WO2012079099A2 - Tightly sealed building shell - Google Patents

Abstract

The invention relates to a method for thoroughly sealing a building shell, wherein sealing systems (9, 10, 11, 12, 13) are drawn in between the floor insulation panels (3), wall insulation panels (6), and roof insulation panels (8) enclosing on all sides and all around the door and window elements (5) in a moisture- and water-resistant manner so that there is general leak-tightness between the inside and the outside of the building shell. At the transition interfaces of the building shell, for example wall-roof, a separate sealing system (10) is drawn in between wall insulation panels (6) and attached roof insulation panels (8) in an outer sealing region (10.1) located directly at the particular transition interface on the outside of the building shell, in a center sealing region (10.2) located between the surfaces of wall insulation panels (6) and attached roof insulation panels (8), and in an inner sealing region (10.3) defined by the surface along the connection point on the inside of the building shell between the building shell components in question. The sealing systems are substantially drawn in by means of sealing tapes (15), joint sealing materials, hard foam, and steel brackets (14) or cover plates.

Description

 High density building envelope

 The invention relates to a method for comprehensive sealing of a building envelope, in which a combined in new form floor wall and roof construction by Dämmpaneele in conjunction with sealing systems consisting of sealing strips, joint sealants and steel angle and a body-appropriate air exchange with optimal system heat recovery realized ,

According to the current state of the art, the current passive house guidelines set the values to be achieved for zero-energy or plus-energy houses. The passive house standard is defined according to the Passive House Institute Darmstadt (Germany) (PHPP = Passive House Planning Package).

Also, the achievement of the values of any other standard (Passive House is known only in a few Central European countries), based on the comparable sizes, are included. Prefabricated houses subjected to passive, low-energy or comparable standards consist mainly of base materials wood, brick or concrete as well as the patents under consideration, which achieve the values of the standards (especially the density) by means of extended construction measures, such as: additional insulation materials ,

In US 2010/0 287 863 A1, the moisture drain within the building envelope is treated specifically at the openings such as windows and doors by means of a so-called moisture drainage. The building envelope construction is defined between vertical elements such as walls and non-vertical elements such as roofs. From a uniform combined floor, wall and roof construction is not spoken explicitly. It is claimed that temperature differences occur between the inside and outside of the building shell in the building shell construction around the openings to moisture formation. This solution assumes that there is no absolute tightness between the inside and outside of the building envelope and thus also heat and cold bridges especially around the openings such as doors and windows or joints between floor - wall, wall - roof can not be prevented , so you have to drain the moisture. This represents a newer system compared to the previous system, which the window and door manufacturers use by means of simple drainage for the outward moisture drains around the doors and windows. However, this does not involve complete sealing of the building envelope construction as a whole, as realized in our invention by means of the sealing levels and the uniformly combined floor, wall and roof construction by means of panels, so that this construction is not directly comparable to our construction.

The essential difference to US 2010/0 287 863 A1 is that between the inside and outside of the building envelope no moisture (condensation) as well as heat / cold bridges within the panels and between the inside and outside of the building envelope even at the openings such as windows and doors as well as transitions floor - wall, wall - roof, can arise. In contrast to a uniform floor, wall and roof structure including the sealing levels in our invention are at the transitions in the execution of US 2010/0 287 863 A1, for example: floor slab - wall, by complex and additional wall, insulating, Assembly effort (ventilation system, fan, humidity sensors, detection electronics integrated into the building envelope construction) produces sources of error or cold / heat bridges. Also, a general edition of the building shell on such a drainage system building physics or static is not possible.

 Without the sealing levels specifically mentioned in our invention and without the combined floor, wall and roof construction, the tightness of a building envelope construction of panels, at least the passive house standard, can not be guaranteed. An additional drainage system for liquid removal, as mentioned in this invention, is not only superfluous with regard to our invention of a high-density building envelope by means of panels, but also means an additional high outlay and sources of error. Also, the mentioned sealing measures are not sufficient for a holistic inclusion of the building envelope.

