Concrete sheet pile clamp assemblies and methods and pile driving systems for concrete sheet piles

Abstract

A clamp assembly for a pile driving system for driving a concrete sheet pile, the clamp assembly comprising a clamp body, a first clamp member supported relative to the clamp body, and a second clamp member supported for movement relative to the clamp body, and a bumper member. A clamp region is formed between the first and second clamp members. The bumper member is supported relative to the clamp body above the clamp region. The clamp body is configured such that the concrete sheet pile enters the clamp region from below. The second clamp member is displaced towards the first clamp member to engage the concrete sheet pile in the clamp region. The bumper member resiliently deforms to inhibit direct transmission of forces between the concrete sheet pile and the clamp body during driving of the concrete sheet pile.

Description

TECHNICAL FIELD

The present invention relates to pile driving systems and methods and, more particularly, to clamp systems and methods adapted to apply vibratory driving forces to concrete sheet piles.

BACKGROUND

Piles are often used in construction to support structures, roadways, earthworks, and the like. At least a portion of a pile is typically arranged within the ground. While a pile may be placed into an excavated hole, piles are typically driven into the ground by the application of a driving force to the top of the pile. The driving force may be one or more of static forces (e.g., weight of pile and pile driving equipment), impulse forces (e.g., drop hammer, diesel hammer), crowding forces (e.g., hydraulic ram), and vibratory forces (e.g., eccentric vibro). The exact nature of the driving force is typically selected for a particular type of pile and, to some extent, to a particular set of soil conditions.

A pile is typically driven by applying the driving force along a longitudinal axis of the pile being driven. As discussed above, a driving force applied to a pile to be driven often includes a vibratory force component. The vibratory force component results in forces being applied to the pile being driven in both directions along the longitudinal axis of the pile. Depending on the nature of the pile and soil composition, vibratory forces can significantly enhance the speed at which piles are driven. Vibratory forces can also be gentler on a pile structure being driven than, say, impulse forces.

Vibratory forces are highly appropriate for use with certain concrete piles and certain soil conditions. The present invention is of particular relevance in the context of applying a driving force having a vibratory force component to a concrete sheet pile. In general, a sheet pile may be characterized as having a width dimension that is significantly greater than a thickness dimension. Therefore, in comparison to a pile driver for cylindrical piles, at least a portion of a pile driving system for sheet piles is typically adapted to accommodate the wide and thin form factor of sheet piles. The form factor of a concrete sheet pile is also basically wide and thin, but a concrete sheet pile is typically a precast, reinforced, concrete structure.

In the context of concrete sheet piles being driven with a driving force having a vibratory force component, the pile driving system typically comprises a vibratory device and a clamp system. The vibratory device generates the vibratory force component, and the clamp system ensures that the vibratory forces are applied in both directions along the longitudinal axis of the pile being driven. The clamp system is adapted for the particular form factor of the pile being driven.

The need exists for improved pile driving systems and methods for concrete sheet piles and, more specifically, to clamp systems and methods for effectively applying the vibratory force component of a driving force to a concrete sheet pile with minimal damage to the concrete sheet pile.

SUMMARY

The present invention may be embodied as clamp assembly for a pile driving system for driving a concrete sheet pile. The clamp assembly comprises a clamp body, a first clamp member supported relative to the clamp body, and a second clamp member supported for movement relative to the clamp body, and a bumper member. A clamp region is formed between the first and second clamp members. The bumper member is supported relative to the clamp body above the clamp region. The clamp body is configured such that the concrete sheet pile enters the clamp region from below. The second clamp member is displaced towards the first clamp member to engage the concrete sheet pile in the clamp region. The bumper member resiliently deforms to inhibit direct transmission of forces between the concrete sheet pile and the clamp body during driving of the concrete sheet pile.

