DE3801990A1 - Abutment which can be positioned in masonrywork - Google Patents

Abstract

In order to channel in loads on facades or other regions of structures, use is made of an abutment which is provided, in particular, for masonry walls. Said abutment is effectively braced in the bore which has been introduced into the masonrywork beforehand, the expansion element influenced by the ring bracing segments and the clamping bolts being configured as a neoprene casing which is closed all the way around and between which and the basic body the ring bracing segments are arranged with clamping bolts running between them. Specific introduction of pressure takes place, in this arrangement, by corresponding thickening of the neoprene casing or by assigning a further outer casing and/or changing the ring bracing segments and/or the clamping bolts, the widening taking place in each case towards the load-bearing region of the masonrywork. This makes it possible to allow the introduction of pressure to take place in precisely that location where the masonrywork, by virtue of the corresponding design, is also best suited for this purpose. <IMAGE>

Description

The invention relates to an abutment for attachment of loads and components on facades of buildings, esp special on brick walls, which is inserted into a hole as far as possible to the load-bearing ceiling, with a tubular base body over a floor and has a releasably arranged closure plate between which be a constant volume, made of elastic material standing expansion element is arranged, the floor and Locking plate against each other shifting clamping bolts inserted clamps and can be pressed against the wall of the bore Patent (patent application P 37 05 961.0).

Such abutments are on buildings from the ver various reasons. For example, the needed for the repair of the facade or the windows Scaffolds fastened in this way or balconies or the like. Extensions attached afterwards. From DE-OS 34 27 513.4 is a known such abutment, which is a special task asked to create an abutment, that certainly also can be struck on the load-bearing ceiling if the facade also has an insulating cladding. This creates a corresponding tubular structure on the ceiling screwed, to which then in the load-bearing masonry seated section is fixed using a kind of expansion anchor. Through washers or through the expansion dowel itself it is also possible to consider the different strengths of the Compensate for the insulating layer or to safely pierce it on the outer facade there is always the same end piece to positio kidneys. Especially where large forces are transferred need, it is necessary to use appropriate high strength connector to be used with the blanket, as the rest of the problem camp is supported at best on the masonry. In contrast teaches the older patent application, P 37 05 961.0, a spread use abutments that brace themselves in the masonry or can be braced so that the attachment to the ceiling  no longer particularly important. The real forces can safely move from the abutment directly into the masonry will wear. Ring clamping segments that are used for this purpose Clamping bolts are pressed apart while pressing on from compliant, i.e. existing elastic material Act on expansion element. The expansion element is featured see to that from the individual ring clamping segments incoming forces as evenly as possible into the masonry conduct. This is an effective fixing in the masonry reached, however, by the ring tension segments outgoing forces evenly in all directions into the wall transfer plant. Especially in the area of breakthroughs, Windows, doors, etc. it can cause it to slide out come from individual bricks, so that the effective Determining the abutment is no longer guaranteed.

The invention has for its object, a need agile anchoring forces targeted into the structure or masonry introductory abutment.

A danger particularly in the area of breakthroughs in the masonry no longer occurs because of the credits targeted forces, i.e. be introduced to such areas where an effective holding or bracing of the abutment is guaranteed. This is achieved by using the expansion element is designed as a completely closed neoprene jacket, between the and the base body ring clamping segments with the clamping bolts extending between are arranged, wherein Neoprene jacket and / or ring clamping segments and / or clamping bolts reinforced to the load-bearing areas of the masonry are trained. This makes it possible to apply the forces for example, targeted only up and down into the masonry to introduce, while none or only relatively small forces are transmitted. The masonry remains in its association, even if it is too through the pages or, if necessary, up or down  Breakthroughs, windows, doors, etc. weakened in that direction is. Another advantage is that the closed Neoprene jacket ver a point transmission of forces changes is because even with a two-sided or one-sided Reinforcement of the neoprene jacket underneath the ring clamping segments over a corresponding area transfer moderate pressure.

A particularly simple and advantageous way To transfer the tensioning forces in a targeted manner is the, at which is the neoprene jacket in the area of increased pressure introduction is thickened. By thickening the neoprene jacket the entire area is targeted in those with increased pressure line and such normal or reduced pressure introduction divided.

Another way to get the neoprene coat adapting to each situation is the same as the one moderate wall thickness neoprene coat a second, assign asymmetrically designed outer jacket. this has the advantage that a precisely tailored one on site Arrangement can be created via which the pressure introduction exactly tailored for the respective areas can be. It is also conceivable to have several of these asymmetrically designed outer coats on the neoprene coat wind up and thereby a different tension to reach over the entire circumference of the expansion element.

