Pile, pile head and connector therefor

Abstract

A pile head for a screw pile having a top end and a longitudinal axis is provided. The pile head comprises a mounting portion engaging the pile and an extendable portion movably mounted to the mounting portion. The extendable portion is movable relative to the mounting portion, along the longitudinal axis. A first fastening means is used to removably fasten the mounting portion of the pile head to the top end of the pile and preventing unwanted movement of the pile head relative to the pile, along the longitudinal axis. A screw pile, a removable helical member and a body extension for a screw pile are also provided.

Claims

1. A screw pile comprising: a pile body having a top end, a bottom end and a wall extending therebetween, the pile body defining a longitudinal axis of the screw pile, the pile body further having at least one bore defined at the top end; a helical member mounted to the bottom end of the pile body; a pile head mounted to the top end of the pile body, the pile head including: a mounting portion including: a sleeve portion engaging the top end of the pile body and at least one hole defined in the sleeve portion, the top end of the pile body being received within the sleeve portion, the at least one hole of the sleeve portion being in alignment with the at least one bore of the pile body; and a plate portion mounted to a top end of the sleeve portion, the plate portion comprising a threaded hole extending along the longitudinal axis; and an extendable portion movably mounted to the mounting portion, the extendable portion being movable relative to the mounting portion, along the longitudinal axis, the extendable portion comprising a threaded shaft threadably engaging the threaded hole of the plate portion for allowing movement of the extendable portion relative to the mounting portion, along the longitudinal axis; and at least one fastener extending through the at least one hole of the sleeve portion and the at least one bore of the pile body for removably fastening the mounting portion of the pile head to the top end of the pile body.

2. The screw pile as claimed in claim 1, wherein the sleeve portion includes a top end, a bottom end and a curved wall extending therebetween.

3. The screw pile as claimed in claim 2, wherein the curved wall has an outer curved surface and an inner curved surface, the top end of the pile body defining an external top end diameter and the inner curved surface defining an inner diameter larger than the external top end diameter.

4. The screw pile as claimed in claim 1, wherein the threaded shaft of the extendable portion comprises a top end, a bottom end and a threaded surface extending therebetween, the extendable portion further comprising a support member mounted to the top end of the threaded shaft.

5. The screw pile as claimed in claim 1, wherein the pile body and the sleeve portion of the mounting portion of the pile head are generally cylindrical.

6. The screw pile as claimed in claim 5, wherein the plate portion of the mounting portion is configured to receive a tool for urging rotation of the mounting portion relative to the pile body when the at least one fastener is removed, thereby urging movement of the extendable portion relative to the mounting portion, along the longitudinal axis.

7. The screw pile as claimed in claim 6, wherein the plate portion comprises a top face, a bottom face in contact with the sleeve portion and at least one side face extending between the top and bottom faces.

8. The screw pile as claimed in claim 7, wherein the top and bottom faces of the plate portion are hexagonal.

9. The screw pile as claimed in claim 1, wherein the at least one fastener of the pile head is threaded.

10. The screw pile as claimed in claim 9, wherein the at least one bore defined at the top end of the pile body is a threaded bore and the at least one threaded fastener includes at least one bolt, the at least one bolt engaging the threaded bore of the pile body.

11. The screw pile as claimed in claim 1, wherein the helical member is removable.

12. A pile head for a pile having a top end, a longitudinal axis and at least one bore defined at the top end thereof, the pile head comprising: a mounting portion including: a sleeve portion configured for receiving the top end of the pile therein and at least one hole defined in the sleeve portion, the at least one hole of the sleeve portion being alignable with the at least one bore of the pile; and a plate portion mounted to a top end of the sleeve portion, the plate portion comprising a threaded hole extending along the longitudinal axis; an extendable portion movably mounted to the mounting portion, the extendable portion being movable relative to the mounting portion, along the longitudinal axis, the extendable portion comprising a threaded shaft threadably engaging the threaded hole of the plate portion; and at least one fastener configured for extending through the at least one hole of the sleeve portion and the at least one bore of the pile for removably fastening the mounting portion of the pile head to the top end of the pile.

13. The pile head as claimed in claim 12, wherein the pile is a screw pile.

14. The pile head as claimed in claim 12, wherein the sleeve portion includes a top end, a bottom end and a curved wall extending therebetween.