The present invention may also be embodied as method of clamping a concrete sheet pile to a pile driving system, the method comprising the following steps. A first clamp member is supported relative to a clamp body. A second clamp member is movably supported for movement relative to the clamp body such that a clamp region is formed between the first and second clamp members. A bumper member is supported relative to the clamp body above the clamp region. The concrete sheet pile is caused to enter the clamp region from below. The second clamp member is displaced towards the first clamp member to engage the concrete sheet pile in the clamp region. Direct transmission of forces between the concrete sheet pile and the clamp body is inhibited during driving of the concrete sheet pile by causing the bumper member to resiliently deform.

The present invention may be embodied as a pile driving system for driving a concrete sheet pile. The example pile driving assembly comprises a vibratory device and a clamp assembly. The clamp assembly comprises a clamp body operatively to the vibratory device, a first clamp member supported relative to the clamp body, a second clamp member supported for movement relative to the clamp body, and a bumper member supported relative to the clamp body above the clamp region. A clamp region is formed between the first and second clamp members. The clamp body is configured such that the concrete sheet pile enters the clamp region from below. The second clamp member is displaced towards the first clamp member to engage the concrete sheet pile in the clamp region. The vibratory device is operated to apply vibratory forces to the concrete sheet pile through the clamp body and the first and second clamp members. The bumper member resiliently deforms to inhibit direct transmission of forces between the concrete sheet pile and the clamp body during driving of the concrete sheet pile.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side elevation view of an example pile driving system and clamp system of the present invention for driving a concrete sheet pile;

FIG. 2 is top plan view highlighting one example concrete sheet pile such as the example concrete sheet pile of FIG. 1 in an overall installation of a plurality of similar concrete sheet piles;

FIG. 3 is a front elevation view of an upper end of the example concrete sheet pile of FIG. 1;

FIG. 4 is a side elevation section view taken along lines 4-4 in FIG. 3:

FIG. 5 is a top plan section view taken along lines 5-5 in FIG. 3;

FIG. 6 is a side elevation view of the example clamp system of FIG. 1 in an open configuration; and

FIG. 7 is a side elevation view similar to FIG. 6 illustrating the example clamp system in a clamped configuration relative to the example concrete pile as depicted in FIG. 1.

DETAILED DESCRIPTION

Referring initially to FIG. 1 of the drawing, depicted therein is a pile driving system 20 constructed in accordance with, and embodying, the principles of the present invention. The example pile driving system 20 is illustrated in connection with a pile 22 to be driven into the ground 24 at a desired location 26. The example pile 22 is a concrete sheet pile.

FIGS. 2-5 illustrate certain details of the example pile 22 driven by the example pile driving system 20. The pile 22 is not per se part of the present invention and may take on configurations other than those depicted in FIGS. 1-5, but an understanding of the example pile 22 will facilitate an understanding of the example pile driving system 20.

FIG. 1 illustrates that the example pile 22 is an elongate structure defining a longitudinal axis A extending along a lengthwise dimension L thereof. A first end portion 30 and a second end portion 32 are spaced at opposite ends of the pile 22 along the longitudinal axis A. The first end portion 30 is adapted to be engaged by the pile driving system 20 as will be described in further detail below. FIG. 5 illustrates that a width dimension W of the pile 22 is significantly larger than a thickness dimension T thereof.

FIGS. 2-5 further illustrate that the example pile 22 defines a center portion 40, first and second arm portions 42 and 44, and first and second edge portions 46 and 48. A gripping projection 50 extends from the center portion 40 at the first end portion 30 of the example pile 22. The gripping projection 50 further extends between the first and second arm portions 42 and 44 at the first end portion 30. A first edge projection 52 is formed on the first edge portion 46, and a second edge recess 54 is formed in the second edge portion 48. First and second engaging surfaces 60 and 62 are formed by the gripping projection 50 and the center portion 40 at the first end portion 30, respectively. An upper surface 64 is defined by the top of the pile 22. A transition surface 66 extends between the first engaging surface 60 and the center portion 40 outside of the first end portion 30 of the pile 22.

The engaging surfaces 60 and 62 are substantially parallel to each other, and the upper surface 64 is substantially orthogonal to the engaging surfaces 60 and 62. Typically, the engaging surfaces 60 and 62 are substantially vertical and the upper surface 64 is substantially horizontal when the pile 22 is driven into the ground 24.