JP 2008 184 828 A describes an externally attached water-repellent construction of buildings. This water-repellent construction of buildings does not mean such a tightness of the building that it at least meets the passive house standards and heat / cold bridges are prevented. Also, this invention does not mean a moisture insulation or a general weather-resistant construction or energy-saving solution, but serves a pure water-repellent property.

In GB 2 093 085 A (hereinafter also referred to as D3) a device is described which serves for fastening and connecting panels In this patent, the arrangement and the nature of the fastening elements provide thermal connections between the building inside and outside, Also, there is no holistic sealing concept regarding the building envelope.Our invention relates to a complete thermal separation between the inner and outer shell and includes a holistic sealing concept regarding the building envelope.

The passive house registered in DE 198 41 922 A1 describes all necessary requirements, but with regard to the solution of the requirements, above all in the construction of the building envelope and sealing system, a completely different and more complex one Way and also leaves with respect to tightness eg: regarding water (thus moisture, mold in the substrate) and heat (cold) bridges miss a complete solution.

Also, in the EP 2 112 288 A2 registered building in which the support elements are arranged decoupled from the building envelope, corresponds to a different structure with other materials. It is not a uniform enveloping uniform design chosen. The wall structure is proposed with concrete slabs, the floor structure with a concrete slab, so that an additional, much more expensive Dämmaufwand or effort for thermal decoupling is required and no complete tightness regarding. Water / moisture is given.

The insulation panels from DE 25 33 300 A1 and DE 24 27 504 A1, which have been used for many years in the industrial sector and are best assessed by means of certificates, can be found in our novel connection system. These panels are sandwiched with panel elements filled between two parallel armor plate bands (top layers are galvanized steel with corrosion protection) and rigid foam (XPS or PUR). Also, they are classified as "low flammability." The construction of a shell by means of these panels means a higher quality in the fitting accuracy and in the tightness.

The SIP (Structured Insulated Panels) applications, which are mainly used in the USA, have improved strength, density and temperature efficiency compared to conventional lightweight construction, but can only reach the standard values mentioned here with additional considerable insulation effort or not at all.

In CA 2655466 A1, the foam panels (EPS panels) framed by an outer shell reinforced with structural steel are prefabricated as prefabricated modules, so that they form vertical wall parts which are applied to a floor panel (wood or concrete) by means of steel or wood guide rails become.

 Furthermore, there are such different SIPs with different foam bodies such as XPS, EPS or PU and different outer cladding such as aluminum foil or OSP - plates.

 These SIP applications are missing exactly the properties with respect to tightness-related weak points, heat (cold) bridges, which our invention includes.

Also vacuum or vacuum insulation panels, such as from DE 102004014248 A1, were included in the consideration. However, they have an increased manufacturing and operating costs and lesser effect with respect to tightness-related weak points, heat (cold) bridges compared to the Dämmpaneelen used for this invention. In the US 2009/0120028 A1, although a special manner of construction and the production of panel walls is described, but it lacks exactly the properties with respect to tightness-related vulnerabilities, heat (cold) bridges, which includes our invention.

All of these applications can be attributed with improved physical properties. However, the problems of tightness with respect to water (thus moisture, mold in the substrate) and heat (cold) bridges and tightness-related vulnerabilities especially in the area of floor and wall, and wall and ceiling connection are not or unsatisfactory solved. Some sub-problems have been solved individually but only with considerable material and cost overhead but never in the entirety.

 Due to the innovative combined floor and wall construction of the building shell by means of the aforementioned insulation panels in conjunction with sealing systems, consisting of Dichtungsbändem, joint sealants and steel angle to achieve a nearly absolute tightness.

Thermal (cold) bridges as well as tightness-related weak points, especially in the area of floor and wall as well as wall and ceiling connections are excluded by our innovative system compared to existing systems on the market.

