DE102008052184A1 - Device for maintaining indoor temperature in e.g. house, has convection channels through which convection current flows, where flowing convection current is limited according to its intensity and corrected according to its direction - Google Patents

Abstract

The device has a solar heat exchanger comprising heat accumulators (1, 22, 24) arranged for maintaining temperature gradients of water by heat insulation shields on heat zones (6) of the heat accumulators. Convection channels (7) are arranged in the shields, where ascending and descending convection current flows through the convection channels. The heat accumulators are provided with connection pieces that enter into each of the heat zones. The flowing convection current is limited according to its intensity and corrected according to its direction.

Description

The The invention relates to heat and solar technology namely, on objects of the room climate in different Buildings: Residential buildings, buildings, greenhouses, Orangeries, greenhouses, winter gardens and the economic spaces.

It is known accumulation of solar heat by the change of the phase state of the substance ( RU 2252374 , 20.10.2003.)

These Invention solves another problem. This patents is only for the solar heating of the tourist Tents predestined.

It is known the method of warming the greenhouse by the accumulation of heat energy in the pits in the summer time and their use in the season of low temperatures by means of the circulation of atmospheric air through the ground. The regulation of the microclimate of the hothouse is realized by the directed change of water in the layers of the soil, by creating the difference of the pressures in the hydrous layer ( SU 1496431 A01G 13/06.) This process is power-intensive and associated with heat losses at the expense of mixing warm and cold water and heat conduction, which means that the heat energy is not used usefully. The abundance of heat is not accumulated, but dispersed. This means that the heat energy is used less effectively.

A next analogue is the invention ( DE 10 2004 001 139 A1 , 31.01.2003), a complex resource-saving greenhouse in which the heat generated by composting is used as the main source of heat energy, and solar energy is used as an additional source of heat. Thermal energy with calculation of the minimum losses is given to the heat accumulator subject to creation and preservation of the maximum temperature gradient used for supply in hothouse departments of a greenhouse of the abandoned microclimate.

The main differences from the prototype are: the prototype requires the large tanks for the heat accumulator. It becomes especially suitable for use in complex greenhouses, greenhouses and in large agricultural objects where compost and process of its preparation are used. Prototype is the invention of the Russian Federation ( 2005128163 , 12.09.2005), it decides similar questions, but their effectiveness depends on the climate and the ground on which the building is built. The aim of the invention is to increase the efficiency and the economy, the extension of the range of application of the heat accumulator for the resource-saving ecologically clean indoor climate in various buildings. The essence of the invention is: resource-saving indoor climate in various constructions in which the solar heat energy is used as the main source, as an additional source of heat energy the solar energy and the internal heat of the earth and heat is used by different household appliances.

These Problems are solved by the in claims 1-25 deleted features listed. The resource-saving Indoor climate of the buildings, the accumulation of heat energy in the tank with the water in the heat accumulator including where to go through the temperature-dependent handover the heat energy from the water and the air in certain Zones of the volume of the heat accumulator - the Heat zone, which is characterized by a lower one to their size outside the heat zone static temperature gradient distinguished the temperature gradient creates and supports the water. The warming or the cooling of the air is through the heat exchange with the water from the corresponding heat zone of the heat accumulator realized, after the heat exchange, the water returns through the distributor into the other heat zone of the heat accumulator according to its changed temperature, back.

The transfer of heat energy from the water realized in the heat exchange in the solar heat exchanger. The tent roof of the building with the double roofing is used as the solar heat exchanger. As a solar heat exchanger it is used a tent roof of the construction, for which it is equipped with a double roof to provide a possibility of movement for water and air in a gap roofs, a transparent external roof and an internal roof, coming from a water collecting gutter with a casting and with consists of the discharge pipes that divert the heat energy of the water into the heat accumulator; the water supplied from the lower heat zones of the heat accumulator from the pump to the ridge of the roof is sprayed in the space between the roofs, the cooled air taken in is taken from the interior of the building, the water flowing down the inner roof decreases in heat exchange with the solar heating roof construction and part of the air, warms up and goes through the distributor into the heat zone of the heat accumulator corresponding to its temperature. The heat accumulator is used to maintain the temperature gradient of the water through the thermal insulation screens to the heat zones assigned. The convection channels are installed in the thermal insulation screens in such a way that the ascending and descending convection currents flow through the various channels.

