DE3943405A1 - Utilisation of low temperature heat for heating building - involves circulation air between inner panels and inner surface of walls - Google Patents

Abstract

The method is for using a source of low temperature heat to reduce the heat loss from the interior of a building. Plaster board panels (12) are installed inside the building near to the inside wall surface so that a narrow gap (11) is formed between the panel and the wall (4). This gap is connected by a duct (13) to an external source (15) of low temperature heat, such as a solar panel (1) or warm waste water. Air heated from this source circulates by convection through the duct and gap and then flows out through the upper duct (9) into a space (6) between the wall (4) and an outer panel (7). The circulation of slightly heated air reduces the temperature difference across the wall (4) and so reduces the heat loss by conduction through the wall. USE/ADVANTAGE - More efficient heating of buildings.

Description

The invention relates to a system according to the preamble of the claim 1, which also has a greatly expanded economic use of solar systems to the point.

The use of solar energy is currently limited to heating energy savings only for heating and not for insulation. With solar cells, glass stems (conservatories) and through large areas South windows in the buildings will occasionally use these alternatives Tried energy type. So far, unfortunately, only these could Temperatures are used, which were above the interior temperature and thus contributed to the warming up of the interior while everyone else underlying temperature gains compared to the outside temperature remained unused.

Cheap hot air solar cells were therefore for the utilization of the Solar energy in our latitudes is not economical. On the one hand they reached heating temperatures that were rarely usable in winter and in In summer, her energy consumption for heating the living space was unnecessary. Your period of use was therefore limited to a few sunny spring and autumn days, which is why these systems do not offer a favorable cost-benefit ratio could be achieved.

For this reason, the use of solar cells was mainly concentrated to the area of water heating, so the period of use to extend beyond the summer.

Large room heat exchangers are also used for heating rooms necessary, given the previously short periods of use, more expensive than useful.

This left a much too small area of application for solar systems. The other method of using large south-facing windows benefit, has enormous disadvantages. On the one hand, they lead too easily in summer overheating and on the other hand they bring about during the winter time in cloudy weather due to their poor insulation properties more losses than profits.  

A better way to use solar energy even in winter, offer glass stems, so-called winter gardens. They are expensive, have only a limited effective area and offer during Sunless times a poorer insulation than one with thermal insulation insulated masonry.

The invention has for its object a cheap and retrospectively to create an installable option that was not previously usable Temperature ranges can be used to save energy. Thereby on the one hand, it should primarily have a very extensive period of effectiveness and Efficiency of solar cells also reached cheaper warm air solar cells will. On the other hand, low levels that are no longer usable should also be used Waste heat temperatures to reduce heating costs or other Heating losses can be used again. Another task is Increasing the cost-effectiveness of thermal energy storage, since this can be discharged more deeply. Even higher temperatures in the ground or in the water should also be used to save energy.

This object is achieved in that an opposite the outside temperature existing excess heat, which for indoor heating is still too low, is used to avoid the harmful To reduce heat gradients of a tempered interior to the outside. This is done by using an appropriately tempered medium (e.g. air) a building or container completely or only partially is enveloped.

E.g. with a heat gradient from + 20 ° (interior) to -20 ° (outside temperature) can by covering the wall or container outer surface with a temperature of 0 ° C the heat gradient and energy loss of the interior reduced by 50% and thus a considerable reduction of heating costs can be achieved.

This would mean a low temperature, which is no longer needed for direct heating is usable, but shows a warming compared to the outside temperature, Can be used to reduce heat loss and therefore fully usable.

As for direct heating only temperatures above the interior temperature are usable and thus z. B. at -20 ° a solar system  which reaches 30 ° C can only give off heat of 10 ° C, it is now possible use the remaining 40 ° C to reduce the heat gradient and in the example, the efficiency of the solar system increases 5 times increase.

