The present invention relates to pile handling systems and methods and, more specifically, to pile handling systems and methods that allow piles to be gripped from the side or the top and which use a combination of driving and vibratory forces to drive the pile.
Modern construction design often requires piles to be driven into the earth at desired locations. In the context of the present invention, the term “pile” will be used to refer to a rigid, elongate member capable of being driven into the earth. Piles may take many forms and are normally used as part of the footing for a structural element such as a building foundation or bridge pier, but piles may be used for many reasons, and the end use of the pile is not a part of the present invention.
The term “drive” as used herein refers to the application of a force along a longitudinal axis of the pile either to force the pile into the earth or to extract the pile from the earth. The terms “handle” or “handling” as used herein refer both to the driving of a pile into the earth and to the movement of pile prior to driving.
The present invention is of particular significance when the pile takes the form of a steel H-beam, and that application will be described herein in detail. However, the principles of the present invention may be applied to other pile configurations, such as cylindrical piles (e.g., wooden piles, pipe piles, caissons, etc.) and/or sheet piles.
Pile handling systems that use vibratory loads in combination with driving loads are highly effective at forcing piles into or extracting piles from the earth. The vibratory forces of such vibratory pile driving systems are transmitted to the pile to be driven by a clamping assembly. The to clamping assembly ensures that the vibratory forces in both directions are applied to the pile to be driven.
Conventional clamping assemblies engage an end of the pile such that the driving and vibratory forces are applied along an axis of the pile. Some specialized pile handling systems employ clamping assemblies that are adapted to grip a side of the pile. Other specialized pile handling systems employ clamping assemblies that are adapted to grip either a side or an end of the pile. The ability to grab either the side or the end of a pile facilitates both moving of the pile prior to driving and driving of the pile without the use of additional equipment. The present invention relates to pile handling systems having clamping assemblies that are adapted to grip either the side or the end of the pile.
The need exists for improved pile handling systems capable of gripping a pile from either the side or the top and driving the pile with a combination of driving and vibration forces.
A pile driving system comprising an engaging system comprising a suspension system, a vibratory system, and first and second clamp assemblies. The primary housing is operatively supported by an arm assembly of a support system. The suspension system is configured to resiliently oppose movement of a secondary housing within a limited range of movement relative to a primary housing. The vibratory system is rigidly connected to the secondary housing. The first and second clamp assemblies are supported by the secondary housing. In a first mode, the first clamp assembly rigidly connects the secondary housing to the pile, and in a second mode the second clamp assembly rigidly connects the secondary housing to the pile. The pile driving system drives the pile using a driving force generated by the support system and/or a vibrational to force generated by the vibratory system.
Referring initially to
The pile handling system 20 comprises a support system 30 and a main assembly 32. The support system 30 is or may be conventional and will be described herein only to the extent necessary for a complete understanding of the present invention. As shown in
The main assembly 32 comprises a coupling assembly 50 and an engaging system 52. The coupling assembly 50 is adapted to allow the engaging system 52 to be attached to the support system 30. In particular, the coupling assembly 50 comprises a yoke member 60, a coupler mount 62, and first and second lateral actuator assemblies 64 and 66. The yoke member 60 is connected to the distal arm member 44 by an arm pin 70 and to the linkage assembly 46 by a linkage pin 72.
As shown in
Referring now to
Referring now to
The coupling assembly 50 thus attaches the engaging system 52 to the arm assembly 42 such that the engaging system 52 may be displaced in many different positions relative to the vehicle 40 in addition to those positions allowed by the conventional arm assembly 42 of the support system 30.
Referring now for a moment back to
While the secondary housing 122 generally moves with the primary housing 120 relative to the axis B, C, and D, the suspension system 124 allows the secondary housing 122 to move within a limited range of movement relative to the primary housing 120. In particular, the elastomeric members resiliently oppose movement of the secondary housing 122 relative to the primary housing 120. As will be described in further detail below, the secondary housing 122 vibrates during normal operation of the engaging system 52, and the suspension system 124 inhibits transmission of these vibrations to the primary housing 120 and thus the support system 30 connected thereto.
