DE202007008753U1 - Air solar collector unit - Google Patents

Abstract

Air solar collector unit with an air guide unit (10) having a substantially nontransparent cover layer, the at least a large part a total topcoat surface forms.

Description

The The invention is based on an air solar collector unit after the Preamble of claim 1.

Advantages of the invention

It is an air solar collector unit with an air guide unit, which has a substantially nontransparent cover layer which at least a large part forms a total topcoat surface, proposed, wherein at least a majority of the total surface layer surface 50% of a surface the air solar panel unit is to be understood by a mounting surface turned away and in particular exposed to solar radiation is. Next is under an "air guide unit" in particular a Unit that is intended to carry air and which is provided that air through solar radiation within the same be heated advantageously can. Under "provided" should be specially equipped and / or designed to be understood. Under a "substantially untransparent cover layer "should a cover layer with a transmission of less than 20%, advantageously less than 10%, and more preferably less than 1% of the incident light. An absorption of more than 50% of the incident light is advantageous. By an opaque cover layer may be the air solar collector unit particularly hard-wearing and is thus particularly in areas with extreme weather conditions and / or with high solar radiation, such as in desert areas or in desert-like areas, used. In particular, the top layer is the sunlight and further weather influences exposed. A metallic cover layer is considered an untransparent cover layer Particularly advantageous because a metallic cover layer is an advantageous thermal conductivity having. But there are also other nontransparent cover layers, such as carbon fiber topcoats, conceivable.

Further It is proposed that the air guide unit a sandwich construction having. Under a "sandwich construction" should in particular a construction to be understood, the two spaced apart Deck units comprises, introduced between the one core unit is. By a sandwich construction, a particularly resilient and at the same time light construction can be achieved, in particular to cover roofing devices such as flat roofs or pitched roofs advantageous is. As cover units are in particular metallic or substantially metallic layers advantageous. As core units are in particular Low density materials such as balsa wood or foam materials, in particular polyurethane, advantageous. But there are also other core units conceivable.

Further An air solar collector unit with an insulation unit is proposed. In particular, an "insulating unit" is intended a unit for thermal insulation be understood, in particular at least substantially a thermal insulation material, preferably made of a foam material, in particular polyurethane, is formed.

Preferably are the air guide unit and the insulation unit at least partially executed in one piece. Thereby a particularly lightweight construction can be achieved.

Further becomes an air solar collector unit with energy recovery unit proposed. Under a "energy recovery unit" is also intended in particular a unit that is intended to absorb the heat of the warmed Air within the air duct unit to make usable. By appropriate design, the components Advantageously matched and it can be a high benefit and efficiency can be achieved.

Preferably forms the air guide unit one Outer surface, causing additional Avoiding components and high efficiency in heating the Air can be achieved, especially if the air guide unit an untransparent cover layer, which is due to the solar radiation is heated and then a heat energy to the guided in the air ducts air emits. Furthermore, can Weight, assembly costs and costs are reduced. The outer surface of the Lufttsonnenkollektoreinheit advantageously forms an outer surface of a building such as a wall outer surface or particularly advantageous a roof outer surface.

It is proposed that the outer surface has a structuring. By "structuring" is meant in particular at least one shaping of the outer surface, which may be formed by elevations or depressions, which covers at least 70%, advantageously more than 80% and particularly preferably more than 90% of the outer surface For example, a roof tile structure may be applied to a roof outer surface, structuring being easy to apply, in particular in the case of a metallically formed outer layer of the air guiding unit unit fastened components can be realized.

Further It is proposed that the air guide unit an at least partially transparent cover layer. Through a partial transparent cover layer can be an efficiency of the air solar collector unit elevated become.

has the air guide unit a plurality of, preferably parallel air ducts can, advantageous flow velocities achieved and in particular, an advantageous assembly of the air guide unit be achieved. Among several "air ducts" to at least two at least one Partial flow separate channels be understood.

