DE102006047126A1 - Device for energy conversion - Google Patents

Abstract

The invention relates to a device (2) for energy conversion, which is designed to suck in the area of a building boundary air and to transmit thermal energy of the extracted air.

Description

The The invention relates to a device for energy conversion, a device for energy conversion, a first method of energy conversion, a second Energy conversion process, a computer program and a computer program product.

In Times of scarce and therefore more expensive becoming energy, it offers itself to develop new sources of energy. Within of buildings this may mean constructing them in such a way that generated Thermal energy is not lost or used again in a suitable manner.

The publication DE 198 36 011 A1 relates to a device for air conditioning and water heating. Here, a heat source with several different types of heating and a cold source for air conditioning is provided, the heat source is used simultaneously for hot water and if desired or need as a heating medium for a radiator network. This device is particularly suitable for low-energy houses, it includes, inter alia, an air-water heat exchanger, wherein cold water from an underground rainwater storage and hot water eg. Directly from the air-water heat exchanger, which is connected downstream of a solar air collector, is provided.

The publication DE 197 09 974 A1 relates to a method for air conditioning of buildings. For this purpose, a fresh air exhaust system is passed through a heat storage to cool the fresh air in summer and warm the fresh air in winter. Fresh air and exhaust air are guided in countercurrent principle by interconnected lines such that the heat energy present in the exhaust air is recovered profitably.

A device in a building for the recovery of heat energy for a heat pump is in the document DE 202 03 713 U1 described. This device is provided on a cold, flowed through by a heat exchange medium side with a flow and a return. In addition, the device comprises a connected between the flow and the return, mounted on a wall or on the roof of the building air / liquid heat exchanger. It is envisaged that this heat exchanger is arranged to form a gap with a small distance from the wall or the roof, wherein the intermediate space is in communication with at least one manifold laid in the building for exhaust air generated in the building.

A solar-thermal heating and industrial water treatment plant is in the document DE 296 04 530 U1 disclosed. This system includes a solar collector, a heat pump, insulated piping, combi storage, regulators and temperature programming and safety technology. It is envisaged that blackened solar absorber are traversed by solar water temperature sensors of heating water or antifreeze. These lie on a roof insulation separated by a heat protection film and are covered by an insulating plate and a rainproof sheathed, transparent thermal insulation.

The publication DE 10 2004 028 662 A1 relates to an exterior wall heating and cooling belt intended for heating and cooling a building. This outer wall heating and cooling belt is pressed into steel plates for good temperature transfer. At the same time, through a substructure, louvers corresponding to an interior partition are arranged such that the entire outer wall surface of individual rooms is flown with cold or warm air. On an outside of the cooling and heating belt, the usual today exterior wall insulation is covered with plaster carriers or other exterior wall elements. The outer wall heating and cooling belt makes it possible to heat reversible heat pumps with solar, ground, water and air heat with a high performance building in winter and to cool in summer by lowering system temperatures.

The inventive device for energy conversion is designed to be in the area of a building boundary Suction air and transfer thermal energy of the extracted air.

The Thermal energy is in this case a suitable heat transfer medium, in particular Water that heats up being transferred. It can be provided that the device with the heated Water a building supplied and thus heated becomes. Furthermore it is alternative and / or supplementary possible, from the thermal energy of the air and in particular by means of the heated To generate water electrical energy.

In In one embodiment, the device comprises at least one in the area the building boundary arranged air suction line and a heat pump. It is the least an air suction line for sucking air formed.

The heat pump is designed to provide water with thermal energy of the air, which is usually through the at least one air suction line is to be sucked, to heat.

The at least one air suction line usually has openings suitable for sucking off the air, which for example are designed as valves or holes are on. In addition, the at least one air suction line cooperates with at least one air suction device which is designed as a suitable pump or suitable fan for sucking off the air. In this case, the at least one air extraction device can be integrated in or connected to the at least one air suction line.

In an area of the building boundary air Suction can mean that the air is within the building boundary is sucked off. In this case, the at least one air suction line within the building boundary arranged. Alternative or supplementary The air can also be inside the building in the area and thus in in close proximity to the building boundary be sucked off. Accordingly, the at least one air suction line to arrange such that they also suck air through them within the building is.

