A DETACHABLE FLUIDISATION DEVICE

Abstract

The invention is directed to a detachable fluidisation device for use in a vertical positioned tubular foundation pile having a pile axis and comprising of a central element and radially extending fixing means. The radially extending fixing means can have a first position wherein, in use, the central element is radially fixed to the interior of the tubular foundation pile and a second position which allows the fluidisation device to axially move along the length of the tubular foundation pile. The central element has at its lower end a rotating lower end provided with horizontally extending arms. The arms are each provided with high pressure water injection nozzles and with mechanical cutting elements extending from the arm in the direction of rotation.

Claims

1. A detachable fluidisation device for use in a vertical positioned tubular foundation pile having a pile axis and comprising of a central element and radially extending fixing means, wherein the radially extending fixing means can have a first position wherein, in use, the central element is radially fixed to the interior of the tubular foundation pile and a second position which allows the fluidisation device to axially move along the length of the tubular foundation pile, wherein the central element has at its lower end, when the detachable fluidisation device is in its orientation of use, a rotating lower end which in use can rotate in a direction of rotation along the pile axis and wherein the rotating lower end is provided with horizontally extending arms, which arms are each provided with high pressure water injection nozzles and with mechanical cutting elements extending from the arm in the direction of rotation.

2. A detachable fluidisation device according to claim 1, wherein the high pressure water injection nozzles are rotating nozzles.

3. A detachable fluidisation device according to claim 2, wherein the high pressure water injection nozzles are rotating nozzles and wherein the nozzles are positioned under an angle of between 30 and 60 degrees with the vertical.

4. A detachable fluidisation device according to claim 1, wherein the high pressure water injection nozzles are positioned in a single row along the arm extending from the central element.

5. A detachable fluidisation device according to claim 2, wherein the rotating nozzle comprises of a non-rotating fixed part and a rotating nozzle head as present in a nozzle head chamber, wherein the rotating nozzle head has an upper and lower end, wherein the nozzle head chamber has a wall defining the chamber and an opening at its lower end, the opening has sides, and the wall of the nozzle head chamber has one or more openings for discharging a water jet into the nozzle head chamber, wherein the lower end of the rotating nozzle head is present in the opening of the nozzle head chamber such that a sleeve opening between rotating nozzle head and the sides of the opening of the nozzle head chamber remains, wherein the non-rotating part is provided with an inlet for pressurised water and a conduit for passage of pressurised water to an inlet for pressurised water as present at the upper end of the rotating nozzle head, said inlet for water being fluidly connected to one or more nozzle outlets as present at the lower end of the rotating nozzle head from which in use a jet is ejected, and wherein the rotating nozzle head is further provided with a horizontal water wheel having a vertical axis of rotation at its upper end which is functionally aligned with the one or more openings for discharging a water jet into the nozzle head chamber such that a rotation of the rotating nozzle head results.

6. A detachable fluidisation device according to claim 1, wherein the rotating lower end is provided with two arms.

7. A detachable fluidisation device according to claim 1-any one of claims 1 6, wherein the mechanical cutting elements are teeth positioned at one side of the arm in the direction of rotation.

8. A detachable fluidisation device according to claim 1, wherein the radially extending fixing means are moved from first to second position by means of hydraulics.

9. A detachable fluidisation device according to claim 1, wherein the high pressure water injection nozzles are connected to pumps via high pressure water conduits.

10. A kit of parts comprising of a vibro-hammer and a detachable fluidisation device according to claim 1.

11. A combination of a vibro-hammer and a detachable fluidisation device according to claim 1, wherein the vibro-hammer is connected to the detachable fluidisation device by in length variable cables.

12. A combination according to claim 11, further comprising a frame work connected to the vibro-hammer and provided with guiding means for high pressure water conduits and with a winch for the in length variable cables.

13. A method of placing a tubular foundation in an underwater bed wherein a combination according to claim 12 is used and wherein the vibro-hammer is positioned at the upper end of the tubular foundation and the a detachable fluidisation device is lowered to the lower end of the foundation at which lower end the detachable fluidisation device is radially fixed to the internal walls of the tubular foundation and wherein the vibro-hammer vibrates the tubular foundation and wherein pressurised water is supplied to the detachable fluidisation device causing the rotating lower end to rotate and eject water jets from the water injection nozzle and causing the soil of the underwater bed to be cut by the mechanical cutting elements.