Preferably are the air ducts at least in assembled state over at least one connecting channel, in particular connected via a transverse channel, so that the individual flows preferably be transferred into a mainstream can.

has the connecting channel in the flow direction a changing one Cross-sectional area, in particular an increasing cross-sectional area, can the flow rate be set advantageously in the connecting channel, wherein the change the cross-sectional area can relate to the shape and / or in particular to the size and graded and / or advantageously can be made steplessly.

The warmed Air can come from different sides of the air duct unit led out be, in particular on a side surface at an upper end face and / or particularly advantageous over at least one recess arranged in its bottom region, whereby an advantageous connection of the energy recovery unit easy can be achieved.

is the air guide unit at least for the most part, i.e. made of more than 50%, made of a plastic, this can be constructively simple with a low weight, inexpensive and durable become.

In Another embodiment of the invention proposes that the air guide unit is intended to be firmly connected to the insulation unit or firmly connected to the insulating unit in the mounted state is, which again other components, weight, assembly costs and costs can be saved in particular, when the air guide unit is directly, i. without intermediate units, connected to the insulating unit is.

Further It is suggested that between the air duct unit and the insulation unit at least one channel arranged for water discharge in the assembled state is, which advantageously a condensate drainage can be ensured. Of the Channel may preferably be of a free space between the air guide unit and the insulating unit may be formed by, for example, spacing means between the air guide unit and the insulating unit are arranged by separate components and / or also to the air guide unit and / or formed on the insulating unit molded components can.

has the insulation unit at least one thermal insulation board with at least one Fastening element, which is for coupling with a corresponding Deck unit, as in particular with the air guide unit is provided, can be an advantageous coupling, in particular at least largely without Thermal bridges reached become. The fastening means can be different, the expert can appear as meaningful forms, for example, can the fastener plate-shaped and / or advantageously web-shaped be formed, this advantageous in a web-shaped training an angle not equal to zero to a side wall of the thermal insulation board includes. In addition, the fastening means by various, the expert be considered meaningful connections with the thermal insulation board, as with tels non-positive, positive and / or particularly advantageous by means of cohesive connections. Further is advantageous, the fastener at least partially in the Insulated thermal insulation board, causing an undesirable supernatant over the thermal insulation board at least largely avoided.

In a further embodiment of the invention it is proposed that the insulating unit has at least one air duct, whereby in turn an advantageous connection of the energy recovery unit can be achieved, in particular if the air duct, in particular with its main extension, an angle not equal to zero to a top of a thermal insulation board the insulating unit includes and thus the heated air can be passed through at least a partial layer of the insulating unit. The angle preferably has between 60 ° and 120 ° and particularly advantageously substantially 90 °. The air duct can be formed by a cover side and / or a side wall of a thermal insulation panel and / or can advantageously be introduced into a thermal insulation panel and / or be integrally formed on a thermal insulation panel. The air duct can advantageously be at least partially formed by a recess of the thermal insulation board, in which an additional channel element used may or may not be.

Further It is proposed that the energy recovery unit at least a heat exchanger and / or a heat pump which reduces the heat energy the warmed up Air can be used very flexibly, and in particular advantageous for heating water.

has the energy recovery unit at least one heating channel, in particular to the leadership of warmed Air, on, can heat Advantageously be used directly. The heating channel is preferably provided, at least partially in a building ceiling, a building wall and / or in a building floor to be integrated. The heating channel can be from a pipe or from a space of multi-layered building ceilings, -walls and / or floors be formed.

Further can the flexibility elevated when the energy recovery unit is at least one unit to generate electricity.

In addition, will proposed that the air solar collector unit at least one refrigeration unit having. Through a refrigeration unit may advantageously be a thermal energy generated by means of the air solar collector unit used to heat a specific area, in particular a building area, to escape, which an air conditioning by means of the air solar collector unit is possible. The refrigeration unit preferably has at least one evaporation unit, in principle However, they are also others that appear appropriate to the person skilled in the art Units and methods conceivable.

