HU181325B - Pile screwable into soil - Google Patents

Description

The present invention further provides a load bearing material for frictional loading of loads of pile structures that can be screwed into the soil by the friction of the sheath resulting from friction due to the peak resistance formed along the pile tip and / or contact between the pile peripheral surface and the soil portions. The pile has a pile head capable of providing a force transfer connection with the structure and a single or multiple spiral ribs along the peripheral surface of the pile body. The piling of the pile into the soil 10 is accomplished by the displacement of the pile by screwing it into a pre-drilled hole of a thickness less than the pile.

The loads of the structures are transmitted to the load-bearing soil by the underlays. When the load-bearing soil layer is located near the surface, the so-called soil layer. flat foundations when deeper, they use deep foundations. They also classify foundation methods according to whether the load transfer occurs along highly exposed surfaces or otherwise locally. The latter group includes pile foundations.

The piles load their loads partly at the end farthest from the soil surface, the so-called. By means of a "peak resistor", 25 partially along their peripheral surface It is handed over by means of a 'mantle friction'. Pile bases themselves can belong to two main families. One of these is the pile raised by the soil and the other by the displacement process which is deepened by drilling, rinsing or other special means.

In the displacement method, delivery to the desired depth is generally accomplished by beating, pressing, vibrating, or a combination thereof. A classic and reliable method is to lower the piles with some kind of beating equipment. The disadvantages of this method are noise pollution, dynamic effects in the environment and generally large space requirements.

Solutions for the further development of displacement piles have been achieved by making piles in the hole produced by the displacement method by concreting on site. Preference is given to prefabricated piles, which are more favorable in terms of durability and corrosion resistance, but have a higher weight, are more costly to produce and difficult to retrieve.

In order to combine the advantages of the various pile foundations, the prefabricated pile type described in U.S. Patent No. 4,027,491 has been developed. In this case, the pile has a straight circular cylindrical circumferential surface with helical ribs thereon, along which the pile can be deepened into the soil, such as by a screw thread.

Before dropping, a hole with a slightly smaller diameter than the pile must be made and the pre-drilled hole is screwed into the threaded pile. Such a pile on the spiral rib

-1181325 has a much larger surface contact with the ground than a conventional smooth-surface pile and is therefore capable of transmitting much greater forces along its circumferential surface.

It also has the advantage that it does not endanger the environment with dynamic effects and noise, since it is deepened by twisting rather than beating. Advantageously, unlike piled piles, its surface is provided with a corrosion-resistant coating which is not damaged by the gentleness of the fold. The pile that can be rolled into the ground can also be recovered and reused as a full pile.

However, a threaded pile with a cylindrical peripheral surface as described in the US specification also has a handicap resulting from the cylindrical shape of the peripheral surface. These include the fact that threaded ribs can only prevent the so-called pile-up to a certain extent. But cannot completely eliminate it.

Flat pile piles are well known for being able to slip into the soil at an angle, thus rendering them unsuitable for transmission of force along their circumferential surface. This phenomenon can also occur with threaded cylindrical piles. The spacing of the ribs is clogged, and thus a ruptured surface may be formed along the pile, which is increased with the profile height but has a more or less uniform diameter, which retards the pile from breaking but cannot completely prevent it. It is also a disadvantage that, due to its constant external diameter, such a pile cannot be tensioned into the ground, i.e. it does not become self-sealing in a way that prevents further twisting. It can also be said that the degree of screwing of such a pile is a matter of determination, since it is not the soil, which indicates' the degree of screwing it requires.

The object of the present invention is to provide a pile-in-the-ground pile which eliminates the disadvantages of the most advanced piles so far, i.e. with screw thread, and provides a foundation that allows for maximum adaptation to the soil, including increased shear strength. said tension and self-closing. A further object of the present invention is to provide a foundation method which is suitable for replacing flat foundations with cheaper and more productive pile foundations for lower depth foundations. SUMMARY OF THE INVENTION It is an object of the present invention to provide a foundation that allows the foundation to be recycled and reused in temporary structures so that, while retaining the advantages of threaded piles, they can be folded down and retrieved with little space in height and piles can be productively produced with factory pre-fabrication.