When building restriction are usually called those building envelopes, the building outward delineate. The building boundary is usually as a roof or as a wall, in particular outer wall formed. The at least one Luftabsaugleitung is therefore in the range of the roof and / or the Wall, for example, in the roof and / or wall, arranged.

In In another embodiment, the device has a mixing chamber and a first turbine on. In this case, the at least one air suction line is to designed to supply air to the mixing chamber. The first turbine is designed to be the heat pump Supply air from the mixing chamber.

In addition, can the device has a water system into which the heated water from the heat pump promoted becomes. This hot water system can regularly a heating circuit or a corresponding heating arrangement, a hot water tank and / or a sanitary Include water system with a process water circuit.

to Generation of electrical energy can make the heat pump of the facility one with a generator over having an axis connected second turbine, said second Turbine through the heated Driving water is. The heated Water can be used for cooling by means of a heat exchanger in the mixing chamber or in an exhaust duct of the device to be cooled.

Of Furthermore, the device may have at least one control device, eg a building control system, which is adapted to an operation of the device to control. In this case, the at least one control device as a control device for controlling the operation of the device be educated. Alternatively and / or additionally, the at least one Control device as a control device for controlling the operation of Device be formed.

The inventive device for energy conversion includes a heat pump. Here is the device and especially the heat pump formed from thermal energy stored in a heat transfer medium is to provide electrical energy.

A such formed for the production of electrical energy heat pump the device can be independent operated by an origin of the heat carrier become. Accordingly, it is not essential that the air from a building boundary is to be sucked off. This heat pump and In particular, an evaporator of the heat pump can the environment, in usually extract heat from water, soil and / or air and by suitable transformation from this heat electric current and thus generate electrical energy.

The Device is designed in an embodiment, from the thermal To generate energy from air electrical energy. It is with the thermal energy from the air, for example, to heat water, so that the electrical energy is also indirectly from the heated water is to produce.

In an embodiment the device is designed to suck air. For this the device may have at least one air suction line, which is designed for the extraction of air.

The At least one air suction line can be in the area of a building boundary and in particular be arranged within the building boundary. The building boundary is usually designed as a roof and / or as a wall.

Of Further, the device may include a mixing chamber and a first turbine exhibit. In this case, the at least one air suction line is designed to to supply air to the mixing chamber. The first turbine is regular is formed, the heat pump Supply air from the mixing chamber.

In In another embodiment, the device has a hot water system in which the heated Water from the heat pump promoted becomes.

The device and in particular the heat pump has in a further embodiment alternatively and / or additionally a second turbine connected to a generator, wherein this second turbine is driven by the heated water is ben, so that by means of the generator and thus with the heat pump of the device to generate the electrical energy.

In addition, can the device at least one as a control device and / or Control device trained control device. This is designed to control an operation of the device and in particular to control and / or regulate.

at the first method according to the invention to energy conversion is in an area of a building boundary Air sucked. In addition, thermal energy is transferred to the extracted air.

at the implementation of the process becomes the thermal energy stored in the air or thermal energy on a heat transfer medium, in particular Water, transfer, so that this heat transfer medium heated becomes.

With The water heated in this first process can supply a building become. It is also conceivable, by means of the heated water electrical energy to create.

In Design is the air and thus within the building boundary aspirated.

In a further embodiment of the first method is provided that by means of at least one air suction duct, which in the area the building boundary is arranged, air is sucked off. The water is made by means of a Heat pump with heated thermal energy of the extracted air.

Of further, the air from the at least one air suction line fed to a mixing chamber be and by means of a first turbine from the mixing chamber of the heat pump supplied become.

at One realization of the first method is the heated water from the heat pump conveyed into a hot water system. It is equally possible over the heat pump by means of a second turbine, a generator which has a Axle connected to the second turbine, driving, causing electrical Energy is generated.

The entire first method or at least individual steps of the method can over at least a control device to be controlled. This can mean that the procedure over at least a control device designed as a control device is controlled. It is also possible the procedure over at least one control device designed as a control device to regulate.

This The first method is in particular with the device according to the invention perform individual steps of this first method with individual components this institution performed can be.