When covering an outer wall with an insulation temperature, this must be Insulated temperature protected from the low outside temperature, and their external heat loss can always be compensated for. This energy balance can be cheap with free solar energy and retrofittable solar cells, heat storage or free Waste heat supply take place. But also geothermal energy or river water can possibly be used to save energy. The inexpensive creation of cavities to accommodate the tempered air layer can be unnecessary in many cases since most masonry can be built from cavity bricks and, if the walling is skillful, these Cavities in the masonry are then available for use.

This can also be done with retro-fitted external building insulation simply be mounted on a counter batten frame so that without essential Additional cavities are created in which the tempered Air at the same time receives insulation from the outside, so that with the existing one Energy supply, e.g. B. of solar cells, the largest possible surface of the building can be covered with a noticeable increase in temperature. In bad weather, when there is no energy supply from solar cells, offers this air gap and the insulation material layer compared to pure Glass fronts from e.g. B. glass stems a much better thermal insulation and heating energy savings. But also the cavities of double glazing would also be used to reduce the heat gradient. At Sunless days can be achieved using an additional heat exchanger Waste heat, stored heat from a heat store or geothermal heat be used to reduce the heat gradient.

In this way, energy stored on sunny days is also used to reduce the heat gradient usable during the night.

Further use of the system installed in this regard is possible with further low expansion boxes always on when using plasterboard when renovating old buildings, the aim is to straighten the inner walls becomes.  

Using a control device, which can be integrated in the solar cell, would be then at a higher solar cell temperature an interior heating by this, close to the interior and large area by means of counter battens created cavity possible by the warm air first in this inner Air gap is passed. The air flowing back into the solar cell can then in the upper wall area via valve chambers in the outer air gap arrive and on their way back the temperature gradient reduce between interior and exterior.

On less energetic days, the control unit and valve chambers the inner air gap is encapsulated and only the outer one is used by the warm air is directed directly into it.

In the application, air does not necessarily have to be used as the heat transfer medium will. There are also other heat transfer media such. B. water usable, so that this from existing or newly installed hot water solar cells is heated and more distant air gaps z. B. Reach on the north side of the building and also there to save energy can contribute. It is also conceivable z. B. the cavities of containers to flow directly with a liquid, e.g. B. with waste water in the industrial sector.

For example, B. also use solar cells to the excess energy of summer in energy storage, which with the Storage temperature exceeding the storage tank interior charge the storage, create a heat gradient reduction at all lower temperatures and thus reduce the energy loss of the storage. In winter when the heat that can be used for heating the living space can be used up lower temperature then to reduce the heat gradient be drawn, so that a large part of the previously no longer usable low Energy content can now be used and thus the utility value the energy storage increases.

Also geothermal energy or river water temperatures but also lower z. B. 4 ° C warm In very cold times, layers of water from the sea can also be used to reduce the heat gradient and thus to save energy.

But even with cheap pure hot air solar systems with this invention the effective period extended over the entire winter area  and thus greatly expanded their use.

Such a plant, once purchased, could be used expand even further, also beyond the summer months, when the outflowing warm air in summer in drying chambers for drying clothes or Fruit dehydration is used. But also by growing a solar chimney at the house z. B. from dark sheet metal or glass to the roof gable, would be one thermal wind caused by the chimney suction and the solar systems, usable for electricity generation without any ugly structures to be built. Such a solar fireplace would even be used as a decoration can be designed for the exterior facade of the house.

The system itself does not have to only one or two air gaps can be created.

Of course, 3 or more air gaps can also be used. Here However, a control unit must then be installed between the inside and outside of the wall then direct the air from the solar cells into the air gap in which the already existing air gap temperature as close as possible to the introduced Air temperature is in order to improve the efficiency of the system. However, the air introduced into the gap must be at least the same temperature as the existing temperature and must never be lower.

While introducing warm air into a fairly outer wall area lying air gap, much more energy through the thinner insulation layer is lost than in a wall that lies further inside the wall and is therefore better air gap isolated to the outside, will be located in a further inside Air gap also a higher temperature with the help of z. B. solar cells or let waste heat hold up than in the outer wall area.

