DE102015210514A1 - Heating device for heating room air and heating water - Google Patents

Abstract

A heating device (1) for heating room air and heating water, with a heat-generating combustion chamber (2), at least one room air heat exchanger (3) for the transmission of at least a portion of the heat to the room air and at least one heating water heat exchanger (4) for the transmission of at least one Part of the heat to the heating water, wherein at least one heat conduction element (5) for the heat conduction from the combustion chamber (2) to the room air heat exchanger (3) and / or the heating water heat exchanger (4) is provided, characterized in that the heat conduction element (5) as adjustable heat conducting element (5) is formed, which changes the conduction of the heat to the room air heat exchanger (3) and / or the heating water heat exchanger (4) in dependence on its position.

Description

State of the art

From the DE 20 2008 012 914 U1 For example, a heater with a combustion chamber module is known. The heater is used both to heat a surrounding the stove air, for example, a room air in a storage room of the heater, as well as a heating of heating water. Heat, which is generated in the combustion chamber, is transmitted via the structure of the combustion chamber module to the room air and the heating water.

It is an object of the invention to provide an improved heating device.

This object is achieved by means of a heating device according to claim 1. Advantageous embodiments are given in the dependent claims.

Disclosure of the invention

According to the invention, it has been recognized that in an improved heating device for heating room air and heating water with a combustion chamber for generating heat, at least one room air heat exchanger for the transmission of at least a portion of the heat to the room air and at least one heating water heat exchanger for the transmission of at least a portion of the heat at least one heat conduction element for the heat conduction from the combustion chamber to the room air heat exchanger and / or heating water heat exchanger is provided on the heating water, wherein the heat conduction element is designed as an adjustable heat conduction element that changes the conduction of the heat to the room air heat exchanger and / or the heating water heat exchanger depending on its position.

Heaters according to the invention include fireplaces, stoves, tiled stoves, heaters, heaters and other individual room fireplaces, which generate heat in a combustion chamber, for example by burning a solid fuel. At least part of the heat is given by the heater to the surrounding space for heating it, for example to the room air in a set-up room (that is, the room where the heater is installed). This purpose, a room air heat exchanger, which may be the outer surface of the heater, which emits the heat through its surface by radiation and / or convection to the environment. Alternatively or additionally, an air flow can flow through the heater through an air duct system, heat up due to convection and be discharged into the installation room. In addition, the heater is a part of the heat from a heating fluid from, for example, heating water. This purpose is served by a water heat exchanger, for example a heating water heat exchanger through which heating water flows. The heated water can be supplied to a heat supply system, for example to supply a building with heat, or a buffer storage.

For the heat conduction within the heating device from the combustion chamber to the room air heat exchanger and / or heating water heat exchanger, a heat conduction element is provided. The heat-conducting element is designed as an adjustable heat-conducting element which changes the conduction of the heat to the room-air heat exchanger and / or to the heating water heat exchanger as a function of its position. With the heat conduction element, the heat generated in the combustion chamber is forwarded. The change in heat conduction may be described in terms of its effect as a change in heat distribution, as a change in heat flows or as a change in the ratio of heat distribution or flows to at least one or both heat exchangers. The heat is divided in variable proportions to at least one or both heat exchangers. The adjustment of the heat conduction element and accordingly the distribution of heat to the room air heat exchanger on the one hand and the heating water heat exchanger on the other hand can be infinitely or in predetermined levels between the limits of maximum possible air heating and maximum possible water heating, for example, between 100% air heating (0% water heating) and 100% Water heating (0% air heating), done. Other, limited distribution limits are also feasible.

In known from the prior art water-guided heaters there is a fixed distribution of heat flows to the room air on the one hand and to the water on the other. By varying the distribution of the heat transferred to the air or to the water, the heating device can be adapted to different operating conditions. For example, a user of a heater will usually want the fastest possible heating of the heated space. He can achieve this by increasing the amount of heat transferred to the air. At a later time, when the heater has already heated the room, it is advantageous to increase the proportion of heat transferred to the heating water. This can be heated via the heat distribution system and adjacent rooms or the heat buffered in a buffer memory for later use. By dissipating the generated heat to the heating water can also a possible overheating of the installation room by prolonged heating via room air heat exchanger can be avoided.

