DE19849127A1 - Composite dynamic heating system for buildings consists of multi-layered outer layer containing air ducts - Google Patents

Abstract

The composite dynamic heating system consists of a multi-ply outer covering for the building, through which air (4) flows. The inside of the building's outer (1) has a layer through which air flows; the outside of the building's outer cover has one or two layers (2,3) through which air flows The outer layer is chiefly for obtaining solar heat; the inner layer on the outside of the building's outer cover is mainly for obtaining heat transmission losses from the inner wall. The layer on the wall's inner side is for heating and ventilating the room. The two layer through which air flows on the outside of the wall are thermally separated by a layer (7). The air ducts are interconnected.

Description

The invention relates to a dynamic composite heating system for reducing the Heating energy needs of buildings.

The heating energy requirement has so far been reduced passively Reduction of transmission and ventilation heat losses.

Transmission heat losses are reduced by the following measures:

• - thermal insulation measures on the outer walls and roof surfaces,
• - Avoidance of thermal bridges and window constructions with a low k-value.

Ventilation heat losses are due to (air-) tight construction and tight closing windows and doors lowered.

The extraction of thermal or photovoltaic solar energy takes place e.g. Currently through Collectors that are also integrated into the overall technical system of a house become.

The energy saving house with heating energy consumption between 60 and 100 kWh / m ² a represents the status achieved today. The consequent further development of passive thermal insulation leads to a passive house with a heating energy consumption of max. 25 kWh / m ² a (sample in Darmstadt, Dr. Feist).

The increasing thickness of the thermal barrier poses the following technical problems:

• - Necessity of new technologies and construction processes, so that insulation thicknesses <150 mm can be mastered in building technology.  
• - The need for technical forced ventilation with heat recovery inside the building to maintain air quality and Moisture transport.

The structural-physical consequences of the path taken up to now to increase the insulation thickness are:

• - Sealing the building envelope with joint-tight thermal insulation measures with very large layer thicknesses against the outside climate and thus impairment of the Moisture transport in building parts (dew point problem and Deterioration of thermal insulation properties due to moisture) and compulsory non-use of the insulated roof and wall surfaces imprinted solar radiation.
• - Use of solar energy only through the windows or through additional collectors and thus the risk of summer overheating of the interior of the building incorrectly dimensioned window areas and no heat dissipation to the outside, as well as the need for additional components (collectors, link with the technical building systems) for the production of solar energy.

The technical problems outlined and their physical consequences economic impact. You can increase the construction and follow-up costs due to increasing difficulties in planning, project planning and construction to lead. (Construction and planning errors, moisture damage to structural parts, possible Reduction of the service life of the building). Correcting the errors is only possible through time-consuming reworking / repairs possible.

Another consequence of the path taken is the impairment of comfort for residents through moisture and ventilation.

The need for forced ventilation in modern house concepts defines the Thoughts close to combine heating and ventilation. Then still  required low heat outputs can, for. B. alternatively by heat pumps be won. Such air heaters, which also function as ventilation are already on offer (e.g. the EUROPA modules from Ochsner, Austria).

The object of the invention is to avoid the current technical, technological and building physics difficulties by leaving the passive path. Passive Thermal insulation measures, forced ventilation, heating and hot water production replaced by an active dynamic system. The active dynamic system is said to Minimize transmission heat losses and the provision of heat requirements of residents (heating and hot water), while using the previous Secure unused wall and roof surfaces to generate solar heat.

Further objects of the invention are:

• - Reduction of the possibility of errors in project planning, planning and construction simultaneous restoration of manageable building-physical relationships for moisture transport between building interior, load-bearing structure and Surroundings,
• - Reduction of user behavior solely on heating energy consumption and the elimination of the influence of building physics connections by the User behavior and
• - Restoration of the comfort component for the residents of a building.

According to the invention, this object is achieved by the features of the main claim, the subclaims show further advantageous embodiments of the invention.