With the foregoing discussion of the example concrete sheet pile 22 in mind, the details of construction and operation of the example pile driving system 20 will now be described in further detail with respect to FIGS. 1, 6, and 7.

As shown in FIG. 1, the example pile driving system 20 comprises a crane 120 from which a crane line 122 extends. A vibration suppressor 124 is connected to the crane line 122. A vibratory device 126 is connected to the vibration suppressor 124. A clamp 128 is connected to the vibratory device 126.

To prepare the example pile driving system 20 for use, the clamp 128 is rigidly connected to the vibratory device 126, and the vibratory device 126 is rigidly connected to the vibration suppressor 124. The vibration suppressor 124 is suspended from the crane 120 by the crane line 122. The example crane 120 takes the form of a tracked vehicle capable of moving across the ground 24. The clamp 128 is adapted to be substantially rigidly connected to the pile 22 as will be described in further detail below.

During use, the clamp 128 is rigidly connected to the pile 22, and the crane 120 is operated to suspend the pile 22 above the desired location 26 on the ground 24. The crane 120 is then operated such that the second end portion 32 of the pile is in contact with the ground 24 at the desired location 26. The vibratory device 126 is then operated such that the vibratory forces created by the vibratory device 126 are transmitted to the clamp 128 and to the pile 22. The vibratory forces created by the vibratory device 126 and the static forces created by the weight of the pile 22, clamp 128, vibratory device 126, and vibration suppressor 124 create a driving force that drives the pile 22 into the ground 24 at the desired location 26. The vibration suppressor 124 inhibits transmission of the vibratory forces from the vibratory device 126 to the crane line 122 and thus to the crane 120.

Referring now to FIGS. 6 and 7, it can be seen that the example clamp 128 comprises a clamp body 130, a first clamp member 132, a second clamp member 134, an actuator assembly 136, and a bumper assembly 138. The example actuator assembly 136 comprises an actuator 140 and an actuator shaft 142. The example actuator shaft 142 extends through an actuator opening 144 formed in the clamp body 130. The example actuator 140 is a hydraulically operated device that uses hydraulic pressure to displace the actuator shaft 142 relative to the actuator 140. The example bumper assembly 138 comprises a bumper base 150, a bumper member 152, and a bumper plate 154. The example clamp body 130 comprises a clamp body base portion 130a, a first clamp body arm 130b, and a second clamp body arm 130c. In the example clamp 128, the first clamp member 132 is rigidly connected to the first clamp body arm 130b, the second clamp member 134 is movably supported relative to the second clamp body arm 130c, and the bumper assembly 138 is rigidly connected to the clamp body base portion 130a.

The first clamp member 132 is rigidly connected to the clamp body 130 on one side of a clamp region 160. The actuator shaft 142 extends through the actuator opening 144 to an opposite side of the clamp region 160. The second clamp member 134 is rigidly connected to the actuator shaft 142 such that the second clamp member 134 is also on the opposite side of the clamp region 160 from the first clamp member 132. The first clamp member 132 defines first clamp surface 162, and the second clamp member 134 defines a second clamp surface 164. The example clamp surfaces 162 and 164 are substantially parallel to each other, and the clamp region 160 lies between these surfaces 162 and 164. In the example clamp 128, first, second, and third guide surfaces 170, 172, and 174 are formed to guide the pile 22 into the clamp region 160 as will be described in further detail below.

The example bumper member 152 is secured to the example bumper base 150 by any appropriate means such as adhesive, clamp, bolts, and the like. The example bumper member 152 is similarly secured to the example bumper plate 154 by any appropriate means such as adhesive, clamp, bolts, and the like. The example bumper base 150 is in turn secured to the clamp body 130 such that the bumper member 152 is arranged above the clamp region 160. The example bumper plate 154 defines a bumper surface 166 that is arranged to define an upper end of the clamp region 160. The example bumper surface 166 is substantially orthogonal to the first and second clamp surfaces 162 and 164. During driving of the pile 22, the first and second clamp surfaces 162 and 164 are substantially vertical, and the bumper surface 166 is substantially horizontal.