In one embodiment of the heating device, the change in the heat conduction to the room air heat exchanger and / or to the heating water heat exchanger can be effected by a change in a heat output to the room air and / or the heating water. Thus, for example, a reduction in the heat output to the room air reduce the heat conduction to the room air heat exchanger and increase the heat flow to the heating water. In the absence or reduction of heat to the room air of the room air heat exchanger is no longer or less cooled and he will absorb no or less heat from the combustion chamber. The heat flow to the heating water is thereby increased. Or it can reduce the heat transfer to the heating water, the heat conduction to the heating water heat exchanger and increase the heat flow to the room air. Absent or reduced heat transfer to the heating water, the heating water heat exchanger will not be cooled or cooled any more, and it will absorb no or less heat from the combustion chamber. The heat flow to the room air is thereby increased.

In one embodiment of the heating device, the heat conduction element and / or the room air heat exchanger and / or the heating water heat exchanger on closure elements for inhibiting or throttling a flow with room air and / or heating water. Thus, the heat output to the room air or to the heating water can be changed, which changes due to the distribution of heat on the room air heat exchanger on the one hand and the heating water heat exchanger on the other. As closure elements can serve flaps, valves, valves and the like.

In one embodiment of the heating device, the change in the heat conduction to the room air heat exchanger and / or to the heating water heat exchanger can be effected by a change in a thermal conductivity. The thermal conductivity is changed by adjusting the heat conducting element. In particular, the thermal conductivity is changed relative to the room air heat exchanger and the heating water heat exchanger, which has a variable distribution of heat on the room air heat exchanger on the one hand and the heating water heat exchanger on the other result.

In one embodiment of the heating device, the heat conduction element comprises variously formed partial regions with regard to thermal conductivity. The at least two subregions connect the combustion chamber to the room air heat exchanger and / or the heating water heat exchanger in a heat-conducting manner. By adjusting the heat conduction element then connect different portions of the heat conduction member the room air heat exchanger and / or the heating water heat exchanger with the combustion chamber, whereby the heat from the combustion chamber depending on the thermal conductivity of the currently set (active) section better or less well flow to the room air heat exchanger and / or the Heizungswasserwärmetauscher can. The different thermal conductivities arise, for example, from different structures (such as macroscopic or microscopic geometries) and / or from different materials (materials of different specific thermal conductivities such as steel, aluminum, copper) of the subregions.

The adjustable heat conduction element may be formed in one embodiment of the heater as a displaceable and / or rotatable heat conduction element. By this adjustment, the heat conduction element is moved in translation and / or rotationally with respect to the combustion chamber and adjusted with the effects described above on the heat conduction between the combustion chamber and heat exchangers. A displacement can take place in the form of a pulling out and pushing back of the heat conduction element with respect to adjacent components (combustion chamber, heat exchanger). Twisting can be a rotational movement about an axis of rotation fixed to the combustion chamber. Shifting and twisting can take place in a combined movement (pivoting) or in two or three consecutive movements (turning, pushing, turning) and serve both for adjustment and for securing locking (latching).

The heat-conducting contact between the heat-conducting element and the adjacent components (combustion chamber, heat exchanger) can take place in contact planes in one embodiment of the heating device. Thus, for example, the heat-conducting element can touch the combustion chamber or a first wall bounding the combustion chamber at least in partial regions of a first contact plane. On the other hand, the heat conduction element may contact the room air heat exchanger and / or the heating water heat exchanger or a second wall delimiting the room air heat exchanger and / or the heating water heat exchanger at least in partial areas of a second contact plane. A heat conduction in the first and / or second contact plane is variable depending on the position of the heat conduction element. If the heat conduction element is designed as a displaceable and / or rotatable heat conduction element, then the displacement and / or Twisting in the first and / or second contact plane. As used herein, a plane of contact may be a plane or curved plane or a plane composed of multiple planar or curved sections.