15. The pile head as claimed in claim 14, wherein the curved wall has an outer curved surface and an inner curved surface, the top end of the pile body defining an external top end diameter and the inner curved surface defining an inner diameter larger than the external top end diameter.

16. The pile head as claimed in claim 12, wherein the threaded shaft of the extendable portion comprises a top end, a bottom end and a threaded surface extending therebetween, the extendable portion further comprising a support member mounted to the top end of the threaded shaft.

17. The pile head as claimed in claim 12, wherein the sleeve portion is generally cylindrical.

18. The pile head as claimed in claim 17, wherein the plate portion of the mounting portion is configured to receive a tool for urging rotation of the mounting portion relative to body extension when the at least one fastener is removed, thereby urging movement of the extendable portion relative to the mounting portion, along the longitudinal axis.

19. The pile head as claimed in claim 18, wherein the plate portion comprises a top face, a bottom face in contact with the sleeve portion and at least one side face extending between the top and bottom faces.

20. The pile head as claimed in claim 19, wherein the top and bottom faces of the plate portion are hexagonal.

21. A screw pile comprising: a pile body having a top end, a bottom end and a wall extending therebetween, the pile body defining a longitudinal axis of the screw pile; at least one body extension mounted to the top end of the pile body, the at least one body extension having: a top end, a bottom end and a wall extending therebetween, the body extension further having at least one bore defined at the top end thereof; a connection portion at the bottom end of the at least one body extension, the top end of the pile body being engaged in the connection portion of the body extension; and at least one fastener extending through the pile body and the wall of the body extension for removably fastening the body extension to the pile body; a helical member mounted to the bottom end of the pile body; a pile head mounted to the top end of the at least one body extension, the pile head including: a mounting portion including: a sleeve portion engaging the top end of the pile body and at least one hole defined in the sleeve portion, the top end of the pile body being received within the sleeve portion, the at least one hole of the sleeve portion being in alignment with the at least one bore of the pile body; and a plate portion mounted to a top end of the sleeve portion, the plate portion comprising a threaded hole extending along the longitudinal axis; and an extendable portion movably mounted to the mounting portion, the extendable portion being movable relative to the mounting portion, along the longitudinal axis, the extendable portion comprising a threaded shaft threadably engaging the threaded hole of the plate portion; and at least one second fastener extending through the at least one hole of the sleeve portion and the at least one bore of the body extension for removably fastening the mounting portion of the pile head to the top end of the body extension.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) For a better understanding of the present, as well as other aspects, and further features thereof, reference is made to the following description which is to be used in conjunction with the accompanying drawings, where:

(2) FIG. 1 is a cross-section view of a pile head for a screw pile, according to the prior art;

(3) FIG. 2 is a side view of a screw pile according to one embodiment;

(4) FIG. 3A is an enlarged, partial view of the screw pile of FIG. 2, showing the pile head;

(5) FIG. 3B is an exploded, perspective view of the pile head shown in FIG. 3A;

(6) FIG. 3C is a cross-section view of the pile head shown in FIG. 3A;

(7) FIG. 4 is a cross-section view of the mounting portion of the pile head shown in FIG. 3A, with the threaded fasteners removed;

(8) FIG. 5 is a side view of helical members in accordance with one embodiment;

(9) FIG. 6 is a side view of a helical members, in accordance with another embodiment;

(10) FIG. 7 is a side view of a screw pile in accordance with another embodiment;

(11) FIG. 8 is a side, exploded view of a screw pile in accordance with yet another embodiment, with three body extensions;

(12) FIG. 9A is a side perspective view of the connecting portion of the body extension of the screw piles shown in FIGS. 7 and 8;

(13) FIG. 9B is an exploded, perspective view of the connecting portion shown in FIG. 9A; and

(14) FIG. 9C is a cross-section view of the connecting portion shown in FIG. 9A.