The Invention also relates to a second method of energy conversion, in the case of a heat pump from thermal energy stored in a heat transfer medium, electric Energy is provided.

This second method can in particular with the device according to the invention be performed, wherein individual steps of this method with components of the device according to the invention carried out can be. Likewise, by Functions of the device according to the invention As well as individual components of this device, steps of the method according to the invention are carried out.

at This second method is used in particular from the thermal energy generated by air electrical energy. This can be done with thermal Energy from the air heats water so that it is possible is that the electrical energy, for example, electric power, off the heated one Water is generated.

If as a heat carrier air is provided, this can usually be especially in the field a building boundary be sucked off.

In Embodiment of the two-way is the mixing chamber For example, sucked air supplied, In addition, a first turbine of the heat pump air from the mixing chamber fed. As well a second turbine can be powered by the heated water. Through this second turbine, a generator can be driven, so that by means of the generator, the electrical energy is generated.

The inventive computer program with Program code means is suitable for all steps of the first to carry out inventive method, if the computer program on a computer or equivalent Arithmetic unit, in particular a control device described in egg ner inventive device is executed.

The invention also relates to a computer program product with program code means which are stored on a computer-readable data carrier in order to carry out all the steps of the first invention Perform method when the corresponding computer program on a computer or a corresponding processing unit, in particular a control device in a device according to the invention, is executed.

One another inventive computer program with program code means is for performing all the steps of the second inventive method provided if the appropriate computer program on a computer or a corresponding computing unit, in particular a control device in a device according to the invention, accomplished becomes.

The Invention also relates a computer program product with program code means operating on a computer readable medium are stored to all the steps of the second method according to the invention perform, if the appropriate computer program on a computer or a corresponding computing unit, in particular a control device in a device according to the invention, accomplished becomes.

With The present method, it is also possible, hot air from the area a designed as a wall building boundary or building envelope with Warm air in the area of the roof designed as a building boundary to mix extracted warm air. The heat energy of the extracted Air is in the heat pump designed in particular as an air / water heat pump used for heating the water.

The Hot water system can have at least one water tank, usually a boiler and / or a radiator for storing hot water or heating water.

The at least one air suction duct may consist of at least one air hose be formed with suitable for aspirating the air openings. Within a conventional one building can be a total length the air hoses up to several hundred meters, for example 1.5 km. The Air suction lines are, for example, between rafters and Roof tiles, especially bricks, to arrange. In such a Designing the air hoses within the roof trained building boundary arranged. In this case would be the area of the roof inside the building side with an insulation, eg. with a vapor barrier or lock provided.

It is envisaged that several Luftabsaugleitungen or air hoses are merged and the extracted air by means of a fan with an intake manifold, which has, for example, a power of 4000 m ³ / h, the mixing chamber is fed, within this mixing chamber air from the interior of the building or a house is also supplied. The air from the inside of the building is sucked out of the air suction lines, which are located within individual rooms of the building. The warm air is fed via the fan into the heat pump. This cold air can be discharged to the outside and thus outside of the building. It is also possible to use such cold air for the warmer season for cooling and thus air conditioning of the building.

Within the hot water system, in particular within at least one hot water tank of the hot water system, may additionally at least a heating rod or Stromheizbalken be arranged, the further warming the water is provided.

With the device and / or the device is a so-called total Thermoabsorber provided with which it is possible to sucked out of the Air to provide thermal and / or electrical energy.

The Control device for controlling and / or regulating at least one of the methods and the device designed as a thermal absorber or device is formed, can be designed as a building control system be.

A Such building control system controls and / or regulates with the thermoabsorber in connection standing thermoabsorption system, which usually all Components of the device according to the invention or device.

By The invention can be an energy efficiency for the entire building elevated become. To provide energy of this building with The device or device is thus no fuel, for example. Oil, necessary. at the device or device or the thermal absorber is a self-sufficient system without additional heating feasible within the building is. The device can be variable between a water tank and a heater integrated. It is also conceivable, the present device in the building as a supplement to another energy supply device, for example. An oil or Electric heating, use.

Further Advantages and embodiments of the invention will become apparent from the Description and attached drawing.