The bumper member 152 is made of a resiliently deformable material that is capable of absorbing at least a portion of shocks from external bodies coming into contact with the bumper member 152. The example bumper member 152 may be made of any resiliently deformable material capable of meeting the functional requirements as described below without substantial degradation in physical structure of the bumper member 152. As one example, the bumper member 152 may be made of a rubber-like elastomeric material. In particular, the bumper member 152 may be made of an elastomeric material similar to or the same as the material used in conventional vibration suppression systems for vibrational pile drivers.

In preparing to operate the pile driving system 20, the actuator 140 is initially operated to retract the actuator shaft 142 as depicted in FIG. 6 such that the clamp 128 is in an open configuration. In this open configuration, the first and second clamp surfaces 162 and 164 are spaced from each other such that the dimensions of the clamp region 160 are greatest. The crane 120 is displaced such that the first end portion 30 of the pile 22 enters the clamp region 160. Continued displacement of the clamp 128 relative to the pile 22 allows the bumper surface 166 to come into contact with the upper surface 64 of the pile 22.

The actuator 140 is then operated to displace the second clamp member 134 towards the first clamp member 132 such that the first and second clamp surfaces 162 and 164 come into contact with the first and second engaging surfaces 60 and 62. The actuator assembly 136 thus applies a clamping force on the center portion 40 and gripping projection 50 of the pile 22 that securely holds the pile 22 relative to the clamp 128. The pile 22 may then be lifted into position above the desired location 26 and lowered until the second end portion 32 contacts the ground 24 at the desired location 26.

The crane 120 is then used to suspend the pile 22 at a desired orientation and the vibratory device 126 is operated. The vibratory forces generated by the vibratory device 126 are transmitted to the pile 22 through the clamp 128. The vibratory forces, along with static force generated by the weight of the pile 22, vibration suppressor 124, vibratory device 126, and clamp 128, create the driving force that drives the pile 22 into position at the desired location. With the example pile 22, the desired position is typically next to an adjacent pile 22 as shown in FIG. 2 such that the first edge projection 52 of one of the piles 22 is received by the second edge recess 54 of an adjacent one of the piles 22.

Further, the first and second clamp surfaces 162 and 164 are sized, dimensioned, and/or configured to minimize slippage between the clamp 128 and the pile 22. However, if such slippage does occur, which is likely under wet, muddy conditions, the bumper plate 154 comes into contact with the upper surface 64 of the pile 22. Should slippage occur and the bumper plate 154 come into contact with the upper surface 64, the bumper member 152 resiliently deforms to absorb shocks that would otherwise be transmitted to the upper surface 64, possibly damaging the pile 22.

Claims

1. A clamp assembly for a pile driving system for driving a concrete sheet pile, the clamp assembly comprising: a clamp body;a first clamp member supported relative to the clamp body; anda second clamp member supported for movement relative to the clamp body, where a clamp region is formed between the first and second clamp members; anda bumper member is supported relative to the clamp body above the clamp region;a bumper plate is secured to the bumper member;the clamp body is configured such that the concrete sheet pile enters the clamp region from below; whereinthe second clamp member is displaced towards the first clamp member to engage the concrete sheet pile in the clamp region;the bumper date is arranged to come into contact with the concrete sheet pile during transmission of forces between the concrete sheet pile and the bumper member such that, if slippage occurs between the concrete sheet pile and the clamp assembly when a driving force is being applied through the clamp assembly to the concrete sheet pile, the bumper member resiliently deforms to absorb shocks that would otherwise be transmitted to the upper surface and possibly damage the concrete sheet pile.

2. The clamp assembly as recited in claim 1, further comprising an actuator member configured to displace the second clamp member towards the first clamp member.

3. The clamp assembly as recited in claim 1, further comprising a bumper base, wherein: the bumper member is secured to the bumper base; andthe bumper base is secured to the clamp body.