The special combination of long-term used and certified components ensures not only the function of a dense building envelope, but also their longevity. Due to the total tightness and an optimum insulation value of <0.1 W / m ² K, we achieve the best conditions for highly energy-efficient use with our building envelope. The savings potential in the area of energy consumption increases considerably. Even by the use of low-cost components, the cost advantage over conventional solutions is considerable.

The building envelope is not only suitable as a single-storey or single-row construction, but also very well as a building envelope in any width and height. The associated adaptation of the static parameters is a matter of course. Also, this building envelope has not yet been applied or realized in residential construction with primary energy values smaller than that of the passive house or comparable standards.

The novel combination of floor, wall and roof elements with the described sealing measures extends the scope of this high-density moisture and water-resistant building shell also flood-prone areas. The use of the panels also for floor construction not only allows a closed system, but can also replace either the floor panel or the use of a support structure allow it to be lifted off the ground without causing any deterioration in the values addressed.

By falling short of the values of cited standards, the possibility is given to realize an optimized gross / gross ratio in the single-storey building envelope, thus avoiding the economic disadvantage of double development and the necessary staircase.

The choice of the outer facade can be arbitrary (for example: plaster, wood, Eternit, aluminum, Maxplatten) and adapted to the local and cultural conditions.

The building body-compatible air exchange with system heat recovery (heating cooling) is done by the prior art known systems. Thus, we ensure optimal climatic conditions with our building shell.

The measures given in the drawings of the embodiment (in cm) are statically calculated and calculated for a building envelope of a one-story 92 m ² house. For building envelopes of different sizes adequate static dimensions are made.

 Details of the invention will become apparent from the following description of a preferred embodiment and the detailed drawings, which in the figures for reasons of clarity, not all details, such.: Outer Vollwärmeschutz, joint sealants are included. These show in

 1 shows the arrangement of different sectional planes, views or the section of the outline of a high-density building envelope according to the invention using the example of a one-story house with pent roof.

 Fig. 2, the section plane A-A

 Fig. 2a shows the cut - corner connection between the floor and wall

Fig. 2b shows the detail - corner joint between wall and roof

Fig. 3, the front view = input side (view A).

Fig. 4, the sectional plane B-B

 4a shows the detail - connection between the floor and door element, lower connection

 Fig. 4b the detail - connection between the door element and wall, upper terminal

Fig. 4c the detail - corner joint between the wall and roof 5: the view from the left side (view B)

 Fig. 6 shows the top view (roof-side element under pent roof).

 In Fig. 2, sectional plane A-A, the basic structure of the high-density building envelope is shown transparently: As a ground subsurface strip foundations 1 are applied in statically calculated distance on prepared flattened soil. At 90 degrees to the strip foundations 1, a carrier grid construction 2 is placed and connected. On the support grid structure 2, the Bodenendämmpaneele 3 are lined up and fixed in 90 degrees. Then an inner steel support structure 4, with panel feedthrough in the bottom area to the carrier grid construction 2, placed. The Wanddämmpaneele 6 are placed on the Bodendämmpaneel 3 and attached to the inner steel structure 4. The Dachdämmpaneele 8 are placed on the inner steel structure 4 and placed on the Wanddämmpaneel 6 or added. Dense connections between the respective insulation panels are given according to the product specification. On the outside of the building a full heat protection 7 is applied with adhesive technology according to the prior art. The drawn details, Fig. 2a and Fig. 2b illustrate the sealing systems between floor 3 and wall 6 and between wall 6 and attached Dachdämmpaneel 8 in more detail.

 At the transitional interfaces of the building envelope described below (for example: wall-wall, wall-roof, wall-windows / doors, floor-wall), in each case a separate sealing system is drawn in an outer, middle and inner sealing area. The outer sealing area is the area which is located directly at the respective transition interface on the outside of the building envelope. The middle sealing area is the area which is located between the building envelope components concerned. The inner sealing area is that area which is located directly at the respective transition interface of the relevant building envelope components on the inside of the building envelope.