In order to shift the neoprene jacket in relation to prevent the outer jacket, it is provided that in the Neoprene jacket and the outer jacket correspond to each other Ending grooves and tongues or approaches are formed. It is then more difficult to keep the outer jacket on the To shift inner jacket or on the neoprene jacket, however is also with appropriately trained grooves and tongues this is possible, especially if it is not too deep  be formed.

Another way in each area To initiate different pressures is the wall reinforce the ring clamping segments in the lateral area to specify the specified dimension thinner than in the upper and / or lower area. This allows the upper and lower Area corresponding to higher pressure to be transferred while none or only one in the side areas reduced pressure is transferred to the masonry.

In addition to this, it is provided that the ring span segments only in the area of increased pressure introduction are arranged, so that only here appropriate forwarding of pressure on the neoprene jacket, while the rest Area due to the lack of ring clamping segments no over Pressure is carried, so that no pressure is introduced into the masonry or just a very small one.

In addition, it is possible to use the ring clamping segments radially having an increasing or decreasing wall thickness train in order to target less in the side area Initiate pressure or even more, depending on how the circumstances make this seem appropriate.

A chipping of the plaster or individual stones This can be specifically prevented in the area of the outer wall be that the ring clamping segments and / or the neoprene jacket axially a wall that preferably increases deepest to the borehole are well trained. This will result in the front A smaller area of the borehole or the abutment and transmit a higher pressure downhole, where up and down by appropriate training of ring tension segments or neoprene sheath again the targeted ones Changes can be made. After all it is also conceivable, from deepest down to about the middle with  the wall thickness, then the neoprene coat, for example, fall off or become thinner to let, so that the main application of force approximately in the middle of Neoprene jacket or the borehole. Other variants are conceivable.

A further adjustment of the pressure introduction to the given units is also possible in that the ring clamping segments in the area of increased pressure introduction from high stable, the rest of normal to flexible material are made so that the transmission in the area of high stable materials occurs faster and is higher than in the other areas.

Finally, it is possible to initiate pressure vary by changing the clamping bolt radially in different Distance or alternately arranged individually and in pairs. This also creates zones of different force application created, although a combination with adaptation of the neoprene jacket or the ring clamping segments is more secure.

The invention is characterized in particular by that a versatile abutment is created that is practical everywhere for example also very close to windows or doors can be attached without the risk that because of the enormously high pressures introduced a stone is pushed or the plaster flakes off or other damage occur. Rather, the introduction of pressure can be very targeted take place in the area where the masonry also has the highest Resistances are present and where deformations or other Impairment of the masonry cannot occur. Another advantage is that retrofitting on the construction is possible if it only turns out during installation, that just the proposed abutment needs an adjustment. Here, for example, there is an asymmetrically designed exterior coat slipped on or there will be additional ring tension  elements provided or changed.

Further details and advantages of the invention stand out from the following description of the associated drawing in which a preferred embodiment example with the necessary details and details share is shown. Show it

FIG. 1 the masonry of a house in the neck with an attached balcony,

Fig. Abutment 2 in section with approximately, indicated voltage distribution,

Fig. Abutment 3 in longitudinal section;

Fig. 4 expansion element with attached outer jacket and

Fig. 5 via tongue and groove spreading element and outer jacket.

Fig. 1 shows the detail of a building ( 1 ) assigned facade ( 3 ), to which a balcony ( 5 ) is subsequently attached. The balcony ( 5 ) can be reached via the French door ( 7 ), its base plate ( 8 ) running approximately at the height of the assigned ceiling ( 23 ).

In addition to the base plate ( 8 ), the balcony ( 5 ) consists of side parts ( 9 ) which are fastened to the profile rails ( 10 ) and the front part ( 14 ) assigned to the guardrail ( 12 ).

The profile rails ( 10 ) are fixed to the building ( 1 ) via abutments ( 70 ) which are introduced into corresponding bores ( 69 ).

In the building ( 1 ) shown in FIG. 1, the facade consists of a corresponding masonry, which is indicated in FIG. 2. A bore ( 69 ) is made in this masonry, into which the abutment ( 70 ) can then be inserted and fixed therein. To enable this setting, the abutment consists of a base body ( 71 ) and the slidable bottom ( 72 ) and closure plate ( 73 ). At the front of the closure plate ( 73 ) retaining screws ( 74 ) are provided, which illustrates Fig. 3, so that the intended loads can be attached to the abutment ( 70 ).

Starting from the closure plate ( 73 ) or connected to it is an extension ( 75 ) which is provided with an external thread ( 76 ) which corresponds to the internal thread ( 77 ) on the base body ( 71 ). The base body ( 71 ) is accordingly a tube. The closure plate ( 73 ) can therefore be brought into a corresponding distance from the building ( 1 ) or the outer wall.