In order to the heat accumulator with the convection channels equipped with lugs in enter that heat zone of the heat accumulator, where through them convective currents flow, the limited by them according to the intensity and direction Getting corrected.

to The next construction of the heat accumulator will be realized recommended: each heat zone will be one or more Assembled tubes whose axes are horizontal respectively forming acute angles with the horizontal; the pipes are with the other heat zones through the verticals respectively with the vertical approach forming the acute angle tube approaches connected in which the convection channels set up become.

The other construction is technologically in fulfillment. The sockets in it are correspondingly by one or several rows the vertical pipes passing through the heat insulation screens divided into the heat zones where the convection channels set up The pipes will go through with the other heat zones the horizontal or with the horizontal tip Angle forming the pipe sockets or pipes connected. At least one row of the vertical tubes of the heat accumulator is set up from the outside of the building; have along the pipes, the lower ones deeper than 1.5-3 m below ground below the construction laid heat zones of the heat accumulator and from the outside of the building furnished pipes one Thermal contact with the ground. The outer part of the Heat accumulator as the excavation with the hydroisolierten inner surface, with the stones, the big one Have heat capacity, be filled, the distances between the stones can with the Water to be filled.

The adapted distribution of the temperature gradient under the construction and in the adjacent zones by the directed heat transfer the abundance of heat energy of the outdoor unit of the heat accumulator and the surrounding soil becomes; what the heat accumulator with a heat shield is equipped, which has a good reflective surface has and the lower more than 1.5-3 M lower heat zones of the heat accumulator, the black surface have a good thermal contact with the ground is ensured this results in the transfer and accumulation of heat energy not only in the heat accumulator, but also in the adjacent ones Zones of the soil.

This allows the inner warmth of the earth to be used that heated by the heat exchange with the ground Water rises with the rising convection currents, because some of the vertical tubes of the heat accumulator with the water in the drilled holes drilled in the ground be set up.

Of the Heat accumulator is in the hydro-insulated basement under the Arranged, at least by one of the wall of the cellar, which is partially or completely thermally conductive, the heat transfer from the internal heat accumulator its outer part is guaranteed.

Of the Heat accumulator is placed in the hydro-insulated basement, that part of the cellar is filled with water, divided by the partitions that make up the labyrinth, prevents the mixing of the water in the partitions are the channels or holes for the water or Pipes with water, and also air pipes which are good Heat exchange through the walls of the pipes and the Air ducts to be ensured with the water of the lower part of the basement.

Of the Outer part of the heat accumulator, is a ditch with the hydro-insulated surface, filled with the stones, the large heat capacity arranged according to the perimeter of the building or the internal heat accumulator. The distances between the stones can with the Water to be filled, the outer part connects with the internal heat accumulator for the Heat transfer through the tubes of the lower heat zones. the outer heat zones become the cold one Removed water for heat exchange.

The water from the lower part of the cellar participates directly in the heat exchange process; for which the lower parts of the heat accumulator are equipped with the valves, regulate the floats or the electromagnets, the valves will take the water from the basement for heat exchange and kernt returned to the basement at the same level in the heat accumulator after heat exchange, and the heat-insulated partitions, which are raised to the level of the water, are connected to the heat-insulated floor, through which the air which has flowed through the windows in the partitions to the air ducts of the heat accumulator acts. Water for cooling a tent roof of a building from a water column and after heat exchange, water enters the internal heat accumulator, from it in a cellar, and from a cell it comes to outside part of the heat accumulator, from there surpluses of water for the needs within of the construction, for example, in the complex greenhouse for watering, exploited or drained into the outer pond.

Of the Heat accumulator with additional accumulation the heat energy by the change of the phase state of the substance, the container with this substance in the level is placed in the heating zone whose maximum temperature higher than its melting point; that the volumes with the substances, for example pipes or containers, in the pipes with the Water in the heat zones of the heat accumulator are arranged, regulating the dynamics of participation of this Stoffs in the process is determined by the ratio of the number of Convection channels or the change of the air flow in the air ducts of the heat accumulator, with them has reached the thermal contact.