An embodiment of the heating device is characterized in that the first contact plane has at least one or more contact regions [webs] in which the heat conduction element and the combustion chamber or a first wall delimiting the combustion chamber are directly or indirectly in contact. The contact is thus limited to the contact areas and does not take place in the entire contact level. Immediate contact means that the contact takes place object by object, while indirect contact means that a heat-conducting layer or a contact agent, for example a thermal compound, is arranged between the objects. A size of a contact surface of the first contact plane is determined by a sum of the areas of the contact areas, wherein the areas of the contact areas are variable depending on the position of the heat conduction element, so that a heat conduction in the first contact plane is variable depending on the position of the heat conduction element.

For example, the mutually facing sides of the heat conduction element and the combustion chamber or the first wall bounding the combustion chamber in the first contact plane have different surface structures and / or different materials, depending on the position of the heat conduction element more or less overlap and more or less large areas of the contact areas form. A sum of the surfaces of the contact regions results in the size of the contact surface of the first contact plane, so that a heat conduction in the first contact plane is variable depending on the position of the heat conduction element. Distance regions may be arranged between the contact regions, in which the heat conduction element and the combustion chamber or a first wall bounding the combustion chamber do not conduct heat because of the underfloor covering of the different surface structures and / or different materials, but, for example, a recess / cavity or a poorly heat conductive Form material contact.

On the other hand, the mutually facing sides of the heat conducting element and the combustion chamber or the combustion chamber limiting first wall in the first contact plane may have continuous surfaces. Then the coverage and the size of the contact surface changes when adjusting the heat conduction element hardly or not at all, so that a heat conduction in the first contact plane is independent of the position of the heat conduction element.

An embodiment of the heating device is characterized in that the second contact plane has at least one or more contact areas in which the heat conduction element and the room air heat exchanger and / or the heating water heat exchanger or a second wall bounding the room air heat exchanger and / or the heating water heat exchanger touch directly or indirectly. The contact is thus limited to the contact areas and does not take place in the entire contact level. A size of a contact surface of the second contact plane is determined by a sum of the areas of the contact areas, wherein the areas of the contact areas are variable depending on the position of the heat conduction element, so that a heat conduction in the second contact plane is variable depending on the position of the heat conduction element.

For example, the mutually facing sides of the heat conducting element and the room air heat exchanger and / or the heating water heat exchanger or the second wall bounding the room air heat exchanger and / or the heating water heat exchanger in the second contact plane have different surface structures and / or different materials, depending on the position of the heat conduction element more or cover less and form more or less large areas of the contact areas. A sum of the surfaces of the contact regions results in the size of the contact surface of the second contact plane, so that a heat conduction in the second contact plane can be changed depending on the position of the heat conduction element. Distance regions may be arranged between the contact regions, in which the heat conduction element and the room air heat exchanger and / or the heating water heat exchanger or a second wall delimiting the room air heat exchanger and / or the heating water heat exchanger do not conduct heat because of the underfloor covering of the different surface structures and / or different materials, but instead For example, form a recess / cavity or a poor heat conductive material contact.

On the other hand, the mutually facing sides of the heat conducting element and the room air heat exchanger and / or the heating water heat exchanger or the second wall defining the room air heat exchanger and / or the heating water heat exchanger in the second contact plane may have continuous surfaces. Then the coverage and the size of the contact surface changes when adjusting the heat conduction element hardly or not at all, so that a Heat conduction in the second contact plane is independent of the position of the heat conduction element.

In one embodiment of the heating device, the room air heat exchanger and / or the heating water heat exchanger are at least partially integrated in the heat conduction element. This can be understood as a complete integration of the room air heat exchanger and / or the heating water heat exchanger into the heat conduction element, so that the heat exchanger is arranged in the interior of the heat conduction element. A partial integration may be provided by a heat exchange on the surface of the heat conducting element.