In Another embodiment proposes that the air solar collector unit at least one adapter element which is for coupling, in particular for direct coupling, with the air guide unit in the area of Air outlet is provided, creating an advantageous simple connection to the air guide unit can be achieved. In particular, flow losses and energy losses simply at the air outlet of the air guide unit at least largely be avoided. The adapter element is preferably from a plastic, particularly advantageous from a foam such as an integral foam, formed. Is the adapter element as insulating trained, can advantageous further insulating and expensive additional Insulating structures are avoided.

Further a sub-assembly is proposed, the one in at least one In the direction of decreasing altitude having. As a result, an advantageous inclination of the air solar collector unit be achieved. Such a substructure unit is in particular for a flat roof construction, which has an unfavorable inclination of a roof surface against a sun, advantageous.

advantageously, the substructure unit is wedge-shaped educated. Under "wedge-shaped" should be understood be that the sub-assembly has two substantially flat surfaces, at an angle greater than 0 ° and smaller 90 ° to each other stand. A wedge-shaped trained sub-unit has an advantageous for an arrangement of the air solar collector unit flat surface on. It is basically but also other sub-units with one in at least one direction decreasing height conceivable, such as stepped-shaped substructure units.

Further it is proposed that the substructure has a basic body, which is at least partially formed of an insulating material. Under an "insulating material" should in particular a foam material, such as polyurethane, understood. By doing so leaves realize a particularly lightweight and flexible substructure unit, which are at the same time provided in particular for insulation can. It is proposed that the insulating unit and the basic body of the Substructure unit are formed of a same material and In particular, it is proposed that the substructure unit at least partially in one piece with the insulating unit, i.e. the insulating unit has at least partially a wedge-shaped form on. Thereby can Cost savings and material can be saved.

drawing

Further Advantages are shown in the following description of the drawing. In the drawing are exemplary embodiments represented the invention. The drawing, the description and the claims contain numerous features in combination. The specialist will the features also expediently individually consider and summarize to meaningful further combinations.

It demonstrate:

1 a side view of a building with an air collector unit according to the invention,

2 a section along the line II-II in 1 .

3 the air solar collector unit during assembly,

4 a side view of a building with an alternative air solar panel unit,

5 a section along the line VV in 4 .

6 Items of another alternative air solar panel unit,

7 a arranged on a flat roof Luftsonnenkollektoreinheit with a sub-assembly.

8th Section through an air guide unit,

9 Section through an air duct unit with one-piece insulation unit,

10 Section through an air guide unit with attached air ducts,

11 Section through an alternative air duct unit with attached air ducts and

12 Section through an air guide unit with a further embodiment of patch air ducts.

Description of the embodiments

1 shows a side view of a building with a roof and with a mounted on the roof of the invention air solar collector unit. The air solar collector unit comprises an air guide unit made of plastic 10 , an insulation unit 12 and an energy recovery unit 14 ( 1 . 2 and 3 ). The air guide unit 10 forms with an untransparent topcoat 18 an outer surface 16 and comprises a plurality of substantially identical air ducts 20 , The outer surface 16 essentially forms the entire outer surface of the roof, ie at least more than 70%, advantageously more than 80% and particularly preferably more than 90%.