Of the Airspace of the heat accumulator, where the heat zone be set up by the thermal insulation screens is divided, passed through this the air ducts be going to the regulation by the heat accumulator Air streams, both convection air streams, as also to ensure the ventilation currents.

In The reason is placed heat shield, which is a good reflective Surface has, the outside embracing of the building foundation along to the heat radiation losses to reduce. The heat shields also set up under the construction, and ensures the angle of installation of all heat shields the maximum reflection of heat radiation to the direction the inner heat accumulator and (or) its outer part. Of the Heat accumulator, heat insulation screen and the Heat shields from the double plate, each one of them has good reflective surface, so is composed that in the gap between the plates either a dilution or a vacuum is created, this condition is maintained thanks to a of the two panels connecting net-like equipment, which forms a mesh structure in which the tightness of each individual Mesh is secured. The heat shield consists of double metallic sheet, consisting of two different fabrics, the have a good reflective surface. This will be the Reduction of thermal losses and maintenance of the temperature gradient guaranteed. Effectiveness of the room climate depends on Heat exchanger, solar heat exchanger - solar heat exchanger The solution prescribed below is aimed at increasing the effectiveness. It is used as a solar heat exchanger the tent roof of the building, for which it is equipped with double roofing is going to be the possibility of movement for water and air in the space to ensure the roofing. The inner roofing becomes the water collecting gutter with the casting and with Equipped with drainage pipes. The heat energy of water drains into the heat accumulator.

The Inner roofing becomes partially or completely uneven Surface executed: stepped or wavy with partially opaque or toned fabric from the areas after which the water can drain off.

The Tiered roof can be stepped, wavy or gregarious as well as constructive Ways, and also carried out by use of special roofing materials become. The heat energy of the water drains into the heat accumulator. The water gets out of the lower heat zones of the heat accumulator from the pump to the ridge in the space between sprayed or sprayed the roofing, it is in the interior of the building cooled down Taken air, the inner cover down-flowing water takes heat exchange with that of the sun's warmed Roof construction and the air part, heats up and goes through the distributor into the heat zone corresponding to its temperature of the heat accumulator.

In the zone of the roof ridge, the distribution channel is set up, the water delivered without the extra water pressure will, according to the lower-lying inner roofs and directional strips equally distributed. The water is with the more economical process without an additional water pressure delivered. It allows to use the weak pumps and save the electrical energy. The accumulation of solar energy in the heat accumulator takes place thanks to the energy, which on the Cooling of the air is consumed in construction, so without additional Energy expence.

The Solar thermal energy is subject to calculations The minimum losses are created in the heat accumulator and the preservation in it of the stable temperature gradient passed on, the room climate abandoned for the supply in the buildings is used.

Therefore the problem of accumulation of thermal energy is decided in the most profitable procedures. The solution to this problem contributes to increasing the efficiency. For the reduction of the material intensity is not the whole construction of the roof, but only the sunlit roof surfaces, their edges and the roof tapes are used on these roof surfaces as a solar heat exchanger, that is, the roof construction is only partially covered twice; For complex roofs with several roof surfaces, the inner roofing is equipped with additional casts and distribution channels that direct the water to the lower-lying roofs and gutters Directional strips, or in the pipes, in addition collecting the heat energy of the water, distribute the heat exchanger.

Of the Solar heat exchanger in which the space of heat exchange on the outer part and the inner parts, passing through a partition wall or a blind be divided; if the two Roofs of the roof are transparent, the dividing partition wall becomes from a toned fabric, or from the fabric, its transparency depending on the intensity of the solar radiation changes, If the inner roof is opaque then it will be made the dividing wall made of any thermally conductive material made with blackened surface. The Water flows to the surface of the septum in its outer part, against the rising warm Air, and the cooled air is in the inner part, which borders on the inner roof of the building, which cooled from there Air is directed into the building.

