DE9419506U1 - Heat storage furnace - Google Patents

Description

Olsberg Hermann Everken GmbH Hüttenstrasse 38

59939 Olsberg

Utility model application: Heat storage stove heated with solid fuels

Description

The invention relates to a heat storage stove operated with fossil fuels, in particular a tiled stove with heat storage, according to the preamble of claim 1.

It is known that the fuels burned in stoves with the formation of flames release a great deal of heat for a short time. In order to have energy available for heating purposes in the long term, storage media in the form of firebricks, stove tiles and the like are installed downstream of the stove's combustion chamber, to which some of the heat contained in the heating gases is transferred. The mild heat emitted by a tiled stove conveys a sense of comfort that is only typical for this type of heating and, together with the element of fire, also gives it that certain something when operating it. Tiled stoves heated with solid fuels are becoming increasingly popular again today, and not just because of the increasing price of heating oil and heating gas. Depending on the room to be heated, the tiled stoves are designed in terms of their design, size, etc. for one or more living rooms or for an entire floor.

The disadvantage of traditionally manufactured tiled stoves with good efficiency is that only experienced specialists can build such systems, with considerable time and effort spent on manual work, and that these stoves are unsuitable for quick heating. The portable ready-made tiled stoves that have come onto the market in recent years, on the other hand, heat up more quickly, but have the disadvantage that they have practically no significant heat storage capacity.

Measures to improve heat storage in portable ovens are described in DE-GM 87 16 439 and DE-OS 31 19 443, among others. The design of a wood-burning oven for better heat storage and short heating times !honors DE-GM 83 30 437 ! All ovens

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However, these types have the disadvantage that they only store a relatively small amount of heat and that the release of this heat cannot be influenced.

DE-OS 27 07 825, on the other hand, already makes suggestions for the use of a separate and larger heat storage unit. This is supplied with air from an air stream heated at the exhaust pipe and conveyed by a fan. On its way through the heat storage unit, the air gives off its heat to the mass of the same before it is fed to the furnace _{or exhaust} pipe for reheating. The temperature, speed of the warm air circuit and the fan speed as well as the exhaust gas data are linked via control elements. :*■···· If the room is to be heated after firing has finished, various flaps can be opened so that the air can circulate through the room and the storage mass, with the storage unit giving off heat and conveying it to the room.

The disadvantage here, however, is that this design is unsuitable for rapid heating because it only works according to the principle of natural convection with warm air outlet at the top. In addition, flaps must be opened for the heat to be released from the heat storage unit to the room, through which the air that was previously only present in the system's inner circuit reaches the room to be heated. From the room, however, the air to be heated is sucked in by the fan via previously opened flaps and conveyed through the heat storage unit. The air paths in the device are therefore significantly wider than, for example, with an electric storage heater. Due to the separate installation of the stove and heat storage unit, there are also high line losses and no use of the radiant heat for the benefit of the heat storage unit.

The aim of the invention is to create a heat storage stove of the type mentioned at the beginning, which does not have the disadvantages mentioned above and in particular enables a controlled release of the large amount of heat that is generated briefly during spontaneous combustion, the so-called heating fire. This should preferably be done taking into account the advantages known from the tiled stove, but without having to forego the conveniences of a modern central or electric storage heating system with regard to the provision of heat. Finally, taking into account the ever increasing use of low-energy building technology, the heating system according to the invention should preferably also meet the requirements of the new thermal insulation regulations in order to be used as a full heating system during the entire heating period.

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To solve this problem, the invention provides for a heat storage furnace of the type mentioned at the outset to have thermal insulation between the combustion chamber and the heat radiating surfaces and for the transfer of the thermal energy generated during combustion to the heat radiating surfaces to be controllable, preferably both when charging and discharging the heat storage device.

This design allows the amount of heat released by the heat storage heater into the surrounding room to be adjusted to meet the respective needs. The amount of heat stored in the heat storage unit can be released quickly or slowly, or at specific times. It is also possible to set whether heat energy should be stored primarily or whether the room should be heated quickly first while heating up, i.e. while charging the heat storage unit.

A basic idea of the invention is to largely separate the combustion chamber thermally from the heat radiation surfaces in order to be able to supply the desired amount of heat to each of them in a controlled manner, i.e. to release the heat once generated in a controlled manner to the room to be heated. The high heating output that inevitably arises with low-emission combustion can thus be used sensibly.