According to the concept of the invention, the dynamic thermal composite system consists of a suitable combination of the currently known components of current construction and building technology. It is characterized by the following features:

• - Multi-skin air-flow structure of the building's outer shell, whereby there is an air-flow shell on the inside of the building's outer shell S1 and one or two air-flow shells S2 and S3 on the outside of the building's outer shell
  • 1. the outer shell S3 primarily to obtain the solar heat present on the outside of the building's outer shell,
  • 2. the inner shell on the outside of the building's outer shell S2, primarily the extraction of the transmission heat losses resulting from the inner wall and
  • 3. the shell S1 lying on the inside of the wall primarily for room heating and ventilation of the room;
  • 4. thermal separation of the two shells S3 and S2 on the outside of the wall, through which air flows, by means of a thermal separation layer between S3 and S2;
  • 5. loading of all air channels with appropriately tempered, moving air;
  • 6. Interconnection of the air ducts according to the invention, including withdrawal, distribution and supply of heat quantities, with one another.

If the shell S1 on the inside of the building's outer shell is marked with a Airflow of suitable temperature, e.g. B. 18 ° C, so the inside is this Approximately this temperature is applied to the shell. It looks like a wall, Ceiling or floor heating. Through targeted openings in this bowl and a A suitable forced guidance of this air becomes an exchange of the air volume made in the interior surfaces of this room (combination of heating and Ventilation).

Work from the inside of the building

• 1. the heating energy supplied,
• 2. the known internal gains (natural sources such as humans, aggregates etc.) such as  
• 3. the solar gains achievable through the windows

increasing the temperature of the interior.

The usual transmission heat losses flow outwards (towards the cold outside S2 or S3), so that the outlet temperature of this air flow is a result of the inlet temperature, the transmission heat losses and the gains.

T _1H = 18 ° C (1)

T _2H = f (T _1H ; Q _H ; Q _T ; Q _I ; Q _SF ), where (2)

T _1H = inlet temperature in shell S1
T _2H = exit temperature from shell S1
Q _H = heating energy
Q _T = transmission heat losses
Q _I = internal heat gains
Q _SF = heat gain through windows

Those to reach certain preferred temperatures (e.g. 20 ° C) heating energy to be supplied is a consequence of the inlet temperature of the Air into the shell S1 and the well-known inner and natural solar gains the window.

Ventilation heat losses through forced ventilation do not occur, since heating and ventilation form an overall system. Further ventilation heat losses can only occur if the residents disturb the system through open windows and / or doors or if the building is not tight. Excluding these cases applies approximately

Q _H = f (T _1H ; Q _T ; Q _I ; Q _SF ) (3)

The transmission heat losses through the wall lead to an increase in temperature in the shell S2. Provided that there is a thermal separation between S3 and S2, the air stream flowing through can absorb this temperature increase and thus the heat quantities of the transmission heat losses. This leads to an increase in the outlet temperature compared to the inlet temperature inside the shell S2. At the inlet temperature z. B. T _1T , in this case the outlet temperature T _{2T is} greater than T _1T . It applies

T _2T = f (T _1T ; Q _T ) (4)

If the thermal separation is not complete, there are in turn transmission heat losses Q _T 'through the thermal separation layer. The level of these losses depends on the average temperature difference between the two outer shells with their air layers S3 and S2.

Q _T '= f ((T _1T + T _2T ) / 2; (T _1S + T _2S ) / 2), where (5)

T _1S = inlet temperature in shell S3
T _2S = outlet temperature from shell S3.

The same relationships apply to the outer shell S3, except that an increase in temperature is not caused by the transmission heat losses of the inner shell S2, but by the solar radiation impressed on the outside. Any transmission heat losses Q _TS going in between S3 and S2 have a temperature- _reducing effect.

T _2S = f (T _1S ; Q _S ; Q _TS ) with Q _S = solar energy (6)

Losses due to the thermal interface between S3 and S2 or vice versa can be avoided by having approximately the same in both layers Temperature prevails. These losses then tend to zero!

If these losses through the thermal interface become zero, then the outlet temperatures of the outer layers S3 and S2, T _2S and T _{2T are} directly proportional to the solar gains Q _S and the transmission heat losses Q _T through the wall.

If the inlet temperatures in the two outer layers S3 and S2 are the same, the losses Q _T 'and Q _TS are approximately the same and cancel each other out, ie the thermal losses of the system become approximately zero!

The transmission heat losses Q _T and the solar energy Q _{S are} recovered by heat pumps. They work on a common storage tank that supplies both the hot water and the heating energy required for certain areas of well-being with higher temperatures (T _I = 20 ° C or 24 ° C).

The appropriate combination of the air flows of the shells through direct multiple use or their coupling via heat exchangers ensures that all heat quantities only in the Moved inside the active dynamic system and no amounts of heat be given to the outside world.