The sealing measures with steel angle 14 40/40/1, 5 or 200/40/1, 5 or 25/130/57/1, 5 or 250/40/1, 5 and precompressed, permanently elastic, foaming sealing tapes 15 at the respective transition interfaces of Dämmpaneele or window and door transitions are explained in the following detailed views. The steel angles 14 are respectively attached along the entire side and the sealing bands 15 are drawn around.

In order to obtain tightness between the floor 3 and wall insulation panel 6, the sealing system 9, Fig. 2a, consisting of an outer sealing region 9.1, which through the area on the outside of the building envelope between the surfaces of the full thermal insulation 7 and the floor 3 or Wanddämmpaneele 6, a middle sealing area 9.2, that is the area between the surfaces of floor 3 and wall insulation panels 6 and an inner sealing area 9.3, which by the area on the inside of the building envelope between the surfaces of the steel support structure 4, which is covered by the steel angles 14 and therefore can not be drawn visible and the bottom 3 or Wanddämmpaneele 6 is given, fed. A steel angle 14 250/40/1, 5 is mounted in the outer sealing region 9.1 so that the narrow side is below the Bodendämmpaneels 3 and the longitudinal side goes beyond the Wanddämmpaneel 6. The sealing bands 15 are mounted below the steel angle so that the respective ends of the steel angle 14 are sealed and thus tightness between the floor 3 and Wanddämmpaneele 6 prevails outside. In the central sealing region 9.2 6 sealing tapes are pulled in each case at the outer and inner third below the Wanddämmpaneels, so that between the outer and inner side prevails tightness. A steel angle 14 40/40/1, 5 is mounted by the inner sealing 9.3 so that one side of the bottom 3 and the Wanddämmpaneel 6 rests. The sealing bands 15 of the inner sealing region 9.3 are mounted below the steel angle 14 so that is sealed from the respective ends of the steel angle 14 and thus also on the inside tightness between the floor 3 and Wanddämmpaneele 6 prevails.

In order to obtain tightness between wall 6 and attached roofing panel 8, the sealing system 10, Fig. 2b, consisting of an outer sealing area 10.1, which through the area on the outside of the building envelope under the Vollwärmeschutz between the surfaces of the inside of the roof projecting Wanddämmpaneele 6 and the top of the attached Dachdämmpaneele 8, a central sealing region 10.2, this is the area between the surfaces of the inside of the Wanddämpananeele 6 and the side surfaces of the attached Dachdämmpaneele 8, and an inner sealing portion 10.3, which by the area on the inside of Building envelope between the surfaces of the steel support structure 4, which is covered by the steel angles 14 and therefore can not be drawn visible and the attached roof 8 or Wanddämmpaneele 6 is given retracted. A steel angle 14 200/40/1, 5 is mounted in the outer sealing region 10.1 so that the narrow side of the Dachdämmpaneel 8 and the longitudinal side is located on the inside of the uppermost Wanddämmpaneels 6. The sealing strips 15 are mounted below the steel angle so that is sealed from the respective ends and additionally in the middle of the longitudinal side of the steel angle 14, so as to gain tightness on the outside between the wall 6 and attached Dachdämmpaneel 8. In the central sealing area 10.2 8 sealing strips are pulled in each case on the outer and inner third between the wall 6 and Dachdämmpaneel, so that prevails between the outside and inside tightness. A steel angle 14 40/40/1, 5 is mounted by the inner sealing portion 10.3 so that one side of the wall 6 and Dachdämmpaneel 8 rests inside. The sealing bands 15 of the inner sealing portion 10.3 are below the steel angle 14 so attached that is sealed from the respective ends of the steel angle 14 and thus also prevails on the inside tightness between the wall 6 and Dachdämmpaneel 8.

 In Fig. 3, the front view = input side (view A) is shown only by the building envelope. This also shows the laying of the wall panels, which takes place in the horizontal direction.