The air ducts 20 run from a lower edge of the roof 54 or from a roof eaves parallel to a roof front side 56 to a roof ridge 58 , The air ducts 20 are formed by individual elements, which during assembly by a plug-in folding movement by means of molded positive-locking elements 60 . 62 be coupled with each other (cf. 3 ). Furthermore, at the the air ducts 20 forming individual elements tab-like fasteners 64 formed, which protrude across the elements and extend over the entire length. It is also possible, however, that the fasteners 64 are arranged only in sections over the length of the elements. By means of the fastening means 64 become the air ducts 20 forming elements with the insulation unit 12 screwed, and that will be screws 66 through the fasteners 64 in in thermal insulation panels 32 . 34 the insulation unit 12 recessed fasteners 36 screwed. In principle, other, in particular by the insulation unit 12 passing fasteners conceivable. The fasteners 64 are from across the air ducts 20 extending wooden strips formed, the material fit with the thermal insulation panels 32 . 34 are connected and flush with a top of the thermal insulation panels 32 . 34 to lock. The thermal insulation panels 32 . 34 are among themselves in joints with angle profiles 68 connected by means of which the thermal insulation panels 32 with a roof beam 70 are bolted. The angle profiles 68 serve on the insulation unit 12 to absorb acting thrust and suction forces. The air guide unit 10 and the insulation unit 12 are attached completely free of heat bridges.

The air guide unit 10 becomes distant from the insulation unit 12 mounted so that is between the air guide unit 10 and the insulation unit 12 in the assembled state, a channel 30 forms the condensation drainage. The thermal insulation panels 32 . 34 the insulation unit 12 , which forms a solid insulation, are permeable to water when viewed from the bottom up and have membrane-like foils on their upper side 72 . 74 on, extending over body 76 . 78 made of polyurethane of thermal insulation panels 32 . 34 extend beyond, so that in the assembled state, an overlap in the joint areas of the thermal insulation panels 32 . 34 can be achieved. Condensation can thus from bottom to top through the body 76 . 78 and the slides 72 . 74 diffuse and over the channel 30 on the slides 72 . 74 , which are permeable to water only in one direction, be discharged over the sloping roof down. The insulation unit 12 may additionally or alternatively also have steel sandwich elements which comprise in particular at least one upper and usually one lower sheet metal layer.

In the area of the roof ridge 58 have the air ducts 20 forming elements in their floor areas 26 one recess each 28 for the removal of warmed-up air 50 from the air guide unit 10 in one the air ducts 20 connecting connection channel 22 on. The connection channel 22 is in the thermal insulation panels 34 the insulation unit 12 inserted, runs parallel to the roof ridge 58 and points in Strö flow direction 24 an increasing cross-sectional area. The connection channel 22 is down by means of thermal insulation panels 80 the insulation unit 12 Completed on a bottom of the thermal insulation panels 34 connect and spread across the entire width of the Air solar collector unit extend. To avoid warmed up air 50 in the channel 30 flows, are preferably in the region of the connecting channel 22 between the air guide unit 10 and the insulation unit 12 screening 90 . 92 arranged, preferably over the entire length of the connecting channel 22 extend.

In the on a front side 82 subsequent thermal insulation board 80 is an air duct 38 the insulation unit 12 forming recess introduced, wherein the air duct 38 about an angle 40 from 90 ° to a top of the thermal insulation board 80 includes.

Over the air duct 38 becomes the heated air 50 the energy recovery unit 14 supplied, preferably at a small distance, ie preferably with a distance less than 2 m, to the air duct 38 is arranged. The energy recovery unit 14 has a heat exchanger 42 , in particular for heating water, a heat pump 44 and one unit 48 to generate electricity from the heat energy of the heated air 50 on. Next includes the energy recovery unit 14 a refrigeration unit designed as an absorption refrigeration unit 46 , which cools by means of a temperature-dependent desorption and absorption process of an ammonia / water mixture. In addition, the energy recovery unit includes 14 a Erdspeicher 94 which is charged with excess energy with heat energy.

Furthermore, the energy recovery unit comprises 14 a system with heating channels 120 that are in building walls 84 and in a building floor 86 are integrated. In the heating channels 120 can warmed up air 50 from the air guide unit 10 be initiated and the warmed-up air 50 can be used to heat the building. The energy recovery unit 14 has a control unit 88 on, by means of the automated depending on various parameters, such as in particular outside temperature, desired indoor temperature, etc., a heating operation is controlled and regulated by means of which, however, the heating operation can be controlled manually.