14. The method of claim 13, wherein the pressure of the water as supplied to the water injection nozzles is at least 5 bar, and preferably between 20 and 500 bar.

15. The method of claim 13, wherein the rotating lower end rotates at between 1 and 120 rotations per minute and preferably between 5 and 60 rpm.

16. The method of claim 13, wherein the internal diameter of the tubular foundation is between 1 and 20 m.

17. The method of claim 13, wherein the underwater bed comprises a layer of sand, silt, soft clay, very stiff clay or Boom clay or any combination of aforementioned.

18. A rotating Rotating-nozzle comprising of a non-rotating fixed part and a rotating nozzle head as present in a nozzle head chamber: wherein the rotating nozzle head has an upper and lower end, wherein the nozzle head chamber has a wall defining the chamber and an opening at its lower end, the opening has sides, and the wall of the nozzle head chamber has one or more openings for discharging a water jet into the nozzle head chamber, wherein the lower end of the rotating nozzle head is present in the opening of the nozzle head chamber such that a sleeve opening between rotating nozzle head and the sides of the opening of the nozzle head chamber remains, wherein the non-rotating part is provided with an inlet for pressurised water and a conduit for passage of pressurised water to an inlet for pressurised water as present at the upper end of the rotating nozzle head, said inlet for water being fluidly connected to one or more nozzle outlets as present at the lower end of the rotating nozzle head from which in use a jet is ejected, and wherein the rotating nozzle head is further provided with a horizontal water wheel having a vertical axis of rotation at its upper end which is functionally aligned with the one or more openings for discharging a water jet into the nozzle head chamber such that a rotation of the rotating nozzle head results.

19. Use of the rotating nozzle of claim 18 in soil-shifting.

Description

[0041] The invention will be illustrated by the following Figures.

[0042] FIG. 1 shows a detachable fluidisation device (1) according to this invention. Radially extending fixing means (2) are connected to a central element (3). The fixing means are beams (4) provided with wheels (5) which are connected to the central element (3) by arms (6). Shown is a first position wherein, in use, the central element (3) is radially fixed to the interior of the tubular foundation pile. The central element (3) has a rotating lower end (7) which can rotate along a centre axis (7a). The rotating lower end part (7) is provided with two arms (8). On each arm (8) cutting teeth (9) are present extending from the arm (8) in the direction (10) of rotation.

[0043] FIG. 2 shows arms (8) of FIG. 1 in more detail as seen under an angle from below. Seven rotating high pressure water injection nozzles (8a) per arm (8) are shown positioned in a row. Further the lower end part (7) is shown as well as the lower end of a beam (4) and part of an arm (6) connected to said beam (4).

[0044] FIG. 3 shows the radially extending end (11) of one of the arms (8) of FIG. 2 showing three of the seven rotating high pressure water injection nozzles (8a) in a single row along the arm (8) as seen under an angle from below. A top cover plate (12) and a bottom plate (13) define an internal space (14) of the arm (8).

[0045] FIG. 4 shows the two arms (8) without the cover plate (12) allowing a view of the internal space (14) of the arms (8) under an angle from above. A non-rotating fixed part (15) per nozzle (8a) is seen as well as various conduits (16) for supply of pressurised water to the various nozzles (8a). The conduits (16) are fluidly connected to supply conduits (17) which extend upwards in the rotating lower end (7) of the central element (3).

[0046] FIG. 5 is a three dimensional cross-sectional view at the second nozzle (8a) of FIG. 3. This view shows the internal space (14) of the arm (8). A structural element (18) extending from the centre axis (7a) to the radially extending end (11) is provided with a channel (18) for supply of pressurised water to conduits (16). This channel (17) fluidly connects the supply conduits (16) of FIG. 4 and the individual rotating high pressure water injection nozzles (8a). The rotating nozzle (8a) comprises of a non-rotating fixed part (15) and a rotating nozzle head (19) as present in a nozzle head chamber (20). The non-rotating fixed part (15) is fixed to the arm (8) in the internal space (14). The rotating nozzle head (19) has an upper (21) and lower (22) end. The nozzle head chamber (20) has a wall (23) defining the chamber (20) and an opening (24) at its lower end. Two manifold channels (25a,25b) for pressurised water are shown. From these channels water is injected into the nozzle head chamber (20) as will be illustrated in FIGS. 6 and 7. To the non-rotating fixed part (15) pressurised water is supplied via conduit (16). The water flows downwards via an axial channel (26), as the conduit for passage of pressurised water, to a pin (27) provided with an outlet fluidly connected to the upper end (21) of the rotating nozzle head (19). The pin (27) is positioned in a pin opening as present in the upper end (21) of the rotating nozzle head (19) such that the rotating nozzle head (19) can rotate around said pin (27).