DETAILED DESCRIPTION

(15) Referring to FIGS. 2 to 4, a screw pile 10 having one embodiment of pile head 12 will be described. The screw pile 10 may be used alone or in conjunction with other similar screw piles 10 to support a beam or a structure such as a fence, a deck, a sun room, a cart port, a cabin and the like. As it will become apparent below, the configuration of the pile head 12 can be adapted to securely receive such beam or structure. As it will become apparent below, the screw pile 10 could also be used horizontally or angularly, for instance to support wall or reinforce cliffs that are susceptible to collapse. The person skilled in the art will understand that in such a case, the movement of pile head 12 relative to the pile body 16, along the longitudinal axis L.sub.1 thereof, is not vertical but rather horizontal or inclined relative to the horizontal.

(16) In the illustrated embodiment, the screw pile 10 comprises an elongated cylindrical and hollow pile body 16 having a top end 20 terminating by an annular top edge 22 (best shown in FIG. 3B), as well as a bottom end 24 terminating by a generally annular bottom edge 26. Mounted to the top end 20 of the pile body 16 is the pile head 12. The screw pile further comprises an helical member 14 mounted to the bottom end 24 of the pile body 16, as it will become apparent below.

(17) Extending between the top and bottom edges 22, 26 of the pile body 16 is a curved wall 28 having an outer curved face 30, an inner curved face 32 (best shown in FIG. 3B), as well as a longitudinal axis L.sub.1 corresponding to the rotation axis of the screw pile 10 when it is being installed. Also extending between the top and bottom edges 22, 26 of the pile body 16, is an internal, cylindrical cavity 36, defined by the curved wall 28. As it will become apparent below, the cylindrical cavity 36, at the top end 20 of the pile body 16, is adapted to receive a portion of the pile head 12 for allowing movement thereof, along the longitudinal axis L.sub.1.

(18) In one embodiment, the pile body 16 is made of galvanized steel. Galvanised steel provides the advantages of being weather resistant and is less susceptible to corrosion and yet has sufficient mechanical strength to support heavy loads such as those associated with structures described above. It is however contemplated that the pile body 16 could be made of any other material that is adapted to resist weather condition and mechanical stresses and strains caused by the installation of the screw pile 10 and/or the loads associated with the structures supported by the screw pile 10.

(19) In one embodiment, the cylindrical cavity 36, at the top end 20 of the pile body 16, is filled with a polyurethane material (not shown). In this embodiment, the polyurethane material is aimed at preventing water accumulation inside the cylindrical cavity 36 and to protect against damages that may be caused over time to the pile body 16 by frost. As it will be appreciated by a person skilled in the art, the cylindrical cavity 36 may be filled with other material such as, for instance, sand, stone screenings, concrete or any other type of material suitable for the purpose of filling the space and preventing water accumulation in the cylindrical cavity 36 and/or provide addition strength to the pile body 16. The person skilled in the art will also appreciate that the cylindrical cavity 36 could be left empty, for instance where the screw pile 10 is not subject to freezing/unfreezing cycles. In another embodiment, the outer curved face 30 of the pile body 16 can be covered with a protective layer or sleeve (not shown) to protect the pile body 16 against elements and to reduce abrasion caused by earth, sand or rock during the installation of the screw pile 10. In one embodiment, the protective layer is a silicone layer, but it is contemplated that other techniques and other types of protective layers could be used to protect the pile body 16. The person skilled in the art will also appreciate that even if such a protective layer may be desirable in some instances, it is not required.

(20) To facilitate the installation of the screw pile 10, the bottom edge 26 of the pile body 16 is inclined relative to the longitudinal axis L.sub.1, to define an angle .sub.1 (shown in FIG. 5) and a tip 40 of the pile body 16. In the illustrated embodiment, the angle .sub.1 is 45 degrees relative to the longitudinal axis L.sub.1. It is however contemplated that other angles may be suitable. For instance, the angle .sub.1 could range from about 30 degrees to about 60 degrees relative to the longitudinal axis L.sub.1 depending, for instance, on the type of soil in which the screw pile 10 is to be installed and/or the equipment used to carry out such installation. The person skilled in the art will further appreciate that such an angle .sub.1 could be 90 degrees, meaning that the bottom edge 26 would extend perpendicularly to the longitudinal axis L.sub.1. In such a case, the pile body 16 would have not tip 40.

