EP0227937B1 - Balcony for subsequent fixation to a building - Google Patents

Description

The invention relates to a balcony which can be retrofitted to the outer wall of a building by means of a balcony support and has a balcony floor and a surrounding railing, the balcony support being held by main supports.

When renovating and overhauling existing buildings, there is often a desire to retrofit balconies to improve the living quality of such buildings. This generally arouses a trouble, since the building structure _'is not designed for the attachment of balconies.

Using a procedure, subsequently attachable balconies are attached to the ascending masonry using brackets. The vertical legs of the brackets can be fastened both below and above the horizontal legs, the fastening means having to be carried by the aspiring masonry. This means that in multi-storey buildings, the balconies in vertical alignment must find enough abutments in the emerging masonry on each floor. As a rule, however, this is no longer the case for the last, the roof-level storey of residential buildings, since there the support forces required to hold the balconies are missing. In addition, the installation requires intervention in the masonry, which is in every floor in the same position, regardless of. heating and other pipe ducts running in the masonry may have to be made.

Such a balcony arrangement, in which the balconies are attached to the outside with the aid of angular bracket supports, which are supported in recesses in the outer wall, is described in DE-OS 15 09 484.

In addition, a balcony arrangement for retrofitting to existing buildings is known, which consists of an essentially vertical column arrangement which is founded separately from the outer wall of the building and runs at a distance from it and on which at least one balcony is arranged which is supported exclusively by the column arrangement (DE -AS 26 12 185).

This column arrangement is supported on a foundation that is also in front of the house according to the column arrangement. Such a construction for retrofitting balconies can therefore not be used on houses that are directly on the property boundary, since in this case there is no space for the necessary foundations for the construction of the main girders. In addition, the individual balconies attached to the column structure must also be connected to the house wall in accordance with DE-AS 26 12 185, as a result of which thermal bridges are formed.

The invention has for its object to develop a retrofittable balcony so that with an enlarged cantilever and greater width, the top floor near the roof can be provided with a balcony and so multi-storey buildings are accessible for retrofitting, with cold bridges to a minimum should be reduced, and the external appearance of the building should not be significantly affected.

According to the invention, the balcony is characterized by a pair of main girders which run almost over the entire height of the building and lie directly against the outer wall and which can be connected to the building wall at least near their upper end by means of fasteners which can be guided through the building wall, and to which one each by means of fastening means Balcony bracket is attached with a vertical leg and an associated horizontal leg, and wherein the horizontal legs serve as a support for the balcony floor.

The provision of main girders, which carry the balconies arranged vertically one above the other, means that the fastening points can be reduced to a few, in the limit case to one. The fastener need not be used directly at the upper end of the main girder, but it can be provided deeper, in an area in which the necessary load is ensured by the rising masonry parts above it. The use of the main girders also allows the balcony girders to be attached using mechanical engineering means, which in turn allows the cantilever to be enlarged.

By reducing the fastening means led through the wall to a few, in the borderline case to one, the number of cold bridges is also reduced, so that additional cold bridges no longer have to be expected on each floor. The balconies attached to the main girders themselves are of the usual type, the balcony floor being present between the horizontal legs of the balcony girder and a balcony railing enclosing the free sides being provided, to which - as is often desired - flower boxes or the like are attached can.

A further development is given in that the fasteners which can be guided through the building wall consist of a wall anchor and an anchor plate, the wall anchor extending through the building wall and being able to be connected to the anchor plate which can be positively attached to the inside of the building wall. This further development ensures that the aspiring masonry is initially only subjected to pressure in the area of the fastening means, due to the force-fitting anchor plate pressed against the inner wall. It goes without saying that the surface of the main carrier facing the wall, which is preferably as the T-leg is directed towards the wall, is used to pull the same-sized counterforce against the outside of the aspiring masonry. The resulting pressures are inversely proportional to the areas. The wall anchor is expediently placed in the upper area of the main girder, but the wall anchor does not have to be provided directly at the upper end of the main girder; it can also be provided at a distance from the upper end, depending on the requirements of the building construction. This design of the fastening means ensures a favorable introduction of the forces acting in the vertical direction into the aspiring masonry via the frictional connection.