In the 4 to 6 Alternative embodiments are shown. Substantially identical components, features and functions are basically numbered by the same reference numerals. To distinguish the embodiments, however, the reference numerals of the embodiments in the 4 to 6 the letters a and b are added. The following description is essentially limited to the differences from the embodiment in the 1 to 3 , wherein with respect to the same components, features and functions on the description of the embodiment in the 1 to 3 can be referenced.

The air solar collector unit comprises an air guide unit made of plastic 10a , an insulation unit 12a and an energy recovery unit 14a ( 4 and 5 ). Air ducts 20a the air guide unit 10a ends at a distance in front of a vertically oriented insulating element 96a the insulation unit 12a , which at its upper En de to a skylight unit 98a followed. In the area between the air ducts 20a and the insulating element 96a includes the air solar collector unit or the insulation unit 12a on the air ducts 20a or on the air guide unit 10a seated and to the insulating element 96a subsequent insulation units 100a , each for multiple air ducts 20a a channel 102a train, over the heated air 50a each via a channel 104a in thermal insulation panels 34a in a canal system 106a and about the canal system 106a the energy recovery unit 14a is supplied. The of the insulation units 100a formed channels 102a are upstream of each other in the flow direction 104a by means of partitions 110a the insulation units 100a decoupled.

Alternatively and / or in addition to the channels 104a in the thermal insulation panels 34a could the heated air 50a over one or preferably over several, preferably at least substantially in the flow direction within the air ducts 20a the air guide unit 10a aligned, at least substantially executed without diversion channels 108a , in particular by an insulating element 96a and / or a support element (frame) of a skylight, in a building interior and from there preferably in the energy recovery unit 14a be guided, as in 5 is indicated.

In 6 are shown parts of another alternative air solar panel unit. The air solar collector unit corresponds essentially to the illustrated individual parts of the embodiment in the 1 to 3 , The air solar collector unit comprises adapter elements 112b made of a plastic foam, which serve as an insulating agent and the on an air guide unit 10b in the area of their air outlet 114b directly by means of a plug connection 116b are plugged for making a plug connection.

The adapter elements 112b have a flow deflection 118b on and serve to air 50b from the air guide unit 10b to an energy recovery unit 14b to lead.

7 shows a further embodiment with an air solar collector unit, which on a Flat roof is arranged. The air solar collector unit comprises a wedge-shaped base unit 122c , Through the substructure unit 122c is an angle, in particular an air guide unit 10c occupies a middle position of the sun, advantageously changed and the efficiency of the solar collector unit is increased.

A basic body 124c the substructure unit 122c is made of polyurethane, the same material as the basic body 76c . 78c of thermal insulation panels 32c . 34c an insulation unit 12c on the main body 124c is attached. Alternatively, the main body 124c and the insulation unit 12c be made in one piece, which material and installation costs can be reduced. An energy recovery unit 14c with a heat exchanger 42c , a heat pump 44c , a refrigeration unit 46c and one unit 48c for power generation is also arranged on the flat roof.

8th shows a cross section of the air guide unit 10 in 2 , the ventilation guide units 10a . 10b . 10c in the 5 . 6 and 7 can be constructed analogously.

The metallically formed cover layer 18 the air guide unit 10 forms a deck unit for a sandwich construction of the air guide unit 10 , the metallically formed floor 52 forms another deck unit. In a gap 126 between the cover layer and the bottom layer, a core unit is inserted, which consists of a trapezoidal shaped intermediate layer 128 consists. A wave-like shaped intermediate layer such as corrugated iron is conceivable. The intermediate layer 128 divides the gap 126 between the cover layer 18 and the floor 52 in the air ducts 20 , Is the cover layer by sunlight 18 heated, the resulting heat energy over the metallic cover layer 18 to the in the air ducts 20 flowing air is released and the air is heated.