(21) The pile body 16 can be sized and shaped to meet certain requirements dictated by the intended use, for instance the load to be carried by the screw pile 10 and the type of soil in which it is installed and the weather conditions. For instance, the length of the pile body 16 (i.e. the distance between the top edge 22 and the bottom edge 26) can be adapted such that the helical member 14 is positioned below the ground freezing zone when the screw pile 10 is installed. In one embodiment, the pile body 16 has a length of 85 inches (215.9 cm). It is also contemplated that the length, diameter and thickness of the pile body 16 may be selected according to its usage. In one embodiment the outer diameter of the pile body 16 (defined by the outer curved face 30) is selected from diameters of 1.875 inches (4.7625 cm), 2.375 inches (6.0325 cm) or 3.5 inches (8.89 cm). In another embodiment, the thickness of the curved wall 28 of the pile body 16 (i.e. the distance between the outer and inner curved faces 30, 32) is selected from thicknesses of 0.156 inch (0.39624 cm), 0.188 inch (0.47752 cm) or 0.25 inches (0.635 cm). It is however contemplated that the pile body 16 could have different dimensions. Further, while in the above described embodiment the pile body 16 has a cylindrical shape (i.e. a circular cross-section), it is contemplated that the pile body 16 could have a cross-section other than circular. For example, the pile body 16 could have a square, rectangular, triangular or oval cross-section.

(22) At the top end 20 thereof, the pile body 16 is provided with two pairs of threaded bores 42a, 42b and 44a, 44b, which extend perpendicularly to the longitudinal axis L.sub.1, between the outer and inner curved faces 30, 32 for securing the pile head 12 to the pile body 16. As best shown in FIGS. 3A and 3B, each pair of threaded bores comprises an upper bore 42a, 44a and a lower bore 42b, 44b, the upper bores 42a, 44a and lower bores 42b, 44b of each pair being longitudinally aligned to one another relative to the top and bottom ends 20, 24 of the pile body 16 and facing each other in radially opposed directions.

(23) With reference to FIGS. 3A to 3C, the pile head 12 comprises mounting portion 46 for mounting the pile head 12 to the pile body 16 and an extendable portion 48 providing an adjustable interface between the mounting portion 46 of the pile head 12 and the structure or beam supported by the screw pile 10.

(24) As best shown in FIG. 4, the mounting portion 46 of the pile head 12 includes a sleeve portion 50, which has the general configuration of a relatively short cylinder having a top end 52, a bottom end 54 and a curved wall 56 extending therebetween. The curved wall 56 of the sleeve portion 50 includes an outer curved face 58 and an inner curved face 60, the inner curved face 60 defining an internal diameter slightly larger than the external diameter of the pile body 16. As such, the top end 20 of the pile body 16 can be received into the sleeve portion 50 of the pile head 12 or, conversely, the sleeve portion 50 can engage the top end 20 of the pile body 16. While in the illustrated embodiment sleeve portion 50 of the pile head 12 is generally cylindrical, it could have other shapes, provided that it is sized and shaped to engage the top end 20 of the pile body 16. For example, should the pile body 16 have an oval cross-section, the sleeve portion 50 of the pile head 12 would have a matching oval cross-section.

(25) Defined in the sleeve portion 50 of the pile head 12 are two pairs of radially opposed bores 62a, 62b, 64a, 64b. As it will become apparent below, each pair of threaded bores 62a, 62b or 64a, 64b is susceptible to collaborate with the upper bores 42a, 44a of the pile body 16 for securing the pile head 12 to the body 16 using a pair of fasteners 66a, 66b. While in the illustrated embodiment the pile head 12 comprises two pairs of bores 62a, 62b, and 64a, 64b, and the pile body 16 comprises 2 pairs of threaded holes 42a, 42b and 44a, 44b, it is contemplated that the pile head 12 and the pile body 16 could have a different number of bores and threaded holes, respectively. For example, the pile head 12 and the pile body 16 could each have two or three bores or holes. It is also contemplated that pile head 12 could be connected to the pile body 16 by fasteners other than bolts 66a, 66b. For example, the pile head 12 could be riveted to the pile body 16.