The transfer of heat energy to the heat radiating surfaces is preferably carried out by means of a controllable heat carrier flow, in particular an air flow. By means of such a controllable air flow, the desired amount of heat is transferred, preferably with the support of a fan, from the heat storage unit to the heat radiating surface, for example the tiled walls of a tiled stove, and from there radiated into the surrounding room.

According to one embodiment of the invention, the heat accumulator at least partially surrounds the combustion chamber and is thermally connected to it. In this way, the radiant heat from the combustion chamber can be advantageously utilized. At the same time, the combustion chamber is thermally insulated from the heat-radiating surfaces. For this purpose, the heat accumulator can also be provided with external thermal insulation.

According to a further embodiment of the invention, a heat exchanger is arranged outside the combustion chamber in the area of the exhaust gas flow, through which heat energy can be extracted from the exhaust gas flow. The

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Thermal energy is preferably supplied to the heat storage unit by an air flow that passes through the heat exchanger, in particular with the help of a fan, and the air flow is then returned to the heat exchanger. In this way, the heat storage unit can be charged both by the radiant heat of the combustion chamber and by the exhaust heat absorbed in the heat exchanger. *·*·

The control of the charging of the heat storage tank is preferably carried out by a central control unit, e.g. with three temperature sensors for exhaust gas temperature, heating gas temperature and storage tank temperature. The heat release from the heat storage tank to the room is preferably controlled by a room thermostat and takes place via a three-way slide valve. In direct heating mode, the heat exchanger air flow is not or not only directed via the storage tank, but directly to the tiled walls. The heat is guided from the circulating air circuit via channels behind the tiled surface. The tiles thus absorb the heat energy from the circuit and release it via their outer surfaces into the living space mainly as radiant heat.

These designs have the advantage that the heat storage device, preferably a solid storage device, absorbs the stored heat in a way that is regulated by the exhaust gas temperature and releases it in a way that is regulated by the room temperature. Bulk material as a solid storage device, in particular a spherical bed, has a particularly favorable charging and discharging behavior.

Further advantageous embodiments of the invention are set out in the subclaims.

The advantages of this design include the fact that the heat storage unit practically encloses the heating element and is thus optimally positioned in terms of its size and for absorbing the radiant heat, that the heat storage unit is also charged by a separately circulating heat exchanger air circuit, and that the discharge is controlled, for example, by a room thermostat and takes place via a separately circulating air circuit that acts on a tiled wall, which continues to emit pleasant radiant heat into the room for a long time even after the fire has gone out. This means that the long-held wish to retain the tiled stove as a heating system for the future and to meet the requirements of modern energy-saving heating systems is met.

An embodiment of the invention is described below with reference to the drawing, in which:

Figure 1 shows a heat storage furnace according to the invention in schematic,

partially cut representation
Figure 2 is a view of the front of the heating element in the direction of arrow A in Figure 1, as a section along the line EF in

Figure 1
Figure 3 is a side view of Figure 2 according to arrow direction B in Figure 2 as a section

Figure 4 a top view of Figure 2

According to Figures 1 to 4, the heat storage stove (1) essentially consists of the heating insert (2) with the combustion chamber (4), the heat storage (8), heat exchanger (26) and the tiled wall (32). If the stove is arranged in the corner of the room, the room walls (33) replace part of the tiled walls (32). The heating insert (2), which preferably has an adjustable heating output, is fed with solid fuel via the fire door (3), which is provided with a viewing window, for example. The heating energy released briefly when flames are formed is used, among other things, via the front side for direct, rapid heating, while the heat radiation emanating from the side walls and the rear wall acts directly on the heat storage (8). This preferably consists of two side and one rear chamber (10) or (9), which is filled with air-permeable storage material (14), ideally with a spherical bed of defined diameter. The storage material (14) rests on an air-permeable base (13) in the form of a grid or sieve, which is itself mounted on a cover made of thermal insulation material of the air duct (11) provided with openings (12).