Of the Solar heat exchanger also closes the facade part one, whose inner part represents one with the concave blackened Side facing the sun and the thermal contact with the tubes located cylindrical surface, the Pipes in the form of serpentine stone carry the water into the heat accumulator, and its outer part provides from a transparent tube or a transparent one Lid one on the sunlit facade of the construction Facade part is equipped with the base parts is connected, this represents a transparent lid, the the sunlit base part of the building closes, above he is with the outer surface of the facade part tightly connected. The lower base part thus covers the heat shield, that between the base part and the heat shield the air can come, and he rests on the air-permeable Substance that ensures the filtering of the incoming air; its inner part consists of the pipes and the water collecting gutters, the collecting and distribution of the effluent water ensured by the inner roof or the pipes, where the water is additionally heated, and then is directed into the heat accumulator.

The Facade part and the base part represents a transparent tube with the reflective cylindrical surface through that moves the air; the reflective cylindrical surface is concentrated the sun's rays on the water flowing internal Pipe with a solar absorber surface.

These Construction of solar heat exchanger shows network of Channels from the pipes with a transparent of the sun facing surface channels are produced which is laid by the colonel in the horizontal level - ridge channel branch; where the water flows into and from where Air is taken. The channels are on the of the Sun heated roofs installed, hanging ducts connect the top ridge channel with the cornice. The Channels either in the depressions of the roof or on their Surface to be installed, from the transparent tube approaches assembled as components or in separable form from above through the transparent lids are closed. In the channels will be set up the light rotors. The lightweight rotors can be turned by the flowing water. The cross sections These channels of the solar heat exchanger can not only a round or oval shape, but also can a sector, segment or semicircular shape, also the shape of a triangle, of the quadrilateral, the pentagon or polygon.

For the avoidance of condensate within the building becomes the next Solution proposed. The condensate drainage channels through which dissipates the condensate in the condensate collector and afterwards as replacement of the water losses in the heat accumulator used in the building interior to those cooled by water Elements of construction with a gap that allows wide access for ensuring free air to them consolidated become. The air flows of the incoming ventilation flows are directed along the condensation gutters. These natural continuation and the supplementation of such Construction that increase the effectiveness guaranteed.

The full variant of such construction of the indoor environment with the solar heat exchanger and the heat accumulator will be submitted below.

Of the Outer part of the heat accumulator and the heat shield is from the outside of the foundation of the building under the transparent cover of the base part of the solar heat exchanger are arranged, while he takes the outer part of the heat accumulator the part of the sides of the perimeter. The outer part of the Heat accumulator lies along the sunlit facade of the building, the upper outer part of the heat accumulator becomes with the air-permeable fabric, for example, the Porosinter gravel, spilled, the air supply is through the pore sinter gravel the bottom of the base part of the solar heat exchanger executed, and the filtering quality and the Initial change of air characteristics in the passage of air thanks to the air-permeable fabric which is thanks to recess ensured the transparent cover of the base part.

The air ducts from the base part of the solar heat exchanger are directed under the Lay the gravel pore gravel of the outer part of the heat accumulator, then pass it through the labyrinth under the cellar floor to the inner heat accumulator and through it the air ducts lead to the top part of the tent roof of the building.

These Solution contributes to increasing the effectiveness when using for in the complex greenhouses, the greenhouses.

outer part of the heat accumulator is equipped, partially or completely arranged according to the perimeter of the hothouse or internal heat accumulator under the layer of the pore sinter gravel of the gravel and top is covered with the transparent lid of the base part covered by the solar heat exchanger. The transparent lid the base part forms the transparent outer roof of the Tent roof of the hothouse, the low part of the outer roof becomes in the gravel of the pore gravel thanks to recess, the space part under the outer roof of the greenhouse is like the base part the solar heat exchanger is equipped. The Water will cool down after the shady side of the Tent roof of the greenhouse the heat energy of the exterior part of the heat accumulator handed over.

