The present invention relates to the treatment of reinforced concrete piles after driving. BACKGROUND

In the use of reinforced concrete piles for supporting buildings, it is common practice to drive the piles and then to cutoff the amount of pile projecting above the desired finished level. This removal of the undesired pile portion involves cutting the pile at a cutoff level and then removing the concrete down to the finished level, exposing length of the reinforcement for incorporation into a subsequently poured concrete structure.

Conventionally, piles are cutoff using explosives. The concrete is removed to the finished level using a jackhammer. This procedure is time consuming and costly. In most cases, it is necessary to obtain a permit for the necessary blasting. In addition, the shock waves caused by the blasting can damage the pile. While mechanical cutters have been proposed for cutting off piles, these have not proven entirely satisfactory because they are difficult to use, especially where access to piles is restricted. They do not address the problem of removing concrete from the reinforcement down to the finished level. SUMMARY

According to one aspect of the present invention there is provided a method of prep_ ing an end of a pile comprising a concrete matrix and elongate reinforcement therein, said method comprising: providing a plurality of blades, oriented transversely of the pile at a selected position along the pile; transversely breaking the concrete matrix at the selected position by

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driving the blade into the surface of the concrete matrix around the periphery of the pile, without engaging the reinforcement; providing a concrete breaker means adjacent the pile and extending between the end of the pile and selected position; fracturing the concrete matrix between the end of the pile and the selected position along the pile by driving the breaker means into engagement with the concrete matrix; and removing the fractured concrete to expose the reinforcement. According to another aspect of the present invention there is provided apparatus for preparing an end of a pile comprising a concrete matrix and longitudinal reinforcement embedded therein, said apparatus comprising: a plurality of blades having respective cutting edges; means for mounting the blades around the pile and at a selected position along the pile with the cutting edges confronting the pile; means for driving the cutting edges of the blades into the surface of the concrete matrix around the periphery of the pile; concrete breaker means; means for mounting the breaker means adjacent the pile and between the end of the pile and the selected position; means for driving the breaker means into engagement with the concrete matrix.

In preferred embodiments of the apparatus, the blades are shaped to match the profile of the pile and are wedge shaped in section so that as they are driven into the surface of the pile, tension is applied to the concrete matrix, causing it to fracture generally

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in the plane of the blades. The breakers are preferably mounted with the blades and operate simultaneously with them so that in a single actuation of the apparatus, the concrete above the finished level is separated from the remainder of the pile and broken into fragments.

It is also preferred that the apparatus be constructed using a frame and drivers that will accommodate a shear blade and an anvil for cutting off the pile. BRIEF DESCRIPTION OF ..E DRAWINGS

In the accompanying drawings, which illustrate exemplary embodiments of the present invention,

Figure 1 is a plan view of an apparatus for cutting off a pile end according to the present invention;

Figure 2 is a cross-section along line 2-2 of Figure 1;

Figure 3 is a side elevation of the apparatus of Figure 1;

Figure 4 is an end elevation of the apparatus of Figure 1;

Figure 5 is a cross-section along line 5-5 of Figure 1;

Figure 6 is a plan view of a set of blades and breakers for cutting and breaking the concrete pile;

Figure 7 is a cross-sectional elevation showing the use of the apparatus using the blades illustrated in Figure 6;

Figure 8 is a plan view of a second embodiment of the blades and breakers;

Figure 9 is a cross section along line 9-9 of Figure 8;

Figure 10 is a plan view of a centering anvil for use with the shear blade of Figure 1; and

Figure 11 is a front elevation of an anvil of Figure 10; and

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DETAΓLED DESCRIPΉQN

Referring to the accompanying drawings, especially Figures 1 through 4, there is illustrated a pile cutter 10 having a rectangular frame 12 with a head end 14, two side rails 16 and 18 and a foot end 20. As illustrated in Figures 1 through 4 the frame accommodates a sliding shear blade 22 and an anvil 24 on the head end 14, confronting the blade. The shear blade is connected to two hydraulic cylinders 26 that extend between the blade and the foot end 20 of the frame. When the cylinders are extended, they drive the blade forwards, into engagement with the anvil 24.

As illustrated most particularly in Figure 2, the foot end of the frame 12 is composed of two plates 27 that are on opposite sides of an end plate 28 and fastened in place by a series of bolts 29. The plates 27 and 28 form a channel 30 opening forwardly into the centre of the rectangular frame for receiving the ends of the hydraulic cylinders as illustrated in Figure 1. Vertical plates 31 form pockets in the channel for seating the cylinder ends.

Each of the side rails 16 and 18 has a centre plate 32 extending from end to end. On either side of the centre plate 32 is a wear plate 34. The wear plates are wider than the centre plate as illustrated most particularly in Figure 5. Each wear plate is covered with an angle 36 that extends between the head 14 and foot 20 of the frame. The angles and plates of each side rail are connected using bolts 37. Between the wear plates, the side rail has a channel 38 that accomodates the edge of the shear blade 22 and guides it as it slides in the frame towards the anvil.

Near the head end of the frame, the side rails are reinforced with plates 40 and 42 fastened in place on top of the horizontal flanges of the angles 36. The plates 40 and 42 project beyond the end of the angles 36 to the head end of the frame. The head

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end, as illustrated in Figure 2 has a centre plate 44 between two wider plates 46, in turn sandwiched between two thinner plates 48. An angle 50 is superimposed on each plate 48 to complete the head of the frame.