The hot combustion gases flow from the heating element (2) into the heating gas pipe (7), then through the heat exchanger (26) and from there to the exhaust pipe (29). After the set exhaust gas temperature has been reached and if it is exceeded, a temperature-dependent controlled fan (30) is switched on, which conveys the thermal energy in the heating gas in an air circuit (18) shown only schematically in Figure 1 via the heat exchanger (26) to the heat storage unit (8).
In addition to the charging from the radiation components, a charging air flow also acts on the storage material (14). The air heated in the heat exchanger (26) with inlet (27) and outlet (28) is conveyed by a fan (30) into the nozzle (5),

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and

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where the air absorbs further heat along its path (18) in the channel (17) from the cover of the heating insert (2), as well as when flowing around the heating gas pipe (7), before it is then fed to the storage material (14), initially from top to bottom within the rear chamber (9). The air blown through the chamber (9) enters the air channel (11) via the floor (13) and the openings (12). From the air channel (11) located at the back, i.e. below the chamber (9), the air flow (18) now splits in such a way that both chambers (10) are evenly supplied, now from bottom to top, in order to achieve heat storage there too. The prerequisite for intensive, optimal heating of the storage material (14) is an appropriate delivery pressure, which is built _up by suitably selected cross-sections in the base (13) depending on the grain size of the storage material (14) and the performance of the fan (30). The cooled air from the charging circuit enters the channel (16) above the chambers (10) and from there through the nozzle (6) again via the fan (30) to the heat exchanger (26), thus closing the circuit of the charging air flow. The heat storage (8) is insulated with thermal insulation (15) in order to be able to access a stored heat reserve over many hours.
The stored heat is called up at the appropriate time via a room thermostat. In this case, the air paths are set to countercurrent operation for discharge via a three-way slide valve (20), so that the air flow (19) shown only schematically in Figure 1 is created by the fan (31) which is now starting up. The air is guided to the chambers (10) via the nozzle (6) and the duct (16). The air (19) flowing through the storage material (14) from above absorbs heat, passes via the floor (13) and the openings (12) into the air duct (11), is brought together below the chamber (9) from both sides and now flows through the chamber (9) from bottom to top. The hottest zone of the heat storage device (8) at the top (the air flow had the highest temperature here during charging!) is passed through last. In this way, the heat flow (19) responsible for heating is given a final heat boost before it is collected in the channel (17) and leaves the heat storage unit through the nozzle (5) to be fed to the tile casing (32) via the shortest route.

The warm air flow now reaches the horizontal distribution channel (21) via the connection (22), from where it can transfer its heat to the tiled wall (32) via individual tile channels (23) installed vertically behind the tiled wall (32). At the upper end, the tile channels (23) open into a horizontal cold air collection channel (24), through which the air within the heating circuit is then fed back to the fan (31) via the outlet connection (25).

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To prevent the warm air flow from releasing heat in an uncontrolled manner, the ducts (21 and 23) towards the inside of the furnace are provided with thermal insulation (36).

If heat is to be supplied to the living space when the stove is being heated up, the stove is operated as "direct heating". The three-way slide valve (20) is switched so that the nozzles (5 and 6) are closed. The warm air flow from the heat exchanger (26) is no longer switched through the heat accumulator (8), but directly onto the tiled walls (32).

If the heat storage heater (1) is to be used as a long-term heat storage device over a whole day, the proportion of heat stored in the storage device is reduced by means of appropriate intermediate insulation (35) between the heating element (2) and the heat storage device (8).

Direct heating reduced accordingly. ·&iacgr;.

In order to separate the hotter charging air flow *««* · (18) when it enters the nozzle (5) or channel (17) from the cooler air flow at channel (16) after the heat has been released in the heat accumulator (8), thermal insulation (34) is provided.

List of reference symbols

1. Heat storage heater 2. Heating insert 3. Fire door of the heating insert 4. Combustion chamber 5. Connection "Heat storage tank inlet" or "Heating circuit ¹ outlet 6. Connection "Heat exchanger output" or "Heating circuit ¹ input 7. Heating gas pipe 8th. Heat storage 9. rear storage chamber 10. side storage chamber 11. Air duct 12. Air duct opening 13. air-permeable floor 14. Storage material! 15. Thermal insulation 16. Channel in the heating insert for cooled air 17. Channel in the heating insert for heated air 18. Airflow during charging 19. Air flow during discharge 20. Three-way valve 21. Warm air distribution duct *** ····* · *
· _&bgr; · · _&bgr; · · · · ·«· · · ···
*· · · ····»

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22. Inlet nozzle to the warm air distribution duct!