This solution contributes to increasing the effectiveness. The resource-saving indoor climate in buildings has many functionalities. The air ducts, the furnace trains, the vents and the ducts are blocked with the sliders connected with switching drives, which can also be controlled automatically, as well as with the help of simple electronic equipment according to the temperature sensors optimal regulation realize optimal specifications. Selection of schemes of functioning air ducts or channels of a heat exchanger, as well as complex electronic systems which maintain a certain temperature and humidity with use of several regimes of optimum control taking into account the given parameters and selected programs. The first variant will be the residential house with gable roof on the 1 shown. On the 1 is the cross section of the vertical secant from the plane of the house, according to the first variant. It includes: The heat accumulator 1 , the solar heat exchanger the ridge channel 2 , the solar heat exchanger, the hanging ducts 3 , the solar heat exchanger, the façade part 4 , the solar heat exchanger, the base part 5 , the horizontal tubes of the heat zone 6 , vertical pipe connections with convection channels 7 , the air pipes 8th , the container with the substances changing the phase state 9 , the air receiver 10 , the pipes of the water 11 , the dividing partition of the ridge channel 12 , the dividing partition wall of the Hangkanals 13 , the transparent cover of the ridge channel of the solar heat exchanger 14 , the transparent cover of the slope channel of the solar heat exchanger 15 , the condensate drainage channel 16 , the water collecting gutter 17 , the pipe in the form of serpentine stone of the facade part 18 , the transparent cover of the base part of the solar heat exchanger 19 , the reflective cylindrical surface 20 , The air-permeable fabric represented, for example, the gravel pore gravel 21 , the fermented bottom tube of the heat accumulator 22 , the heat shield 23 , the outer part of the heat accumulator 24 , the heat-insulated partitions 25 , On the figs 2 is the cross section of the complex greenhouse. It includes: The heat accumulator 1 , the solar heat exchanger the base part 5 , the horizontal tubes of the heat zone 6 , the vertical of the tubes with the convection channels 7 , the air pipes 8th , the container with the substances changing the phase state 9 , the pipes of the delivery of water 11 , the solar heat exchanger 14 , the transparent cover of the slope channel of the solar heat exchanger 15 , the water collecting gutter 17 , the pipe in the form of serpentine stone of the facade part 18 , the transparent cover of the base part of the solar heat exchanger 19 , the reflective cylindrical surface 20 , The air-permeable fabric represented, for example, the gravel of the pore interlacer 21 , the fermented bottom tube of the heat accumulator 22 , the heat shield 23 , the outer part of the heat accumulator 24 , the heat-insulated partitions 25 , the outside roof 26 , the inner roofing 27 , Distribution channel 28 , the air receiver through the pebble gravel of the gravel 29 , Pipes with the warm water 30 , On the figs. 3 are the variants of On the figs 3 Variants of designs of hanging channels of a solar heat exchanger are provided: Variants of designs of transparent covers 15 , the condensate drainage channels 16 , the lightweight rotors 31 ,

Let's take a look at some functionalities of the resource-saving indoor climate according to the 1 at. All parts of the solar heat exchanger together form the unified ventilation system, which changes the filtration, temperature and humidity of the fresh air, and which ensures the required indoor climate with profitable processes within the building. It is calculated on the steady functioning, but can be used in certain periods, for example, if its use is particularly effective. In the sunny summer day the external air enters the base parts of the solar heat exchanger, overcomes the air-permeable partition, filters and runs into the base part of the solar heat exchanger 5 , and then to façade parts and suspension ducts of the solar heat exchanger in the upper zone of the ridge channel 2 when its temperature is up exceeds the specified limit, the pump turns on, which takes the cold water to the pipe 11 supplies. The water is sprayed or distributed through the nozzles. The water flows to the hanging channels 3 Solar heat exchanger, participating in the heat exchange, warms itself and at the same time cools the oncoming air, if the cooling of the air is not sufficient, so the air from that part of the heat exchanger penetrates, where the water is sprayed or sprayed. The air is then directed into the room or into the air duct of the heat accumulator. The water enters the water collection channel 17 into the drainage tube of the serpentine stone form 18 the base part of the solar heat exchanger, where is additionally heated by the sun, and enters, through the distributor, in the heat zone of their temperature corresponding to the heat accumulator. The water catcher is led out of the cold peripheral zone of the heat accumulator. The accumulation of heat is led to the outside from the central part of the heat accumulator. Thus, the transfer and accumulation of heat energy is performed not only in the heat accumulator, but also in the adjacent zones of the soil.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - RU 2252374 [0002]
• - SU 1496431 [0004]
• DE 102004001139 A1 [0005]
• - RU 2005128163 [0006]