In a further embodiment of the heating device of the room air heat exchanger is at least partially formed by the distance ranges in the first and / or second contact plane. Distance ranges are those in which the combustion chamber or a first wall bounding the combustion chamber or the heating water heat exchanger or a second wall delimiting the heating water heat exchanger do not touch the heat conduction element but form a recess or cavity, wherein the distance ranges of room air can be flowed through. One of the advantages here is the high degree of integration and the compact design.

The drawing illustrates an embodiment of the invention. It shows:

1 Heating device for heating room air and heating water according to the prior art

2 Heating device for heating room air and heating water (detail)

3 Heating device for heating room air and heating water (detail)

4 Detail heat conduction element of a heater in cross section

5 Detail heat conduction element of a heater in cross section

6 Detail heat conduction element of a heater in cross section

7 Detail heat conduction element of a heater in cross section

8th Detail heat conduction element of a heater in cross section

9 Detail heat conduction element of a heater in cross section

10 Detail heat conduction element of a heater

1 shows a heating device ( 1 ) according to the prior art for heating room air and heating water, with a heat-generating combustion chamber ( 2 ), a room air heat exchanger ( 3 ) for the transfer of heat to the room air and a heating water heat exchanger ( 4 ) for the transfer of heat to the heating water, wherein a heat conduction element ( 5 ) for the heat conduction from the combustion chamber ( 2 ) to the room air heat exchanger ( 3 ) and to the heating water heat exchanger ( 4 ) is provided. In the heater ( 1 ) is in the combustion chamber ( 2 ) burned a solid fuel under the supply of combustion air with flame formation, hot combustion exhaust gases are produced and heat is generated. This heat is transferred to the room air heat exchanger ( 3 ) and the heating water heat exchanger ( 4 ), where it heats room air and heating water. The cooled combustion exhaust gases are discharged via an exhaust pipe from the heater.

2 shows a detail of an embodiment of the invention the heating device ( 1 ) for heating room air and heating water, with a heat-generating combustion chamber ( 2 ), at least one room air heat exchanger ( 3 ) for the transfer of at least a portion of the heat to the room air and at least one heating water heat exchanger ( 4 ) for the transfer of at least a portion of the heat to the heating water, wherein at least one adjustably formed heat conduction element ( 5 ) for the heat conduction from the combustion chamber ( 2 ) to the room air heat exchanger ( 3 ) and / or to the heating water heat exchanger ( 4 ) is provided. The adjustable heat conduction element ( 5 ) changes the line of heat to the room air heat exchanger and / or the heating water heat exchanger depending on its position. In the illustrated embodiment, a solid fuel is burned in the combustion chamber with the supply of combustion air with flame formation, whereby hot combustion exhaust gases are produced and heat is generated. This heat is at least partially by means of the heat conduction element ( 5 ) to the room air heat exchanger ( 3 ) and the heating water heat exchanger ( 4 ), where it heats room air and heating water. The room air heat exchanger ( 3 ) is in this embodiment at least partially formed by the outer surface of the heater, it is at least partially heat conductive with the adjustable heat conduction element ( 5 ) and gives the heat Radiation and / or convection to the surrounding installation room. The heating water heat exchanger ( 4 ) is formed by at least one so-called water pocket, the at least partially heat conductive with the adjustable heat conduction element ( 5 ) connected is. The heating water heat exchanger ( 4 ) has connecting devices ( 6 ) for connection to a heating water return and a Heizwasswassernorlauf, he can be so charged with cold heating water and flowed through and deliver the heated water to a heat supply system or a buffer memory. The adjustable heat conduction element ( 5 ) is heat-conducting between combustion chamber ( 2 ) and room air heat exchangers ( 3 ) and heating water heat exchanger ( 4 ) and can by its adjustment the division of the to the room air heat exchanger ( 3 ) on the one hand and the heating water heat exchanger ( 4 On the other hand, change the amount of heat transferred. 2 shows the heat conduction element ( 5 ) in a first exemplary position. In this position, it is by means of an adjustment ( 7.1 . 7.2 ), for example manually ( 7.1 ) or motorized ( 7.2 ) can be driven. A motorized adjustment device ( 7.2 ) can receive their control signals from a controller and automatically respond to room temperatures or water temperatures, or from a timer, or by a user, for example by remote control. The heating water heat exchanger ( 4 ) can by means of a suspension device ( 8th ) at the combustion chamber ( 2 ) be attached. This suspension device ( 8th ) may be formed so that they the adjustable heat conduction element ( 5 ) serves as a warehouse.