It is understood that the above-mentioned and to be explained below Characteristics can be used not only in the specified combination, but also in other combinations or in isolation, without departing from the scope of the present invention.

1 shows a schematic representation of an embodiment of a device according to the invention.

2 shows a schematic representation of an embodiment of a device according to the invention.

The Invention is based on embodiments schematically shown in the drawing and is below under Referring to the drawings described in detail.

The Figures become coherent and overarching described. Like reference numerals designate like components.

In the 1 schematically shown embodiment of the device according to the invention 2 includes in clockwise direction the following components: one from air suction lines 4 formed air duct system, a mixing chamber 6 , a first turbine 8th , a heat pump 10 with a water cycle, an exhaust duct 12 , an expansion vessel 14 , as well as a hot water system, which has a heating circuit 16 , a hot water tank 18 , a water circuit 20 with a tap, a heating rod 22 , comprising a control device designed as a building control station 24 , as well as sensor and electric cables 26 ,

The air suction lines 4 are arranged in the area of at least one designed as a roof or wall building boundary or building envelope. Here are the air suction lines 4 arranged in the present embodiment, under the roof and within the wall formed at least one building boundary. By means of these air suction lines 4 Air is sucked in areas of at least one building boundary air and used to obtain thermal energy.

With the present also referred to as a thermal absorber device 2 is a heating method for a building in which the facility 2 is installed, feasible. The air suction lines 4 are usually made of plastic and installed between the rafters and inside the walls or building envelopes. The air suction lines 4 are further at least partially thermally insulated. This will be Luftabsaugleitungen 4 from the area of the roof as well as from the areas of the walls in the mixing chamber 6 merged so that the extracted air from the air suction lines 4 in the mixing chamber 6 to mix is. By means of the first turbine 8th following the mixing chamber 6 connected, which is the mixing chamber 6 sucked in and enriched with heat energy extracted air and the heat pump 10 , which has an automatic defrost, supplied. The heat pump 10 is designed to supply water with the heat energy of the extracted air. Provided cooled exhaust air can either be returned to the air conditioning in the building or via the exhaust duct 12 be discharged to the outside.

The hot water obtained by the conversion is via the hot water circuit of the heat pump 10 in the hot water tank 18 , which is designed as a buffer and combi storage and an expansion vessel 14 has promoted. The hot water recovered via the water cycle can be used by the heating circuit 16 and thus radiators, floor, wall or ceiling radiators are supplied, whereby the building is heated. In the process water cycle 20 and the hot water tank 18 with integrated heating element 22 the hot water can be further heated and thus serves to ensure the hot water as service water for kitchen, sanitary facilities and the like. The control and thus control and regulation of the device 2 via integrated pumps, valves, switches, sensors and sensors via the integrated, computerized control device 24 and thus building control technology are combined.

In the 2 schematically shown embodiment of a device according to the invention 28 includes those from the 1 known embodiment of the device 2 and thus all components of this device 2 , in the 2 with the same reference numerals as in 1 are designated.

In addition, the in 2 presented embodiment of the device 28 compared to the device 2 out 1 the following component: a second embodiment of a mixing chamber 30 , a heat exchanger 32 inside the mixing chamber 30 , a first turbine 34 , a heat pump 36 with a coolant circuit 38 , a second turbine 40 , an axis 42 , a generator 44 , an inverter 46 , a counter 48 and an exhaust duct 50 ,

In this embodiment of the device 28 are the air suction lines 4 also arranged or installed in the area of the building boundaries. In addition to the heat generation, as already based on the in 1 shown embodiment of the device 2 was presented with the in 2 presented embodiment of Vorrich device 28 additionally also a power generation possible. It is within the cooling circuit 38 of the heat pump 36 In the present embodiment, between an expansion valve and a compressor, a second turbine 40 built-in. By rotational movements of the turbine 40 , which is driven by the heated water, gets over the axis 42 in the generator 44 Electricity generated. This second turbine, which is intended to generate electricity, may also be located at another suitable location of the coolant circuit 38 be arranged. The inverter 46 is designed to subsequently treat the recovered electricity for feeding into a power grid. This is followed by the electricity meter 48 the feeding of electricity into the power grid. Unnecessary heat within the coolant circuit 38 the heat pump 36 is through the heat exchanger 32 inside the mixing chamber 30 returned to the heat cycle or in the exhaust duct 50 the heat pump 36 dissipated.