However, the higher the temperature of the enveloping air layer, the more the lower the heat gradient from the interior to the outside and the lower are the losses since all further losses to the outside are no longer from the interior removed, but taken from the enveloping air layer and Z. B. the solar cells with their energy supply and be it only 0 ° C at -10 ° C, this energy loss in the air gap with free Equalize energy supply again and thus its utility value almost down expand to ambient temperature.

Description of exemplary embodiments

Example A shows a warm air solar system with two air gap layers. The system can have higher temperature values for heating the living area insert and back into the solar cell flowing air still the existing heat gradient of the building wall to reduce.

Fig. II shows the plant operation at low temperature, where it only achieves a reduction in the heat gradient of the building wall.
With an expanded valve system, this example could in principle also be used to control 3 or more air gap layers.

1 = hot air solar cell z. B. mounted in the lower wall area so that an automatically starting and circulating air flow can form without a fan. The solar cell automatically stops working as soon as the air in it is colder than that in the air gap. In operation to reduce the heat gradient, the warm air is circulated in just 1 air gap ( Fig. AI). In the additional heating mode, the warm air rises in one air gap and decreases in the other, reducing the heat gradient.
2 = battens that divide the cavity into strips and prevent direct warm air from flowing back into the solar cell.
3 = valve flap of the control unit, it is held in one or the other end position by the temperature-dependent control unit.
If there are more than 2 air gap layers, a separate pipe socket with its own valve can be installed on the solar cell for each of these.
The control device then causes only one valve flap to be opened, namely that which releases the warm air into the air gap which is optimal for its temperature.
4 = outer wall of the building
5 = Old existing insulation layer or external plaster (it is not necessary).
6 = outer air gap layer to reduce the heat gradient of the wall.
7 = external insulation mounted on counter battens.
8 = valve flap electrically controlled by control unit to isolate the air gap ( 11 ).
9 = Pipe shaft connection between the inner and outer air gap.
10 = valve flap in addition to ( 8 ) for better sealing against heat loss, it is closed when the energy of the system for heating the living space is not sufficient.
11 = Inner air gap created by battens and facing, for large-scale heating of the interior.
12 = facing z. B. from plasterboard so that the air circulating through the system is not directly mixed with the possibly damp room air.
13 = Lower pipe shaft for warm air, from the solar cell into the inner air gap.
14 = living space.
15 = Possibly additional solar water heating.

Example B shows a system with only one insulating gap per outer wall.
The tempered air builds up in it or circulates with the solar system. An air gap open at the top to allow warm air to flow through would also be conceivable, but here the degree of utilization will certainly decrease. On the south side, a sewage pipe is also used to temper the air. The effect of the solar system is not affected as a colder airbag forms around the sewage pipe during operation of the solar system, over which the warmer air of the solar cell can circulate.

The hot water solar cell on the roof will also be expanded here Fed by using a heat exchanger on the north side of the House supplied with temperature and also with sufficient capacity charges an energy storage device, which then reduces the heat gradient at night the outer wall continues to operate.

The hot water solar system can be provided with a priority circuit, after which it primarily heats the domestic water and only with excess temperature or with low no longer usable for domestic water heating Temperatures insulate the building wall or charge the energy storage. Overall, the degree of utilization of these hot water solar cells also increases. It would also be the waste heat at this point using a heat exchanger usable from the smoke passages of the building heating.

1 = waste water pipe heat exchanger
2 = insulation
3 = warm air solar cell
4 = insulation to create the air gap
5 = air gap for the tempered air. The exhaust air from an air conditioning system can also be blown in here
6 = hot water solar cell
7 = pipeline
8 = heat exchanger
9 = energy storage z. B. Kettle
10 = Air conditioning system that blows its exhaust air into the air gap and thus tempered it

Example C also shows a system with z. B. only one insulating air gap per outer wall and the use of an existing winter garden to reduce the heat gradient of two house wall surfaces. The tempered air circulates in each of these air gaps as indicated by the arrows.
An existing conservatory can be used to create a cheap system, since only external insulation has to be installed.