A preferred embodiment of the wall anchor is given by a sleeve, an outer anchor plate and an inner anchor plate, the outer anchor plate being fixedly connected to one end of the sleeve and the other end of the sleeve being connectable to the inner anchor plate, and the outer anchor plate preferably has fasteners designed as outer bolts. The wall anchor thus created requires a single hole corresponding to the outer diameter of the sleeve. The sleeve itself is not guided through the entire masonry, so that uneven masonry thicknesses can be bridged by the inner anchor plate connectable to the free sleeve end, the distance between the. inner anchor plate and the sleeve end corresponds to the difference between the wall thickness and sleeve length. It goes without saying that e.g. soft plaster layers can be worked out so that the anchor plate comes to rest against the masonry.

A further development is given in that the sleeve end which can be connected to the inner anchor plate has means for receiving an adjusting and holding screw guided through the inner anchor plate, with which the inner anchor plate can be tightened against the sleeve, preferably the means for receiving the adjusting and Retaining screw are formed by a central nut which is firmly connected to a counter bearing plate which at least partially fills the cross section of the wall sleeve. This embodiment pulls the inner anchor plate against the sleeve with a single screw. It goes without saying that this "pull against the sleeve indicates the direction, the inner surface of the masonry limiting the path so that it does not come into contact with the sleeve and also does not come about because of the forces to be introduced into the masonry by friction may come. By choosing the abutment and the retaining and fastening screw, the wall anchor can be easily adapted to the required power transmission conditions.

Particularly for buildings with a floor or ceiling construction that may not be subjected to significant static loads, it is advantageous that the inner anchor plate is provided with a tie rod which has fastening means for fastening in a transverse wall at least near its free end. In addition, it is proposed that the fastening means arranged at the free end of the tie rod be designed as a sleeve which can be inserted into the transverse wall and corresponds to the sleeve of the wall anchor. Through this additional tie rod, which is firmly connected to the inner anchor plate, the transmitted forces can be introduced into the transverse walls dividing the structure into rooms. These tie rods are advantageously designed as flat steel profiles that are guided in the ceiling area to the opposite ceiling. The angular position of the tie rod is determined by the position of the anchor in relation to the corner to be assigned. The tie rod advantageously runs in the area of the ceiling plaster. Because of the flush installation, the tie rod disappears completely. The fastening in the area of the opposite corner takes place in the transverse wall, the fastening means also being able to be designed as an angle profile section which are welded to the free end of the tie rod. While one leg of the angle section section e.g. is anchored in the wall opposite the outer wall by means of dowel screw connections, the second leg of the angle section section is provided with holding means which can be inserted into the transverse wall, so that the force is primarily introduced into the transverse wall. This type of fastening requires that the tie rod can be guided into the corner of the room. If this is not the case, the free end of the tie rod is provided with fastening means which can be inserted into the transverse wall and which are advantageously designed as a sleeve. If it is not possible to pass the wall anchors close to the ceiling, but the wall anchors can be arranged close to the transverse walls, it is possible to guide the tie rods, which are designed as flat steel profiles, flush with the plaster walls and at a certain distance from the outer wall, depending on the location 2.0 to 3.5 m, to be anchored in the transverse wall.

The further development of the use of the wall anchor even with masonry provided with non-load-bearing facing shells is provided in that the sleeve has an abutment at a distance from the outer anchor plate, the contact plane of the inner anchor plate running essentially parallel to the contact plane of the outer anchor plate. It is further proposed that the wide bearing be designed as a ring placed on the outside of the sleeve and firmly connected to it. Alternatively, it is proposed that the abutment, which is preferably designed as a contact sleeve, is adjustable with respect to its distance from the outer anchor plate. The length of the sleeve of this abutment creates the possibility of tightening the sleeve of the anchor against the aspiring masonry through the abutment and through the inner anchor plate, the frictional engagement between the corresponding sides of the masonry and on the one hand the abutment and on the other hand the inner anchor plate is produced by tightening the connecting and retaining screw. The outer anchor plate is at a distance from the abutment, which is dimensioned such that the outer anchor plate rests essentially without force on the facing shell forming the facade or - if this can be left out - is arranged flush in it. The design of the abutment as a ring firmly connected to the sleeve allows the bore necessary for inserting the sleeve to be made with a diameter slightly larger than the sleeve diameter through the facing shell and masonry, and then a further hole corresponding to the ring diameter through the facing shell alone. In order to be able to bridge different thicknesses of the facing shells and also to provide rear-ventilated facing shells with a greater distance for the use of the wall anchor, it is advantageous to make the distance between the abutment and the outer anchor plate changeable. One possibility is given by the fact that the abutment is designed as a ring which can be displaced on the sleeve with close play and can be fixed at the desired distance using suitable means.