[0047] The non-rotating part is provided with an inlet (not shown) for pressurised water and fluidly connected to an inlet for pressurised water as present at the upper end of the rotating nozzle head. Said inlet for water being fluidly connected to two nozzle outlets (28) as present at the lower end (22) of the rotating nozzle head (19) from which in use a jet is ejected.

[0048] The rotating nozzle head (19) is further contained within the chamber (20) because the upper end (21) of the rotating nozzle head (19) has a larger diameter than the opening (24). The lower end (22) of the rotating nozzle head (19) is present in the opening of the nozzle head chamber such that a sleeve opening between rotating nozzle head and the sides of the opening (24) of the nozzle head chamber (20) remains. Via this sleeve opening water can flow out of the nozzle head chamber (20). The two nozzle outlets (28) for discharging a water jet make an angle of 45 degrees with the vertical such that in use the water jet is discharged making an angle of 45 degrees with the vertical. Preferably this angle is between 30 and 60 degrees.

[0049] FIG. 6 shows a cross-sectional view of the first nozzle (8a) when counting from the radially extending end (11) of arm (8) from aside. The cross section is made at AA' as indicated in FIG. 7. The internal of the nozzle head chamber (20) is shown in which a horizontal water wheel (29) having a vertical axis of rotation as part of the rotating nozzle head (19) is present. The wall (30) of the nozzle head chamber (20) has two openings (31) for discharging a water jet into the nozzle head chamber (20). The direction of these water jets is tangential with the water wheel (29) as shown in FIG. 7. The water as supplied to these two openings (31) is supplied from manifold channels (25a,25b).

[0050] FIG. 7 shows a horizontal cross-section BB' as shown in FIG. 6. The horizontal water wheel (29) is shown as positioned in the nozzle head chamber (20) and the two openings (31) from which a water jet is ejected in use in a tangential direction vis--vis the water wheel (29). In this manner the water wheel (29) is functionally aligned with the one or more openings for discharging a water jet into the nozzle head chamber such that a rotation of the rotating nozzle head (19) results.

[0051] FIG. 8 shows a combination (41) of a vibro-hammer (42) and the detachable fluidisation device (1) of FIG. 1 as positioned on and in a foundation pile (43) having a pile axis (40) which is placed in an underwater bed (44) which has sand layers (45) and clay layer (46). The vibrohammer (42) is connected to the detachable fluidisation device (1) by in length variable cables (47). The vibrohammer (42) is positioned at the upper end (48) of the tubular foundation (43) and the a detachable fluidisation device (1) is lowered to the lower end (49) of the foundation (43). At which lower end (49) the detachable fluidisation device (1) is radially fixed to the internal walls of the tubular foundation (43). The vibrohammer vibrates the tubular foundation (43). Pressurised water is supplied to the detachable fluidisation device (1) causing the rotating lower end (7) to rotate and eject water jets from the water injection nozzles (8a) and causing the soil (45) of the underwater bed to be cut by the mechanical cutting teeth (9).

[0052] FIG. 9 shows the combination (41) in more detail without the foundation pile. The combination (41) has a frame work (50) connected to the vibrohammer (42) and provided with guiding means (51) for high pressure water conduits (52) and with a winch (53) for the in length variable cables (47).

[0053] The invention has been tested for a 2 m internal diameter foundation pile as shown in FIG. 3. It was found that the average penetration speed (FIG. 10) and average refusal depth (FIG. 11) is increased substantially and average strain is reduced (FIG. 12) and less energy is required (FIG. 13) when the combination is used as compared to only use of only a vibrohammer.