3 shows the heat conduction element ( 5 ) in a second exemplary position with a change in the heat flow compared to the first position on the room air heat exchanger ( 3 ) and heating water heat exchanger ( 4 ), here exemplified the heat conduction element ( 5 ) as a displaceable heat conduction element ( 5 ) is formed and a translational (horizontal) adjustment is indicated.

4 shows a detail of an embodiment of the heater ( 1 ) in cross-section, for example, from the direction of a view from above. Between combustion chamber ( 2 ) and heating water heat exchanger ( 4 ) is the heat conduction element ( 5 ) arranged in a first position. The heating water heat exchanger ( 4 ) allows a passage of heating water (not shown here). The illustrated first position of the heat conduction element ( 5 ) can be a first extreme position (maximum shift to a first page). The heater ( 1 ) comprises an adjusting device ( 7.2 ) for adjusting the heat conduction element ( 5 ), wherein the adjusting device ( 7.2 ) is driven by a motor. The adjusting device ( 7.2 ) has in this embodiment its fixed point to the heating water heat exchanger ( 4 ), against which the movement and adjustment in the heat conduction element ( 5 ) is initiated. The contact of the heat conduction element ( 5 ) with the combustion chamber ( 2 ) or a combustion chamber bounding the first wall (not shown here) takes place heat-conducting in a first contact plane ( 9 ). The contact of the heat conduction element ( 5 ) with the room air heat exchanger ( 3 ) and the heating water heat exchanger ( 4 ) or the room air heat exchanger ( 3 ) and / or the heating water heat exchanger ( 4 ) limiting second wall (not shown here) is heat-conducting in a second contact plane ( 10 ). A heat conduction in the first contact plane ( 9 ) of the example shown is not dependent on the position of the heat conduction element ( 5 ), since the contact is full and the size of the contact surface regardless of the position of the heat conduction element ( 5 ), since they are in any position of the heat conduction element ( 5 ) over the entire width of the combustion chamber ( 2 ). In the area of the second contact level ( 10 ) have both the heat conduction element ( 5 ) as well as the heating water heat exchanger ( 4 ) a textured wall. Thus, the heat conduction element ( 5 ) and the heating water heat exchanger ( 4 ) at least two subareas ( 11 . 12 ) for heat-conducting bonding, wherein the portions are formed differently in terms of thermal conductivity. A first subarea ( 11 ) is defined by the first sub-areas ( 11a ) and has, for example, a low thermal conductivity. A second subarea ( 12 ) is defined by the second sub-areas ( 12a ) and has, for example, a high thermal conductivity.

The first subarea ( 11 ), as shown here, in the form of, for example, semi-cylindrical recesses (distance ranges) designed. The recesses may be in a first embodiment, air-flow-through recesses, which open to the installation room and the room air heat exchanger ( 3 ) form. This is the room air heat exchanger ( 3 ) partially integrated into the heat conduction element ( 5 ) educated. The heat conduction element ( 5 ) and the heating water heat exchanger ( 4 ) may have closure elements (not shown here) for preventing or throttling a flow with room air and / or heating water. For example, a closure element may be designed as a flap which is manually or thermostatically adjustable and opens or closes the openings through which the air can flow if required. In another exemplary embodiment, the recesses may be filled with a material which, with regard to the thermal conductivity, is differently shaped than the base material of the heat conduction element ( 5 ) and Heating water heat exchanger ( 4 ). The second subarea ( 12 ) can be designed from between the recesses arranged flat areas of the base material. In the embodiment according to 4 is a low heat conduction to the heating water heat exchanger ( 4 ) and a large heat conduction to the room air heat exchanger ( 3 ) reached.