Claims (26)

The resource-saving indoor climate in buildings, which includes accumulation of heat energy in the water tank in the heat accumulator, where by the temperature-dependent transfer of heat energy from water and air in certain zones of the volume of the heat accumulator - the heat zone, which is characterized by a low static in temperature gradient compared to its size outside the thermal zone, creates and sustains the temperature gradient of the water; the heating or the cooling of the air is realized by the heat exchange with the water from the corresponding heat zone of the heat accumulator, after the heat exchange, the water returns through the distributor into the other heat zone of the heat accumulator according to its changed temperature, according; the heat accumulator is classified for maintaining the temperature gradient of the water through the heat shields on the heat zones in which the convection channels are arranged in such a way that the ascending and descending convection flows through the various channels, characterized in that the heat accumulator with the convection channels with is equipped with the end pieces which enter each heat zone of the heat accumulator, where they flow convection currents, which are limited by the intensity and corrected for the direction. The resource-saving indoor climate with the heat accumulator according to claim 1, characterized in that each heat zone composed of one or more tubes whose axes horizontally or the acute angle with the horizontal are aligned; the pipes become with the other heat zones through the vertical or with the vertical tips Angle forming the pipe joints connected in which the Convection channels are set up, characterized that the pipe approaches accordingly by one or several rows the vertical tubes are replaced by the thermal insulation screens are divided into thermal zones in which the convection channels be set up, the pipes are with the other heat zones through the horizontal or with the horizontal the acute angles forming the pipe sockets or pipes connected. The resource-saving indoor climate with the heat accumulator according to claim 1, characterized in that the Outer part of the heat accumulator as the excavation with the hydro-insulated inner surface with the stones, have the large heat capacity, filled is, the distances between the stones can be filled with the water. The resource-saving indoor climate with the heat accumulator according to claim 2, characterized in that the adapted Distribution of the temperature gradient under the construction and in the adjacent Zones by the directed heat transfer of abundance the heat energy of the outer part of the heat accumulator and the surrounding soil is ensured; for this is the heat accumulator with a heat shield equipped, which has a good reflective surface has and thereby lower with the lower more than 1,5-3 m placed heat zones of the heat accumulator, the one have black surface, good thermal contact with the ground, that results in the surrender and accumulations the heat energy not only in the heat accumulator, but also in the adjacent zones of the soil. The resource-saving indoor climate with the heat accumulator according to claim 4, characterized in that also of The inner warmth of the earth is made use of: the water heated by the heat exchange with the soil rises with the rising convection currents, because some vertical pipes of a heat accumulator with water into the drilled holes drilled in the ground become. The resource-saving indoor climate with the heat accumulator according to claim 5, characterized in that it is in the hydro-insulated basement under the building, at least through one of the basement walls, which is partially or completely thermally conductive, the heat transfer from the internal heat accumulator its outer part is guaranteed. The resource-saving indoor climate with the heat accumulator according to claim 6, characterized in that the heat accumulator in the hydro-insulated basement is placed, that the cellar part way filled with water and from the partitions which forms the labyrinth, the mixing of the water is prevented, in the partitions are the channels or holes for the water or pipes with the water, and also air ducts that allow the good heat exchange Walls of pipes and air pipes with water of the lower part of the cellar. The resource-saving indoor climate with the heat accumulator according to claim 7, characterized in that the outer part of the heat accumulator is to be made like the trench with the hydro-insulated inner surface arranged according to the perimeter of the building or the inner heat accumulator connected to the bricks have high heat capacity, is filled, the intervals between the stones are filled with the water, the outer part connects to the internal heat accumulator for heat transfer through the tubes of the lower zones, from the outer zones of the cold water is removed for heat exchange. The resource-saving indoor climate with the heat accumulator according to claim 8, characterized in that the water from the lower part of the cellar directly at the heat exchange process increases; for this are the lower parts of the heat accumulator equipped with valves on floats or electromagnets regulate, over the valves, the water from the basement removed for heat exchange and returns to the cellar at the same height in the heat accumulator after the heat exchange back, the heat-insulated partitions, close above the water level to the heat-insulated floor, under the through the windows in the