(26) Secured to the top end 52 of the sleeve portion 50 is a plate portion 70, designed to abut the top edge 22 of the pile body 16 when the pile head 12 is positioned thereon. In the illustrated embodiment, the plate portion 70 is hexagonal and is configured to engage a tool such as a wrench (not shown) for adjusting the position of the mounting portion 46 relative to the pile body 16 and to the extendable portion 48 of the pile head 12, as it will become apparent below. As such, the plate portion 70 comprises a hexagonal top face 72, a hexagonal bottom face 74 in contact with the top end 52 of the sleeve portion 50, and 6 lateral faces 76a to 76f extending between the hexagonal top and bottom faces 72, 74 (only lateral faces 76a, 76b and 76c are identified with a reference numeral in the figs). In one embodiment, the hexagonal bottom face 74 of the plate portion 70 is welded to the top end 52 of the sleeve portion 50. Extending axially between the hexagonal top and bottom faces 72, 74 is a centrally disposed threaded hole 78 for receiving the extendable portion 48 of the pile head 12, as it will become apparent below.

(27) The extendable portion 48 of the pile head 12 includes a threaded fastener 80 having a lower end 82, an upper end 84, and a threaded surface 86 extending therebetween. The threaded surface 86 is configured to threadably engage the threaded hole 78 defined on the plate portion 70. Secured at the upper end 84 of the threaded fastener 80 is supporting portion 88 sized and shaped to provide an adequate load bearing surface for the structure to be supported by the screw pile 10 and securing the same. In the illustrated embodiment, the supporting portion 88 has the general configuration of a square plate and comprises a lower face 90 in contact with the top end 84 of the threaded fastener 80 and an upper face 92, configured to receive thereon a portion of the structure to be supported. In the embodiment illustrated, the supporting portion 88 and the threaded fastener portion 80 are centrally aligned. In an alternate embodiment, the supporting portion 88 could be offset relative to the threaded fastener 80 or could have a different configuration. For instance, the supporting portion 88 could have a U-shape, a V-shape or any other shape that is suitable for receiving a structure having a defined shape. As it will be apparent, a rotation movement of the extendable portion 48 and the mounting portion 46 relative to one another in one direction (e.g. clockwise) will allow displacement of the supporting portion 88 relative to the pile body 16 in one direction along the longitudinal axis L.sub.1 while a rotation in the opposite direction (e.g. counter clockwise) will allow the displacement of the supporting portion 88 in the opposite direction, thereby allowing adjustment of the pile head 12 before the structure or after the structure is disposed thereonto. More specifically, configuration of the pile head 12 permits a vertical adjustment of the screw pile 10 without having to lift the structure from the pile head 12 for allowing rotation of the extendable portion 48, while enabling securing the pile head 12 to the pile body 16 of the screw pile 10 to prevent unwanted vertical movement of the pile head 12 relative to the pile body 16. In other words, the above described pile head configuration allow the screw pile 10 to work both in compression and in tension and yet provide adjustment along the longitudinal axis L.sub.1. Accordingly, while in the illustrated embodiment the plate portion 70 is generally hexagonal to engage a tool, it is contemplated that the plate portion 70 could have a different shape. For example, the plate portion 70 of the pile head 12 could be square or pentagonal, or could include grooves or protrusions for engaging a corresponding tool. The plate portion 70 could even be circular, preferably in a manner that would allow a rotation of the mounting portion 46 of the pile head 12 relative to the pile body 16 and to the extendable portion 48, for allowing longitudinal adjustment of the extendable portion 48 when the screw pile 10 is installed and a structure is supported thereto.

(28) While in the above-described embodiment the pile head 12 is mounted to a pile body 16 of a screw pile 10, it is contemplated that it could be mounted to a structure that is different than a pile body 16 of the screw pile 10. For instance, the pile head 12 could be mounted to a pipe or tubular support anchored in a concrete foundation. Further, it is contemplated that the fasteners 66a, 66b may not be required where the pile head 12 is being used to work in compression only. Also, intermediate structures such as rubber seals may be positioned in various locations, including between the pile head 12 and the pile body 16, or about the fasteners 66a, 66b, to reduce water infiltration into the cylindrical cavity 36 of the pile body 16.