9 shows an alternative embodiment of an air guide unit 10d , In a gap 126d between a metallic cover layer 18d and a metallic floor 52d is an insulating foam material such as polyurethane introduced. Next are in the gap 126d Air ducts 20d arranged from a metallic material, with the cover layer 18d are connected, whereby between the acted upon by solar irradiation cover layer 18d and the air ducts 20d a thermal bridge is created by a heat energy from the cover layer 18d to the in the air ducts 20d flowing air can be discharged. The foam material connects the cover layer 18d and the floor 52d spaced and largely free of thermal bridges, causing the soil 52d opposite the cover layer 18d is isolated. The air guide unit 10d forms part of an insulating unit 12d ,

10 shows a further embodiment of an air guide unit 10e that is a structuring of a topcoat 18e having. In a cross section forms the air guide unit 10e essentially three layers, which are metallic. Parallel to a floor 52e is an intermediate layer 128e arranged, a gap 126e between the ground 52e and the intermediate layer 128e is filled with a foam material and forms part of an insulating unit 12e , On the interlayer 128e is the metallic cover layer 18e attached, which has a cuboid-like structure in cross-section and with the intermediate layer 128e Air ducts 20e forms.

11 shows an embodiment of an air guide unit 10f in which a cover layer 18f and an intermediate layer 128f Trapezoidal are formed. The cover layer 18f and the intermediate layer 128f are shifted from each other, whereby the trapezoidal formations form spaces that serve as air ducts 20f be used. At the interlayer 128f is a floor 52f attached, in intermediate spaces 126f between the ground 52f and the intermediate layer 128f is introduced as the core unit, a foam material, which is the air guide unit 10f reinforced for loads perpendicular to the cover layer.

12 shows a section through an air guide unit 10g with a further embodiment of mounted air ducts 20g which are particularly easy to make. The air ducts 20g are different from the ones in 10 shown air ducts 20e in that a cover layer 18g has a trapezoidal structuring tion in cross section, with an intermediate layer 128g the air ducts 20g forms. Such a configuration is particularly advantageous because it is easy to manufacture and has good efficiency.

10

Air distribution unit

12

insulation unit

14

Energy recovery unit

16

outer surface

18

topcoat

20

Air duct

22

connecting channel

24

flow direction

26

floor area

28

recess

30

channel

32

thermal insulation board

34

thermal insulation board

36

fastener

38

Air duct

40

angle

42

heat exchangers

44

heat pump

46

refrigeration unit

48

unit

50

air

52

ground

54

roof edge

56

Roof front side

58

ridge of the roof

60

Form-fitting element

62

Form-fitting element

64

fastener

66

screw

68

angle section

70

roof beam

72

foil

74

foil

76

body

78

body

80

thermal insulation board

82

front

84

building wall

86

building floor

88

Tax- and control unit

90

screening

92

screening

94

underground tank

96

insulating

98

Skylight unit

100

insulation unit

102

channel

104

channel

106

channel system

108

channel

110

partition wall

112

adapter element

114

air outlet

116

plug-in connection

118

flow deflection

120

heating duct

122

subassembly

124

body

126

gap

128

interlayer

Claims (31)

