WO2023067182A1 - Device for installing a foundation pile - Google Patents

Abstract

Disclosed is a screwing-in device (1) for a screw foundation (2), attached to an excavator extension arm (3), the mounting of which device is designed as a gimbal suspension which receives the screw foundation (2) and has a rotary drive (4). The gimbal suspension is designed such that the screw foundation (2) can be rotated about its longitudinal axis (5) for screwing-in or screwing-out and can be pivoted about a first pivot axis (6) at the front end of the excavator extension arm (3). The first pivot axis (6) intersects the longitudinal axis (5). The gimbal suspension can be pivoted about a second pivot axis (7), which passes through the rotary drive (4) in the radial direction thereof. The second pivot axis (7) extends in the region of the centre of mass of the rotary drive (4) and has a common point of intersection (11) at least with the longitudinal axis (5) of the screw foundation (5).

Description

DEVICE FOR INSTALLING A FOUNDATION POLE

The invention relates to a screwing-in device for a screw foundation attached to an excavator arm.

Screwing devices, which are attached to an excavator arm, by means of which screw foundations can be screwed into the ground, are known. US 4,199,033 describes a screw foundation to be driven into the ground by means of a rotary device attached to an excavator arm. The rotary device in the form of a hydraulic drive unit is attached to the excavator boom arm, on which there is a clamping device for the screw foundation on its side facing the ground, in which the screw foundation is clamped and finally screwed into or out of the ground with the hydraulic drive unit by means of the excavator becomes. The rotary device drives the screw foundation to rotate about its longitudinal axis. A pivot axis extending radially to the drive unit runs on the opposite side of the rotating device from the screw foundation, ie in its upper part. The screw foundation can thus be introduced into a floor area in any direction, including in the horizontal direction. So that the rotary device can be pivoted with respect to the attachment to the excavator arm, this pivot axis is arranged in the upper area of the rotary device and is held on both sides by means of angle plates. In addition, the front part of the excavator arm can be pivoted sideways about another axis together with the hydraulic drive device with clamped screw foundation. On the one hand, all pivot axes are arranged in such a way that they do not intersect. On the other hand, the pivot axis running in the radial direction of the drive unit is arranged in the upper area of the rotary device, so that it runs relatively far away from the center of mass or from the area of the center of gravity of the rotary device. With the three drive axles, it is possible to screw a screw foundation into the ground at different angles, depending on the requirement. However, this known device has the disadvantage that although the excavator arm is deflected as far as possible, this is associated with a higher tilting moment of the screw foundation. When screwing in, the screw foundation can therefore wobble mentes, which makes it difficult to screw in reliably and securely at a desired, defined angle. The arrangement of the three pivot axes without an intersection with each other results in a skewing moment, which occurs when the excavator boom arm is pushed down by a feed force as soon as there is an axis offset of the load application point to the turning axis. This skewing torque causes the screw-in foundation to be screwed in to run out of the desired screw-in direction. With the known device, this can only be attempted to be compensated for by the excavator driver. This means that the screwing-in process is heavily dependent on the excavator operator's ability to carry out the screwing-in process in the desired way.

US 2011/0 225 855 A1 describes a device for bringing in a burial container in the form of a large screw foundation, the screw foundation is provided with a swiveling clamping device and is screwed in the direction of the longitudinal axis of the coffin container and swiveling about a vertical, in the longitudinal direction of the screw-in vehicle directed axis as well as a direction that can be pivoted transversely thereto and can be erected in any direction of introduction and can also be screwed into the ground in this position. For this purpose, hydraulic cylinders attached to the outside at the end of the transport vehicle and connected to the tensioning device are provided, which must be adjusted by the vehicle driver using his skills to avoid skewing torques when screwing in.

The object of the invention is compared to this known device is to create such an arrangement of a screwing device together with such a suspension on the excavator arm, by means of which screwing the ground screw occurs with as little skewing torque as possible.

This object is achieved with a screwing-in device attached to an excavator arm for screwing in a screw foundation with the features according to claim 1 . Expedient developments are defined in the dependent claims.

