NL1005236C2 - Installation for the removal of driven objects. - Google Patents

Description

Installation for the removal of driven objects

The invention relates to an installation for removing a slender object driven into the ground, such as a pipe, pile or sheet pile wall, from that bottom, which installation comprises a striking device with a striking weight, driving means for moving the striking weight, striking means impact surface facing the slender object for receiving impacts from the impact weight set in motion by the drive means, as well as a tensile structure by means of which the impact means may be connected to the slender object.

Such an installation is known from EP-A-692578. In this installation, the pulling means can be designed as cables or tie rods, which are attached at one end to a post, and at the other end to the impact means. Although the principle of this known device is attractive, in practice the design with pull cables could entail problems. The pulling cables are subjected to high dynamic loads, on which the connections to the pile and the impact means must be designed.

20 On the other hand, the use of pull cables is favorable for the effectiveness of the installation. That beneficial effect must be attributed to the long duration of the pull stroke, which is much greater than 5 milliseconds. If the tensile force entering the pile, generated by the impact weight, is greater than half of the total shaft friction before the start of the pulling out of the pile, the shaft friction appears to be excessively reduced for each soil layer by the residual impulse increasing after each pile driving impact. and duration of the residual impulse, making the removal of the pile much faster than expected.

The object of the invention is therefore to provide an installation of the above-mentioned type, which can be equipped with cables in a simple and reliable manner. That object is achieved in that the tensile structure comprises loop-shaped cable means (grommets) which cooperate with the impact means at one end and which can be brought into contact with the slender object at their other end.

Thanks to the loop-shaped design of the cable means, the connection with the impact means and the object can be carried out in such a way that, on the one hand, the above-mentioned favorable effects on the operation of the installation are obtained, and on the other hand, a reliable and uniform force transmission, also with the high dynamic loads, is assured. The loop shape allows the cable means to adjust to the connections to the impact means and the object, such that uneven loads can be avoided.

The cable means may comprise two steel cables, each of which is formed into a cable loop consisting of two straight, substantially parallel parts and two bent parts, which extend over a bend 10 of essentially 180 degrees. The ends of each steel cable can be connected to one another by means of one or more clamping sleeves.

In order to ensure the desired, uniform force transfer, a cable lug can be incorporated in each of the bent parts, which surrounds the cable 15 closely. The cable lugs allow the loop to adjust to load both parts equally. In addition, the cable lugs provide lateral support to the curved cable parts, so that the cable cannot be pulled flat under the high impact loads.

Preferably, each cable lug has a substantially U-shaped outer circumference, and the bent portions of a cable loop are held captive by means of locking means, such as pins or bolts extending between both legs of the U-shaped outer circumference. Particularly with thicker cables, which try to move back to a less curved shape, it can thus be ensured that the cooperation with the cable shoes is maintained.

Each cable loop can have an impact shoe, which has an essentially flat impact surface on its side remote from the U-shaped outer circumference. The bottom of the U-shaped outer circumference of each impact shoe essentially coincides with a portion of an imaginary circle, while the impact surface of the impact shoe is between the center of that imaginary circle and the bottom of the outer circumference. Such an embodiment offers the advantage that the impact shoe remains in stable interaction with the steel cable, even under the high loads 35 which could otherwise lead to a tilting movement relative to the steel cable.

In that connection, the distance from the impact surface to the bottom of the U-shaped outer circumference, measured perpendicular to the impact surface, is preferably less than or equal to the radius of that imaginary circle. In particular, the distance from the impact surface to the bottom of the U-shaped cross-section may be greater than 60% of the radius of that imaginary circle.

In order to ensure optimum impact transfer, the impact surface is defined by a plateau adjacent on both sides to recessed parts that extend to the outer circumference of the impact shoe.

Furthermore, each cable loop has a pole shoe that can be brought into cooperation with a pole or tube, which pole shoes each have a bearing surface on their side remote from the outer circumference which can be brought into cooperation with a support ear provided on the pole or tube.

According to the invention, the impact weight with drive means 15 is accommodated in a frame which is provided at the bottom with a pile-driving cap and which is guided along a leader of a mobile pile-driving machine, such that the frame with its pile-driving cap can be placed on the slender object, and the looped cable means extend from the slender object along the frame and the impact shoes are in the path of the impact weight, which impact shoes are suspended from the lifting means of the pile driver.