partitions the air to the Air lines of the heat accumulator flows. The resource-saving indoor climate with the heat accumulator according to claim 9, characterized in that the water for the cooling that Tent roof of the construction from the watery column and after the heat exchange into the inner heat accumulator enters, into the cellar, and from the cellar into the Outer part of the heat accumulator, from there the surpluses of the water for the needs within the building, for example in the complex greenhouse for watering, exploiting or in the outer pond drained. The resource-saving indoor climate with the heat accumulator according to claim 10 with the additional accumulation the heat energy by the change of the phase state of the Stoffes, characterized in that the container with this substance is placed in the levels of the heat zone, its maximum temperature is higher than its melting point is; the volumes with the substances, for example pipes or containers, in the pipes with the water in the heat zones of the heat accumulator arranged the regulation of the dynamics of participation of this substance in the process is determined by the ratio of the number of convection channels or the change in the air flow in the air ducts the heat accumulator, the thermal contact with them has reached. The resource-saving indoor climate with the heat accumulator according to claim 11, characterized in that its air space, where the heating zone is installed, through the thermal insulation screens divided, through which the air ducts are passed, to the regulation of going through the heat accumulator Air flows, both convection airflows as well To ensure ventilation flows. The resource-saving indoor climate according to the claim 12 in buildings where heat shields are placed in the ground, which has a good reflective surface, the outside Surrounding the building foundation is placed along the heat dissipation losses reduce, characterized in that the heat shields are also set up under the construction, and the angle of installation all heat shields ensures the maximum Reflection of heat radiation in the direction of the inner Heat accumulator and (or) its outer part. The resource-saving indoor climate according to the claim 13, characterized in that the heat accumulator, the thermal insulation screen and the heat shields consist of a double plate, each of them has a good one has reflective surface that is composed so that either a dilution in the gap between the plates or a vacuum is created, this condition is maintained thanks a net-like equipment connecting the two panels, which forms a mesh structure in which the tightness of each individual Mesh is secured. The resource-saving indoor climate according to the claim 1, characterized in that in the building one as a solar heat exchanger used the tent roof of the building, what with the double roof is equipped to the possibility of movement to ensure the roofing for water and air in the space between them, the transparent outer roof and the inner roof, one Water collecting gutter with a casting and equipped with the discharge pipes, the heat energy of the water in the heat accumulator derived; from the lower heat zones of the heat accumulator of The pump to the ridge water supplied is in the room sprayed or sprayed between the roofing, from it is the cooled in the interior of the building the led Taken from the air, the inner roof down flowing water takes on the heat exchange with the sun-warmed Roof construction and the air part, heats up and goes through the distributor into the heat zone corresponding to its temperature of the heat accumulator, characterized in that the inner cover partly or completely with an uneven Surface is equipped: stepped or wavy with partially opaque or tinted fabric in the areas where the water can drain. The resource-saving indoor climate after Claim 15 with the accumulation of solar energy in the heat accumulator thanks to the energy consumed in the cooling of the air in the construction realized without additional expenditure of energy, characterized in that the inner roof tiered, wavy or gaufriert not only the constructive ways, and also fulfilled the application of special roofing materials. The resource-saving indoor climate with the solar heat exchanger according to claim 15, characterized in that in the zone of the roof ridge the distribution channel is set up, which is the water without the additional water pressure in the low-lying inner roofs and directional strips evenly distributed. The resource-saving indoor climate after with the solar heat exchanger according to claim 16, the space of the heat exchange on the outer part and the inner parts by a partition wall or a blind is divided; if the two Roofs of the roof are transparent, the dividing partition wall becomes from a tinted fabric or from the fabric, its transparency varies depending on the intensity of solar radiation, is made, if the roof is opaque, then The dividing wall is made of any thermally conductive Fabric made with blackened surface, thereby characterized in that the water is after the surface of the Partitions in their outer part, against the ascending warm air flows out, and the cooled air flows in the inner part, which borders on the inner cover of the building, the cooled air flows into the building. The resource-saving indoor climate with the solar heat exchanger according to claim 18, characterized in that as solar heat exchanger not the whole construction of the roof, but only the sunlit ones Roof surfaces, their edges