Another proposal is that at least the side of the outer anchor plate facing the inner anchor plate has an elastic compensation pad. This elastic compensation underlay ensures a secure and tight fit of the outer anchor plate, regardless of whether the outer anchor plate rests on the outer surface of the masonry or the facade or is embedded in it. It goes without saying that the abutment can also be provided with a corresponding elastic compensation pad, which compensates for unevenness and ensures an even introduction of force. In addition, this compensation underlay has a heat-insulating function; the dreaded cold bridges can be largely prevented by their use. Such cold bridges are already interrupted in the proposed wall anchor embodiment because the means for receiving the screw guided through the inner anchor plate mean an extension of the heat transfer path and can also be kept in their cross sections so that the heat transfer remains within limits for a given power transmission . This is further supported by the fact that existing cavities (in which air can be transferred by convection) can be filled with insulating foams.

It is further proposed that the vertical legs of the balcony beams are arranged substantially above the horizontal legs. In addition, it is proposed that the upper ends of the vertical legs and the outer ends of the horizontal legs are connected by tension belts. This arrangement makes it possible to advantageously introduce the moment transmitted from the horizontal legs into the main carrier and thus to select the force distribution by appropriately choosing the fastening points above and below the starting point of the horizontal leg. A tension belt, which is guided diagonally outwards from the upper end of the vertical leg to the underlying outer end of the horizontal leg, is able to absorb additional forces and moments.

Another embodiment is given in that outer vertical struts are attached to the outer ends of the horizontal legs, which are connected to the main support by means of an upper strut above the balcony support. It is also proposed that the top strut be horizontal. Finally, it is proposed that an oblique connecting link is provided between the upper end of the outer vertical strut and the outer end of the horizontal upper strut. This design creates an at least three-sided frame on both sides of the balcony, which is arranged above the balcony support and e.g. can accommodate the necessary balcony railings. If the outer vertical strut is raised very high, it may be advantageous to provide an oblique link in order to maintain the architectural line. It goes without saying that the vertical struts of the balcony girder can also be guided up to the height of the fastening points, so that the framework can also form an all-round closed frame on the side.

This embodiment is advantageous for balconies for the top floors, for example; sun protection or rain protection roofs can be provided here. The all-round closed side frame can also accommodate side weather protection or viewing panels.

Another embodiment is provided in that an approximately semicircular support extending from the lower end of the vertical leg to the main support above the balcony support is provided, which is connected to the outer end of the horizontal leg. This structure allows the balconies to have a special architectural shape, with each balcony being designed in a circular section.

A further development is given in that the balcony floor is formed from plates or planks preferably provided on their underside with longitudinal reinforcing ribs, one longitudinal edge of the plates or planks each having a longitudinal groove and the opposite side of the plates or planks having a longitudinal, has a form-fit insertable projection. The floor lying between the balcony girders can be formed by boards and planks, which - to ensure perfect fit and tightness to reach below - are provided with connecting means in the manner of a tongue and groove connection. The projection that can be inserted into the groove can have any conceivable cross-section, in particular rectangular or triangular, but also shapes such as a semicircle or a rectangle with a semicircular leading edge. Providing the underside of the plates with reinforcing ribs enables a material-saving design. The production of the plastic plates, where recycled material is advantageously used, allows the production of plates or planks that are completely rot-proof, that are lighter than concrete, that have high bending tensile strengths, and that are ultimately sun and UV resistant. The use of recycled material is economically advantageous and offers a possible use for old material. The plates are produced as pressed parts, the plastic which has become dough under the action of heat is introduced in portions into the molds and is pressed out into a plate by means of a press ram.

