second end of the second connecting line is arranged higher than the first end.

In a particularly preferred embodiment of the invention it is provided that in the third connecting line from the second memory to the first memory-promoting pump and / or at least one check valve and / or a control valve is arranged.

For warming up the heat carrier, at least one heat exchanger is advantageously arranged in the first storage, the supply and return of which can preferably be connected to a solar collector.

To use the heat, for example in a heating system, the heat storage device may have at least one plant supply line and at least one system return line, preferably the plant supply line emanating from the upper portion of the first memory and particularly preferably the system return line is guided to the lower portion of the second memory.

The inventive method for operating the heat storage device provides that the flow through the second 3

Connection line is temperature-dependent controlled, preferably the flow through the second connection line is closed below a defined threshold temperature and above the defined threshold temperature for loading the second memory is opened. The threshold temperature may be defined between about 40 ° C and about 60 ° C, preferably between about 45 ° C and 55 ° C.

As a result, a usable temperature level is available in a very short time. Since the second memory does not have to be heated in this first step, there are only small radiation losses.

The heat carrier of the first accumulator is preferably heated via at least one heat exchanger, wherein particularly preferably the heat exchanger is connected to at least one solar collector.

The heated heat carrier can be removed via a feed line from an upper region of the first memory. Via a return line, the cooled heat carrier can be returned to a lower region of at least one reservoir, preferably the second reservoir.

As soon as a reference temperature of the first store drops below a reference temperature of the second store, the heat carrier is pumped via the third connecting line from the second store to the first store, wherein the reference temperatures are measured in reference areas of the first and second store.

The invention will be explained in more detail below with reference to the figure

The figure shows schematically a heat storage device 1 for a heating and / or service water system with a first storage 2 and a second storage 3 for a liquid heat carrier. The memories 2, 3 are flow-connected to one another via a plurality of connecting lines 4, 5, 6 arranged at different heights. Each connecting line 4, 5, 6 has a first end 4a, 5a, 6a in the region of FIG

first memory 2 and a second end 4b, 5b, 6b in the region of the second memory 3. A first connecting line 4 is arranged in the lower region 7, for example in the lower third, the memory 2, 3.

A second connecting line 5 is positioned in the central region 8, for example in the middle third of the reservoirs 2, 3. The third connecting line 6 is located in the upper region 9, for example, in the upper third of the reservoirs 2, 3. The heat carrier in the first reservoir 2 can be heated by at least one heating device 10 formed, for example, by heat exchangers 11, 12. Flow 11a, 12a and return 11b, 12b of the heat exchanger 11, 12 may be connected to a solar collector, not shown.

The flow through the second connecting line 5 can be controlled or regulated as a function of temperature via at least one first valve 13. A particularly simple automatic control results when the first valve 13 is formed by a thermostatic valve.

In the third connecting line 6, a pump 14 and at least one example designed as a check valve second valve 15 is arranged. Reference symbol 16 designates further valves in the third connecting line 6. Heat is only introduced into the first storage 2 via the heat exchangers 11, 12 formed, for example, by solar registers. The first valve 13 in the second connecting line 5 initially remains closed - thus, only a relatively small amount of water of the first accumulator 2 has to be heated. As a result, a usable temperature level is available in a very short time. Since the second memory 3 does not have to be heated in this first step, there are only small radiation losses.

Thus, the first memory 2 is charged approximately halfway to a sufficiently high temperature level. If more energy is available, the connection will be made to the lower solar register and the first memory will be stored in the 5 * · · · · · · · · »» »» »» »• • • • • • • • 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 9 9 9 9 4 Λ 4 4 9 4 4 9 9 4 4 9 ♦ · Μ ·· * · V «·· ·· * * lower area 7. If the temperature in the region of the first end 5a of the second connecting line 5 exceeds the threshold temperature for opening the first valve 13, the gravitational charge in the second accumulator 3 is released.

As soon as the temperature in the region of the second connecting line 5 of the first accumulator 2 exceeds the defined threshold temperature of the first valve 13, for example 45 ° C., the first valve 13 thus opens. The second accumulator 3 is charged completely without auxiliary energy via the thermal buoyancy. The lower portion 7 of the first memory 2 remains free until full charge for a possible further, for example solar, heat input.

This loading function thus offers a three-stage buffer loading (three-zone stratified charge). The great advantage is that in the respective zone of the buffer memory a very good temperature stratification is achieved and that the memory 2, 3 are loaded in three stages. Thus, the respective temperature zone in the memory 2 is raised to an exploitable temperature level even at low solar yield.

If sufficient heat energy is supplied, for example via a boiler and / or solar collectors, then finally both stores 2, 3 are completely charged with thermal energy.

During the discharge of the heat storage device 1, the heat energy is removed from the first storage 2 with priority. The removal of the liquid heat carrier via the plant supply line 17 is carried out in the upper region 9 of the first memory 2, while 7 flows cooler cooler on the first connecting line 4 in the lower region of the second memory 3. The system return line 18 opens in the lower area 7 of the second memory 3 a. This causes a cooling of the lower portion 7 of the first memory 2, which thus quickly available again for an additional, for example, solar heat input 6

stands. Thus, an optimal temperature stratification in both memories 2, 3 takes place permanently. A forced flow through the second memory 3 - as would be the case with a serial connection of the two memories 2, 3 - is avoided.

