AN END PLATE SYSTEM FOR JOINING SPUN PILES

Abstract

The present invention discloses an end plate system for joining spun piles together comprises a top end plate (100) mounted at a bottom end of a first spun pile: and a bottom end plate (200) mounted at a top end of a second spun pile; wherein the end plates (100, 200) respectively have an interlocking surface that is formed with a plurality of segmental protrusions (110, 210) and segmental recesses (120, 220) arranged in an alternate configuration; characterized in that each segmental protrusion (110, 210) has a first radial interlocking profile (111, 211) and a second radial interlocking profile (112, 212) that extend towards the central portion of the end plates (100, 200); wherein the top end plate (100) and the bottom end plate (200) are mated by registering the segmental protrusion (110, 210) of one end plate to the segmental recess (120, 220) of another end plate and through a rotating movement about the central axis of the mated end plates (100, 200), a first interlocking joint (300) is formed by two adjacent first radial interlocking profiles (111, 211) in full surface contact, and a second interlocking joint (400) is created by inserting a pin (402) into a passageway (401) formed between two adjacent second radial interlocking profiles (112, 212).

Claims

1. An end plate system for joining spun piles together comprising: a top end plate (100) mounted at a bottom end of a first spun pile; and a bottom mi plate (200) mounted at a tip end of a second spun pile; wherein the end plates (100, 200) respectively have an interlocking surface that is formed with a plurality of segmental protrusions (110, 210) and segmental recesses (120, 220) arranged in an alternate configuration; characterized in that each segmental protrusion (110, 210) has a first radial interlocking profile (111, 211) and a second radial interlocking profile (112, 212) that extend towards the central portion of the end plates (100, 200); wherein the top end plate (100) and the bottom end plate (200) are mated by registering the segmental protrusion (110, 210) of one end plate to the segmental recess (120, 220) of another end plate and through a rotating movement about the central axis of the mated end plates (100, 200), a fin* interlocking joint (300) is formed by two adjacent first radial interlocking profiles (ill, 211) in full surface contact, and a second interlocking joint (400) is created by inserting a pin (402) into a passageway (401) formed between two adjacent second radial interlocking profiles (112, 212).

2. The end plate system according to claim 1, wherein the first radial interlocking profiles (111, 211) are identical to the second radial interlocking profiles (112, 212) so that the end plates (100, 200) are rotated in either a clockwise or an anticlockwise direction to from the first and second interlocking joints (300, 400).

3. The end plate system according to claim 1, wherein the first radial interlocking profiles (111, 211) are configured in Z-shape, semi-circular shape, ledge shape, triangular shape, tilted semi-rectangular shape, S-shape, C-shape, tongue and groove a-like shape or in any combination thereof.

4. The end plate system according to claim 1, wherein the second radial interlocking profiles (112, 212) ate configured in parallelogram shape, wave shape, circular shape, oval shape, polygonal shape, triangular shape, square shape, rectangular shape, or in any combination thereof.

5. The end plate system according to claim 3 and claim 4, wherein the first radial interlocking profiles (111, 211) are not identical to the second radial interlocking profiles (112, 212).

6. The end plate system according to claim 1, wherein the second radial interlocking profiles (112, 212) and the pins (402) are tapered.

7. The end plate system according to claim 1, wherein the first and second radial interlocking profiles (111, 211, 112, 212) are formed by hot forging process or cold form press.

8. The end plate system according to claim 4, wherein the first radial interlocking profiles (111, 211) are not identical to the second radial interlocking profiles (112, 212).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] For the purpose of facilitating an understanding of the invention, there is illustrated in the accompanying drawing the preferred embodiments from an inspection of which when considered in connection with the following description, the invention, its construction and operation and many of its advantages would be readily understood and appreciated.

[0021] FIG. 1-1C illustrate a perspective view of the end plates in a mated configuration and enlarge views respectively taken from a first radial interlocking profiles and a second radial interlocking profiles resisting an axial pulling tension force.

[0022] FIG. 2A illustrates a top perspective view of the end plates in the mated configuration by laying the segmental protrusion of one end plate to the segmental recess of another end plate.

[0023] FIG. 2B illustrates a side view of the end plates in the mated configuration.

[0024] FIG. 3A illustrates a top perspective view of the mated end plates in an interlocking configuration by a rotation movement which embodies therein the principle features of the invention.