As illustrated most particularly in Figure 4, the centre plate 44 and plates 46 extend beyond the end of the plate 48 and angles 50, between the extended ends of the plates 40 and 42. The head is connected to the side rails by bolts 54. The anvil 24 is mounted on the face of the vertical flanges of angles 50.

The configuration of the shear blade is most clearly illustrated in Figure 2. The cutting edge 56 of the blade is an assymmetric bevel, a long bevel 58 extending from the top face of the blade the edge and a shorter bevel 60 along the bottom. The bevelling along the cutting edge is assymmetrical as shown so that the blade not will have a tendency to be cammed up as it is being driven through the concrete pile. The blade serves to sever the concrete matrix as well as the steel reinforcement cables of the pile.

Once the top of the pile has been cut off, the blade 22 and anvil 24 may be removed from the frame and replaced with a second set of tooling for removing the concrete matrix from the reinforcement above a selected level. A set of blades for this purpose is illustrated in Figures 6 and 7. It includes a blade 62 that replaces the shear blade 22 and a blade 64 that replaces the anvil 24. Each blade has a cutting edge 66 that matches the profile of one-half of the pile 68 (Figure 1). The illustrated pile is hexagonal and each of the blades has a half hexagonal edge.

As illustrated most particularly in Figure 7, each of the blades has a flat bottom surface 70 and a bevel 72 along the top surface, adjacent the cutting edge. The blade 62 slides in the channels 38 of the side rails like the shear blade 22. The blade 64 is set into the channel in the head of the frame that is exposed when the anvil is removed.

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This is most clearly shown in Figure 7. Two additional shim plates 73 are inserted between the blade and the plates 46. Two pins 74 extend through holes 76 in the blade and through mating holes in the frame head to keep the blade 64 in place. These pins do not take a great deal of stress and serve primarily to keep the blade attached to the head when the blades are withdrawn from the pile.

Blade 62 has a rectangular stop 78 mounted on its top surface. This engages the back edge of a bracket 80 fastened to the top of the blade. The bracket includes an angle 82 with a horizontal flange on top of the blade and a vertical flange projecting upwardly from the top of the blade. The vertical flange is supported by gussets 84. The bracket is fastened to the blade by two bolts 86.

A concrete breaker 88 is mounted on the bracket 80. This is an upright section of angle 90 fastened to the front face of the bracket. The leading edge 91 of the breaker slopes rearwardly away from the cutting edge, with the bottom of the leading edge, located slightly behind the cutting edge of the blade of blade 62, with the bottom of the leading edge located slight behind the cutting edge of the blade. A second breaker 92 is mounted on the head of the frame above blade 64. The second breaker is a section of angle 94 formed with a hook 96 at the top, rear of the flanges for engagement over the vertical flange of the upper angle 50 as illustrated in full in Figure 7 and ghost line in Figure 6.

The blades 60 and 62 and the associated breakers are used as illustrated in Figure 7. The blades are located below the position 98 where the pile has been severed by the severing blade 22. The blades 63 and 64 are driven into the surface of the pile at a finished level 100. As the blades penetrate the surface of the concrete matrix, the wedging action produced by the bevel 72 on each blade applies tension on the concrete matrix of the

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pile, splitting the concrete at the plane of the blades. The blades do not penetrate far enough into the concrete to engage the reinforcement strands 102. The two breakers are also driven against opposite sides of the concrete and produce high local stresses that will fracture the concrete matrix off of the reinforcement. The cutter may then be lifted as a unit to pull the broken concrete off the reinforcement. This progress may be repeated to expose as much reinforcement as is required.

A second embodiment of the breaker is illustrated in Figure 8 and 9. In this embodiment, a breaker 104 is mounted on the blades 62. It is similar to the breaker 88 but has two side by side angles 106 on the face of the bracket. Two concrete retaining plates 107 that extend outwardly from the other sides of the angles. These act to retain loose concrete and assist in lifting it off the reinforcement.

Blade 64 in this embodiment carries a breaker 108 consisting of two upright angles 110 mounted on the front of a vertical flange of a mounting angle 112. Two retaining plates 113 extend outwardly from the outer sides of the angles 110. The angle 112 also has a horizontal flange at the top that extends over the top of the head angle 50 and is secured to a bracket 114 by a bolt 116. The bracket is mounted on the back of the angle 50, which is reinforced with a series of gussets 118. In this embodiment, bolts 120 extend through the angle 50, through the plates 48 and into plates 46 above and below the blade 64. Additional bolts 122 extend through the angles, the plates and the centre plate of the frame head.

The double breaker is used for breaking piles of a larger size than th. _e accommodated by the single angle breaker of the previous embodiment.

Figures 10 and 11 illustrate a centering guide and anvil 124 for use with the shearing blade of Figures 1 and 2. The unit includes a base plate 126 that mounts on the

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head of the frame in place of the anvil 24. The base plate has a series of four bolsters 128 on its front face. The bolsters have angled front faces that match the configuration of the pile so as to engage around a side of the pile and centre the frame properly on the pile for cutting purposes. Two flanges 130 project from opposite sides of the bolsters at the top to rest on the side rails of the frame. Two lugs 132 project from the back face of the base plate 126 to be bolted to the frame head. The bolsters are arranged in vertically spaced pairs leaving a slot 134 across the middle of the unit to accommodate the shear blade 22.

While particular embodiments of the invention have been described in the foregoing, it is to be understood that other embodiments are possible within the scope of the invention. Thus, for example, particular reference has been made to an hexagonal pile. Other pile shapes are known however, and may be processed according to the invention using blades that are shaped to match the cross-sectional profile of the pile. It is therefore to be understood that the invention is to be construed as limited solely by the scope of the appended claims.

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