The previous static k-value of a component (wall, roof, floor) can therefore no longer be used. Through the recovery of the transmission heat losses and the recovery of the solar energy, it changes into a dynamic k-value (k _dyn ) depending on the current overall condition of the system. To calculate the dynamic k-value of the system, the efficiency of the recovery of the transmission heat losses η _T and the degree of recovery of the solar energy η _{S are} decisive. The dynamic k-value is determined by:

k _dyn = k _stat . (1-η _T ). (1-η _S ) (7)

The static k-value necessary for the determination of the dynamic k-value results according to the known rules of technology, neglecting the inner  Shell S1 from the wall structure with the shells S2 and S3 and under the assumption dormant air layers in S2 and S3.

The choice of the entry temperatures of the air flows into the shells S1, S2 and S3 (T _1H , T _1T and T _1S ) has an influence on the functionality and overall efficiency of the system.

The following main advantages result from the application of the invention. Model calculations have shown that with an efficiency of around 30% for the recovery of transmission heat losses (η _T = 0.3), the system achieves the same energy properties as a similar house built according to the state of the art. At about 50% efficiency (η _T = 0.5) the low energy standard is achieved and at about 70% (η _T = 0.7) the thermal properties are the same as those of a passive house.

Will the solar energy generation and the temporary storage contained in the system the thermal energy is taken into account, so the thermal engineering improve Properties further.

The dynamic heat composite system has the following advantages:

• - It consists of the merging of commercially available components according to the Technology and can be used with conventional construction and expansion methods.
• - The use of the overall system is cost-neutral compared to conventional construction and expansion standard, whereby the cost proportions of the individual construction and Shift expansion areas towards each other. Construction cost savings are through The masonry is expected to be reduced to a load-bearing function only.
• - The energy values that can be achieved with the system reduce the Heating costs and leave the zero energy house when optimizing the system expect.
• - The moisture transport between the interior of the building and the surroundings is controlled by the Use of the system is not affected. Moistures on parts of the building  no longer occur, the dew point problem with in its consequence the Deterioration of the thermal insulation properties of the materials used not applicable.
• - The system is also able to cool the interior of the building in summer to be used. This can cause summer overheating of the building interior can be avoided without additional technical measures.
• - The comfort component for the residents of a building restored and the user behavior only influences the still necessary heating energy requirements.
• - A house built according to the dynamic heat composite system differs not externally of previously common house designs.
• - The system is independent of the material used for the load-bearing construction and also suitable for retrofitting existing buildings.

Further details, features and advantages of the invention result from the following description of an embodiment with reference to the associated drawings. Show it

Fig. 1 is a basic representation of the multi-layered structure of the building outer shell the example of a building outer wall,

Fig. 2 representation of the construction of the building outer shell using the example of a family home with the heat flows acting on the shells.

Fig. 3 interconnection of the air flows from the shells S1 and S3 to the overall system.

Fig. 1 illustrates the basic illustration of the multi-layer structure using the example of an outer wall of a building. The basic structure according to FIG. 1 encloses the entire building, whereby layer S3 can be omitted in the base part. When viewed from the outside in, the wall structure has the following layer sequence:

• - outer surface of the building envelope 8 , which is carried out on the walls with external plaster,
• - shell S3 3 for airflow 4 ,
• Thermal separation layer 7 ,
• - shell S2 2 for the air flow 4 ,
• - load-bearing building envelope 5 ,
• - shell S1 1 for the air flow 4 ,
• - Inner surface of the building envelope 6 .

Fig. 2 shows a basic representation of the layer structure and the heat flows acting on and in the layers or shells Q _H , Q _T , Q _T ', Q _I , Q _S , Q _SF , Q _{TS using} the example of a family home. Air is passed through the shells S1 to S3. In the area of openings (windows, doors), the air flows are directed around these openings.

The outlet temperatures of the air streams 4 from the respective shells S1 to S3 are always a function of the inlet temperatures into the shells S1 to S3 and the heat quantities acting on the air streams 4 in the shells. If the shells S3 and S2 have the same temperature, the losses Q _SF and Q _T 'cancel each other out and the outlet temperatures of these two air layers 4 are determined by the solar radiation Q _S acting on them and the transmission losses Q _T.