According to the invention, the screwing device for a screw foundation attached to an excavator boom arm is designed as a gimbal suspension and has a rotary drive for receiving the screw foundation, ie with a clamp. According to the invention, the gimbal suspension is designed in such a way that the screw foundation can be rotated about its longitudinal axis for screwing in or out and can be pivoted about a first pivot axis, which is arranged at the front end of the excavator boom arm, wherein the first pivot axis intersects the longitudinal axis of the ground screw. In addition, the gimbal suspension can be pivoted about a second pivot axis, which is arranged in such a way that it penetrates the rotary drive in its radial direction. The second pivot axis is arranged in the area of the center of mass of the rotary drive, which is preferably located in the lower part of the rotary drive in the direction of the screw foundation. The second pivot axis has a common point of intersection at least with the longitudinal axis of the screw foundation.

Because both pivot axes of the gimbal mount, i. H. the first pivot axis and the second pivot axis, have no offset to the longitudinal axis of the screw foundation, the moment that occurs when the excavator boom arm is pushed down by the feed force can be avoided or kept small. The skewing torque occurs when there is an axis offset between the load application point and the screw-in axis. Screwing in by means of the device according to the invention is thus possible essentially without any skewing torque. The deeper in the rotary drive, relative to the clamping point of the screw foundation, the second pivot axis is arranged, the lower the moments that occur and the easier it is to keep the bending moment that acts on the screw foundation during the screwing-in process small. This is especially true when the excavator driver intervenes to correct any obstacles that may appear in the ground. Ultimately, it is about the fact that the moment that occurs on the flange, i. H. acts at the clamping point of the screw foundation can be kept low. The arrangement of the axes relative to one another is therefore important in order to achieve the object of the invention, so that at least both the first pivot axis and the second pivot axis intersect the longitudinal axis of the screw foundation, with an offset definitely being possible between the two. As long as both pivot axes intersect the longitudinal axis of the screw foundation, the skewing torque can be avoided or at least kept very small. A low-lying pivot axis also reduces the effective buckling length. As a result, there is a lower risk of buckling with larger feed forces.

A particularly preferred exemplary embodiment is given when not only does the second pivot axis form a common point of intersection with the longitudinal axis of the screw foundation, but also when the first pivot axis also runs through this common point of intersection. With such an arrangement of the pivot axes relative to one another, it can be ensured that the screw foundation can be screwed into the ground in the desired direction, and specifically without requiring the excavator driver to have any special skills. If the second pivot axis in the rotary drive is arranged as far as possible in its lower area where the center of mass of the rotary drive runs, then free pivoting of the rotary drive is not possible due to its, for example, fork-shaped or ring-shaped suspension on the excavator arm. Unless, for example, you want a fork-shaped suspension with long forks, which in turn could result in instabilities and vibrations. However, since the first pivot axis is arranged via a joint at the front end of the excavator boom arm, the turning device, i.e. the rotary drive together with the screw foundation, can also be rotated laterally in relation to the excavator boom arm and in this position even in a horizontal arrangement in a floor area. be screwed into the side walls of a ditch, for example.

The fork provided as part of the gimbal suspension is preferably arranged on the head of the excavator boom arm in such a way that the second pivot axis runs through the fork ends in such a way that it intersects the longitudinal axis of the screw foundation.

According to a further exemplary embodiment, a ring is provided which, in its interior, accommodates the rotary drive in a functionally identical manner to that described above, with the second pivot axis also intersecting the longitudinal axis of the screw foundation. The ring is created, so to speak, by the two fork ends being extended around the rotary drive, which preferably has a cylindrical outer shape, so that the fork ends merge into one another, as a result of which a closed ring is formed.

So that a screw foundation can also be screwed in horizontally or in a direction in which the longitudinal axis of the screw foundation runs in the direction of the ground surface, the gimbal suspension can be pivoted to a corresponding extent about the first pivot axis.

Further advantages, details and possible applications of the present invention will now be explained using the following drawing. Show in the drawing:

FIG. 1 shows a three-dimensional view of a screwing-in device in the form of a gimbal suspension for screw foundations according to the invention, attached to an excavator arm;

FIG. 2 shows the exemplary embodiment according to FIG. 1 in a side view; FIG. 3 shows the exemplary embodiment according to FIG. 1 in plan view with a fork-shaped holder for the gimbal suspension;

FIG. 4 shows a further exemplary embodiment in which the fork-shaped fastening of the gimball suspension has an annular holder;

FIG. 5 shows the screwing-in device with a partially screwed-in screw foundation with acting lateral force and torque curve in a gimbal suspension according to the invention; and

FIG. 6 shows a screwing-in device with a suspension mounted above the rotary drive, with the lateral force and moment progression shown.