Another suggestion is that the outer ends or horizontal legs of the Blakonträger are connected by means of a front horizontal support beam to a three-sided circumferential support frame, this support frame at least supports the balcony railing. It is further proposed that between the horizontal legs of the balcony beams and transversely to them are arranged transverse beams which are applied to the horizontal legs by means of preferably sound-insulated thrust bearings. Finally, it is proposed that the balcony floor has a slope at least towards one of the outer sides, and that this side is provided with a rain gutter. A front frame for the balcony floor creates a support frame for the balcony floor, thus securely supporting the balcony floor even with oversized cantilevers. The other crossbeams, which are parallel to the front horizontal end beam, support this. It goes without saying that parallel additional girders can be introduced to the horizontal legs, which also enables oversized spans. In order to avoid sound transmissions via the cross members or the front horizontal end member, these are placed using sound-insulated pressure bearings, such as pressure-resistant acoustic panels placed between them. The sound path over the plates or planks of the balcony floor and the cross beams or the front horizontal end beam to the horizontal legs of the balcony beams is effectively interrupted. Additional soundproofing measures to prevent sound transmission via the main beam into the masonry can thus be omitted. The inclined floor arrangement allows rainwater to flow away in the direction of the gutter. Rain gutters can be provided on all three sides, while the balcony is only inclined to the rain gutter assigned to the front side. It is also possible to incline the balcony on one or both sides or to provide the inclination on all three sides. In all of these cases, the rainwater is drained through the gutters.

• Fig. 1 drei übereinander an einer Gebäudewand angeordnete Balkone
• Fig. 2 Einzelheit eines Balkons
• Fig. 3 Einzelheit eines Balkons anderer Ausführungsart
• Fig. 4 Einzelheit eines Balkons mit hochgezogener vorderer Vertikalstrebe und Querstrebe
• Fig. 5 Einzelheit Balkon mit halbkreisförmigen Träger
• Fig. 6 Aufsicht auf einen Balkon
• Fig. 7 Vorderansicht eines Balkons
• Fig. 8 Einzelheit Bodenbohlen
• Fig. 9 Einzelheit Auflage Querträger
• Fig. 10 Einzelheit Bodenbohlen
• Fig. 11 einen Querschnitt durch einen Maueranker im Mauerwerk mit vorgesetzter Fassaden-Schale
• Fig. 12 eine perspektivische Ansicht des Mauerankers
• Fig. 13 Außenansicht des Mauerankers
• Fig. 14 Innenansicht des Mauerankers
• Fig. 15 Balkonanbringung mit Zugankern (schematisch)
• Fig. 16 Zuganker, befestigt an Maueranker
• Fig. 17 Zuganker-Widerlager
  • a : horizontal geschnitten
  • b : vertikal geschnitten
• Fig. 18 Zuganker längs der Querwand

The essence of the invention is illustrated by way of example with reference to FIGS. 1 to 17; show in detail:

• Fig. 1 three balconies arranged one above the other on a building wall
• Fig. 2 detail of a balcony
• Fig. 3 detail of a balcony of another embodiment
• Fig. 4 detail of a balcony with raised front vertical strut and cross strut
• Fig. 5 detail balcony with semicircular support
• Fig. 6 supervision of a balcony
• Fig. 7 front view of a balcony
• Fig. 8 detail floor planks
• Fig. 9 detail edition cross member
• Fig. 10 detail floor planks
• Fig. 11 shows a cross section through a wall anchor in the masonry with front facade shell
• Fig. 12 is a perspective view of the wall anchor
• Fig. 13 exterior view of the wall anchor
• Fig. 14 Interior view of the wall anchor
• Fig. 15 Balcony attachment with tie rods (schematic)
• Fig. 16 tie rods, attached to wall anchors
• Fig. 17 tie rod abutment
  • a: cut horizontally
  • b: cut vertically
• Fig. 18 tie rods along the transverse wall

1, three balconies I, II and 111 are mounted one above the other on a vertical main beam 2 on a building wall 1, the balcony appearances roughly matching those from the tops of the floor ceilings 1.2. The main girders 2 are fastened with anchor bolts 11 guided through the wall 1 near their upper ends and the inner anchor plates 12 pressed against the wall on the inside of the wall 1. This attachment can also be set deeper without the top balcony I having to change its position. This is necessary in cases where the brickwork above the attachment point 10 - e.g. because the roof has been pulled down so far - it can no longer provide the necessary contact force and thus the counterforce necessary for secure holding.