Air solar collector unit with an air guide unit ( 10 ) having a substantially nontransparent cover layer forming at least a majority of a total topcoat surface. Air solar collector unit according to claim 1, characterized characterized in that the air guide unit has a sandwich construction. Air solar collector unit according to claim 1 or 2, characterized by an insulating unit ( 12 ). Air solar collector unit at least according to claim 2 and 3, characterized in that the air guide unit and the insulation unit at least partially executed in one piece. Air solar collector unit according to one of the preceding claims, characterized by a energy recovery unit ( 14 ). Air solar collector unit according to one of the preceding claims, characterized in that the air guide unit ( 10 ) an outer surface ( 16 ). Air solar collector unit according to claim 6, characterized characterized in that the outer surface is a structuring having. Air solar collector unit according to one of the preceding claims, characterized in that the air guide unit ( 10 ) an at least partially transparent cover layer ( 18 ) having. Air solar collector unit according to one of the preceding claims, characterized in that the air guide unit ( 10 ) several air ducts ( 20 ) having. Air solar collector unit at least according to claim 9, characterized in that the air ducts ( 20 ) at least in the mounted state via at least one connecting channel ( 22 ) are connected. Air solar collector unit according to claim 10, characterized in that the connecting channel ( 22 ) in the flow direction ( 24 ) has a varying cross-sectional area. Air solar collector unit according to one of the preceding claims, characterized in that the air guide unit ( 10 ) in its bottom area ( 26 ) at least one recess ( 28 ) for the removal of warmed-up air ( 50 ) having. Air solar collector unit according to one of the preceding claims, characterized in that the air guide unit ( 10 ) is made at least for the most part of plastic. Air solar collector unit at least according to claim 3, characterized in that the air guiding unit ( 10 ) in the mounted state firmly with the insulation unit ( 12 ) connected is. Air solar collector unit at least according to claim 3, characterized in that between the air guiding unit ( 10 ) and the insulating unit ( 12 ) in the mounted state at least one channel ( 30 ) is arranged to drain water. Air solar collector unit at least according to claim 3, characterized in that the insulating unit ( 12 ) at least one thermal insulation board ( 32 . 34 ) with at least one fastening element ( 36 ) provided for coupling with a corresponding deck unit. Air solar collector unit according to claim 16, characterized in that the fastening element ( 36 ) at least partially in the thermal insulation board ( 32 . 34 ) is admitted. Air solar collector unit at least according to claim 14 and claim 16 or 17, characterized in that the air guide unit ( 10 ) in the mounted state on the fastening element ( 36 ) is attached. Air solar collector unit at least according to claim 3, characterized in that the insulating unit ( 12 ) at least one air duct ( 38 ) having. Air solar collector unit according to claim 19, characterized in that the air duct ( 38 ) in a thermal insulation board ( 34 . 80 ) of the insulating unit ( 12 ) introduced and / or is formed on the thermal insulation board. Air solar collector unit according to claim 19 or 20, characterized in that the air duct ( 38 ) an angle ( 40 ) not equal to zero to a top of a thermal insulation board ( 34 . 80 ) of the insulating unit ( 12 ). Air solar collector unit at least according to claim 5, characterized in that the energy recovery unit ( 14 ) at least one heat exchanger ( 42 ) and / or at least one heat pump ( 44 ) having. Air solar collector unit at least according to claim 5, characterized in that the energy recovery unit ( 14 ) at least one heating channel ( 120 ). Air solar collector unit at least according to claim 5, characterized in that the energy recovery unit ( 14 ) at least one unit ( 48 ) to generate electricity. Air solar collector unit at least according to claim 5, characterized in that the energy recovery unit ( 14 ) at least one refrigeration unit ( 46 ) having. Air solar collector unit according to one of the preceding claims, characterized by at least one adapter element ( 112 ), which for coupling with the air guide unit ( 10 ) in the area of their air outlet ( 114 ) is provided. Air solar collector unit according to claim 26, characterized in that the adapter element ( 112 ) a plug connection ( 116 ) for the production of a plug connection with the air guiding unit ( 10 ) having. Air solar collector unit according to claim 26 or 27, characterized in that the adapter element ( 112 ) at least one flow deflection ( 118 ) having. Air solar collector unit according to one of the preceding claims, characterized by a substructure unit ( 122 ) having a decreasing height in at least one direction. Air solar collector unit according to claim 29, characterized in that the substructure unit ( 122 ) is wedge-shaped. Air solar collector unit according to claim 29 or 30, characterized in that the substructure unit ( 122 ) a basic body ( 124 ), which is at least partially formed of an insulating material.