[0025] FIG. 3B illustrates a side view of the mated end plates in an interlocking configuration.

[0026] FIG. 3C is an enlarged view taken from section A of FIG. 2A.

[0027] FIG. 4A-4H illustrate eight examples of shapes formed by two adjacent first radial interlocking profiles of the end plates.

[0028] FIG. 5A-5H illustrate eight examples of shapes formed by two adjacent second radial interlocking profiles of the end plates.

DETAILED DESCRIPTION OF THE INVENTION

[0029] The invention will now be described in greater detail, by way of example, with reference to the drawings.

[0030] Referring to FIGS. 1 to 3, the end plate system for joining concrete piles as illustrated therein comprises a top end plate 100 which is mounted at the bottom end of a first pile, a bottom end plate 200 which is mounted at the bottom end of a second pile, the end plates 100, 200 respectively have an interlocking surface that carries a plurality of segmental protrusions 110, 210 and segmental recesses 120, 220 arranged in an alternate configuration, each segmental protrusion 110, 210 has a first radial interlocking profile 111, 211 and a second radial interlocking profile 112, 212 that extend towards the central region of the end plates 100, 200. The central region preferably includes a centre point of the end plates or the surrounding areas of the centre point whereby the longitudinal axis of the pins may be inclined radially surrounding the centre point of the mated endplates.

[0031] Preferably, the opening of each recess 120, 220 is dimensioned sufficiently to receive a segmental protrusion 110, 210. The top and bottom end plates 100, 200 are mated by registering the segmental protrusion 110, 210 of one end plate to the segmental recess 120, 220 of another end plate. Immediately after the mating of the two end plates 100, 200, each pair of adjacent radial interlocking profiles 111, 211 112, 212 forms a gap therebetween allowing the mated end plates 100, 200 to be rotated or twisted slightly about the centre axis of the end plates 100, 200 in either clockwise or anticlockwise direction. Each segmental protrusion 110, 210 and recesses 120, 220 are fabricated with a plurality of holes 130 for receiving rebars of the piles. The holes 130 are arranged in a configuration such that the rebars of the pre-stressed spun pile can be pre-tensioned and locked into the array of holes 130 and this pre-tensioned force which can be carried across the end plates 100, 200 through the jamming of pins 402.

[0032] Whilst the application of the present invention is not limited to certain type of pile, the annular shape of the end plates 100, 200 with the central opening makes the present invention suitable to be employed as a pile connector for spun piles as spun piles are constructed in round and hollow in cross section. However, it should be noted that the end plates 100, 200 can be of various shapes, including square, hexagonal, and triangle.

[0033] As shown in FIGS. 3A to 3C, through a rotation movement about the central axis of the mated end plates 100, 200, the first interlocking joint 300 is formed by a pair of adjacent first radial interlocking profiles 111, 211 in full surface contact, and a second interlocking joint 400 is created by inserting a pin 402 into a passageway 401 formed between two adjacent second radial interlocking profiles 112, 212. The first interlocking joint 300 effectively prevents the end plates 100, 200 from further movement while the pins 402 are being hammered into the passageways 401. The first interlocking joint 300 is interlocked without pins 402 and it is even stronger than the second interlocking joint 400 to sustain stresses and resist bending and pulling forces.

[0034] Preferably, the second radial interlocking profiles 112, 212 are tapered by a small degree that is sufficient to allow the pin 402 to be held in friction when jammed into the passageway 401. This tapered feature is constructed to provide tolerance for easy insertion of the pins 402 as well as for fitting the segmental protrusions 110, 210 of the end plates 100, 200 to the segmental recesses 120, 220. The surface of the pins 402 are preferably able to engage and lock in full surface contact with the corresponding passageways 401 to provide contact bearing resisting forces against the bending movement and axial force along the pile.