The individual balconies are provided between the two main girders 2.1 and 2.2 (FIG. 7), a balcony girder having its vertical leg 4 being attached to each of the main girders 2.1 and 2.2. Fastening means 5 are provided near its upper and lower ends for fastening. On the vertical leg 4 of the balcony support is the horizontal Schentel 3, which supports the balcony floor 6. In the case of larger spans, it is advisable not to use cross members 8 or one to be provided in more detail - to provide the front end support. The rain gutter 9 collects the rainwater running off the balcony floor 6 and drains it away. The safety railings 13 required for the balcony are connected to the main beams 2.1 and 2.2 on the one hand and, on the other hand, to supports either with the horizontal legs 3 of the balcony beams or with the covering on plates or planks 6.1 of the balcony floor 6. The balcony boxes 14, which are often attached, with a suitable one Planting can be easily attached to the front of the balcony railing 13 - as well as to the side. Access to the balcony is through the balcony door 1.1; with 1.2 the floor ceiling forming the floor of this floor is designated. While in FIG. 2 the vertical leg 4 of the balcony support runs essentially below the horizontal leg 3, in FIG. 3 the vertical leg 4 is arranged above the horizontal leg 3.

FIG. 4 shows a balcony with the same reference numbers as discussed in FIGS. 1 to 3, only an outer vertical strut 3.2 is provided which extends beyond the railing 13 and an obliquely running connecting member 3.4 is connected to the very short top strut 3.3 here. The upper strut 3.3 in turn is attached to the main support 2. A sun protection roof or a rain protection roof can be applied to the inclined connecting link 3.4. It goes without saying that, instead of the oblique link 3.4, the upper link 3.3 can be guided horizontally forward until it abuts the elongated outer vertical strut 3.2 and is fastened there. It also goes without saying that the upper strut 3.3, which is guided in this way to the outer vertical strut 3.2, can be provided as an upper railing closure at the level of the upper edge of the railing 13. The frame formed by the outer vertical struts, the connecting links and upper struts can also accommodate lateral weather protection and privacy screens.

FIG. 5 shows an architecturally special form of training with a balcony, in which the peripheral frame is made approximately semicircular and is returned from the lower end of the vertical leg 4 via the outer end of the horizontal leg 3 to the main beam 2. The correspondingly shaped semicircular beam 3.6 takes over the function of the three-sided circumferential frame formed from the outer vertical strut 3.2, the upper strut 3.3 and the oblique member 3.4.

Figure 7 shows a front view of the balcony, which is arranged between the two main beams 2.1 and 2.2. The front of the balcony is secured with the balcony railing 13, which is designed as a grid element. This does not exclude other training courses on the balcony railing. Two flower boxes 14 are provided on the balcony grille 13. The top of the balcony floor 6 can be seen, as is a cross member 8. The front rain gutter 9 enables water to drain off.

FIG. 6 shows a top view, the building wall 1 being shown in section; the balcony door 1.1 - shown interrupted - allows access to the balcony, which is arranged between the two main beams 2.1 and 2.2. The balcony floor is provided with a wooden tile covering 6.5, which sits on the planks 6.1 at a distance (FIG. 8). All three free balcony sides are provided with balcony grilles 13; on the front of the balcony grille 13 two flower boxes 14 are provided. The three-sided, all-round rain gutter can be clearly seen in the supervision, which drains the collected rainwater to an outlet 9.1, which is connected to a downpipe (not shown).