Example D, here mainly the arrangement of solar cells is shown, which generate a warm air flow without blower or pump support.
Each solar cell arrangement can either work isolating only for its assigned living area.
Eg solar cell group 1 only works for the ground floor
Solar cell group 2 only works for the upper floor
Solar cell group 3 works for the attic
or you can install valves to let all 3 groups work together at appropriate working temperatures (sketch). In such a case, the warm air rises on the south side and is recharged again and again by the higher cells until it also covers the roof area in an insulating manner, in order to then also cover the north, and partly the west and east walls with their remaining insulation temperature.

Via extra air shafts in the basement or in the east or west wall area it then cools down and flows back into the bottom solar cell. Another positive side effect can be installed this way Offer solar cells by being at the higher position of the sun in summer (a) shade the windows on the south side and overheat the Help prevent interior. In winter with the low sun position (b) however, the sun can reach the windows unhindered and warm them up.

Example E shows an extended application of the hot air solar cells of such a system in the summer time.
In view of the enormous energy with which the sun covers every m² in summer, it would be conceivable to use electricity to generate electricity by means of thermal winds, which arise from the solar system on the one hand and the chimney suction on the other. Since the solar cells have already been purchased in the presence of a heat gradient reduction system, the purchase price of such a power generation system is reduced only at the cost of the fireplace and the generator attachment.

Fig. I shows a glass fireplace that even heats the rising air.

Fig. II shows an existing fireplace, which is used in summer for power generation. If such a fireplace is made of dark sheet metal instead of stone, it is also able to heat the warm air further.

Part of the electricity could be delivered on site without many transmission losses be generated yourself.

Example "F"

Here an energy tank is charged with solar energy in summer. The energy tank does not necessarily have to be a single tank, but can also consist of several circular tanks or spherical tanks which are mounted one inside the other. Or also from individual tanks which are arranged around each other so that one or more tanks is surrounded by a ring of other tanks ( Fig. II).

The advantage of such tanks arranged around each other, compared to a single one large tank consists in better energy yield and reduction of the heat gradient.

At a during the summer time on z. B. + 70 ° C charged individual Tank, the solar cell can only supply energy to the tank again when it this exceeds 70 ° C while all temperatures below it were previously no longer usable in this case.

In contrast, several tanks are arranged in a ring around each other and yet against each other thermally insulated, then the innermost tank z. B. with the temperature peaks charged and can e.g. B. reach more than 100 ° C under pressure. The low temperatures then heat the outside in the return less hot tanks and at the end the heat transfer medium still works Heat gradient reduction in the outer insulation layer. So then that Heat carriers removed much more energy, which is then a significant amount lower return temperature in the solar cell. this in turn leads to a larger medium in the solar cell Record temperature difference and what the efficiency of the solar system considerably increased.  

Overall, this method leads to a significantly better yield Solar energy. So it is also possible, despite the high storage tank temperature in late summer or autumn, also solar energy in the Store tanks.

Another advantage of these multi-layer tanks compared to a single tank exists during the times when the system is out of order and the tanks cool down and energy losses occur. Have here the multilayer tanks have the advantage that they have the heat gradient between them reduce and cool down less. For example, a single tank from + 80 ° to + 5 ° earth temperature has a heat gradient of 75 °. A Three-layer tank with + 100 ° in the innermost tank + 70 ° in the middle tank around + 40 ° in the outermost tanks, on the other hand, only has a heat gradient of max. 35 ° and therefore only approx. 50% energy loss with equivalent insulation materials. This allows the energy to be stored better over longer periods of time save than with single tanks.

In addition, even in winter, any positive temperature from the solar cells to further reduce the heat gradient and thus to save energy can be used (see description of heat gradient reduction of living spaces). In this case the cavity does not have to be with air but can be filled with water or another heat transfer medium. The energy stored in summer can later be used to heat a living space be used in the colder season until they reach approx. + 30 ° has cooled down.