(29) With reference to FIG. 5, the helical member 14 mounted to the bottom end 24 of the pile body 16 will now be described. In this embodiment, the helical member 14 is adapted to engage a soil material and to force the pipe body 16 to move thereinto when the pile body is rotated about its longitudinal axis. Once the screw pile 10 is properly positioned, it provides resistance against movement of the screw pile 10 along the longitudinal axis, as it will be appreciated by those skilled in the art. In the embodiment illustrated in FIG. 5, the helical member 14 comprises a twisted plate member 100 fixedly attached, to the lower end 24 of the pile body 16, preferably by welding. In one embodiment, the helical member 14 has a diameter D.sub.1 and a number of threads adapted to the material in which the screw pile 10 is to be installed, as well as the to the load to be supported. Further, the screw pile 10 could comprise more than one helical member. In non-limitative examples, the helical member 14 has a diameter D.sub.1 selected from an 8 inch (20.32 cm) diameter (e.g. to support relatively light structures, such as balconies and galleries, patios, sheds and fences), an 11 inch (27.94 cm) diameter (e.g. to support medium weight structures, such as docks, solarium and walk ways) or a 13 inch (33.02 cm) diameter (e.g. to support heavier structures, such as cabins, permanent or temporary agricultural infrastructures, extensions, building foundations, and bridges).

(30) FIGS. 6 and 7 show another embodiment of an helical member 100 to be used in conjunction with a screw pile such as screw pile 10. In this embodiment, instead of being permanently welded to the pile body 16, the helical member 100 is removable. As such, the helical member 100 could be described as a helix adaptor.

(31) In this embodiment, the helical member 100 includes a sleeve portion 102 adapted to engage the lower end 24 of the pile body 16, and a twisted plate member 104 securely fastened to the sleeve portion 102 and defining a helix thereonto. In non-limitative examples, the helical member 100 has a diameter D.sub.2 selected from a of 8 inches (20.32 cm) diameter (e.g. to support relatively light structures, such as balconies and galleries, patios, sheds and fences), a 11 inches (27.94 cm) diameter (e.g. to support medium weight structures, such as docks, solarium and walk ways) or a 13 inches (33.02 cm) diameter (e.g. to support heavier structures, such as cabins, permanent or temporary agricultural infrastructures, extensions, building foundations, and bridges).

(32) Defined on the sleeve portion 102 of the helical member 100 are two pairs of radially opposed holes not shown. The holes of the helical member 100 coincide with apertures (not shown) defined on the lower portion 24 of the pile body 16 to receive a corresponding pair of bolts 106a, 106b therein. As best shown in FIG. 6, the bolts extend on one side of the helical member 100 to receive a corresponding pair of nuts 108a, 108b to secure the helical member 100 to the lower end 24 of the pile body 16. As such, the helical member 100 is removable from the pile body 16. This embodiment of helical member 100 provides distinct advantages over prior art configurations of helical members. For instance, the use of the helical members such as helical member 100 provides with a greater flexibility with respect to the onsite installation of screw piles. More specifically, since it is oftentimes difficult to evaluate soil conditions, required screw pile length and load to be supported while offsite, manufacturers, distributors and/or installers of screw piles can transport a variety of pile bodies (e.g. having various length and diameters and a variety of helical members (e.g. having different diameters, number of threads and different sizes of sleeves) and assemble pile bodies onsite. Accordingly, because of the configuration of the helical member 100, one can use a same pile body and attach thereonto helical member 100 having various characteristics (size, number of threads) for the intended purpose and/or ground conditions. Because the helical members 100 are detachable from the pile body 16, they also tend to make storage in warehouses and/or trucks easier because less space is required than for screw piles provided with helical members fixedly mounted to the pile body, which may also be found to be advantageous in some circumstances.

(33) According to another embodiment, shown in FIGS. 7 to 9C, a screw pile 120 comprises a pile body 16 to which are attached one or more body extensions 130 (in the case of FIG. 7 only one body extension 130 is shown while three body extensions 130a-130c are shown in FIG. 8) provided to extend the length of the screw pile 120. The body extensions 130a-130c being identical, only body extension 130a will be described.

(34) The body extension 130a includes a top end 132, a lower end 134 and a cylindrical wall 136 extending therebetween. Provided at the top end 132 are two pairs of threaded bores 142a, 142b, 144a, 144b (only threaded bores 142a and 142b are shown in FIG. 8), which extend perpendicularly to the longitudinal axis L.sub.1, similarly to threaded bores 42a, 42b and 44a, 44b of the pile body 16, adapted to secure a pile head 12 or another body extension (e.g. 130b), as it will become apparent below.