Tempered outside air is fed to the shells S3 and S2, each separately. For the shell S3, the outside air supplied is, for. B. tempered by a floor heat exchanger 10 , while that for the shell S2 z. B. happens with a cross-flow heat exchanger 10 on the exhaust air of the system, see. Fig. 3.

Insofar as solar gains lead to a usable outlet temperature in the shell S3, these solar gains can be fed to a store 11 via a heat pump 9 .

The outlet temperature of the air in the shell S2 is determined by the transmission heat losses. The heat quantities contained therein can be extracted from this air flow 4 via a heat pump 9 . This air flow 4 is then fed to a heat exchanger 10 . This heat exchanger 10 connects the exhaust air from the shell S1 to the air flow 4 . The air flow 4 from S2 takes on the temperature of the exhaust air from S1.

This air flow 4 is then fed to the inner shell S1 and distributed in this shell and in the building.

The exhaust air from the shell S1 is a result of the amounts of heat acting on it. It passes on its temperature level via the already mentioned heat exchanger 10 to the air entering the shell S1.

Then the air flow 4 from S1, which is still subjected to the application of heat, is fed to the heat exchanger 10 , through which the inlet air is conducted into the shell S2. It releases its remaining heat energy and returns to the temperature level of the outside air.

Under the condition of the same temperature level in layers S2 and S3 in the overall system are those that normally flow outside to the environment Zero losses.

Due to the constant fresh air supply to the system, any inside the building existing moisture is always transported to the outside, the interior of the building and the load-bearing building structures are dry.

The overall efficiency of the system depends on the efficiency of the Individual components (heat exchangers, heat pumps) and of the selected ones Entry temperatures in layers S1 to S3.

The peculiarity of the system is that the outside air is fed to the shell S2 via the heat exchanger 10 with the exhaust air from the shell S1. 1 inner shell S1
2 inner outer shell S2
3 outer shell S3
4 air flows
5 load-bearing building envelope
6 inner surface of the building envelope
7 thermal interface
8 outer surface of the building envelope (on walls with external plaster)
9 heat pump
10 heat exchangers
11 memory

LIST OF REFERENCES

Claims (4)

1. Dynamic heat composite system for minimizing transmission heat losses in buildings and providing the desired heat requirements with regard to heating, air conditioning and hot water,
characterized by

• a) a multi-layer, air-flowed structure of the building outer shell, wherein there is an air-flowed shell on the inside of the building's outer shell S1 ( 1 ) and one or two air-flowed shells S2 ( 2 ), S3 ( 3 ) on the outside of the building's outer shell, and
  • 1. the outer shell S3 ( 3 ) primarily to obtain the solar heat Q _S applied to the outside of the building's outer shell,
  • 2. the inner shell on the outside of the building's outer shell S2 ( 2 ) primarily to obtain the transmission heat losses Q _T and from the inner wall
  • 3. the shell S1 ( 1 ) lying on the inside of the wall serves primarily for room heating and ventilation of the room;
• b) the thermal separation of the two shells S3 and S2 ( 2 , 3 ) on the outside of the wall, through which air flows, by means of a thermal separation layer ( 7 ) between S3 and S2;
• c) the loading of all air channels ( 1 , 2 , 3 ) with appropriately tempered, moving air ( 4 );
• d) the interconnection of the air ducts ( 1 , 2 , 3 ), including withdrawal, distribution and supply of heat, with each other.

2. Dynamic heat composite system according to claim 1, characterized in that the recovery of the transmission heat losses Q _T and the recovery of the solar energy Q _{S is carried out} by the combination of heat pumps ( 9 ) and heat exchangers ( 10 ), which work on a common store ( 11 ), which supplies both the hot water and the heating energy Q _H required for certain areas of wellbeing with higher temperatures. 3. Dynamic thermal composite system according to claim 1 or 2, characterized in that the insulating effect of the components used in the dynamic thermal composite system for wall, roof, floor ( 1 , 2 , 3 , 5-8 ) is determined by the dynamic k-value including the efficiency of the recovery of the transmission heat loss η _T and the degree of recovery of the solar energy η _S
k _dyn = k _stat . (1-η _T ). (1-η _S ). 4. Dynamic heat composite system according to one of claims 1 to 3, characterized in that the outside air via a heat exchanger ( 10 ) with the exhaust air of the shell S1 ( 1 ) is fed to the shell S2 ( 2 ) at a temperature.