Claims (56)

Energy conversion device designed for this purpose is in the area of a building boundary Suction air and transfer thermal energy of the extracted air. Device according to claim 1, designed for this purpose is, with the thermal energy of the extracted air to water heat. Device according to claim 2, adapted thereto is, with the heated Water a building to supply. Device according to one of the preceding claims, which is designed to extract from the thermal energy of the Air to generate electrical energy. Device according to claim 3 or 4, adapted for this purpose is to provide the electrical energy from the heated water. Device according to one of the preceding claims, comprising at least one air suction line ( 4 ), wherein the at least one air suction line ( 4 ) is designed for the suction of air. Device according to claim 6, wherein the at least one air suction line ( 4 ) is arranged in the area of the building boundary. Device according to claim 6 or 7, wherein the at least one air suction line ( 4 ) is arranged within the building boundary. Device according to one of claims 6 to 8, wherein the at least one air suction line ( 4 ) is arranged in the area of a roof designed as a building boundary. Device according to one of claims 6 to 9, wherein the at least one air suction line ( 4 ) is arranged in the region of a wall designed as a wall boundary. Device according to one of the preceding claims, comprising at least one heat pump ( 10 . 36 ), wherein the at least one heat pump ( 10 . 36 ) is designed to heat water with thermal energy of the extracted air. Device according to claim 11, comprising a mixing chamber ( 6 . 30 ) and a first turbine ( 8th . 34 ), wherein the at least one air suction line ( 4 ) is adapted to the mixing chamber ( 6 . 30 ), And wherein the first turbine ( 8th . 34 ) is adapted to the at least one heat pump ( 10 . 36 ) Air from the mixing chamber ( 6 . 30 ). Device according to claim 11 or 12, having a hot water system into which the heated water from the heat pump ( 10 . 36 ). Device according to one of claims 11 to 13, wherein the heat pump ( 10 . 36 ) one with a generator ( 44 ) connected second turbine ( 40 ), this second turbine ( 40 ) is to be driven by the heated water, where by means of the generator ( 44 ) to generate the electrical energy. Device according to one of the preceding claims, comprising at least one control device ( 24 ), which is designed to facilitate operation of the device ( 2 . 28 ) to control. Device according to Claim 15, in which the at least one control device ( 24 ) as a control device for controlling the operation of the device ( 2 ) is trained. Device according to Claim 15 or 16, in which the at least one control device ( 24 ) as a control device for regulating the operation of the device ( 2 ) is trained. Energy conversion device comprising a heat pump ( 10 . 36 ) and is adapted to provide electrical energy from thermal energy stored in a heat transfer medium. Apparatus according to claim 18, adapted thereto is, from the thermal energy of air electrical energy too produce. Apparatus according to claim 18 or 19, adapted thereto is to heat water with thermal energy from the air. Device according to one of claims 18 to 20, adapted thereto is to generate the electrical energy from the heated water. Device according to one of claims 18 to 21, adapted thereto is to suck air. Device according to one of the preceding claims, comprising at least one air suction line ( 4 ), wherein the at least one air suction line ( 4 ) is designed for the suction of air. Device according to Claim 23, in which the at least one air suction line ( 4 ) is arranged in the area of a building boundary. Device according to Claim 24, in which the at least one air suction line ( 4 ) is arranged within the building boundary. Device according to claim 24 or 25, wherein the at least one air suction line ( 4 ) is arranged in the area of a roof designed as a building boundary. Device according to one of claims 24 to 26, wherein the at least one air suction line ( 4 ) is arranged in the region of a wall designed as a wall boundary. Device according to one of claims 23 to 27, comprising a mixing chamber ( 6 . 30 ) and a first turbine ( 8th . 34 ), wherein the at least one air suction line ( 4 ) is adapted to the mixing chamber ( 6 . 30 ), And wherein the first turbine ( 8th . 34 ) is adapted to the heat pump ( 10 . 36 ) Air from the mixing chamber ( 6 . 30 ). Device according to one of claims 20 to 28, comprising a hot water system, in which the heated water from the heat pump ( 10 . 36 ). Device according to one of claims 20 to 29, wherein the heat pump ( 10 . 