(35) The body extension 130 is preferably made of galvanized steel, similarly to the pile body 16, and the cylindrical wall 136 has a diameter d.sub.2, which correspond to the diameter d.sub.1 of the pile body 16. At the bottom end 134 thereof, the body extension 130 is provided with a connecting portion 138. With reference to FIGS. 9A to 9C, the connecting portion 138 has the general configuration of a cylindrical sleeve partially engaging cylindrical wall 136, at the lower end 134. More specifically, the connecting portion 138 comprises a top end 140, a bottom end 142 and a cylindrical wall 144 extending therebetween. The cylindrical wall 144 has an inner curved face 146 and an outer curved face 148. The inner curved face 146 defines an inner cylindrical cavity 150 having a diameter d.sub.3, which is adapted to allow engagement of the connection portion 138 about the cylindrical wall 144 of the body extension 130. As such, the diameter d.sub.3 is slightly larger than the diameter d.sub.1. In the illustrated embodiment, the connecting portion 138 is engaged about the cylindrical wall 136 from the top end 140 to an intermediate region 152 located between the top end 140 and the lower end 142. In one embodiment, the connecting portion 138 is secured to the cylindrical wall 136 by welding, preferably at the top end 140 of the connecting portion 138 (i.e. outside the connecting portion 138) and at the intermediate location 152, in the internal cylindrical cavity 150. As it will be appreciated by one skilled in the art, different manufacturing options are available to provide a body section with a connecting portion. For instance, the connecting portion 138 and the cylindrical wall 136 could be integrally formed. It is also contemplated that the body extension 130 could have a shape and size different from illustrated in the figures as long as it is sized and shaped to connect with sufficient resistance to a pile body 16 or to another body extension 130.

(36) Provided between the intermediate position 152 and the lower end 142 of the connection portion 138 are two pairs of radially opposed holes 154a, 154b, 156a, 156b for receiving fasteners 158a, 158b and fastening the top end 20 of the pile body 16 to the bottom end 134 of the body extension 130. As best shown in FIG. 9C, when the top end 20 of the pile body 16 (or the top end 132 of another body extension 130) is received in the internal cylindrical cavity 150 of the connecting portion 138, the two pairs of holes 42a, 42b, 44a, 44b of the pile body 16 (or of another body extension 130) are in alignment with the corresponding two pairs of holes 154a, 154b and 156a, 156b respectively (only holes 154a and 154b being shown), of the connecting portion 138 to receive the pair of fasteners 158a, 158b, to thereby secure the body extension 130 to the pile body 16 (or to another body extension 130). In the illustrated embodiment, the fasteners 158a are bolts and nuts, but it is contemplated that other kind of fasteners could be used such as, for instance, rivets. Other ways of connecting a body extension 130 of a screw pile are contemplated. As it will be appreciated, using body extensions 130 allows a greater onsite flexibility, similarly to the use of a removable helical member. Indeed, it becomes possible to have screw piles of variable length without having to carry or store pile bodies 16 of variable length. Further, the use of body extensions tends to facilitate the installation of long screw piles since the equipment used for installation (e.g. a mini-excavator provided with a hydraulic tool) does not need to be configured particularly to handle extra-long pile bodies, as it will become apparent below. Further, having a pile body made of two or more sections (e.g. one pile body and one or more body extensions) connected to each other via connecting portions 138 may strengthen long piles and reduce risks of movements of the pile. In such a case, the connecting portions would then act as a reinforced joint.

(37) Having described the general configuration of the screw pile 10, a method of installation and adjustment of the screw pile 10 will now be described. In a first step, a worker evaluates the conditions of the ground on which the structure needs to be supported. Based on his or her assessment, the worker selects the length of pile body 16 required to ensure that the helical member 14 will be positioned at an adequate depth, as well as proper helical member parameters to ensure adequate support (e.g. a larger helix diameter for heavy structure and/or soft soil). If the helical member is a removable helical member 100, the worker positions the sleeve portion 102 of the helical member 100 about the lower end 24 of the pile body 16, aligns the holes of the helical member 100 with those of the pile body 16 and engages the threaded fasteners 106a, 106b therein. Once the threaded fasteners (i.e. the bolts) are properly positioned in the holes, the installer secures the nuts. Where the helical member 14 is welded directly to the pile body 16, the installation step of the helical member 14 to the pile body 16 is generally carried out in a manufacturing plant rather than onsite.