5 shows a detail of the same embodiment of the heater ( 1 ) as 4 with the difference that the heat conduction element ( 5 ) is in a second position, in which it is from the first position ( 4 ) is shifted. The illustrated second position may be a second extreme position (maximum displacement to a second side). A heat conduction in the second contact plane ( 9 ) of the illustrated example is dependent on the position of the heat conduction element ( 5 ) dependent. Depending on the position of the heat conduction element ( 5 ) shifts the coverage of the two different heat-conducting portions ( 11 . 12 ) of heat conduction element ( 5 ) and heating water heat exchanger ( 4 ), so that the size of the contact surface depends on the position of the heat conduction element ( 5 ). In the first position ( 4 ) is the overlapping of the subareas ( 11 . 12 ) minimally, so that the heat conduction from the heat conduction element ( 5 ) to the heating water heat exchanger ( 4 ) is minimal, but the heat conduction to the room air heat exchanger ( 3 ) maximum. During operation, so much room air and little heating water is heated. In the second position ( 5 ) is the overlapping of the subareas ( 11 . 12 ) maximum, so that the heat conduction from the heat conduction element ( 5 ) to the heating water heat exchanger ( 4 ), the heat conduction to the room air heat exchanger ( 3 ) minimal. During operation, so little room air and plenty of heating water is heated. Due to the possible intermediate positions of the heat conduction element ( 5 ) between its first and second extreme position, the distribution of the heat flow can be changed.

As with air-permeable recesses in the above embodiment, in another embodiment, the first portions ( 11 ) of heat conduction element ( 5 ) and heating water heat exchanger ( 4 ) are also made of a material that is different in terms of thermal conductivity (poor heat conduction) formed as the base material of heat conduction element ( 5 ) and heating water heat exchanger ( 4 ) in the second subarea ( 12 ). By changeable overlapping of the subregions ( 11 . 12 ) by changing the position of the heat conduction element ( 5 ) changes the heat conduction to the heating water heat exchanger ( 4 ) similar to the above embodiment. The room air heat exchanger ( 3 ) is then at other areas of the heater ( 1 ) educated. The to the room air heat exchanger ( 3 ) passed heat fraction varies depending on the to the heating water heat exchanger ( 4 ) passed on heat fraction. In the embodiment according to 5 is a large heat conduction to the heating water heat exchanger ( 4 ) and a low heat conduction to the room air heat exchanger ( 3 ) reached.

The 6 and 7 show details of a similar embodiment of the heater ( 1 ) as the 4 and 5 with the difference that here both in the area of the first contact level ( 9 ) as well as the second contact level ( 10 ) both the combustion chamber ( 2 ) as well as the heat conduction element ( 5 ) (both sides) and the heating water heat exchanger ( 4 ) have a textured wall. So include the combustion chamber ( 2 ), the heat conduction element ( 5 ) and the heating water heat exchanger ( 4 ) at least two subareas ( 11 . 12 ) for heat-conducting bonding, wherein the portions are formed differently in terms of thermal conductivity. A first subarea ( 11 ) is defined by the first sub-areas ( 11a ) and has, for example, a low thermal conductivity. A second subarea ( 12 ) is defined by the second sub-areas ( 12a ) and has, for example, a high thermal conductivity. Depending on the position of the heat conduction element ( 5 ), variable parts of the combustion chamber ( 2 ) to room air heat exchanger ( 3 ) and heating water heat exchanger ( 4 ) passed on heat. In the embodiment according to 6 and 7 the heat exchanger surface of the room air heat exchanger is opposite to that 4 and 5 significantly larger. In the embodiment according to 6 is a low heat conduction to the heating water heat exchanger ( 4 ) and a large heat conduction to the room air heat exchanger ( 3 ) reached. In the embodiment according to 7 is a large heat conduction to the heating water heat exchanger ( 4 ) and a low heat conduction to the room air heat exchanger ( 3 ) reached.

