DE19632541A1 - Single mast tower building footing e.g. for areal mast - Google Patents

Abstract

The footing includes a concrete bore pile (3) which ends in the region of the edge of the ground with a quiver or holder (1) for receiving the foot of the mast. The holder is made of steel reinforced concrete and has an inner cladding tube (19). The wall of the holder has at least two concentric reinforcement frames or cages. An inner frame or cage (10) is formed by an upper end of the reinforcement cage (4) for the pile (3) having a larger diameter. An outer cage (12) is formed by fastening its elements to the inner cage. The reinforcement is expanded conically in the transition region (8) from the reinforcement cage (4) for the pile to the inner cage (10). In the region of the expansion the reinforcement is surrounded by a number of reinforcement rings (9).

Description

The invention relates to a foundation for single masted Tower structures such as masts for transmission or wind power plants, consisting of an in-situ concrete bored pile with a quiver in the area of the top edge of the site Intake of the mast foot ends, with the quiver out Reinforced concrete exists and inside with a quiver tube is lined.

The invention further relates to a method for Manufacture of a large-size in-situ concrete bored pile with one Quiver in the area of the top edge of the terrain for recording of a mast foot, with a hollow shape for the quiver between a quiver tube and an outer jacket Reinforcing concrete manhole rings and finally above the finished bored pile Concrete is backfilled.

With the pile foundation mentioned at the beginning, which without Bottom plate does not need to be lifted an excavation pit, lowering the groundwater or even the creation of sheet piling. Rather, it allows light them with a single bored pile that over a quiver with a mast clamped in it connected, the realization of such a tower buildings in a simple and quick way. Also the machine effort is relatively low; by means of a piping machine the Bohr pipes deposited; The earth is excavated using a rope excavators and drilling grapples, e.g. B. for pipe diameter of 900, 1,250 or 1,500 mm. Such devices come with  a limited job; You can also can be used very close to existing buildings.

A particular problem with such pile foundations is the connection between that of the anchor serving the actual bored pile and the quiver, in which the mast foot is used. The height of the quiver is the corresponding clamping depth of the mast to choose so that the mast to a certain extent the Continuous continuation of the bored pile that is therefore only subjected to bending. Here all through the mast over the quiver onto the Bored pile forces introduced into the ground carry. Especially the transition area between the Bored pile and the quiver is high bean exposed to stresses, adding to the aggravation comes that the support of the quiver in the surrounding Soil depending on soil conditions and groundwater stand can vary widely.

Accordingly, the present invention lies in the Based on the task of a reliably calculable, sufficiently firm connection of the quiver to the drill to create pile, which the Bedin explained above is enough and still an inexpensive Construction possible.

This task is inventively in a foundation of the type mentioned in that the Wall of the quiver at least two concentric blows tion baskets that an inner basket by a in Flared upper end portion of the  Reinforcement cage is formed for the bored pile and that an outer basket by attaching its elements to Inner basket is formed.

On the procedural side, it is essential that the upper side of the bored pile is pointed before backfilling becomes, after which the cavity mold low to a level fit over the lower edge of the quiver tube with concrete is filled and that the hollow shape only after part wise solidification of the concrete in place is constantly filled with concrete. The reinforcement cage is useful only after its installation in the Drill hole in the area of the hollow shape according to their Diameter expanded.

The two concentric reinforcement cages are advantageously arranged so that the inner basket near the Outside of the quiver tube, the outer basket near the The outer wall of the quiver is positioned. Its outside coat is expediently formed by whole or concrete manhole rings partially lowered into the ground, which is also called "well rings" are known and for example a nominal size of 2,500 mm have. With a quiver tube of 1,500 mm nominal width this results in a quiver wall thickness of 500 mm with a height of the quiver tube of approx.2,500 mm. The numbers mentioned refer to a specific one Example of a foundation plan for a mobile radio pylons at a total depth of the pile foundation including quiver of 11 m.  

An essential embodiment of the invention exists in that the reinforcement in the transition area from Reinforcement cage for the bored pile to the inner cage is funnel-shaped and in the area of this Expansion by a plurality of reinforcement rings is included. Both expanding and that The reinforcement rings are attached after the on bring the pile reinforcement into the borehole and its Filling with concrete while pulling the Piping. After completing the inner basket the outer basket, the Elements essentially best from individual temples hen, which individually in the cavity for the quiver be installed, so that they are each in radial planes arranged through the quiver axis are.

It is advantageous that the bracket of the outer basket are designed as a U-bracket, each with their open end facing down with its inner Legs are hooked into the inner basket and their Leg length corresponds approximately to the height of the quiver. In this way, the bracket can be easily removed from the Top edge of the terrain to be installed. In addition they can still further increase the strength be surrounded by spiral reinforcement, d. H. the Spiral reinforcement is on the radially outer bracket thighs, wrapping them helically, attached. Such spiral reinforcement is useful moderately also on the outer circumference of the inner basket see.  