4. The clamp assembly as recited in claim 1, in which the clamp body comprises: a clamp body base;a first clamp body arm; anda second clamp body arm; whereinthe first clamp member is rigidly connected to the first clamp body arm;the second clamp member is movably supported by the second clamp body arm; andthe bumper member is supported by the clamp body base.

5. The clamp assembly as recited in claim 4, further comprising an actuator member mounted on the second clamp body arm, where the actuator member is configured to displace the second clamp member towards the first clamp member.

6. A method of clamping a concrete sheet pile to a pile driving system, the method comprising the steps of: providing a clamp body;supporting a first clamp member relative to the clamp body; andmovably supporting a second clamp member for movement relative to the clamp body such that a clamp region is formed between the first and second clamp members;supporting a bumper member relative to the clamp body above the clamp region;causing the concrete sheet pile to enter the clamp region from below;displacing the second clamp member towards the first clamp member to engage the concrete sheet pile in the clamp region; and if slippage occurs between the concrete sheet pile and the clamp assembly when a driving force is being applied through the clamp assembly to the concrete sheet pile, the bumper member resiliently deforms to absorb shocks that would otherwise be transmitted to the upper surface and possibly damage the concrete sheet pile; andsecuring a bumper late to the bumper member such that the bumper plate comes into contact with the concrete sheet pile during transmission of forces between the concrete sheet pile and the bumper member.

7. The method as recited in claim 6, further comprising the step of arranging an actuator member displace the second clamp member towards the first clamp member.

8. The method as recited in claim 6, further comprising the steps of: securing the bumper member to a bumper base; andsecuring the bumper base to the clamp body.

9. The method as recited in claim 6, in which the step of supporting a bumper member relative to the clamp body comprises the steps of rigidly connecting the first clamp member is rigidly to a first clamp body arm of the clamp body;movably supporting the second clamp member on a second clamp body arm of the clamp body;securing the bumper member to a bumper base; andthe bumper member is supported by securing the bumper base to the clamp body.

10. The method as recited in claim 9, further comprising the steps of: mounting an actuator member on the second clamp body arm; andconfiguring the actuator member to displace the second clamp member towards the first clamp member.

11. A pile driving system for driving a concrete sheet pile, the pile driving assembly comprising: a vibratory device;a clamp assembly comprising a clamp body operatively to the vibratory device;a first clamp member supported relative to the clamp body;a second clamp member supported for movement relative to the clamp body, where a clamp region is formed between the first and second clamp members;a bumper member supported relative to the clamp body above the clamp region; anda bumper plate is secured to the bumper member; whereinthe clamp body is configured such that the concrete sheet pile enters the clamp region from below;the second clamp member is displaced towards the first clamp member to engage the concrete sheet pile in the clamp region;the vibratory device is operated to apply vibratory forces to the concrete sheet pile through the clamp body and the first and second clamp members; andthe bumper plate is arranged to come into contact with the concrete sheet pile during transmission of forces between the concrete sheet pile and the bumper member such that, if slippage occurs between the concrete sheet pile and the clamp assembly when a driving force is being applied through the clamp assembly to the concrete sheet pile, the bumper member resiliently deforms to absorb shocks that would otherwise be transmitted to the upper surface and possibly damage the concrete sheet pile.

12. The pile driving system as recited in claim 11, further comprising: a vibratory suppression assembly operatively connected to the vibratory device; anda crane operatively connected to the vibratory suppression assembly; wherethe crane supports the vibratory suppression assembly, the vibratory device, the clamp assembly, and concrete sheet pile during driving of the concrete sheet pile.

13. The pile driving system as recited in claim 11, in which the clamp assembly further comprises a bumper base, wherein: the bumper member is secured to the bumper base; andthe bumper base is secured to the clamp body.

14. The pile driving system as recited in claim 11, in which the clamp body comprises: a clamp body base;a first clamp body arm; anda second clamp body arm; whereinthe vibratory device is rigidly connected to the clamp body base;the first clamp member is rigidly connected to the first clamp body arm;the second clamp member is movably supported by the second clamp body arm; and the bumper member is supported by the clamp body base.