Another continuation of the in the 4 to 7 illustrated inventive idea is the 8th and 9 refer to. The special feature of this embodiment is that the heating device ( 1 ) two heat conduction elements ( 5.1 . 5.2 ). These can be adjustable together or independently. In the embodiment according to 8th and 9 is the heat exchanger surface of the room air heat exchanger ( 3 ) compared to those after 4 to 7 once again significantly larger. The element between the two heat-conducting elements ( 5.1 . 5.2 ), a first heating water heat exchanger ( 4.1 ) be. This first heating water heat exchanger ( 4.1 ) will show a higher temperature level in the heated heating water than the second heating water heat exchanger ( 4.2 ), as he is closer to the Combustion chamber ( 2 ) lies. This results in the possibility of dividing a heating water flow into two partial flows, one of them in the first heating water heat exchanger ( 4.1 ), the other in the second heating water heat exchanger ( 4.2 ) and then to supply them for various uses, for example a heat distribution system and a buffer storage, or two heat distribution systems to be tempered differently, such as an unmixed radiator heating circuit and a mixed underfloor heating circuit. Will the heat conduction elements ( 5.1 . 5.2 ) Adjusted differently, so further advantageous applications can be realized. By way of example, an adjustment is picked out in which the combustion chamber-near heat conduction element ( 5.1 ) in a second position (cf. 9 ) and the combustion chamber-distant heat conduction element ( 5.2 ) in a first position (cf. 8th ) stands. Then from the combustion chamber ( 2 ) incoming heat well to the first heating water heat exchanger ( 4.1 ) and bad on the second heating water heat exchanger ( 4.2 ) forwarded. This could be the room air and above ( 4.1 ) a buffer storage, but a heat distribution system ( 4.2 ) stay cold, because ( 4.2 ) no or almost no heat is supplied.

10 shows a heat conduction element ( 5 ), which deviates from the 4 to 9 shown no displaceable, but a rotatable about a central axis heat conduction element ( 5 ). It has in the figure only on its right side, a structure influencing the thermal conductivity, according to the heat conduction element ( 5 ) in the 4 and 5 , In a heating device, he would have a room air heat exchanger on the right side ( 3 ) or a heating water heat exchanger ( 4 ) adjacent to a corresponding structure. By rotating the heat-conducting element, the heat conduction to the adjacent heat exchanger (s) can then be changed, that is, increased or decreased. For example, the heat conduction element ( 5 ) and the adjacent heat exchanger ( 3 . 4 ) here two subareas ( 11 . 12 ) for heat-conducting bonding, wherein the portions are formed differently in terms of thermal conductivity. A first subarea ( 11 ) is defined by the first sub-areas ( 11a ) and has, for example, a low thermal conductivity. A second subarea ( 12 ) is defined by the second sub-areas ( 12a ) and has, for example, a high thermal conductivity. By adjusting the heat conduction element ( 5 ), the distribution of heat to the heat exchanger ( 3 . 4 ) can be varied.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• DE 202008012914 U1 [0001]

Claims (12)

