DE202022101887U1 - Building - Google Patents

Abstract

Building with a building shell (1) composed of at least one floor surface (3), several outer walls (4) enclosing a building interior (2) and at least one roof surface (5) at least partially covering the building interior (2), characterized in that the entire building shell (1) is made of brick masonry.

Description

The invention relates to a building according to the preamble of claim 1. The building envelope of a building consists essentially of a floor area, which usually extends over the entire interior of the building, of outer walls, which enclose the interior of the building and finally, as a closure on the top, of a roof surface. The roof area usually completely covers the interior of the building. If, for example, an inner courtyard or patio is to be left free, it is also conceivable that the surface only covers a partial area of the interior of the building and leaves another partial area free to form the inner courtyard.

In the course of the so-called "climate discussion" and the climate targets to be met in the future, efforts are being made when constructing new buildings to be as resource-saving and sustainable as possible. In particular, the ongoing energy consumption for heating in winter and for cooling in summer should be minimized.

Proceeding from this, the present invention is based on the object of designing a building in such a way that it can be completely decoupled from public energy supply networks with regard to the energy supply, ie it can be operated independently of the network.

This object is achieved by the combination of features of claim 1 in an inventive manner. The dependent claims relate to partially advantageous and partially inventive developments of this basic invention.

The invention is based on the basic idea of designing the building shell of a building in such a way that it has a highly thermally insulating and also heat-storing effect.

According to the invention, the building shell consists of brick masonry. The brick material is particularly suitable for storing heat and can also be easily and inexpensively adapted to other energy requirements. Standardized brick building materials or brick building elements are also available on the market which, on the one hand, are suitable for implementing the invention and, on the other hand, are available on the market in sufficient quantities and at low cost.

In an advantageous embodiment, the building envelope has a consistently constant wall thickness. A wall thickness in an interval greater than 50 cm and less than 100 cm is particularly preferred. A wall thickness of 75 cm is considered optimal.

In a further preferred embodiment, a pore lightweight brick with a wall thickness of 75 cm is used as the building material for the brickwork. A pore lightweight brick with a wood fiber filling, preferably with a 60% wood fiber filling, is particularly suitable. A very thick building envelope of this type insulates the building very well. The brick material also has a high heat storage capacity, so that the installation of a conventional heating system, e.g. oil heating, gas heating or a heat pump, can be completely dispensed with in the building.

The above-mentioned favorable properties of heat storage are further increased in a further advantageous embodiment in that interior walls made of solid bricks are used to subdivide the interior of the building. Such inner walls made of solid brickwork form a heat accumulator with a particularly high degree of efficiency.

For better load transfer on the one hand and as an additional heat store on the other hand, a further variant of the invention provides for a reinforced concrete floor slab to be introduced into the ground as a building foundation. This reinforced concrete floor slab is additionally shielded from the ground with the help of a pressure-resistant perimeter insulation. The floor made of bricks or the floor surface made of bricks is placed on this reinforced concrete floor slab. It is particularly expedient to compose the floor area of heavy solid bricks while maintaining the consistently constant wall thickness, in particular the wall thickness of 75 cm for the building envelope. These solid bricks have the same wall thickness as the above-mentioned lightweight pore bricks with wood fiber filling, which are used in this preferred variant only for the outer walls and the roof surface. The floor area, which consists of heavy solid bricks, forms a heat storage block that can usually store heat introduced by its own solar power in winter in order to release this heat to the building interior with a time delay.

To stabilize the peripheral outer walls made of lightweight pore bricks, a support structure composed of vertical supports and horizontal ring beams is proposed, which forms the skeleton for the building or for the outer walls and the roof surface of the housing. It is particularly advantageous to make this supporting structure from reinforced concrete. In a further development of this skeleton construction, it is advantageous to arrange a reinforced concrete slab in the area of the roof surface, which stiffens the roof surface of the building. The stiffening function is of the respective reason crack and the shape of the building and must be statically verified in each case.

In a first embodiment, the roof surface can be configured as a flat roof. In the case of a flat roof, a covering of lightweight pore bricks with wood fiber filling is then simply placed on the aforementioned reinforced concrete slab. A standard flat roof structure is then applied to this. In order to realize a pitched roof or gable roof, a roof structure is proposed which consists of several rafters arranged next to one another and leaving an intermediate space between them. So-called hook-in ceiling stones can be hung between these rafters. This area, formed from hanging brick ceiling stones, then serves as a support surface for the lightweight pore bricks of the building shell that are to be arranged above it. The lightweight pore tiles then form the roof surface in the narrower sense. They are glued on with their perforation in the direction of the roof pitch. The hanging brick ceiling stones with the reinforced concrete reinforcement plate above them also serve as additional heat storage for the building.

Steel profiles, in particular hollow profiles with a rectangular hollow cross section, can be used as rafters.