FIG. 8 shows two cut planks 6.1 for the balcony floor with triangular grooves 6.2 and longitudinal projections 6.3. The projections 6.3 can be positively inserted into the grooves 6.2. Any type of shape design is conceivable, for example rectangular, rectangular with a semicircular outer edge or semicircular. Depending on the span of the balcony, these planks 6.1 rest on the horizontal legs 3 of the balcony beams and then run transversely to them or - as shown in FIG. 9 - on the cross beams 8 and then run parallel to the horizontal legs 3 of the balcony beams. Tiles 6.5 designed as tiles (see also FIG. 6) are placed on the planks. The individual planks 6.1 can - according to FIG. 10 - be provided with reinforcing strips 6.4 on their underside. In Fig. 11, the aspiring masonry is shown at 1, which is covered on the inside with the plaster layer 1.5. A facing shell 1.7 held with a support structure formed from vertical battens 1.8 and horizontal battens 1.9 is designed as a ventilated facade. The vertical main beam 2 is the beam that carries the load of the attached balconies. Through the emerging masonry 1, the bore 1.6 is placed, in which the sleeve 21 of the wall anchor 11 can be inserted. In order to bring the wall anchor 11 into frictional engagement with the emerging masonry 1, a circumferential ring 22 is provided as an abutment, which is pulled against the outside of the emerging masonry with elastic supports 22.1, the inner anchor plate 12 being flush with the plaster layer 1.4 of the emerging masonry 1 serves as an inner abutment. This inner anchor plate 12 is connected via an adjusting and holding screw 21.3 to a counterbearing 21.1 at the free end of the sleeve 21, which in this illustration consists of a counterbearing plate which fills the entire cross section of the sleeve 21 and which has a central bore behind which a weld-on nut 21.2 is welded on. The counter-bearing plate 21.1 is welded to the free end of the sleeve 21. At the outer end of the sleeve 21, the outer anchor plate 23 is provided, which in this embodiment on the front facade 1.7 does not exert any force, the distance between the abutment 22 and the outer anchor plate 23 of course being set up corresponding to the thickness of the curtain wall 1.7 and an air gap lying behind it. The outer anchor plate 23 is welded to the outer end of the sleeve 21 and is thus pulled together with the abutment ring 22 when the screw 21.3 is tightened into its position within the curtain shell 1.7. Elastic leveling pads 23.1 serve both to compensate for dimensional tolerances and to seal in order to prevent moisture from penetrating into the space behind the curtain wall 1.7 at this point. The outer anchor plate 23 itself is provided with fastening means for holding the load, in this case the vertical main beam 2. For this purpose, bolts 24 are guided through the outer anchor plate 23, the head of these bolts 24 being welded on the inside to the outer anchor plate 23. The vertical main beam 2, which is designed as a T-beam, is provided with corresponding bores in its flanges 2. With the help of the attached nuts 24.1, if necessary with appropriate washers or locking washers, the vertical support 2 is screwed to the wall anchor.

FIG. 12 shows a perspective view of the wall anchor 11 with the sleeve 21, the outer anchor plate 23 and the inner anchor plate 12, the parts being shown in the position that belongs to one another. Arranged on the sleeve 21 is the abutment 22, which here is divided into three circular sector-shaped segments, the spacing of which from the outer anchor plate 23 is determined by the local conditions. The outer anchor plate 23 is provided with the protruding bolts 24, which are able to absorb the load. At the free end of the sleeve 21, the counter-bearing 21.1 for the adjusting and holding screw 21.3 is shown - hidden in this illustration. Here, the middle part provided with the receiving thread is held by means of three webs arranged at an angular distance of 120 °. The inner anchor plate 12 interacts with the adjusting and holding screw 21.3, which allows the wall anchor to be tightened when it is screwed into the thread of the counterbearing.

The external and internal views of the wall anchor 11 are shown again in FIGS. The outside of the outer anchor plate 23 is visible from the outside, on which — in the selected illustration — two pairs of fastening bolts 24 are provided. This arrangement is particularly advantageous when attaching T-beams. It goes without saying that other and offset arrangements of the bolts are possible. The interior view shows the surface of the inner anchor plate 12 with the inserted adjusting and holding screw 21.3, which is shown as a slotted screw. It goes without saying that other screw shapes can also be used. In both representations, the sleeve 21 (FIG. 12) is shown in dashed lines in its contour, only the outer anchor plate 23 having a fixed connection to the sleeve 21. The counter bearing 21.2 assigned to the inner head plate (FIG. 11) is not recognizable in its representation in its plate shape.

FIG. 15 shows a distributed application of force to the wall anchors, the fastening means 10 designed as wall anchors for the (not shown) main girder being provided with tie rods 25 and these tie rods 25 introducing the forces occurring into transverse walls 1.3 by means of fastening means 26. In the right half of FIG. 15, the tie rod 25 is guided obliquely through the space to the rear corner, which is formed by the transverse wall 1.3 with an inner longitudinal wall 1.4. The details of this connection are shown in Figs. 16 and 17. The left side of FIG. 15 shows a tie rod 25 which is at right angles to the inner anchor plate and is guided to a fastening means 26 left in the transverse wall 1.3. The details of this type of tie rod connection are shown in FIG. 18.