(38) The pile body 16 provided with the helical member 14 or 100 is then inserted into the ground at a location corresponding to a location where they will be used as a support to the structure. A heavy duty machine such as a hydraulic rotating tool mounted on a small excavator is preferably used to rotate the pile body so that the helical member 14 or 100 mounted at the lower end 24 of the pile body 16 engages a portion of the soil and forces the helical member 14 or 100 and the pile body 16 attached thereto to move into the ground until reaching the desired depth. Once placed in the ground, the upper end 20 of the pile body 16 extends above the ground level.

(39) Based on the required screw pile length, the worker may choose to use one or more body extensions 130. If such is the case, the worker positions a body extension 130 to the top end 20 of the pile body 16 already installed in the soil. The worker aligns the pair of holes 154a, 154b and 156a, 156b of the connection portion 138 of the body extension 130 with the corresponding holes 42a, 42b and 44a, 44b, at the top end 20 of the pile body 16 (or of another body extension 130, if more than one body extensions are used). At that point, the worker positions fasteners 158a, 158b in the holes to secure the body extension 130 to the pile body 16, and the pile body 16 and the body extensions 130 are ready for a further installation operation. More specifically, the worker uses its rotating tool, this time mounted to the top end 132 of the body extension 130, to rotate the pile body 16 and the body extension 130 attached thereto, the helical member 14 or 100 forcing the pile body 16 and the extension 130 further deep into the ground.

(40) Once a proper length has been achieved, the pile head 12 is positioned on the upper end 20 of the pile body 16. More specifically, the sleeve portion 50 is engaged about the cylindrical wall 28 of the pile body 16 (or the cylindrical wall 136 of a body extension 130), until the bottom face 74 of the plate portion 70 abuts the top edge 22 of the pile body 16 (or of the body extension 130, as the case may be). At that point, the extendable portion 48 of the pile head 12 is adjusted to a desired height so that the screw pile 10 is properly leveled to receive a structure thereon.

(41) Once the structure is received on or supported by the extendable portion 48 of the pile head 12, it may become more difficult to fine tune a level adjustment, either because of the structure it is secured thereto (for instance a wooden beam secured to the plate of the extendable portion by way of screws), because the configuration of the extendable portion 48 does not permit rotation (e.g. a U-shaped supporting portion engaging two faces of a vertically extending wooden post) or because the weight of the supported structure causes a frictional engagement too significant to allow rotation of the extendable portion 48. Where such level fine tuning is required, the worker uses a tool such as a wrench engage the plate portion 70 and to rotate the mounting portion 46 of the pile head 12 relative to the pile body 16 (or the body extension 130, as the case may be), where rotation movement in one rotation direction causes an upward movement of the extendable portion 48 and while movement in the other rotation direction causes downward movement of the extendable portion 48. Once the height of the extendable portion 48 is proper, the worker secures the pile head 12 to pile body 16 (or the body extension 130, as the case may be) by fastening the bolts 66a, 66b into the bores 62a, 62b or 64a, 64b and holes 42a, 44a of the pile head 12 and pile body 16, respectively. By having the pile head 12 secured to the pile body 16 in this manner, as opposed to merely maintaining it by way of gravity, the pile head 12 is prevented from moving away from the pile body 16, in the longitudinal direction. As such, the screw pile can work both in compression and in tension, therefore allowing its use in a variety of applications, in addition to improve the safety. Further, it will be appreciated that such a pile head 12 configuration allows further level adjustments (e.g. after a number of soil freezing/unfreezing cycles or soil compaction over the years) and yet, preserve the above mentioned advantages. Where such further level adjustments are required, a worker simply removes the fasteners 66a, 66b, rotates the mounting portion 46 of the pile head 12 in the direction appropriate to reach the desired level, and secures back the fasteners 66a, 66b.

(42) Modifications and improvements to the above-described embodiments of the present may become apparent to those skilled in the art. The foregoing description is intended to be exemplary rather than limiting. The scope of the present is therefore intended to be limited solely by the scope of the appended claims.