In order to supply the off-grid building with electricity, the arrangement of photovoltaic modules on the outside of the roof surface is proposed, which overlap and form the roof covering at the same time. These photovoltaic modules are part of a further proposed photovoltaic system. This photovoltaic system is fed by the photovoltaic modules arranged on the outside of the roof and, in addition to the standard inverter, also has a battery storage system to store excess energy and release it back to the building on days with little sunshine.

Furthermore, the photovoltaic system according to the invention has an electrical interface to the outside. Via this electrical interface, electricity can be fed into the building from outside, for example from a so-called "power bank". An electric vehicle can also be connected to the interface in order to charge its vehicle battery or to feed current into the building from a vehicle battery. The interface is therefore suitable for bidirectional charging.

According to the invention, the heat source initially used is the body heat emitted by the building users into the interior of the building. In addition, there is the waste heat from electrical devices, e.g. a stove, an oven, a washing machine, a tumble dryer, a dishwasher, a refrigerator, a television, a PC with a computer, a lamp or the like. In the case of the building according to the invention, this waste heat does not simply dissipate in the outside air, but is absorbed by the inner walls and the building shell and thus stored in the inner walls of the building and the building shell.

In order to be able to additionally heat the building when the outside temperatures are particularly low, a floor temperature control system or electric cables are provided in the core of the brick floor panel, which can be heated with electricity generated by the photovoltaic system. The heat introduced is then slowly released from the brick storage block to the interior of the building with a time lag. The photovoltaic system also supplies the electricity for the kitchen appliances, the building lighting, the water heating or the like. Due to the thick brick building shell, mechanical cooling is no longer necessary in summer.

In a consistent continuation of the considerations on which the invention is based, window openings and door openings are kept as narrow and high as possible. Larger window areas are only planned to the south. The small narrow windows sit on the inside of the outer wall and therefore have very deep outer reveals. This means that no sun protection is required as a blind. With the large south-facing window element, a patio roof is placed in front of it in such a way that it provides shade in summer and allows the sun to shine through the window element into the building in winter when the sun is flat. In this way, solar heat gains are achieved for the interior of the building in winter. For additional thermal insulation, it is advantageous to install windows with triple glazing in the window openings with interior fittings.

The invention thus uses the building shell consisting of target masonry to cool against the heat surrounding the building in summer and in winter as a heat store for internal heat diffusing from the interior of the building to the outside. Overheating of the interior of the building in summer or overcooling of the interior of the building in winter is effectively prevented in this way in terms of building physics. The interior rooms are generally ventilated via motor-operated window sashes, which, controlled by the CO ₂ content of the air, only ventilate intelligently until the CO ₂ content of the air is acceptable again. Night cooling in summer is particularly important here. In addition, the building according to the invention does not emit any CO ₂ and thus serves to achieve the internationally agreed climate targets during building operation nor with a building that can be built easily and massively without much technology (low-tech).

• 1 die schematische Darstellung eines Querschnitts eines erfindungsgemäß gestalteten Gebäudes,
• 2 den Längsschnitt des Gebäudes aus 1,
• 3 den Grundriss des Gebäudes aus 1 und 2 von oben gesehen,
• 4 den detaillierten Aufbau einer ersten Ausführungsform des Gebäudes gemäß der Erfindung,
• 5 eine Ausführungsform eines Ziegel-Einhängedeckensteins,
• 6 die Darstellung eines Porenleichtziegels,
• 7 eine perspektivische Ansicht einer möglichen Gebäudeform,
• 8 eine Längsschnittdarstellung einer Dachkonstruktionsmöglichkeit und
• 9 erfindungsmäßige Stahl-Hohlprofile mit rechteckförmigem Hohlquerschnitt.

The invention is explained in further detail on the basis of the exemplary embodiments shown in the drawing figures. Show it:

• 1 the schematic representation of a cross section of a building designed according to the invention,
• 2 the longitudinal section of the building 1 ,
• 3 the floor plan of the building 1 and 2 seen from above,
• 4 the detailed construction of a first embodiment of the building according to the invention,
• 5 an embodiment of a brick suspended ceiling stone,
• 6 the representation of a pore lightweight brick,
• 7 a perspective view of a possible building shape,
• 8th a longitudinal section view of a roof construction possibility and
• 9 inventive steel hollow profiles with a rectangular hollow cross section.

Identical and structurally identical parts are provided with identical reference numbers. Some of the figures contain simplified or schematic representations. Different views of the same parts can be scaled differently.

This in 1 The building shown schematically in a cross-sectional view has a building shell 1 and a building interior 2 encased by the building shell 1 . The building shell 1 is composed of a floor surface 3, outer walls 4, which enclose the building interior 2, and a top surface 5, which forms a gable roof for the building in the exemplary embodiment. According to the invention, this entire building shell 1 consists of brick masonry.

The outer walls 4 are punctuated by openings 6 as installation space for doors, windows or similar surface elements.