The inventive idea is based on the realization that, while exploiting the advantages of the most advanced pile so far, their disadvantages can be eliminated by forming the threaded rib on a downwardly slimming peripheral surface. Such a pile acts as a wedge during the lowering of the pile, at a minimum revolution, and the wedge effect results in a significant increase in the friction of the jacket, while also automatically tensioning the pile 2 into the ground.

In accordance with the object of the present invention, the load of the pile structures which can be screwed into the soil according to the present invention is improved by has a pile head suitable for connection, and a single or multiple spiral ribs along the perimeter of the pile body, and incorporating the pile into the ground, e.g. it is formed by screwing into a pre-drilled hole with a thickness smaller than the pile - it is formed in such a way that the peripheral surface of the pile body from the soil surface to the top of the pile has a decreasing and, where appropriate, a threaded projection, which may be retracted under the pile, is connected to the pile tip, if necessary.

A further feature of the pivotable pile may be that at least one filling tube extending from the pile head to the pile tip is capable of introducing post-solidifying material inside the pile body into the area of the pile tip and thereby providing a peak plug that increases resistance.

The threaded projection has a hollow stem inserted into the pile body filling tube, a helical leaf providing threading along the peripheral surface of the hollow stem, and a sealing insert at the end of the hollow stem. The hollow shaft of the threaded projection is provided with a perforation for delivering a curing material to the area of the pile tip and thereby forming the foot plug.

The end cap of the threaded projection has a connection opening for receiving the end of a transfer tool for further twisting the threaded projection after the pile has stopped. The end of the conveying tool opposite to the rotatable pin, which is operable from the surface of the ground, is a screwdriver-shaped flat part fitting into the connection opening of the threaded projection.

The pile body has a more moderate or faster cross-sectional reduction that is adapted to the physical characteristics of the soil, and the tapered thread along the circumferential surface also has a pitch and a pitch corresponding to the physical characteristics of the pole. The pile head with a part connected to the structure, e.g. with a bracket to be concreted into it and a coupling part for transmitting the torque for mounting the pile, e.g. with rotary opening.

The main advantage of the pile-wrapped pile according to the invention is that it is adapted to the soil conditions due to its conical circumferential surface. On the one hand, this is achieved by infinitely screwing it into the soil, so the resistance exerted by the soil reflects the extent to which it can absorb the penetrating pile. On the other hand, the pile adjusts to

-2181325 so that, if no tensioning occurs, the pile can be removed from the ground and replaced with another pile of more appropriate size, pitch and optionally thread profile. The benefits of threading on the tapered circumferential surface are also due to the fact that during piling, the pile continuously compresses its surroundings, thereby compressing it into a smaller gap volume (higher density) and ultimately making it more solid.

The invention will now be described in more detail with reference to an exemplary embodiment. The attached drawing shows

Figure 1 is a side view of the pile, a

Fig. 2 is a threaded extension of the pile, a

Fig. 3 shows a transfer tool for this purpose.

Fig. 1 shows a pile body 2 which can be placed in the soil 1 with a pile head 2a above the ground surface la and a circumferential surface 2b having a conical thread 3. The pile head 2a is provided with a bracket 8, by means of which a power transmission connection with the structure can be realized, and a rotary opening 9, by means of which a suitable torque for folding can be applied to the pile body 2.

The peripheral surface 2b of the pile body 2b is continuously leaning from the pillar head 2a to the pile top 2c. In the present example, the cone angle of the peripheral surface 2b, in other words the degree of slimming, is constant. In principle, there is no obstacle for the cone angle to change along the peripheral surface 2b.

Inside the pile body 2, the filling tube 4 is preferably coaxial with which a post-solidifying material, e.g. the cement mortar can be placed under the pile top 2c, thereby converting the ground curb to the bottom plug 5 shown in Fig. 2 near the pile top 2c. Thereby, it is possible to greatly increase the peak resistance of the pile body 2.

More particularly, this purpose is provided by providing the pole body 2 with the threaded projection 6 shown in Figs. The stem 6a of the threaded projection 6 has a perforation 6b to allow post-curing material to enter the soil environment.