Another energy yield up to even lower temperatures is still possible by switching to heat gradient reduction, so that the efficiency of such energy storage is also considerable in this way is increased. The usable temperature difference is e.g. without heat gradient reduction at + 80 ° starting temperature to 30 ° discharge temperature approx. 50 °. With heat gradient reduction, however, from + 80 ° to 0 ° and thus the usable temperature difference 80 °, which in this case is an increase corresponds to 60%.

Fig. I
1 = solar cell
2 = supply line to the storage tank
3 = gap to reduce the heat gradient
4 = isolation of 3
5 = insulation of the tank
6 = energy tank
7 + 8 = control valves for steering the heat transfer medium
9 = return line to the solar cell
10 = event. Extra residential building connection if the solar cell cables are not used
11 = internal high temperature storage
Fig. II
12 = insulating layers
13 = outer storage tanks
14 = inner high temperature tank

Example "G"

Here is a way how z. B. also in industrial Area using a waste heat pipe is unsuitable for direct flow Wastewater for heating an air gap and thus can be used to reduce the heat gradient.

1 = air gap with the warm air (possibly also gas or liquid)
2 = tank interior
3 = waste water pipe with cooling plates as heat exchangers. It supplies the energy that is lost to the outside from the air gap ( 1 ) and is therefore no longer removed from the tank contents.
4 = insulating layers made of insulating material.

The advantages that can be achieved with the invention are as follows:
Use of temperature ranges below the interior temperature of a container or building to save energy and reduce heating costs. As a result, the usable temperature ranges of solar cells and energy storage devices can also be expanded, thereby enormously improving their energy yield. Through the now possible utilization of a larger usable heat gradient, which is no longer determined downwards by an existing building or container interior temperature, but only by the outside temperature, on the one hand the efficiency of solar systems increases and on the other hand the period of use of these systems is precisely the cold Extended in seasons, their value in use had increased enormously.

In this way, cheap hot air solar cells reach our latitudes a positive cost-benefit ratio.

Because of the reasonably priced use of warm air solar cells there is again the advantage that cheap heat exchanger surfaces are created or as a free side effect for renovation or insulation work may be incurred.

Existing conservatories and glass stems can replace hot air solar cells or additionally used and thus used for a new application will. Existing hot water solar cells are also included System can be integrated.

The whole building (or container) gets relatively cheap through this and retrofittable equipment an additional heat insulation through the insulation materials used, so that even at night and less heating energy is used on sunless days.

Through the additional use of energy storage or one in the earth area Such a system is also installed heat exchanger surface during the sunless times with stored free energy still available. Due to the presence of warm air solar systems, Such an installation can be made with relatively little financial resources expand and generate electricity directly at the consumer during high energy Use summer months without impairing the Landscape structures emerge. For saving energy and heating costs In winter, apart from solar systems and energy storage, so far have not been more usable low temperatures, from waste heat z. B. of air conditioning, of cold stores, exhaust gases, or waste water still usable.

A subsequent installation of such a system can be done in stages respectively. The work required is fairly minor and done quickly if the system was designed with only one air gap becomes.

With two or more air gaps that have arisen as a side effect also not a lot more effort to operate when in the solar cells Control unit is integrated, which the escaping warm air in the right Air gap directs.

Even large building complexes can be equipped with such a system, with the solar cells a sun protection of the windows for the summer time can be created.

The complete encapsulation of a building or container from the positive usable temperature ranges of such a system is also possible.  

With a related application of solar cells one can Hot water energy storage not only recharge and recharge, but also at brake its discharge and in winter to lower temperatures use.

Other containers or boilers in the industrial sector can also be used this invention by relatively low waste heat better at temperature are kept (e.g. steam boilers when generating electricity if the Steam emerging from the turbines is used again in this regard becomes).