Fig. 16 shows the detail according to XVI (Fig. 15). The vertical main beam 2 is fastened to the outer anchor plate 23 of the wall anchor by means of the fastening bolts 24; the sleeve 21 is inserted into a bore provided in the emerging masonry 1 and lies with its abutment 22.1 against the outer side, here a plaster layer 1.5, of the aspiring masonry 1. The inside of the sleeve is to avoid cold and sound bridges with an insulation -Material 21.4 filled or foamed. The inner end of the sleeve 21 is connected to the inner head plate 12 via the adjusting and holding screw 21.3. On the inner head plate 12, the tie rod 25 is attached, which runs directly under the floor ceiling 1.2 formed with wooden beams and can be plastered with. This tie rod 25 extends at a certain angle to the associated room corner, which is formed by the next transverse wall 1.3 and the rear longitudinal wall 1.4. There, according to FIGS. 17a and 17b, the tie rod 25 is firmly connected to a fastening piece 26, which is designed here as an angle with the legs 26.2 and 26.3. While the leg 26.3, which lies approximately transversely to the main direction of tension of the tie rod 25, is connected to the inner longitudinal wall 1.4 by means of dowel bolt connections (not specified in any more detail), the angle leg 26.2, which lies essentially in the main direction of tension, is provided with a sleeve 26.1 corresponding to the sleeve 21 of the wall anchor, which in a hole - not going through the wall - is embedded in the transverse wall 1.3. The fastening piece 26 is selected so that it lies flush with the plaster layer 1.5 and can thus be attached inconspicuously. 17b shows the situation in the (partially cut) top view, with the angle leg 26.3 lying essentially transverse to the main pulling direction in the top view and the angle leg 26.2 lying essentially in the main direction of the tie rod 25 can be seen in section. The ceiling 1.2 lying above the fastening piece 26, formed from wooden beams, remains without force in this type of fastening; the force is essentially introduced into the emerging masonry 1 and into the emerging masonry 1 perpendicular walls 1.3.

18 shows the detail again for fastening the main girder 2 in front of the aspiring masonry 1, the tie rod being guided directly above a floor ceiling 1.2 designed as a wooden beam ceiling, that is to say in the vicinity of the floor. The wall anchor is placed directly next to the transverse wall 1.3 (FIG. 15; left side), so that the tie rod 25 welded to the inner anchor plate 12 runs in the cleaning area of the inner transverse wall 1.3 and the fastening means 26 as essentially in the direction of pull of the tie rod 25 lying angle leg 26.2 (Fig. 17) corresponding plate 26.3 is formed. This plate is inserted into the wall as shown in FIG. 17 with a sleeve 26. 1 corresponding to the sleeve 21, and therefore transmits the forces into the transverse wall in a similar manner to that described under FIG.

The balcony formed in this way can be retrofitted to buildings, even multi-storey ones, whereby the top floor value can also be provided with a balcony if the load on the protruding masonry is not sufficient for direct fastening of the balcony beams at the desired height. The balcony also allows for idiosyncratic architectural designs using its surrounding side frame. Sun protection, bwz. Rain protection can be provided. Impact sound insulation prevents annoying sound transmission. The use of recycled plastic for the floor panels opens up an economical way of recycling and processing thermoplastic materials, whereby the balcony floor made from it is rot and corrosion resistant to almost all attacks of the contaminated atmosphere, including attacks by ultraviolet radiation or the resulting photo oxidants of photochemical smog. The special wall anchor allows the main girder to be securely attached to the striving masonry and, moreover, force can be introduced into the transverse walls if, for static reasons, e.g. In the case of wooden beam ceilings, it is not possible to apply force only to the aspiring masonry. The wall anchors can be sound and heat insulated.

Claims (18)

1. Balcony (I, II, III), which is mountable by way of addition to the outside wall of a building by means of balcony carriers, with a balcony floor (6) and an encircling parapet (13), wherein the balcony carrier is retained by main carriers (2), characterised by a pair of main carriers (2), which extend over nearly the entire height of the building, lie directly against the outside wall and are connectable with the building wall at least near their upper end by means of fastening means (10) leadable through the building wall (1) and at each of which a respective balcony carrier with a vertical limb (4) and an horizontal limb (3) connected therewith is fastened by means of fastening means (5), wherein the horizontal limbs (3) serve as bearing for the balcony floor (6).

2. Balcony according to claim 1, characterised thereby, that the fastening means (10), which are leadable through the building wall (1), consist of a wall clamp (11) and an anchor plate (12), wherein the wall clamp (11) is leadable through the building wall (1) and connected with the anchor plate (12), which is layable force-lockingly against the inside of the building wall (1).