The quiver tube, which is usually made of steel exists, but alternatively also as a plastic part, e.g. B. made of GRP-reinforced plastic can be either cylindrical or the shape of a pot, the bottom of which has holes or Vent valves for venting during filling lens of the quiver shape is provided with concrete. It will advantageous after completion of the inner basket the inner circumference fixed.

With a wall thickness of the quiver of, for example, 500 mm can use the U-bracket for the outer basket with a Distance between legs of about 300 mm so that the radial distance between the inner and outer basket is almost 2/3 of the wall thickness of the quiver.

Depending on the installation situation, the quiver can be approximately flush end with the top of the terrain; but he can also end clearly above the edge of the terrain, e.g. B. at high groundwater level, which is the lowered one Making the quiver would complicate.

In the following an embodiment of the Invention explained with reference to the drawing. It shows

Fig. 1 shows a longitudinal section through the bored pile,

Fig. 2 shows a cross section through the bored pile at the level of the quiver, according to II-II of Fig. 1 and

Fig. 3 shows a cross section through the bored pile under half of the holder, according to III-III in FIG. 1.

A foundation for a single-masted structure, e.g. B. a transmission mast includes a quiver 1 with an opening 2 , in which the mast base of the transmission mast, not shown, is used. The quiver 1 made of reinforced concrete is connected monolithically to a concrete bored pile 3 . In the drawing, for the sake of a better overview, the concrete filling has been omitted. Instead, you can see the reinforcements to be attached within the outline of the quiver 1 on the one hand and the bored pile 3 on the other hand. The reinforcement cage 4 of the bored pile 3 has numerous longitudinal bars distributed over its circumference - with a pile diameter of 1,500 mm, for example, 46 longitudinal bars 22, for example, with a 25 mm diameter, which are connected at 2 m intervals by means of mounting rings 5 to form a cylindrical grid. Spiral irons 6 are wound around the grid over the entire height of the bored pile, e.g. B. with a distance of 80 mm with a wire thickness of 12 mm. At the lower end, all longitudinal iron 22 are welded to a flat iron mounting ring 7 .

After the Bochloch is sunk and provided with a pipe, the reinforcement cage 4 for the bored pile 3 is retracted. Then the pipe is pulled in the course of filling with concrete and only afterwards the reinforcement cage 4 is expanded in the area of the quiver 1 . To simplify this activity, the corresponding end section of the reinforcement cage 4 has neither mounting rings nor spiral reinforcement, so that the corresponding ends of the longitudinal bars can be bent with little effort using a special tool. After bending, they run in the transition region 8 between the upper end of the bored pile 3 and the lower region of the quiver 1 approximately in a funnel shape until the diameter D1 of an inner basket 10 of the quiver reinforcement is reached, then again axially parallel to the upper end of the inner basket 10 . On the outside of the funnel-shaped section, a plurality of reinforcement rings 9 are provided for absorbing tensile loads. The inner basket 10 of the quiver reinforcement is wrapped with a spiral reinforcement 11 in order to fix the diameter D1 of the inner basket 10 . Within the hollow shape for the quiver 1 , in addition to the inner basket 10 , a concentric outer basket 12 is also provided for this. The outer basket 12 is formed by the outer legs 13 U-shaped iron bracket 14 , the inner legs 15 are interwoven with the inner basket 10 . A spiral reinforcement 16 is also wound around the outer legs 13 of the iron bracket 14 , which secures the diameter D2 of the outer basket.

The diameter D1 of the inner basket 10 is selected such that the inner basket 10 is only slightly larger than a quiver tube 19 which limits the hollow shape of the quiver 1 towards the inside. The diameter D2 of the outer basket 12 is chosen so that it is only slightly smaller than the inner diameter of concrete manhole rings 18 , which limit the hollow shape of the quiver 1 to the outside.

The quiver tube 19 is shown in section, that is, it has no bottom, which, however, could be useful to create a defined support surface for the mast base. Such a floor would, however, have air holes or would have to be provided with ventilation valves to ensure that the concrete filling underneath reached the entire floor area from below.

The filling with concrete takes place in such a way that the bored pile is first filled up to a first level N1 immediately before the transition area 8 in the quiver 1 . Then the top 20 of the concrete pile, which determines the level N1, is sharpened to improve the concrete binding and the so-called cranking of the reinforcing bars to the diameter D1 and the introduction of the quiver reinforcement follows. Then the filling continues until the level N2 is reached directly above the transition area 8 inside the quiver 1 . Now wait until the concrete has partially hardened to level N2; after this "ramming" of the concrete, the cavity for the quiver is filled up to the formation of an inclined upper edge 21 of the quiver 1 .