Claims (18)

1. Use of low temperatures, but above the ambient temperature, to reduce the heat losses in buildings, building surfaces or temperature-storing containers, characterized in that an existing positive temperature difference, e.g. B. from solar systems, from waste heat or from water or other sources to reduce the heat gradient of an indoor temperature to be insulated. 2. Plant according to claim 1, characterized in that one or more Cavities the casing of a container or the outer wall area divide a building into two or more cladding layers, thus the tempered medium (e.g. warm air or liquid) there is space and at the same time protected from the cold environment is, so that with the energy supply z. B. by solar cells or waste heat dispenser, but large wall surfaces with an insulation temperature can be covered. 3. Plant according to claim 1 and 2, characterized in that at several existing air gaps, the heated medium air or water over z. B. Valves and pipes in the correct temperature Gap is steered in order to achieve the best possible efficiency to reach. 4. Plant according to claims 1-3, characterized in that the as Medium used heat transfer medium, e.g. B. air, in a closed Circulates, and thus with its residual heat back into the Collector enters. 5. Plant according to claim 1-4, characterized in that occasionally occurring higher system temperatures z. B. when using solar panels and at least two void layers, one of which is close is on the inner wall area, the higher temperature values are used, to the inside cavity or an extra heat exchanger To heat the interior of the building or container. During the rewind of the heat transfer medium then takes place via the outer cavity and thereby additionally the existing heat gradient of the to be insulated Wall reduced.   6. Plant according to claim 1-5, characterized in that valves and Control units are integrated in the warm air solar collectors, so that only appropriate temperature sensors and pipe connections from the air gaps must be led to the outside, so that the solar panels can then simply be plugged on and no complex assembly work has to be done. 7. Plant according to claim 1 and 2, characterized in that the or Cavities through one with the appropriate distance, through spacers (e.g. counter battens), attached facing shell has arisen. 8. Plant according to claim 1 and 2, characterized in that by corresponding Masonry of hollow blocks for the tempered Air void streaks appear in the masonry. 9. Plant according to claim 1 and 2, characterized in that the solar panels are arranged below, so that the system by itself starts when it reaches a corresponding temperature advantage and through the medium without a blower or pump support Temperature and weight differences begin to circulate. 10. Plant according to claim 1 and 2, characterized in that only a single correspondingly wide air gap is used, the z. B. by the Installation of a subsequent external insulation is created and so solar cells or conservatories or glass stems without a special pipe layer and valves can be used for this purpose leaves. 11. Plant according to claim 1 and 2, characterized in that in the or the air gaps only heat exchanger z. B. with one or more pipes Cooling fins or in addition to the connected solar cells such or such pipes or heat exchangers are attached to Residual heat from a temperature source other than the solar cells to be able to use or share, by passing through the air in the air gap co-heated or only heated by it. 12. Plant according to claim 1 and 2, characterized in that another Medium as air (e.g. water) is heated in the solar panels and thus the air in some areas further away via heat exchangers  Air gaps such as B. north of the house or heated in energy storage can be. 13. Plant according to claim 1 and 2, characterized in that also an energy store is heated or heated with and thus in turn missing sun still a certain period of time with stored energy can be bridged. 14. Plant according to claim 1, 2 and 5, characterized in that they have energy storage by solar panels temporarily with solar energy, charges and reduces their heat losses at low temperatures, so that the stored energy is retained for longer and further use of temperature when extracting energy in winter allows down. 15. Multi-layer energy store according to claim 13 and 14, characterized in that a lower temperature than the interior temperature an insulated memory encased and that this lower Temperature itself in a memory that may be again from a lower temperature storage in front of a too large one Heat gradient is protected. 16. Plant according to claim 1 and 2, characterized in that z. B. the Cavities are also taken up directly by a medium other than air or are flowed through. 17. Plant according to claim 9, characterized in that the economy of air collectors is preserved even in summer by the warm air through chimneys adjacent to or integrated in the house conducted and thus used to generate electricity using thermal winds without the landscape being defaced by any towers becomes. 18. Plant according to claim 1, characterized in that z. B. also in the ground or in liquids compared to the ambient temperature positive temperature differences can be harnessed to the To reduce the heat gradient of a heated living space.