 In Fig. 4, sectional plane B-B, the building envelope is cut laterally. Therein, the roof pitch and the projection or the rectangular arrangement of the lateral Wanddämmpaneele 6 can be seen. The drawn details, Fig. 4a and Fig. 4b show the Abdichtungungssysteme in the doors 5 in more detail, with identical measures are taken even in windows. Fig. 4c shows the sealing system between wall 6 and attached Dachdämmpaneel 8 in more detail.

 So that between the floor and door or window element 5 tightness is present, starting from the respective underlying Dämmpaneel 6 as the lower connection the sealing system 11, Fig. 4a, consisting of an outer sealing region 11.1, which through the area on the outside of the building envelope between the surfaces of the full heat protection 7 and the door or window element 5 and the respective underlying Dämmpaneel 6, a central sealing region 11.2, that is the area between the surfaces of the lower terminal of the door or window element 5 and the upper surface of the respective underlying Dämmpaneels 6, and an inner sealing portion 11.3, which is given by the area on the inside of the building envelope between the surfaces of the lower terminal of the door or window element 5, which is placed on the central sealing portion 11.2, and the respective underlying Dämmpaneels 6 is a drawn. In the outer sealing region 11.1, a cover plate 16 90/1, 5 is mounted so that it covers half of the Dämmpaneel and the door or window 5 in each case. Both just above the lower end of the cover plate 16 and just above the lower end of the door or window stock ever a sealing strip 15 is retracted. Thus, the outside between Dämmpaneel 6 and door or window 5 is tight. In order to seal between Dämmpaneel 6 and respective door or window element is backfilled as a middle sealing region 11.2 with a hard foam 17. A steel angle 14 25/130/57/1, 5 is mounted by the inner sealing portion 11.3 so that the lower side of the angle is attached to the lower door or window 5 stock. The sealing bands 15 of the inner sealing portion 11.3 are mounted below the steel angle 14 so that is sealed from the respective ends of the steel angle 14 and thus also prevails on the inside tightness between Wanddämmpaneel 6 and door or window element.

In Fig. 4b, the sealing system 12 between the door or window element, upper terminal and Wanddämmpaneel 6 consisting of an outer Sealing area 12.1, which is given by the area on the outside of the building envelope between the surfaces of the full heat protection 7 and the door or window element 5 and the respective overlying Dämmpaneels 6, which is placed on the central sealing region 12.2, a central sealing region 12.2, this is the area between the surfaces of the upper terminal of the door or window element 5 and the lower surface of the respective overlying Dämmpaneels 6, and an inner sealing portion 12.3, which through the area on the inside of the building envelope between the surfaces of the upper terminal of the door - or window element 5 and the respective overlying Dämmpaneels 6, which is placed on the central sealing region 12.2, given in detail. It can be seen that exactly the same sealing measures as at the lower terminal, only mirror returns, are taken, so tightness between Türbzw. Window upper connection and Dämmpaneel 6 prevails.