Fig. 2 shows the cross-sectional shape of the quiver 1 with an outer jacket made of concrete manhole rings 18 and the quiver tube 19 , which each form a firm connection with the concrete filling. The two reinforcement baskets inside the quiver 1 are shown in simplified form, namely only by drawing the longitudinal iron 22 of the inner basket 10 and the outer legs 13 of the iron bracket 14 of the outer basket 12 .

The section shown in FIG. 3 through the bored pile 3 makes it clear that its outer casing is interlocked with the surrounding earth. A basket in reinforcement 4, only the longitudinal rods 22 are shown for simplicity.

In a schematic representation, the pile foundation according to FIGS. 1 to 3 is produced according to the following method steps:

• a) Excavation and lowering of concrete manhole rings 18 , which limit the outer circumference of the quiver 1 ,
• b) Setting up the hydraulic piping machine and the associated hydraulic excavator for bet the piping machine,
• c) Drilling the cased pile bore using Duty cycle crawler crane,
• d) inserting the reinforcement cage 4 into the borehole,
• e) filling the borehole with concrete to the lower edge of the concrete manhole rings 18 ,
• f) sharpening the top 20 of the concrete pile 3 ,
• g) cranking the upper ends of the longitudinal iron 22 of the reinforcement cage 4 in accordance with the funnel-shaped transition region 8 and the expansion region in the quiver hollow shape until the diameter D1 of the inner cage 10 is reached ,
• h) fastening the reinforcement rings 9 in the transition area 8 ,
• i) inserting the outer basket 12 into the quiver cavity,
• k) sinking the quiver tube 19 and its fastening supply on the inside of the inner basket 10 , z. B. by welding,
• l) Filling the quiver cavity with concrete up to Reaching level N2 and letting the Concrete,
• m) completely filling the quiver cavity with concrete,
• n) Insert the mast foot into the opening 2 of the quiver 1 so that the mast sits on the concrete floor at level N2.

Claims (11)

1.Foundation for single-mast tower structures such as masts for transmitters or wind turbines, consisting of an in-situ concrete bored pile ( 3 ) which ends in the area of the top edge of the site with a quiver ( 1 ) for receiving the mast base, the quiver ( 1 ) being made of reinforced concrete and lined inside with a quiver tube ( 19 ), characterized in that the wall of the quiver ( 1 ) comprises at least two concentric reinforcement cages, that an inner cage ( 10 ) through an enlarged end section of the reinforcement cage ( 4 ) for the bored pile ( 3 ) and that an outer basket ( 12 ) is formed by attaching its elements to the inner basket ( 10 ). 2. Foundation according to claim 1, characterized in that the reinforcement in the transition region ( 8 ) from the reinforcement cage ( 4 ) for the bored pile to the inner cage ( 10 ) is expanded in a funnel shape and is in the area of this expansion by a plurality of reinforcement rings ( 9 ) . 3. Foundation according to claim 1, characterized in that the inner basket ( 10 ) on its outer circumference is comprised of a spiral reinforcement ( 11 ). 4. Foundation according to claim 1, characterized in that the elements of the outer basket ( 12 ) consist essentially of individual brackets ( 14 ) which are each arranged in radial planes through the quiver axis. 5. Foundation according to claim 4, characterized in that the brackets ( 14 ) of the outer basket are designed as U-brackets, each with its open end facing down with its inner leg ( 15 ) in the inner basket ( 10 ) are hooked and whose leg length corresponds approximately to the height of the quiver ( 1 ). 6. Foundation according to claim 4, characterized in that the bracket ( 14 ) of the outer basket ( 12 ) from the outside by a spiral reinforcement ( 16 ) are included. 7. Foundation according to claim 1, characterized in that the quiver tube ( 19 ) has a bottom which is provided with holes and / or vent valves for venting during the filling of the quiver shape with concrete. 8. Foundation according to claim 1, characterized in that the radial distance between the inner ( 10 ) and outer basket ( 12 ) is a maximum of 2/3 of the wall thickness of the quiver ( 1 ). 9. Foundation according to claim 1, characterized in that the outer jacket of the quiver is formed by wholly or partially in the ground abge lowered concrete manhole rings ( 18 ). 10. A method for producing a large-size in-situ concrete bored pile with a quiver ( 1 ) in the area of the top edge of the terrain for receiving a mast foot, wherein a hollow form for the quiver ( 1 ) rings between a quiver tube and an outer jacket made of concrete shaft ( 18 ) and is provided with reinforcement and finally, above the finished bored pile ( 3 ) is filled with concrete, characterized in that the upper side ( 20 ) of the bored pile ( 3 ) is pointed before the filling, after which the hollow form up to a level (N2) slightly above the lower edge of the quiver tube ( 19 ) is filled with concrete and that the hollow form is only completely filled with concrete after the concrete has partially solidified. 11. The method according to claim 10, characterized in that the reinforcement cage ( 4 ) of the bored pile ( 3 ) is expanded in the region of the hollow shape according to its diameter.