If a reference temperature measured in a reference region of the first memory 2 in the first memory 2 drops below a reference temperature of the second memory 3 measured in a corresponding reference region of the second memory 3, the heat from the second memory 3 is transferred to the first memory 2 by activating the pump 14 the third connecting line 6 and conveying the heat carrier from the second memory 3 in the first memory 2 rearranged. Thus, an optimal temperature stratification is maintained in both memories 2, 3.

The heat storage device 1 described and the method for operating the heat storage device 1 combines the advantages of parallel and serial loading and unloading and minimizes their disadvantages. Since only one store 2 in the upper area 9 is charged with heat energy in the heating phase, the amount of water that has to be additionally heated is very low (for example 50 to 70 l). As a result, a heating system is very quickly enough energy at a high temperature level available. The fact that during the discharge phase of the second memory 3 is not - as in a series circuit - forced flows, the temperature in the second memory 3 is not affected by the system return 18. 7

Claims (16)

♦ · ················································································································································································································································································· for a liquid heat carrier, soft stores (2, 3) are connected to each other in flow communication via a plurality of connecting lines (4, 5, 6) arranged at different heights, each connecting line (4, 5, 6) having a first end (4a, 5a, 6a) in the area of the first memory (2) and a second end (4b, 5b, 6b) in the region of the second memory (3), and at least one first connecting line (4) in a lower area (7), at least one second connecting line ( 5) in a central region (8) and a third connecting line (6) in an upper region (9) of the memory (2, 3) is arranged, and wherein the heat carrier in the first memory (2) by at least one heating device (10) is heated, characterized in that d he flow through the second connecting line (5) via at least one first valve (13) is temperature-dependent controllable. 2. Heat storage device (1) according to claim 1, characterized in that the first valve (13) is formed by a thermostatic valve. 3. Heat storage device (1) according to claim 1, characterized in that the first valve (13) has a temperature-dependent switching range between a Schiießstellung and an open position in the range of a defined threshold temperature, wherein preferably the threshold temperature between about 40 ° C and about 60 ° C. , preferably between about 45 ° C and 55 ° C. 4. Heat storage device (1) according to one of claims 1 to 3, characterized in that the first valve (13) in the region of the first end (5a) of the second connecting line (5) is arranged. 8th 5. Heat storage device (1) according to one of claims 1 to 4, characterized in that the second end (5b) of the second connecting line (5) is arranged higher than the first end (5a). 6. heat storage device (1) according to one of claims 1 to 5, characterized in that in the third connecting line (6) from the second memory (3) to the first memory (2) conveying pump (14) is arranged. 7. Heat storage device (1) according to one of claims 1 to 6, characterized in that in the third connecting line (6) at least one in the direction of the first memory (2) opening check valve (15) and / or at least one control valve is arranged. 8. heat storage device (1) according to one of claims 1 to 7, characterized in that in the first memory (2) at least one heat exchanger (11, 12) is arranged, the supply and return (11a, 11b, 12a, 12b) preferably can be connected to a solar collector. 9. heat storage device (1) according to one of claims 1 to 8, characterized in that the heat storage device (1) at least one plant supply line (17) and at least one system return line (18), wherein preferably the plant supply line (17) from the upper region (9 ) of the first memory (2) emanates and particularly preferably the system return line (18) to the lower portion (7) of the second memory (3) is guided. 10. A method for operating a heat storage device (1), in particular for a heating and / or process water system, with at least a first and a second memory (2, 3) for a liquid heat carrier, which over several in different 9 ·· »f # · ♦ Height-arranged connecting lines (4, 5, 6) are flow-connected to each other, wherein each connection line (4, 5, 6) has a first end (4a, 5a, 6a) in the region of the first memory (2) and a second end (4b, 5b , 6b) in the region of the second memory (3), and at least one first connecting line (4) in a lower region (7), at least one second connecting line (5) in a central region (8) and a third connecting line (6) In an upper region (9) of the memory (2, 3) is arranged, and wherein the heat carrier in the first memory (2) by at least one Helzeinrichtung (10) is heated, characterized in that the flow through the second connecting line (5) is temperature-dependent controlled. 11. The method according to claim 10, characterized in that the flow through the second connecting line (5) is closed below a defined threshold temperature and above the defined threshold temperature for loading the second memory (3) is opened. 12. The method according to claim 11, characterized in that the Schwelitemperatur between about 40 ° C and about 60 ° C, preferably between about 45 ° C and 55 ° C is defined. 13. The method according to claim 11 or 12, characterized in that the heat carrier of the first memory (2) via preferably at least one heat exchanger (11, 12) is heated, wherein particularly preferably the heat exchanger (11, 12) is connected to at least one solar collector , 14. The method according to any one of claims 11 to 13, characterized in that via a plant supply line (17) of the heated heat carrier from an upper region (9) of the first memory (2) is removed. 10 15, Method according to one of claims 11 to 14, characterized in that via a system Rückieieitung (18) of the cooled heat transfer medium in a lower portion (7) at least one memory (3), preferably the second memory (3), is returned. 16. The method according to any one of claims 11 to 15, characterized in that the heat transfer medium via the third connecting line (6) from the second memory (3) in the first memory (2) is pumped when a reference temperature of the first memory (2) below a reference temperature of the second memory (3) decreases, the reference temperatures being measured in reference areas of the first and second memories (2, 3). 2011 03 01 Fu Paferttariwait ^ DipUng, Mag. Michael Babeluk A-1150 Vienna, Mariahilfer «tartel 19/17 m; M31) Often 31-0 Fa «(+431) Ml M 4M« Η · 4 · Ηκ »μ · Ιη · ^ ι · * 11