3. Balcony according to claim 2, characterised thereby, that the wall clamp (11) is formed by a sleeve (21), an outer anchor plate (23) and an inner anchor plate (12), wherein the outer plate (23) is firmly connected with the one end of the sleeve (21), the other end of the sleeve (21) is connectable with the inner anchor plate (12) and the outer anchor plate (23) displays the fastening means preferably constructed as external bolts (24).

4. Balcony according to claim 3, characterised thereby, that the sleeve end connectable with the inner anchor plate (12) displays means for the reception of an adjusting and retaining screw (21.3), which is led through the inner anchor plate (12) and by which the inner anchor plate (12) is tightenable against the sleeve (21), wherein the means for the reception of the adjusting and retaining screw (21.3) are preferably formed by a central nut (21.2), which is firmly connected with a counterbearing plate (21.1) at least in part filling out the cross-section of the sleeve (21).

5. Balcony according to one of the claims 3 and 4, characterised thereby, that the sleeve (21) at a spacing from the outer anchor plate (23) displays a counterbearing (22), the bearing plane of which facing the inner anchor plate (12) extends substantially parallely to the bearing plate of the outer anchor plate (23), wherein the counterbearing (22) is preferably constructed as a ring placed on the outside of the sleeve (21) and connected with it.

6. Balcony according to claim 5, characterised thereby, that the counterbearing (22) is adjustable in respect of its spacing from the outer anchor plate (23).

7. Balcony according to one of the preceding claims 3 to 6, characterised thereby, that at least that side of the outer anchor plate (23), which faces the inner anchor plate (12), displays an elastic compensating underlay (23.1).

8. Balcony according to one of the claims 2 to 7, characterised thereby, that the inner anchor plate (12) is provided with a tie rod (25), which at least near its free end displays fastening means (26) for fastening in a transverse wall (1.3).

9. Balcony according to claim 8, characterised thereby, that the fastening means (26) arranged at the free end of the tie rod (25) are constructed as sleeve (26.1), which corresponds to the sleeve (21) of the wall clamp (11) and is lettable into the transverse wall (1.3).

10. Balcony according to one of the claims 1 to 9, characterised thereby, that the vertical limbs (4) of the balcony carriers are arranged substantially above the horizontal limbs (3).

11. Balcony according to claim 10, characterised thereby, that the upper ends of the vertical limbs (4) and the outer ends of'the horizontal limbs (3) are connected by tie straps (3.1).

12. Balcony according to one of the claims 1 to 10, characterised thereby, that outer vertical stays (3.2), which are connected with the main carrier (2) above the balcony carrier by means of preferably horizontal upper stays (3.3), are fastened at the outer ends of the horizontal limbs (3).

13. Balcony according to claim 12, characterised thereby, that an obliquely extending connecting member (3.4) is provided between the upper end of the outer vertical stay (3.2) and the outer end of the horizontal upper stay (3.3).

14. Balcony according to one of the claims 1 to 13, characterised thereby, that an about semicircular carrier (3.6) is provided, which extends from the lower end of the vertical limb (4) to the main carrier (2) above the balcony carrier and stands in connection with the outer end of the horizontal limb (3) of the balcony carrier.

15. Balcony according to one of the claims 1 to 14, characterised thereby, that the balcony floor (6) is formed of plates or planks (6.1) preferably provided at their underside with longitudinally extending re-inforcing ribs, wherein one longitudinal edge of each of the plates or planks (6.1) displays a longitudinally extending groove (6.2) and the opposite side of each of the plates or planks (6.1) displays a longitudinally extending projection (6.3) introduceable shape-lockingly into the groove (6.2).

16. Balcony according to one of the claims 1 to 15, characterised thereby, that the outer ends of the horizontal limbs (3) of the balcony carriers are connected by means of a frontal horizontal end carrier (8) into a carrier frame running round three sides, wherein this carrier frame carries at least the supports of the balcony parapet.

17. Balcony according to claim 16, characterised thereby, that transverse carriers (8.1), which mounted on the horizontal limbs (3) by means of preferably sound-absorbing thrust bearings (8.2), are arranged between the horizontal limbs of the balcony carrier and transversely to them.

18. Balcony according to claims 15 to 17, characterised thereby, that the balcony floor (6) displays a gradient towards at least one of the outward sides and that this side is provided with a rain-collecting gutter (9).

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