and the roof tapes on These roof surfaces are used, that is the roof construction is only partially covered twice; For the complicated roofs with several roof areas becomes the inner roof with the additional leads and the distribution chutes, which the water up the lower-lying roofs and directional strips, respectively in the tubes of the heat exchanger, in addition to the Accumulating heat energy of water, distribute. The resource-saving indoor climate with the solar heat exchanger according to claim 19, also includes the facade part one, whose inner part represents one with the concave blackened Side facing the sun and getting in thermal contact with represents the cylindrical surface of the tubes, the pipes in the form of serpentine stone carry the water into the heat accumulator, and its outer part consists of a transparent tube or a transparent one Lid, with which sunlit facade of the building equipped a facade part which is connected to the socket part, this one sets transparent lid, the sunlit base part of the building closes, it is above with the outer surface the facade part tightly connected, characterized in that the lower base part covers the heat shield so that can between the base part and the heat shield come the air and he relies on the breathable fabric, which ensures the filtering of the incoming air; its inner part consists of the pipes and the water collecting gutters, which the collection and distribution of the effluent water ensure from the inner roof or the pipes, where the water is additionally heated, there comes put it in the heat accumulator. The resource-saving indoor climate according to the claim 20, characterized in that the facade part and the base part a transparent tube with a reflective cylindrical surface through which the air moves; the reflective cylindrical Surface concentrates the sun's rays on the water dissipating inner tube with a solar absorber surface. The resource-saving indoor climate with the solar heat exchanger according to claim 20, its construction provides in the form of the roof scaffolding or network of channels from the tubes in the transverse Cut not only a round or oval shape, but also a sector, Segmental or semicircular shape, also the shape of the triangle, the Rectangles, pentagons or polygons are possible with a transparent surface facing the sun Channels produced by the Colonel in the horizontal level laid down - ridge channel; the flows into the water and from which the air is taken which is on the roofs heated by the sun installed channels - hanging channels connect the top ridge channel with the cornice, which Channels either in the depressions of the roof or on their surface will be installed, from the transparent Pipe fittings mounted as components or separable Shape from above through the transparent lid closed, thereby characterized in that in the channels the light rotors arranged, which turned in the draining water become. The resource-saving indoor climate according to claim 22, characterized in that the condensate drainage channels through which the condensate discharged into the condensate collector and thereafter used as a substitute for water losses in the heat accumulator, being internally consolidated to the water cooled elements of the construction with a gap ensuring sufficient free air supply to them. The resource-saving indoor climate according to the claim 23, with the heat accumulator according to the patent claim 12 with the outer part of the heat accumulator after according to claim 8, characterized in that that the outer part of the heat accumulator and the Heat shield from the outside of the foundation of the building under the transparent cover of the base part of the solar heat exchanger are arranged, it takes the outer part of the heat accumulator the part of the sides of the perimeter, but it lies along the sunlit facade of the building, the upper outer part of the heat accumulator becomes with the air permeable Fabric, for example, the pore gravel, spilled, the Air is supplied through the porosine gravel in the lower base part performed the solar heat exchanger, the filtering quality and the initial change of the air characteristics are at the Passage of air through the breathable fabric thanks the recess of the transparent lid of the base part ensures; the Air ducts from the base part of the solar heat exchanger be under the layer of gravel of pore interlacer of External part of the heat accumulator set up, then they are leaving the labyrinth under the floor of the basement to the inner heat accumulator and through it The air ducts lead to the top of the tent roof of the building. The resource-saving indoor climate according to the claim 17 or 24, with the heat accumulator according to the patent claim 10-12 is equipped with the outer part of the heat accumulator and partially or completely after the perimeter of the construction or inner heat accumulator set up under the layer pebble gravel and above becomes transparent Cover the base part of the solar heat exchanger covered, characterized in that the transparent lid of the base part the transparent external roof of the tent roof of the hothouse forms, the low part of the outer roof is in the Gravel of the pore scotch thanks to a depression, the part of space under the outer roof of the greenhouse is like the base part the solar heat exchanger according to claim 20 or 21 is equipped; and the water gives way the cooling on the shady side of the tent roof of the hothouse the heat energy of the outer part of the heat accumulator.