The bracing of the abutment ( 70 ) takes place in that the clamping bolts ( 81 , 82 ) fixed in the front clamping ring ( 79 ) and in the bottom ( 72 ) act on slopes ( 83 , 84 ) on ring clamping segments ( 85 , 86 ). These ring clamping segments are pressed outwards and thereby press the expansion element ( 80 ) against the inner wall of the bore ( 69 ). This expansion element ( 80 ) is a completely closed neoprene jacket ( 87 ) which, due to its design, can be pressed evenly against the masonry ( 88 ) or pressed against this masonry ( 88 ).

The bottom ( 72 ) is fixed to the ceiling ( 23 ) by means of the anchor screw ( 89 ) with nut ( 90 ), so that a fixation of the abutment ( 70 ) is ensured or it is ensured that the abutment ( 70 ) is released when it is braced , ie do not pull out of the bore ( 69 ) when tightening the clamping bolts ( 81 , 82 ).

Fig. 2 illustrates that the neoprene jacket ( 87 ) is not all parts or areas of the same thickness. Rather, this results in corresponding thickening differences in the introduction of pressure, which leads to the different stress distribution shown in FIG. 2.

It has already been pointed out above that the bottom ( 72 ) is fixed deepest in the borehole via the anchor screw ( 89 ), so that the predetermined line between the outer wall surface ( 100 ) and the closure plate ( 73 ) is independent of the degree of tensioning of the abutment ( 70 ) is maintained.

To produce different pressure introduction, an outer jacket ( 96 ) is fitted onto the outer surface ( 93 ) of the expansion element ( 80 ) or the neoprene jacket ( 87 ). This can according to FIG. 5 to be effectively chains ver over groove (94) and projection (95) so that rotation of both parts is not possible to today. On the other hand, according to the embodiment according to Fig. 4 depending on the turning of the outer shell (96) on the neoprene sheath (87) of either the lateral portion (97) or as shown here, the upper portion (98) or possibly also the lower portion (98) be specifically the zone of higher pressure introduction.

In the embodiment shown in FIG. 2, the ring clamping segments ( 85 , 86 ) in the upper and lower region ( 98 ) and in the lateral region ( 97 ) are formed differently. The arranged in the lateral area ( 97 ) ring tension segments have a smaller wall thickness, so that accordingly a lower pressure is accordingly introduced in this area. The approximate voltage distribution shown clearly shows this. The corresponding curve is labeled ( 101 ).

Claims (10)

1. abutment for attaching loads and components to facades of buildings, especially on brick walls, which is used in a hole that is preferably brought up to the load-bearing ceiling, with a tubular base body, which has a floor and a detachably arranged closure plate has, between which a constant volume, made of elastic material spreading element is arranged, clamped against the bottom and locking plate against each other ver sliding bolts and pressed against the bore wall, according to patent (patent application P 37 05 961.0), characterized in that the expansion element ( 80 ) is designed as a completely closed neoprene sheath ( 87 ), between the and the base body ( 71 ) ring clamping segments ( 85 , 86 ) with the clamping bolts ( 81 , 82 ) running between them, neoprene sheath ( 87 ) and / or ring clamping segments being arranged ( 85 , 86 ) and / or clamping bolts ( 81 , 82 ) to the load-bearing areas of the wall plants ( 88 ) are increasingly trained. 2. abutment according to claim 1, characterized in that the neoprene jacket ( 87 ) is thickened in the region of increased pressure introduction. 3. abutment according to claim 2, characterized in that the uniform wall thickness neoprene jacket ( 87 ) is assigned a second, asymmetrically formed outer jacket ( 96 ). 4. abutment according to claim 2 and claim 3, characterized in that in the neoprene jacket ( 87 ) and in the outer jacket ( 96 ) mitein other corresponding grooves ( 94 ) and springs or approaches (95) are formed. 5. abutment according to claim 1, characterized in that the wall thickness of the annular clamping segments ( 85 , 86 ) in the lateral area ( 97 ) are thinner by a predetermined amount than in the upper and / or lower area ( 98 ). 6. abutment according to claim 1, characterized in that the ring clamping segments ( 85 , 86 ) are arranged only in the region of increased pressure introduction. 7. abutment according to claim 1, characterized in that the ring clamping segments ( 85 , 86 ) are formed radially having an increasing or decreasing wall thickness. 8. abutment according to claim 1, characterized in that the ring clamping segments ( 85 , 86 ) and / or the neoprene jacket ( 87 ) are formed axially preferably to the deepest hole ( 99 ) to be taken wall thickness. 9. abutment according to claim 1, characterized in that the ring clamping segments ( 85 , 86 ) in the area of increased pressure introduction of highly stable, the rest of normal to flexible material are made. 10. abutment according to claim 1, characterized in that the clamping bolts ( 81 , 82 ) are arranged radially at different distances or alternately individually and in pairs.