The spiral leaf 6c serves to fold the 6-threaded projection, which forms the thread of the 6-threaded projection. After the pile body 2 has been lowered, the conveying tool 7 shown in Fig. 3 is used to further screw down the threaded projection 6, the shaft 7a of which passes through the filling tube 4 and has a rotating lever 7b for applying torque.

The end 7c of the shank 7a opposite the pivoting arm 7b is formed so as to penetrate into the connection opening 6e formed on the end cap 6d of the shank 6a of the threaded projection 6 so that the torque required to retighten the threaded projection 6 is released explained. This tool end 7c is temporarily engaged with the connection opening 6e as the screwdriver edge fits into the notch of the screw head to be inserted or unscrewed.

As regards the design of the tapered thread 3 on the circumferential surface 2b of the pile body 2, it must be adapted to the physical characteristics of the soil. In our experience, it is expedient to use a low draft profile and a small pitch that is capable of transmitting a large amount of force within the pile length to the soil. On loose soils, on the other hand, it is advisable to use a high draft profile and a high pitch. It also has to adapt to the conicity of the peripheral surface 2b to the nature of the soil. Thus, for loose soils with a small taper angle and for hard soils with a large taper angle, it is expedient to form the pile body 2.

Fig. 2 shows some auxiliaries which are provided for the conveyance of the post-curing material 11 forming the sole plug 5. These include a funnel or vessel, which may be capable of delivering post-solidifying material from a line 12 from a remote mixing point to the filling tube 4. The funnel or container 10 may optionally be provided with a closing device 13.

The foundation of the piles according to the invention can be used well in cases requiring a standard pile foundation (eg with frame, skeleton or tower structures) for relatively small loads. Using "short piles" for transfer to the ground.

The pile according to the invention can be used for the foundation of single and multi-storey structures and civil engineering structures, even in the presence of groundwater. It can also be used as a temporary foundation or anchor as it can be removed from the ground and reused using a thread.

Claims (7)

Patent claims: 1. The transverse contact surface of the pile structure, which is capable of being relied upon to support the load bearing substrate by means of a point resilient and / or the pile body has one or more spiral ribs along its circumferential surface, and the pile is embedded in the ground, e.g. in a pre-drilled hole of a thickness less than the pile, by means of a displacement by screwing, characterized in that the peripheral surface (2b) of the pile body (2) the ribs being formed are formed by a tapered thread (3) adapted to the characteristics of the soil (1); An embodiment of the pile according to claim 1, characterized in that the post-solidifying material inside the pile body (2) is surrounded by a pile tip (2c). At least one filler tube (4) extending from the pile head (2a) to the pile tip (2c) is provided for introducing into the shaft and thus forming a peak plug (5) increasing the peak resistance. Embodiment 5 according to claim 1 or 2, characterized in that the threaded projection (6) with a hollow shaft (6a) inserted into the filling tube (4) of the pole body (2) extends along the peripheral surface of the hollow shaft (6a). having a screw leaf (6c) for threading the threaded projection (6) and a sealing insert (6d) at the end of the hollow shaft 10 (6a). An embodiment of a pile according to claim 3, characterized in that the hollow shaft (6a) of the projection (6) is provided with a perforation (6b) for introducing post-solidifying material into the area of the pile tip (2c) and thereby forming the foot plug 15 (5). provided. An embodiment of a pile according to claim 3, characterized in that the connection opening for receiving the end (7c) of the conveying tool (7) for retracting the extension (6) after the pile has stopped is located on the end plate (6d) of the threaded projection (6). (6e) is. An embodiment of a pile according to claim 5, characterized in that the end (7c) of the conveying tool (7) opposite the rotary arm (7b) operable from the ground surface (1a) is screw-like in the connection opening (6) of the threaded projection (6). 6e) is formed as a flat profile. 7. An embodiment of a pile according to any one of claims 1 to 3, characterized in that the pile head (2a) has a part connected to the structure, e.g. with a bracket (8) which can be concreted into it and a coupling part for transmitting the torque for mounting the pile, e.g. has a rotary opening (9).