DE3941641C1 - Drive unit for foundation I beams - has ground drills within beams, retrieved after beams are properly installed - Google Patents

Abstract

Driving foundation I beams involves drills working alongside the beam. In the case of an I beam, augers (9,9a) should be arranged in the symmetrical beam hollows (8) as divided by the centre web and retrieved once the beam has been driven to depth, the augers pref. preceding the beam and beam and augers together joined forcibly for positive movement to a guide sled. USE/ADVANTAGE - Building foundations. Auger drills both sides of beam web displace ground in overlapping region ahead of easily driven beam in continuous operation.

Description

The invention relates to a method for driving in Supporting elements in the floor according to the preamble of Claim 1.

In basic construction, it is often necessary to support elements from to drive into the ground from the surface of the site. A essential area is the driving in of rolled profiles open double symmetrical cross section, in particular Double-T beams, such as those used for Building pit securing in the so-called "Berlin shoring" be used. Thereby, after driving in Beam in the course of removing the floor from the assembly between two beams installed planks, which in the Cavities between the web and the flanges of the beams be performed. The same applies to the so-called "Essener Shoring ", in which the support elements consist of two by webs interconnected U-profiles exist.

There are various ways of introducing such support elements Opportunities. The most economical option is in Just ram in the support elements. Due to the Noise nuisance and the shocks will this Application method used less and less. Another economic possibility is the support elements shake into the ground if this is due to the construction of the ground is possible. This is done using Vibrating devices under the simultaneous influence of Aixal powers. The shaking of the support elements is however often prohibited because the vibrations are caused by the Propagate soil and affect neighboring buildings must be feared.

Another option is to drill in the support elements. First, a hole is made that  mostly due to construction reasons. in the The groundwater area must work with excess water pressure will. Then the support element is in the borehole set and filled this. This will happen later Clamping area of the support element, if necessary Lean concrete, in the rest of the area while pulling the Drill pipes with sand. This way of bringing in Supporting elements is very complex; also must be very careful be worked.

A combination of these two is also known Method, initially up to the clamping range of the Support element drilled, then the support element in the Borehole set and to the required depth is shaken. Due to the lack of skin friction in the area of the borehole can make good progress when shaking achieve; in the lower area is the introduction of Vibrations in the lower soil layers are usually less critical with regard to damage to neighboring buildings. Nevertheless, this combined procedure is also time and cost consuming.

For driving sheet piles and piles into the ground it has already become known in neighboring sheet piles Arrange driving tools working in driving direction. So is it is known from DE-OS 23 12 032, near the To create a cavity by drilling, the volume of which is sufficient to accommodate the Sheet piles at least partially displaced space to accomplish. Drilling takes place in stages and driven, the drilling process each Driving operation precedes.

This known method has the disadvantage that batches must be worked. First, the Drilling tools drilled from the ground, but after that the  Drilling tool to be withdrawn accordingly to expose large cavity. Another disadvantage is but in the fact that the following driving in the Sheet pile displaced soil must be brought to the Fill in the cavity. This sets the ground in motion and transversely to the direction of driving ahead Loosening symptoms lead and the safe Anchoring the relevant support element in the ground can affect.

Against this background, the object of the invention based on creating a way to support elements with open, double-symmetrical cross-section, such as. B. Double-T beams, fast, safe and economical to be able to drive into the ground without vibrations.

According to the invention this object is achieved by the characterizing part of claim 1 specified Features solved.

Advantageous further developments result from the Subclaims.

The invention is based on the knowledge that driving in of support elements with double T or similar cross-section can be decidedly relieved if that Soil structure only in the immediate area of the corresponding profile of displaced soil is destroyed. Zones destroyed soil structure occurs, for example, when Screwing augers into the ground in the immediate vicinity Circumferential area of the augers. If two augers are arranged close to each other, overlap between these the fault zones. This phenomenon will exploited according to the invention in this Overlapping area under the web of a double-T beam Soil displacement in a continuous process  vibration-free and using comparatively lower forces. It should however, the augers to the support element run ahead. Since the augers without removing soil again be unscrewed as soon as the supporting element reaches its target depth has achieved soil extraction with formation of a Cavity does not take place, is the fault zone in the ground the surrounding soil is not extremely small impaired. Of course, this is particularly advantageous then when the supporting elements for a construction pit enclosure be used; this is done by the augers loosened soil in the cavities between the bridge and Flanges of a double-T beam dug up later anyway.

Depending on the nature of the soil, many are sufficient Cases that occur when the augers are screwed into the The resulting feed force from a to the Augers connected by force and movement Drive the support element into the ground. According to the invention it is therefore easily possible to add additional ones To exert axial forces on the support element, for example by load, even the steps of loosening the soil and Separate driving-in of the support element from one another, d. H. the support element in the course of screwing in Augers, but without force and movement Connection with these by separately applied Drive in axial forces.

The invention will now be described with reference to the drawing explained. It shows

Fig. 1 in side view of the introduction of a double T-beam with the aid of a Broker's fixed to an excavator,

Fig. 2 is a front view of FIG. 1,

Fig. 3 shows a cross section along the line III-III in Fig. 2 and

Fig. 4 shows the lower region of the auger and the support element in a larger scale,

Fig. 5 is a Fig. 1 corresponding further embodiment in side view and

Fig. 6 in front view.

In Fig. 1, an excavator 1 is shown in side view, which carries a leader 3 on a boom 2 . On the leader 3 , a guide carriage 5 is guided in a height-adjustable manner via a cable 4 . The guide carriage 5 runs along the leader 3 in a guide 6 . Is located on the guide carriage 5, a clamping device 7 for fixing the support element to recover afterwards. 8 At the same time, two augers 9 with the associated drilling motors 10 are mounted parallel to one another and close to one another on the guide carriage 5 ( FIG. 2).