36 ) one with a generator ( 44 ) connected second turbine ( 40 ), this second turbine ( 40 ) is to be driven by the heated water, whereby by means of the generator ( 44 ) to generate the electrical energy. Device according to one of claims 18 to 30, comprising at least one control device ( 24 ), which is adapted to prevent operation of the device ( 2 . 28 ) to control. Device according to Claim 31, in which the at least one control device ( 24 ) is designed as a control device for controlling the operation of the device. Apparatus according to claim 31 or 32, wherein the at least one control device ( 24 ) is designed as a control device for regulating the operation of the device. Method of energy conversion, in which in one Area of a building boundary Air sucked and transferred thermal energy of the extracted air becomes. Method according to claim 34, with which it is provided that with the heated Water a building is supplied. A method according to claim 34 or 35, provided with the is that by means of the heated water electrical energy is generated. A method according to any one of claims 34 to 36, wherein the Air from the building boundary is sucked off. Method according to one of claims 34 to 37, wherein by means of at least one air suction line ( 4 ), which is located in the area of the building boundary, air is sucked off, and in which the water by means of a heat pump ( 10 . 36 ) is heated with thermal energy of the extracted air. The method of claim 38, wherein the air from the at least one air exhaust duct ( 4 ) a mixing chamber ( 6 . 30 ) and by means of a first turbine ( 8th . 34 ) from the mixing chamber ( 6 . 30 ) of the heat pump ( 10 . 36 ) is supplied. A method according to claim 38 or 39, wherein the heated water from the heat pump ( 10 . 36 ) is conveyed into a hot water system. Method according to one of claims 34 to 40, wherein the heat pump ( 10 . 36 ) a generator ( 44 ) and electrical energy is generated. Method according to one of claims 34 to 41, which comprises at least one control device ( 24 ) is controlled. Method according to claim 42, which comprises at least one control device ( 24 ) is controlled. Method according to claim 42 or 43, comprising at least one control device ( 24 ) is regulated. Method of energy conversion, in which with a heat pump from thermal energy stored in a heat transfer medium, electric Energy is provided. The method of claim 45, wherein the thermal Energy generated by air electrical energy. A method according to claim 45 or 46, wherein thermal energy from the air water is heated. The method of claim 47, wherein the electrical Energy from the heated Water is generated. A method according to any one of claims 46 to 48, wherein the Air is sucked off. A method according to any one of claims 46 to 49, wherein the Air in the area of a building boundary is sucked off. Method according to one of claims 45 to 50, wherein the air of a mixing chamber ( 6 . 30 ), and in which a first turbine ( 8th . 34 ) of the heat pump ( 10 . 36 ) Air from the mixing chamber ( 6 . 30 ) feeds. Method according to one of claims 47 to 51, wherein a second turbine ( 40 ) is driven by the heated water, and by the second turbine ( 40 ) a generator ( 44 ), whereby by means of the generator ( 44 ) the electrical energy is generated. Computer program with program code means for carrying out all the steps of a method according to one of Claims 34 to 44, if the computer program is stored on a computer or a corresponding arithmetic unit, in particular a control device ( 24 ) in a facility ( 2 ) according to one of claims 1 to 17, is executed. A computer program product comprising program code means stored on a computer-readable medium for carrying out all the steps of a method according to one of claims 34 to 44, when the computer program is stored on a computer or a corresponding computing unit, in particular a control device ( 24 ) in a facility ( 2 ) according to one of claims 1 to 17, is executed. Computer program with program code means for performing all the steps of a method according to one of Claims 45 to 52, if the computer program is stored on a computer or a corresponding arithmetic unit, in particular a control device ( 24 ) in a device ( 28 ) according to one of claims 18 to 33, is executed. A computer program product comprising program code means stored on a computer-readable medium for carrying out all the steps of a method according to one of claims 45 to 52, when the computer program is stored on a computer or a corresponding arithmetic unit, in particular a control device ( 24 ) in a device ( 28 ) according to one of claims 18 to 33, is executed.