The roof structure is based on the 4 described from top to bottom. Photovoltaic elements 7 form the outer surface of the roof of the building. The photovoltaic elements 7 cover the entire roof surface. A batten for the photovoltaic elements 7 is arranged below the photovoltaic elements 7 . Below this are longitudinal battens and counter battens, a vapor-permeable underlay, a cross-laminated timber roof panel 17 and a building protection mat. Some of these items are in 4 not visible. Furthermore, two layers of lightweight pore bricks 8 are shown below the photovoltaic elements 7 and the cross-laminated timber roof panel 17, with only a few lightweight pore bricks 8 being provided with a reference number for the sake of clarity. The pore lightweight bricks 8 have a 60% wood fiber filling.

Finally is in 4 a roof structure 9 can be seen. The roof structure 9 consists of rectangular tubes designed as hollow steel profiles 20 as rafters and between the hollow steel profiles 20 between hung brick hanging ceiling stones 11. The in 5 The tile hanging ceiling stones 11 shown consist of a ceiling stone body 12 and two laterally projecting support cheeks 13. The support cheeks 13 protrude from two opposite side walls of the ceiling stone body 12. With these supporting cheeks 13, the hanging bricks 11 lie on the hollow steel profiles in the final assembly state. In the representation of 4 Finally, an inner wall 14 dividing the building interior 2 into several rooms can be seen. The inner wall 14 consists of solid bricks with high storage capacity.

In the representation of 4 a reinforced concrete stiffening plate 15 can also be seen, which is arranged between the lightweight pore bricks 8 and the brick suspended ceiling stones 11 .

The wall structure consists of an outer plaster and light pore bricks 8 arranged below the outer plaster, with not all the light pore bricks 8 being provided with reference numerals for the sake of better clarity. A mineral fiber insulation 16 is arranged below the lightweight pore brick 8 , which separates the lightweight pore brick 8 from reinforced concrete supports 18 . Another row of lightweight pore bricks 8 is provided on the side of the reinforced concrete supports 18 facing the building interior 2 . The layer of lightweight pore bricks 8 facing the interior of the building 2 is covered with a layer of clay plaster compared to the interior.

Finally, in the presentation of 4 a reinforced concrete floor slab 19 that serves to distribute the load evenly into the subsoil can be seen. Above the reinforced concrete floor slab 19 there are in turn several layers of brick masonry, in the exemplary embodiment three, which form the floor surface 3 of the illustrated building.

8th shows the roof structure 9 with steel hollow sections 20 as rafters. The steel hollow sections 20 usually have a rectangular hollow cross section. Between the steel hollow profiles 20 are flat brick ceiling stones 11 according to 5 mounted. The hanging bricks 11 lie with their support cheeks 13 on the hollow steel profiles 20 .

Reference List

1

building envelope

2

building interior

3

floor area

4

outer wall

5

roof surface

6

opening

7

photovoltaic element

8th

porous lightweight brick

9

roof structure

10

brick memory block

11

Brick suspended ceiling stone

12

ceiling stone body

13

support cheek

14

inner wall

15

Reinforced concrete reinforcement plate

16

mineral fiber insulation

17

Cross laminated timber roof panel

18

reinforced concrete column

19

reinforced concrete floor slab

20

Steel hollow profile as a rectangular tube

Claims (13)

Building with a building shell (1) composed of at least one floor surface (3), several outer walls (4) enclosing a building interior (2) and at least one roof surface (5) at least partially covering the building interior (2), characterized in that the entire building shell (1) is made of brick masonry. building after claim 1 characterized by a building shell (1) with a consistently constant wall thickness. building after claim 1 or 2 characterized by a wall thickness greater than 50 cm and less than 100 cm, preferably a wall thickness of 75 cm. building after one of Claims 1 until 3 characterized by brick masonry made of lightweight pore bricks (8) with a wood fiber filling. building after one of Claims 1 until 4 characterized by one or more interior walls (14) of solid brick masonry dividing the building interior (2) into individual rooms. building after one of Claims 1 until 5 characterized by a reinforced concrete floor slab (19) for load transfer and by a floor surface (3) made of brick masonry, in particular solid brick masonry, supported by the reinforced concrete floor slab (19). building after one of Claims 1 until 6 characterized by a supporting structure composed of vertical supports and horizontal ring beams. building after claim 7 characterized by a supporting structure made of reinforced concrete. building after one of Claims 7 or 8th characterized by a reinforced concrete slab additionally stiffening the roof surface (5). building after one of Claims 1 until 9 characterized by several rafters arranged next to one another and leaving a gap between them as a roof structure and by suspended tile ceiling stones (11) suspended between the rafters as a suspended ceiling. building after claim 10 characterized by steel profiles, in particular hollow profiles (20) with a rectangular hollow cross section as rafters. building after one of Claims 1 until 11 characterized by photovoltaic elements (7) arranged on the roof surface. building after claim 12 characterized by a photovoltaic system, comprising at least one battery store and preferably an electrical interface for bidirectional charging, in particular for charging the vehicle battery of an electric vehicle from the battery store on the one hand and for feeding electrical current into the battery store, for example from a rechargeable battery (= power bank) or the vehicle battery of the electric vehicle on the other hand.