As shown particularly in FIGS. 3 and 4 show, there is a support element 8 from a so-called Peiner-beams, that is a special case of a double-T-carrier from a web 8 'and two flanges 8''. The arrangement is such that the two augers 9 are arranged in the cavities formed from the web 8 ' and the flanges 8'' and their dimensions with respect to the support element 8 are selected so that they essentially fill the cavities.

Fig. 4 shows the lower region of the auger 9 and of the supporting element 8. The augers 9 are provided at their tips with cutting edges 11 which serve to loosen the soil along the helical coils 12 . Each auger 9 has a continuous axial channel 14 in its core 13 . The axial channel 14 is provided at the lower tip with outlet openings, which are symbolized in Fig. 4 only by arrows 14 ' for a material emerging from these openings.

In the situation shown in FIGS. 1 and 2, a nonpositive and non-positive connection between the support element 8 to be driven and the augers 9 is effected via the guide carriage 5 , to which the support element 8 is fastened by clamping. The attachment can also be designed so that differences in length between the augers 9 and the support element 8 to be driven can be bridged without having to lengthen or shorten the screw 9 .

If the two augers 9 are now set in rotating motion by means of the drilling motors 10 , they are screwed into the ground in the manner of a corkscrew. This creates a certain loosening zone along the immediate circumference of the two augers 9 , but especially in the area between the two augers, in which the cross section of the support element 8 to be driven is largely located. Since the augers are guided ahead of the support element ( FIG. 4), this penetrates into the ground without vibration and displacing the ground as the screws are screwed into the ground. The weight of the guide carriage, with which the support element 8 is non-positively connected, acts as a load.

If the two augers 9 have the same direction of rotation, the bottom between the augers is moved in opposite directions; this leads to an easier penetration of the support element 8 , but also to a torsional stress on the leader 3 used for penetration. If the augers 9 have the opposite direction of rotation, the bottom between the augers 9 moves in one direction; the leader 3 is only slightly stressed.

Basically, there are three variants of this procedure driving in support elements conceivable in Depending on the pending soil types selected can be. In a sense, this is the normal case Drilling a support element to the final depth and that Unscrew the screws in the opposite direction. In in the same way it is possible to have a support element on this Way only to drive in until the start of the clamping area, then unscrew the augers and finally to shake or to support the support element on final level ram.

As indicated in Fig. 4, a liquid can be pumped during drilling through the axial channels 14 of the augers 9 , such as. B. water, which serves to facilitate drilling by a flushing process. By this axial channel 14 during the unscrewing of the augers 9 can also be a support liquid, such. B. a bentonite suspension are introduced, the z. B. in the groundwater area supports the walls of the cavity left by the augers. A polymer suspension, sealing wall compound or cement suspension and materials which are suitable for solidifying the soil can also serve a similar purpose.

In FIGS. 5 and 6, another embodiment of the invention is illustrated. Here, a non-positive and non-positive connection of the supporting element 8 to be driven in with the augers 9 a is dispensed with. The guide carriage 15 suspended from the leader 3 via a cable 4 carries only the drilling motors 10 for the augers 9 a. To hold the support element 8 , a clamping head 17 is provided here, which, like the guide carriage 15, is likewise guided in a longitudinally movable manner on the leader 3 and is equipped with a clamping device 18 . The clamping head 17 can be adjusted and adjusted in height via a cylinder-piston unit 19 . The cylinder-piston unit 19 is attached to the leader 3 by means of a bracket 20 .

By means of this device, the support element 8 can also be driven into the ground without a direct connection to the augers 9 a, the driving force, if the dead weight is not sufficient, can be increased by the cylinder-piston unit 19 .

. In which in Figures 5 and 6 illustrated embodiment, the two augers are 9 a provided only over a lower portion with a drill helix 12; the upper region of the augers 9 a represents the core 13 , which serves to transmit the torque and is designed as a tube in order to be able to bring liquids to the drill tip.

Claims (6)

1. A method for driving support elements into the ground with the aid of drilling tools that work adjacent to each support element to be driven in the driving direction, characterized in that with a support element ( 8 ) with an open, double-symmetrical cross section, such as. B. a double-T beam, in the two symmetrically opposite, through the web ( 8 ' ) of the support element ( 8 ) separate cavities of the cross section, a auger ( 9, 9 a) is arranged that the support element ( 8th ) in the course of screwing in the augers ( 9, 9 a) is driven into the ground, and that after the support element ( 8 ) has been completely driven in, the augers ( 9, 9 a) are rotated out of the ground again. 2. The method according to claim 1, characterized in that the augers ( 9, 9 a) of the supporting element to be driven ( 8 ) are guided ahead. 3. The method according to claim 1 or 2, characterized in that the supporting element ( 8 ) and the augers ( 9 ) is non-positively and non-positively connected to the guide carriage ( 5 ). 4. The method according to any one of claims 1 to 3, characterized in that supporting axially forces are exerted on the support element ( 8 ) and / or on the augers ( 9, 9 a). 5. The method according to any one of claims 1 to 4, characterized in that during the screwing in of the augers ( 9, 9 a) through an in their soul ( 13 ) and opening at the tip axial channel ( 14 ) liquid, for. B. water, bentonite suspension or the like. Is introduced into the soil. 6. The method according to any one of claims 1 to 5, characterized in that during the unscrewing of the augers ( 9, 9 a) by an axial channel ( 14 ) extending in the core ( 13 ) and opening at the tip thereof, hardening and / or the bottom supporting and / or solidifying material, e.g. B. bentonite or cement suspension, sealing wall mass or the like. Is pressed into the ground.