[0035] As shown in FIGS. 4A to 4H, the first radial interlocking profiles 111, 211 can be respectively configured in Z-shape, semi-circular shape, ledge shape, triangular shape, tilted semi-rectangular shape, S-shape. C-shape, tongue and groove a-like shape or any combination thereof. As shown in FIGS. 5A to 5H, the second radial interlocking profiles 112, 212 can be respectively configured in parallelogram shape, wave shape, circular shape, oval shape, polygonal shape, triangular shape, square shape, rectangular shape or any combination thereof. Preferably, the first and second radial interlocking profiles 111, 211, 112, 212 can have a same interlocking profile with symmetry in the cross-section about the x-axis and y-axis at the mid-point in the interlocking profile, where the z-axis is taken to be perpendicular to the surface plane of the endplates so that any of the radial interlocking profiles 111, 211, 112, 212 can be transformed into either the first interlocking joint 300 or the second interlocking joint 400. As such, the end plates 1.00, 200 can be rotated in both directions to form the first and second interlocking joints 300, 400.

TECHNICAL ASPECTS OF THE INVENTION

[0036] The interlocked endplates 100, 200 in FIG. 1 has been designed to exceed the main body of the pile in axial tension, bending, twisting and axial compression. To securely interlock the mated endplates 100, 200, a tapered locking pin 402 can be inserted to any of the openings of the passageway 401. As seen in FIG. 1A and FIG. 1B, the passageway on one side of the mated endplates 100, 200 is jammed with a tapered locking pin 402 and the opposite side as in FIG. 1C experienced an equal opposite jamming force thereby binding the two-contacting first adjacent radial interlocking profiles 111, 211 in the segmental protrusions 110, 210 of the top and bottom endplates 100, 200 together. It is noted in FIG. 5B, that when the endplates 100, 200 undergoes a tension force or bending, it resulted in a large rotational moment caused by the pulling tension force in the z-axis perpendicular to the surface plane of the mated endplates that rotates the tapered locking pin 402 along the longitudinal axis causing deformation stresses in the contacting surfaces 112, 212 between the passageways of the protrusions 110, 210 and tapered locking pin 402. This is unlike the endplates 100, 200 in FIG. 1C wherein the opposite two-contacting first adjacent radial interlocking profiles 111, 211 binds together without the tapered locking pin 402 to experience pure vertical shear. Through the interlocking of the pure vertical shear in two-contacting first adjacent radial interlocking profiles 111, 211 of the protrusions 110, 210, it can withstand very large pulling tension forces and hence strengthened the weaker interlocked tapered locking pin 402 to produce a more superior endplate joint. As seen in the detail in FIG. 1B, the rotation force becomes more significant as the width of the tapered locking pin 402, W becomes larger. It is therefore the object of this invention to reduce the ratio of width to the height of the tapered locking pin 402, W/H to be preferably less than 1 at the largest end of the tapered locking pin 402, and yet provide sufficient clearance for the top and bottom endplates 100, 200 to be mated. Therefore, the shape of the pin 402 must have a small taper and be slender, also it must be mentioned that towards the tapering end of the tapered locking pin 402, the ratio of W/H is considerably less than 0.5. Thus, by jamming the tapered locking pin 402 into the opening using a hammer or any horizontal force the friction resistance is more than sufficient to prevent it from being permanently dislodged.

[0037] A single stage hot forging process is preferred to the costlier multiple hot forging stages using multiple moulds to allow the complexities of having different thickness and shapes in the forged work piece. In this present invention, unlike as in a casting process, the shape of the endplates 100, 200 in the present invention is dictated by the material flow displacement in the steel annulus plate of uniform thickness under a single stage Hot Forging Closed Mold process. It is preferable to start the forging work piece as a pre-formed annulus plate, therefore in this process of forging manufacturing, the endplates 100, 200 are specially restricted to have more uniform thickness and lower embossed material flows to create small localised increased thickness, unlike as in the casting process which can produce vastly different thickness and width as required for the joints in the prior arts. This single stage Hot Forging Closed Mold process however has a great advantage as it dramatically reduces the costs and increase speed of mass manufacturing as compared to casting or machining from a solid piece.

[0038] For thinner endplates, it may be cold form under heavy press to bend the endplates 100, 200 into the interlocking profile edges 111, 211, 112, 212. However, the material flows are limited, thereby it may not possible to create large embossment.

[0039] The present disclosure includes as contained in the appended claims, as well as that of the foregoing description. Although this invention has been described in its preferred form with a degree of particularity, it is understood that the present disclosure of the preferred form has been made only by way of example and that numerous changes in the details of construction and the combination and arrangements of parts may be resorted to without departing from the scope of the invention.