In order to achieve tightness between wall 6 and attached (as opposed to the attached in Fig. 2b) Dachdämmpaneel 8, the sealing system 13, in Fig. 4c, consisting of an outer sealing portion 13.1, which by the area on the outside of the building envelope under the Full thermal protection between the surfaces of the Wanddämmpaneele 6 superior or placed Dachdämmpaneelen 8 and the Wanddämmpaneelen 6 is given, a central sealing region 13.2, that is the area between the surfaces of the upper side of the Wanddämmpaneelen 6 and the underside of the attached Dachdämmpaneele 8, and an inner sealing area 13.3, which is given by the area on the inside of the building envelope between the surfaces of the steel support structure 4, which is covered by the steel angles 14 and therefore can not be drawn visible and the underside of the attached roof 8 or inside of Wanddämmpaneelen 6 is confiscated. A steel angle 14 40/40/1, 5 is mounted in the outer sealing region 13.1 so that one side of the wall 6 and Dachdämmpaneel 8 rests outside. The sealing tapes 15 from the outer sealing portion 13.1 are mounted below the steel angle 14 so that the respective ends of the steel angle 14 are sealed and thus prevails on the outside tightness between the wall 6 and Dachdämmpaneel 8. In the central sealing area 13.2 8 sealing tapes are drawn in each case on the outer and inner third between the top wall 6 and bottom Dachdämmpaneel so that prevails between the outside and inside tightness. A steel angle 14 40/40/1, 5 is mounted by the inner sealing region 13.3 so that each side on the wall 6 and Dachdämmpaneel 8 rests inside. The sealing strips 15 from the inner sealing portion 13.3 are mounted below the steel angle 14 so that the respective ends of the steel angle 14 are sealed and thus also on the inside tightness between the wall 6 and 8 Dachdämmpaneel prevails. In order to gain tightness even in the corner joints between the abutting Wanddämmpaneelen 6 is a sealing system consisting of an outer sealing region, which is given by the area on the outside of the building envelope between the surfaces of the Vollwärmeschutzes 7 and the surfaces of the respective meeting in the corner Wanddämmpaneelen 6 , an intermediate sealing area, that is the area between the surfaces of the respective wall dam panels 6 meeting in the corner and an inner sealing area passing through the area on the inside of the building envelope between the faces of the steel supporting structure 4 obscured by the steel angles 14 and therefore can not be drawn visible and given the respective meeting in the corner Wanddämmpaneelen 6, fed.

 The sealing measures in the form of the sealing systems 9, 10, 11, 12, 13 with outer, middle and inner sealing area result according to the invention with the arrangements of conventional Dämpananeele and joint sealants a high-density building envelope, so that heat and cold bridges are excluded and by a body-friendly air exchange With optimum system heat recovery, healthy climatic conditions are generated under best energy and cost-saving effectiveness.

 Reference symbols

 1 strip foundations

 2 carrier grid construction

 3 floor dam panels

 4 Internal steel support structure made of hot and cold rolled steel profiles

5 door or window

 6 wall insulation panels

 7 full heat protection

 8 roof insulation panel

 9 Sealing system between floor and wall insulation panel, consisting of:

9.1 outer sealing area

 9.2 middle sealing area

 9.3 inner sealing area

 10 sealing system between wall and attached roof insulation panel, consisting of:

 10.1 outer sealing area

 10.2 middle sealing area

 10.3 inner sealing area

 1 1 Sealing system between floor or wall insulation panel and door or window element, lower connection, consisting of:

 1 1 .1 outer sealing area

1 1 .2 medium sealing area 11.3 inner sealing area

 12 sealing system between door or window element and Wanddämmpaneele, upper terminal, consisting of:

 12.1 outer sealing area

 12.2 middle sealing area

 12.3 inner sealing area

 13 Sealing system between wall and topped roof insulation panel, consisting of:

 13.1 outer sealing area

 13.2 middle sealing area

 13.3 inner sealing area

 14 steel angles

 15 sealing tapes

 16 cover plate

 17 hard foam

Claims

claims:  1. A method for the comprehensive sealing of a building envelope, characterized in that between the all-round enclosing floor (3), wall (6) and Dachdämmpaneelen (8) and around the door and window elements (5) sealing systems (9, 10, 1 1, 12, 13) moist or wasserresi stent be retracted.  2. A method for the comprehensive sealing of a building envelope according to claim 1, characterized in that between the floor (3) and Wanddämmpaneelen (6) a sealing system (9) in an outer sealing region (9.1), which by the area on the outside of the building envelope between the Areas of the full thermal protection (7) and the bottom (3) or Wanddämmpaneele (6) is given, in a central sealing area (9.2), that is the area between the surfaces of floor (3) and wall damper panels (6) and in an inner sealing area (9.3), which is fed through the area on the inside of the building envelope between the surfaces of the steel support structure (4) and the floor (3) or wall insulation panel (6).  3. A method for the comprehensive sealing of a building envelope according to claim 1, characterized in that between the wall (6) and attached Dachdämmpaneelen (8) a sealing system (10) in an outer sealing region (10.1), which by the area on the outside of the building shell under the full heat protection between the surfaces of the inside of the roof projecting Wanddämpananeele (6) and the top of the attached Dachdämmpaneele (8) is given in a central sealing region (10.2), that is the area between the surfaces of the inside of the Wanddämmpaneele (6) and in the side surfaces of the attached roofing membrane panels (8), and in an inner sealing area (10.3) passing through the area on the inside of the building envelope between the surfaces of the steel supporting structure (4) and the attached roofing (8) or walling panels (6) is recovered. 4. A method for the comprehensive sealing of a building envelope according to claim 1, characterized in that between the bottom and door or window element (5), starting from the respective underlying Dämmpaneel (6) as a lower connection a sealing system (11) in an outer sealing region (11.1) , which is given by the area on the outside of the building envelope between the surfaces of the full thermal protection (7) and the door or window element (5) and the respective underlying Dämmpaneel (6), in a central sealing region (11.2), that is Area between the surfaces of the lower terminal of door or window element (5) and the upper surface of the respective underlying Dämmpaneels (6), and in an inner sealing area (11.3), which by the area on the inside of the building envelope between the surfaces of the bottom terminal of the door or window element (5) aufges on the central sealing area (11.2) ow is, and the respective underlying Dämmpaneels (6) is given, is recovered.  5. A method for the comprehensive sealing of a building envelope according to claim 1, characterized in that between the upper terminal of the door or window element (5) and the Wanddämmpaneel (6) a sealing system (12) in an outer sealing region (12.1), which by the Area on the outside of the building envelope between the surfaces of the full thermal protection (7) and the door or window element (5) and the respective overlying Dämmpaneels (6), which is placed on the central sealing region (12.2) is given, in a middle Sealing area (12.2), which is the area between the surfaces of the upper terminal of the door or window element (5) and the lower surface of the respective overlying Dämmpaneels (6), and in an inner sealing region (12.3), which by the area the inside of the building envelope between the surfaces of the upper terminal of the door or window element (5) and the respective übereinli Seten Dämimpaneels (6), which is placed on the central sealing area (12.2) given, is retracted.  6. A method for the comprehensive sealing of a building envelope according to claim 1, characterized in that between the wall (6) and attached Dachdämmpaneel (8) a sealing system (13) in an outer sealing region (13.1), which by the area on the outside of the building shell under the full thermal insulation between the surfaces of the Dachdämmpaneelen (8) and the Wanddämmpaneelen (6) projecting the Wanddämpananeele (6), in a central sealing region (13.2), that is the area between the surfaces of the upper side of the Wanddämmpaneelen (6) and the underside of the attached Dachdämmpaneele (8), and in an inner sealing region (13.3), which by the area on the inside of the building envelope between the surfaces of the steel support structure (4) and the underside of the attached roof (8) or Inside the Wanddämmpaneelen (6) is given, is retracted. 7. A method for the comprehensive sealing of a building envelope according to claim 1, characterized in that in the corner joints between the abutting Wanddämmpaneelen (6) a sealing system in an outer sealing region, which by the area on the outside of the building envelope between the surfaces of the Vollwärmeschutzes (7) and the areas of the respective wall-damper panels (6) meeting in the corner, into a central sealing area, that is the area between the surfaces of the wall-damper panels (6) respectively meeting in the corner and into an inner sealing area passing through the area on the inside the building envelope between the surfaces of the steel supporting structure (4) and the respective wall damper panels (6) meeting in the corner is drawn in. 8. A method for the comprehensive sealing of a building envelope according to claim 1 to 7, characterized in that the respective outer (9.1, 10.1, 11.1, 12.1, 13.1) and inner sealing areas (9.3, 10.3, 11.3, 12.3, 13.3) with steel angle (14) Cover plate (16) and the underlying sealing strips (15) are performed.  9. A method for the comprehensive sealing of a building envelope according to claim 1 to 7, characterized in that the respective central sealing areas (9.2, 10.2, 11.2, 12.2, 13.2) with sealing strips (15) or hard foam (17) are performed.