Heating device ( 1 ) for heating room air and heating water, with a heat-generating combustion chamber ( 2 ), at least one room air heat exchanger ( 3 ) for the transfer of at least a portion of the heat to the room air and at least one heating water heat exchanger ( 4 ) for the transfer of at least a portion of the heat to the heating water, wherein at least one heat conduction element ( 5 ) for the heat conduction from the combustion chamber ( 2 ) to the room air heat exchanger ( 3 ) and / or to the heating water heat exchanger ( 4 ) is provided, characterized in that the heat conduction element ( 5 ) as an adjustable heat conduction element ( 5 ), which directs the heat to the room air heat exchanger ( 3 ) and / or to the heating water heat exchanger ( 4 ) changed depending on its position. Heating device ( 1 ) according to claim 1, characterized in that the change in the heat conduction to the room air heat exchanger ( 3 ) and / or to the heating water heat exchanger ( 4 ) Is effected by a change in heat output to the room air and / or the heating water. Heating device ( 1 ) according to one of the preceding claims, characterized in that the heat conduction element ( 5 ) and / or the room air heat exchanger ( 3 ) and / or the heating water heat exchanger ( 4 ) Have closure elements for blocking or throttling a flow with room air and / or heating water. Heating device ( 1 ) according to one of the preceding claims, characterized in that the change in the heat conduction to the room air heat exchanger ( 3 ) and / or to the heating water heat exchanger ( 4 ) is effected by a change in thermal conductivity. Heating device ( 1 ) according to one of the preceding claims, characterized in that the heat conduction element ( 5 ) and / or the room air heat exchanger ( 3 ) and / or the heating water heat exchanger ( 4 ) at least two subareas ( 11 . 12 ) for heat-conducting bonding, wherein the subregions ( 11 . 12 ) are formed differently in terms of thermal conductivity. Heating device ( 1 ) according to one of the preceding claims, characterized in that the heat conduction element ( 5 ) as a displaceable and / or rotatable heat conduction element ( 5 ) is trained. Heating device ( 1 ) according to one of the preceding claims, characterized in that the heat conduction element ( 5 ) the combustion chamber ( 2 ) or one the combustion chamber ( 2 ) limiting first wall in a first contact level ( 9 ) and that the heat conduction element ( 5 ) the room air heat exchanger ( 3 ) and / or the heating water heat exchanger ( 4 ) or the room air heat exchanger ( 3 ) and / or the heating water heat exchanger ( 4 ) limiting second wall in a second contact plane ( 10 ), wherein a heat conduction in the first and / or second contact plane ( 9 . 10 ) depending on the position of the heat conduction element ( 5 ) is changeable. Heating device ( 1 ) according to any one of the preceding claims, characterized in that the first level of contact ( 9 ) has at least one or more contact areas in which the heat conduction element ( 5 ) and the combustion chamber ( 2 ) or one the combustion chamber ( 2 ) bordering first wall directly or indirectly, that a size of a contact surface of the first contact plane ( 9 ) is determined by a sum of the areas of the contact areas, and that the areas of the contact areas depending on the position of the heat conduction element ( 5 ) are variable, so that a heat conduction in the first contact plane ( 9 ) depending on the position of the heat conduction element ( 5 ) is changeable. Heating device ( 1 ) according to one of the preceding claims, characterized in that the second contact plane ( 10 ) has at least one or more contact areas in which the heat conduction element ( 5 ) and the room air heat exchanger ( 3 ) and / or the heating water heat exchanger ( 4 ) or the room air heat exchanger ( 3 ) and / or the heating water heat exchanger ( 4 ) bordering second wall directly or indirectly, that a size of a contact surface of the second contact plane ( 10 ) is determined by a sum of the areas of the contact areas, and that the areas of the contact areas depending on the position of the heat conduction element ( 5 ) are variable, so that a heat conduction in the second contact plane ( 10 ) depending on the position of the heat conduction element ( 5 ) is changeable. Heating device ( 1 ) according to one of the preceding claims, characterized in that the room air heat exchanger ( 3 ) and / or the heating water heat exchanger ( 4 ) at least partially into the heat conduction element ( 5 ) are integrated. Heating device ( 1 ) according to one of the preceding claims, characterized in that the room air heat exchanger ( 3 ) is at least partially formed by distance ranges in the first and / or second contact level ( 9 . 10 ), where distance ranges are those in which the combustion chamber ( 2 ) or one the combustion chamber ( 2 ) limiting first wall or the heating water heat exchanger ( 4 ) or a heating water heat exchanger ( 4 ) limiting second wall the heat conduction element ( 5 ) do not touch, but form a recess, wherein the distance ranges of room air can be flowed through. Heating device ( 1 ) according to one of the preceding claims, characterized in that the heating device ( 1 ) an adjusting device ( 7 ) for adjusting the heat conduction element ( 5 ), wherein the adjusting device ( 7 ) is driven by a motor.

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