23. Tile channel

24. Cold air collection duct

25. Outlet nozzle to the cold air collection duct

26. Heat exchanger

S *

27. Heat exchanger inlet .**♦%

28. Heat exchanger outlet *«·«**

29. Exhaust pipe ,"***.

30. Fan for charging

31. Fan for discharge ·

32. Tiled wall .»

33. Room wall l**lll

34. Thermal insulation between warm and cold air flow %,* !

35. Intermediate insulation

36. Thermal insulation for tiled walls

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Claims (20)

SF/br-VG 94-1507 Protection claims %·§·* 1. Heat storage furnace (1) for heating rooms with a combustion chamber (4), with a heat accumulator (8) for storing heat energy generated during combustion, and with heat radiation surfaces (32) for the targeted distribution of heat to the room to be heated, characterized in that there is thermal insulation between the combustion chamber (4) and the heat radiation surfaces (32) and that the transfer of the heat energy generated during the combustion of fuel in the combustion chamber (4) to the heat radiation surfaces (32) is controllable, preferably both when charging and discharging the heat accumulator (8). 2. Heat storage furnace according to claim 1, characterized in that the desired amount of heat energy is transferred to the heat radiation surfaces (32) by means of a controllable heat carrier flow (19), in particular an air flow. 3. Heat storage furnace according to claim 2, characterized in that the heat carrier flow (19) forms a closed circuit which in particular is not in contact with the air of the room to be heated. 4. Heat storage furnace according to one of claims 1 to 3, characterized in that the heat radiation surfaces (32) at least partially surround the combustion chamber (4). 5. Heat storage oven according to one of the preceding claims, characterized in that the heat accumulator (8) at least partially surrounds the combustion chamber (4) and is thermally connected thereto."**. is bound. "«···* 6. Heat storage oven according to claim 5, characterized in that the heat storage device (8) has a thermal insulation (15) on its outside. 7. Heat storage furnace according to claim 5 or 6, characterized in that the heat storage device (8) is flowed through by the heat carrier flow (18, 19), in particular air flow. 8. Heat storage furnace according to claim 7, characterized in that air-permeable bulk material is used as storage material (14), which is stored on an air-permeable base (13). 9. Heat storage furnace according to claim 7 or 8, characterized in that the heat storage (8) is U-shaped in cross section and surrounds the combustion chamber (4) on three sides. 10. Heat storage oven according to claim 9, characterized in that the heat storage (8) has air channels (11) and openings (12) on its underside for the targeted guidance of the air flow (18, 19). 11. Heat storage furnace according to claim 10, characterized in that that the air channels (11) and the openings (12) as well as the air permeability of the floor (13) are dimensioned such that a desired delivery pressure of the air flow (18, 19), in particular in conjunction with a fan (30, 31) , is adjustable. *···· 12. Heat storage furnace according to one of the preceding claims, characterized in that as storage material (14) bulk material, in particular in spherical shape is used. 13. Heat storage furnace according to one of the preceding claims, characterized in that outside the combustion chamber (4) in the area of the exhaust pipe (7) there is a heat exchanger (26) which is preferably thermally insulated towards the outside. 14. Heat storage furnace according to claim 13, characterized in that a heat transfer circuit (18) is guided through the heat exchanger (2 6), which is guided as a charging circuit through the heat storage (8). 15. Heat storage furnace according to claim 13 or 14, characterized in that a heat transfer medium circuit is guided through the heat exchanger (26), which is guided as a direct heating circuit over the radiating surfaces (32). 16. Heat storage furnace according to claim 15, characterized in that the direct heating and charging circuits (18) are connected to one another by the heat exchanger (26) and can be controlled by a common control device in such a way that the heat transfer medium can be supplied optionally to the heat radiating surfaces (32) or through the heat storage device (8) or each 4
which is partially supplied to both. 17. Heat storage oven according to claim 16, 18. Heat storage oven according to one of the preceding claims, characterized ,
that charging and/or discharging circuit (18, 19) and/or
Direct heating circuit can be controlled depending on exhaust gas temperature and/or heating gas temperature and/or room temperature and/or storage temperature. 19. Heat storage furnace according to one of claims 13 to 18,
characterized , that when charging the heat storage device (8), the hot air coming from the heat exchanger (26) first flows through the storage material (14) from top to bottom in the area of the rear wall of the heating insert (2), before the already slightly cooled air flows from bottom to top in the area of the two side walls and finally, after appropriate heat dissipation, is directed back to the heat exchanger (26). 20. Heat storage furnace according to one of the preceding claims, characterized , that the discharge current, preferably opposite to the charging current direction (18), through the heat accumulator (8) and from there into channels behind the heat radiation surfaces (32) and from there back to the heat accumulator
(8) is carried out. • · • a characterized , ··.. that the discharge circuit (19) is also connected to the charging circuit *····* (18) and the direct heating circuit and through .····. • · the same control device can be controlled. ····