FIG. 1 shows a three-dimensional representation of a screwing-in device 1 for a screw foundation 2 , which is attached to an excavator arm 3 as a gimbal suspension with a rotary drive 4 by means of a fork-like holder 9 . The ground screw 2 is fastened or connected to the rotary drive 4 by means of a clamping device 8, namely on the flange area of the ground screw 2. The ground screw 2 is screwed in or out about its longitudinal axis by means of the screwing device 1 in the form of a gimbal suspension 5 rotatable. In addition, the screw foundation 2 with the gimbal suspension and thus with the rotary drive 4 can be pivoted about a first pivot axis 6 and thus in the transverse direction to the longitudinal extension of the excavator boom arm 3 .

Furthermore, the turning device 1 can be pivoted about a second pivot axis 7 , specifically in a plane imaginary through the longitudinal extension of the excavator boom arm 3 . The rotary drive 4 is held laterally by a bracket in the form of a fork 9, which is attached on one side to the head of the excavator boom arm 3 and through which the second pivot axis 7 runs in the radial direction through the rotary drive 4 at the opposite end of the fork. The pivot axes 6, 7 are now arranged such that both the first pivot axis 6 and the second pivot axis 7 each intersect the longitudinal axis 5 of the screw foundation 2, ie they have at best an existing offset on the longitudinal axis 5 to one another. Since both pivot axes intersect the longitudinal axis 5, the skewing moment, which is caused by the feed force when the excavator boom arm 3 is pushed down, is low as soon as the load application point is offset from the turning axis. It can be seen from FIG. 1 that the point of intersection of the second pivot axis 7 with the longitudinal axis 5 of the screw foundation 2 runs in the center of mass of the rotary drive 4 , which is arranged in the lower region of the rotary drive 4 . The lower area means that the lower part of the rotary drive 4 pointing to the flange of the screw foundation 2 is arranged near the clamping device 8 on the flange of the screw foundation 2, i.e. it is shifted significantly further downwards than is the case with a suspension in the prior art is known.

The disadvantage of such an arrangement is that with the illustrated size of the fork 9 for fastening the rotary drive 4 within the gimbal suspension, the screw foundation 2 together with the rotary drive 4 cannot be pivoted so far about the pivot axis 7 that the screw foundation 2 may in a direction parallel to the ground surface, d. H. certainly in the horizontal direction, can be aligned. This is because the upper area of the rotary drive 4 would hit the front, head-side area of the excavator boom arm 3 . If the length of the fork 9 were to be extended so far in the direction parallel to the first pivot axis 6, it would possibly be possible to pivot the rotary drive 4 through the area between the fork 9 and past the head of the excavator boom arm 3, but the length of the fork arms would increase during operation can lead to instabilities and vibrations, which would be even more detrimental for safe and clean and angle-defined screwing of the ground screw 2 into the ground. If, for example, the ground screw 2 is to be inserted essentially horizontally into the ground, for example, pivoting about the first pivot axis 6 with the entire gimbal suspension at the head of the excavator boom arm 3 is possible, so that the screw foundation 2 then, so to speak, to the excavator boom arm 3 in the lateral direction pointing can be screwed in or screwed out of the ground. Bringing it into the horizontal above all makes it easy to pick up and couple large screw foundations in particular. The common point of intersection of the first pivot axis 6 with the longitudinal axis 5 of the ground screw 2 is denoted by the reference number 12, whereas the common point of intersection between the second pivot axis 7 and the longitudinal axis 5 of the ground screw 2 is shown with the reference number 11.

According to a preferred embodiment, the point of intersection 12 of the first pivot axis 6 with the longitudinal axis 5 of the ground screw 2 and the point of intersection 11 between the second pivot axis 7 and the longitudinal axis 5 of the ground screw 2 form a common point of intersection. This means that the first pivot axis 6, the second pivot axis 7 and the longitudinal axis 5 of the ground screw 2 in the common cut seed intersection. In this case, screwing in the screw foundation 2 can be done particularly well because the skewing torque in this exemplary embodiment is small and is particularly easy to handle when screwing in the screw foundation 2 or when unscrewing it.

FIG. 2 shows the exemplary embodiment according to FIG. 1 in a side view. The offset in the direction of the longitudinal axis 5 of the screw foundation 2 between the first longitudinal axis 6 and the second pivot axis 7 running in the radial direction through the mounting of the rotary drive 4 is clearly visible. All other functions and movement sequences correspond to those explained in connection with Figure 1 became; they will therefore not be repeated.