The installation appears to function well if the thickness of the steel cables is between 25 and 120 mm, in particular between 50 and 120 mm. When non-rotating steel cables are used, the impact shoes can be prevented from rotating too much around a vertical axis during operation, as a result of which the impact weight can incorrectly hit the impact surface of the impact shoe and damage the cable and / or the pile driver.

The cables of the installation can also be constructed from threads, or yarns, manufactured artificially, such as those made of a polyamide, polyethylene, polyester, polypropylene, carbon or combinations thereof. The thickness of this type of cables is between 50 and 200 mm, preferably between 100 and 170 mm.

The invention will be explained in more detail below with reference to an illustrative embodiment shown in the figures.

Figure 1 shows an installation according to the invention, designed as a mobile pile-driving installation.

1005236

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Figure 2 shows an enlarged detail of the installation according to Figure 1.

Figure 3 shows a front view of the detail according to Figure 2.

Figure U shows a striking weight or drop block as used in the installation according to figures 1-3.

Figure 5 shows a detail with striking shoe.

The installation shown in figure 1 comprises a mobile pile-driving machine shown in its entirety by 1, provided with a movable undercarriage 2 with caterpillar tracks, as well as a housing 3 rotatably mounted thereon. This housing 3 is adjustable by means of hydraulic cylinders. piston device and 5 a column 6 is attached. Column 6 and also the frame 2 are supported on a surface, for example consisting of planks 7.

A leader 8 is mounted on the column 6, along which the frame 9 to be further described can be moved by means of claws 10.

The tube 11 can be driven in as well as removed from the bottom 12 by means of the pile driver 1. This tube 11 is provided at its top with a head 13 with filling opening 11 for pouring a concrete pile into work. The frame 9 is placed on the upper end of the tube 11, as can also be seen in figures 2 and 3. * In figures 2 and 3, the outline of the frame 9 is shown schematically with dashed-dot lines. Furthermore, one of the two main posts 15 of that frame is shown. A hydraulic cylinder-piston device 16, as well as the associated accumulator device 17 and hydraulic lines 18., are attached to the piston rod 19 of the hydraulic cylinder-piston device 16.

The impact weight 20 according to the invention can be applied in two ways. According to a first possibility, in which it is used as a pile driver, the impact weight 20 is moved upwards by means of the hydraulic cylinder-piston device, and then released such that the nose 21 of the impact weight can deliver 20 strokes on the cap 22 which is placed on the top of the tube 35 11. In that case, the installation according to the invention functions as a pile driver.

According to a second possibility, the impact weight can be used for pulling a guided tube 11 out of the ground. For that purpose, the installation is equipped with two loop-shaped cables or growers 23 · These growers 23 built from a single cable piece of which the ends secured to each other by means of compression fittings 24, comprises two substantially straight sections 25. as well as a lower part 26 curved by approximately 180 ° and an upper curved part 27

Pole shoes 28 are attached to the lower curved part, as well as the upper curved part impact shoes 29 ·

The post shoes 28 and the impact shoes 29 have an essentially U-10 shaped slot extending through a 180 ° bend. Figure 5 shows a striking shoe 29, the bottom of which is indicated by 30. In this U-shaped slot, the curved parts 27 of each grommet 23 are tightly received, such that they cannot be pulled flat under the influence of the tensile forces.

The curved cable sections 27, 28, which, due to the thickness of the cables used, attempt to assume a less curved shape, are secured therein by means of bolts or pins 36, which extend between the two heats of the U-shaped slot held.

A fastening cable 32 is attached to the impact shoes 29, which is connected by means of block 33 to a cable 31 which is suspended from the hoisting cable 35 of the pile driver.

The pole shoes 28 located on the underside of the grommers 23 are hooked behind the ears 32 which are welded to the pole 11.

The drop weight 20 has two opposing projections 39. 25 which are arranged such that the impact shoes 29, in particular the impact surface 37 thereof, is located in the path of these projections 39. By means of the hydraulic cylinder-piston device 16, the impact weight 20 are accelerated upwards, with the projections 39 each eventually touching the striking surface 37 of a striking shoe 29. The thrust generated thereby is transferred to the pole 11 via the cable loops 23, causing it to move upwards.

During the application of the strokes, the cable loops 23 are continuously pulled up by means of the hoisting cable 35 of the pile driver.

The striking surface 37 of the striking shoes is preferably spaced from the imaginary center point 41 of the circle defining the bottom 30 of the U-shaped slot. Thanks to this position 1005236 6 of the striking surface 37, it is avoided that the striking shoes 29 could tip over under the influence of the strokes exerted thereon by the protrusions 39.