FIG. 3 shows the exemplary embodiment according to FIGS. 1 and 2 in plan view. On the one hand, the second pivot axis 7 is shown, which runs in the radial direction through the rotary drive 4 through the fork 9 arranged at the front head end of the excavator boom arm 3 . Also shown is the first pivot axis 6 arranged essentially perpendicularly or at right angles thereto, which runs through the rotatably mounted head on the excavator boom arm 3 and at the same time through the longitudinal axis 5 of the screw foundation 2, which is not shown and runs perpendicular to the plane of the drawing. The same reference numbers designate the same parts.

FIG. 4 shows an exemplary embodiment that is modified compared to FIGS. The course of the axes and the mobility of the gimbal suspension correspond to those of the exemplary embodiment according to FIGS. 1 to 3. Only the fork-shaped attachment for the rotary drive 4 was modified in such a way that the ends of the fork 9 are extended around the rotary drive 4 and merge into one another , so that the fastening device for the rotary drive 4 is designed as a closed ring 10 .

FIG. 5 shows a basic representation of the transverse force and moment progression in a gimbal suspension for the screwing-in device 1, ie the rotary drive 4 with the screw foundation 2 according to the invention already partially screwed into the ground. The common point of intersection of the pivot axes 6 and 7 through the center of mass in the lower area of the rotary drive 4 is drawn, whereby the distance between the torque application and the flange of the screw foundation 2, on which the rotary drive 4 acts, has the smallest possible distance. The transverse force is constant for the entire area from the center of gravity of the rotary drive 4 to the ground, whereas the moment increases linearly up to the ground. The magnitude of the moment acting on the flange is qualitatively defined with the quantity 17 measured by the double arrow. Reference number 15 represents the transverse force curve and 16 the moment curve.

In contrast, FIG. 6 shows the suspension of a rotary device 4 as is known in the prior art. There, the suspension of the rotary device 4 is arranged at the front end of the excavator boom arm above the rotary device 4, so that from the outset the screwing device tends to swing together with the screw foundation 2, which ultimately also leads to an increased tendency to pull askew when screwing in. The wobbling or tipping of the ground screw 2 cannot be easily compensated for by the excavator operator having special skills for guiding the excavator. FIG. 6 shows that the transverse force profile is constant over the entire area from the suspension to the ground surface, whereas the torque profile increases linearly. Qualitatively, the moment acting on the flange of the screw foundation 2 is drawn in and also identified by the reference number 17 by the double arrow. The comparison between the designs of the prior art according to FIG. 6 and the design according to the invention according to FIG the training according to Figure 5.

REFERENCE LIST

1 screwing device

2 screw foundations

3 excavator boom arm

4 rotary drive

5 Longitudinal axis screw foundation

6 first pivot axis suspension

7 second pivot axis suspension

8 jig

9 fork

10 rings

11 Intersection of the second axis with the longitudinal axis of the screw foundation

12 Intersection of the first axis with the longitudinal axis of the screw foundation

15 lateral force

16 moment

17 moment acting on the flange

Claims

EXPECTATIONS

1. Screwing device (1) for a screw foundation (2) attached to an excavator boom arm (3), which has a suspension which is designed as a gimbal suspension which accommodates the screw foundation (2) and has a rotary drive (4), the gimbal - the suspension is designed in such a way that the screw foundation (2) can be rotated about its longitudinal axis (5) for screwing in or out and can be pivoted about a first pivot axis (6) at the front end of the excavator boom arm (3) which intersects the longitudinal axis (5), characterized in that the gimbal suspension can be pivoted about a second pivot axis (7) which penetrates the rotary drive (4) in its radial direction, the second pivot axis (7) running in the area of the center of mass of the rotary drive (4) and at least with the longitudinal axis (5) of the screw foundation (2) has a common point of intersection (11).

2. Screwing device (1) according to claim 1, characterized in that the first pivot axis (6) intersects the second pivot axis (7).

3. Screwing device (1) according to claim 1, characterized in that it receives the rotary drive (4) by means of a fork (9).

4. Screwing-in device (1) according to claim 1, characterized in that it receives the rotary drive (4) by means of a ring (10) enclosing it.

5. Driving device (1) according to one of claims 1 to 4, characterized in that the gimbal suspension can be pivoted about the first pivot axis (6) to such an extent that the longitudinal axis (5) of the screw foundation (2) points in the direction of the ground surface runs, in which the ground screw (2) can be assembled or disassembled.