The impact weight 20 shown in detail in Figure 4 is provided with guides 40, which engage in pairs on either side of a main post 15 of the frame 9 in pairs.

As shown in Figure 4, the drop weight nose 21 is narrower than the rest of it. The transition between that nose 21 and that remainder proceeds smoothly via a curved line, such that the force wave generated in the striking weight 20 generates virtually no parasitic shock waves. The projections 39 also gradually transition into the lower parts of the impact weight 20, so that the generation of parasitic shock waves is also avoided here.

Thanks to this design, hardly any stress concentrations 15 occur in the impact weight 20, which has a favorable influence on the service life thereof.

1005236

Claims (18)

1. Installation for removing a slender object driven into the ground, such as a pipe, pile or sheet pile plank, from said bottom, which installation comprises a striking device with a striking weight, driving means for moving the striking weight, striking means which a slender object having a striking impact surface for receiving impacts from the impact weight set in motion by the drive means, as well as a tensile structure by means of which the impact means may be connected to the slender object, characterized in that the tensile structure comprises loop-shaped cable means attached to their one cooperate with the impact means at the other end and can be brought into engagement with the slender object at their other end. 15 Installation according to claim 1, wherein the cable means comprise at least two cables, each of which is formed into a cable loop (grommet) consisting of two straight, substantially parallel parts as well as two bent parts extending over a bend of substantially 180 degrees. Installation according to claim 2, wherein the ends of each steel cable are connected to one another by means of one or more clamping sleeves. 25 Installation as claimed in claim 2 or 3. wherein in each of the curved parts a metal cable shoe is included which surrounds the cable tightly. 30 Installation according to claim 4, wherein each cable lug has a substantially U-shaped outer circumference, and the bent parts of a cable loop are caught by means of locking means, such as pins or bolts extending between both legs of the U-shaped outer circumference being kept. Installation according to claim 4 or 5, wherein each cable loop has an impact shoe, which impact shoe has an essentially flat impact surface on its side remote from the U-shaped outer circumference. 35 1005236 Installation according to claim 6, wherein the bottom of the U-shaped outer circumference of each impact shoe essentially coincides with a portion of an imaginary circle, and the impact surface of the impact shoe is between the center of said imaginary circle and the bottom of the outer circumference. 8. Installation according to claim 7, wherein the distance from the striking surface to the bottom of the U-shaped outer circumference, measured perpendicular to the striking surface, is less than or equal to the radius of that imaginary circle. Installation according to claim 8, wherein the distance from the striking surface to the bottom of the U-shaped cross section is greater than 60% of the radius of that imaginary circle. 15 Installation according to claim 6, 7, 8 or 9. wherein the striking surface is defined by a plateau which is adjacent on both sides to recessed parts which extend to the outer circumference of the striking shoe. 20 11. Installation as claimed in any of the claims 6-10, wherein each cable loop has a pole shoe which can be brought into contact with a pole or tube, which pole shoes each have a bearing surface on their side remote from the outer circumference which can be brought together with a the post or tube provided with support ear. 12. Installation as claimed in any of the claims 6-11, wherein the impact weight with driving means is accommodated in a frame which is provided at the bottom with a pile-driving cap and which can be guided along a leader of a mobile pile-driving machine, such that the frame with its pile-driving cap can be placed on the slender object, and the loop-shaped cable means extend from the slender object along the frame and the impact shoes are located in the path of the impact weight, which impact shoes are suspended from the lifting means of the pile driver. Installation according to claim 12, wherein the impact weight has two opposite protrusions, and the cable means comprise two cable loops (grommets), such that the impact weight protrusions extend into the cable loops. Installation according to any one of the preceding claims, wherein the 5 cables are of the steel cables, the thickness of which is between 25 and 120 mm. Installation according to claim 14, wherein the thickness of the steel cables is between 50 and 120 mm. 10 Installation according to claim 14 or 15. wherein the steel cables are rotation-free. Installation as claimed in claims 6-13, wherein the cables are built up of artificially manufactured threads, or yarns, such as of a polyamide, a polyethylene, a polyester, a polypropylene, a carbon or of combinations thereof, and wherein the thickness of the cables are between 50 and 200 mm. Installation according to claim 17, wherein the thickness of the cables is between 100 and 170 mm. 10 ^ 5236