As perhaps best shown in
The number of elastomeric members 126 determines the amount of shock absorption provided by the suspension system 124. In the example main assembly 32 depicted in
As perhaps best shown in
Referring now to
The arm grip assembly 146 comprises a pair of movable grip members 150a and 150b, while the stop grip assembly 148 comprises a pair of fixed grip members 152a and 152b. These example grip members 150a,b and 152a,b are rectangular rigid members adapted to securely grip the pile 22 to transmit both driving and vibratory forces to the pile 22, but other shapes and configurations may be used. The use of different materials, surface treatments, and/or texturing on the surfaces of the grip members 150a,b and 152a,b can help increase friction between the engaging system 52 and the pile 22. The pairs of grip members 150a,b and 152a,b defines upper and lower first gripping locations X1 and X2 as shown for example in
In addition, the example arm grip assembly 146 comprises a first pick member 154, while the example stop grip assembly 148 comprises a second pick member 156. The pick members 154 and 156 define tip portions 154a and 156a that can be used to move piles under certain circumstances. The pick members 154 and 156 allow the side clamp system 130 to pick one, two, or more sheet piles from a nested stack of such piles. For example,
Referring now to
The bottom clamp actuator assembly 164 is configured such that extension thereof causes the moveable clamp member 162 to engage the fixed clamp member 160 in a second clamp plane F2 defined by the fixed clamp member 160. In particular, the clamp members 160 and 162 engage each other at a third gripping location Y. The third gripping location Y lies in the second clamp plane F2. As shown in
Referring back to
Referring now to
The vibrational system 134 is contained within a vibro housing 186 attached to or formed as part of the secondary housing 122. In addition, as shown in
The vibro axis H is substantially aligned with the clamp plane F1 such that the vibrational forces created by the vibrational system 134 are transmitted directly to the pile 22 to be driven. In addition, the vibro axis H is substantially parallel to and spaced a short distance from the third axis D about which the main assembly 32 is rotated.
The first and second clamp planes F1 and F2 are angled with respect to each other. In the example system 20, the clamp planes F1 and F2 are substantially orthogonal to each other as is apparent from an examination of the drawings. The first and second gripping locations X1 and X2 are spaced from each other in the first clamp plane F1, while the third gripping location Y is spaced from the first and second gripping locations X1 and X2 within the second clamp plane F2.
The relationship of the first and second clamp planes F1 and F2 and first, second, and third clamping locations X1, X2, and Y changes the character of the clamp assemblies 130 and 132 and allows the system 20 to be used as required by a particular task at hand. The first clamp assembly 130 is particularly suited to gripping a side of an H-beam type pile as depicted in
During driving of a pile such as the example elongate pile 22 or sheet piles 28, in addition to the vibrational forces created by the vibrational system 134, the support system 30 applies a driving force (in either direction) to the pile 22 through the main assembly 32. The driving force is applied substantially along the third axis D as defined above. When the pile 22 is gripped by the support system 30, the pile axis A is substantially parallel to the third axis D and the vibro axis H and is spaced a short distance from these axes D and H. The pile handling system 20 thus applies both driving and vibratory forces along axes that are substantially aligned with the pile axis A, thereby minimizing bending moments on the pile 22 during insertion and extraction.
The pile driving system 20 thus may be used operates in either of first or second modes using the first and second clamp assemblies 130 and 132, respectively, to secure the secondary housing 122 to the pile 22. In addition, the pile driving system may be used in a third mode, in which the first clamp assembly is used to pick one or more sheet piles 28 from a stack or in a fourth mode to move piles 22 or 28 around prior to driving. The pile driving system 20 is thus a highly flexible device that can easily and efficiently accomplish a number of tasks related to the movement and driving of piles of different types.
From the foregoing, it should be clear that the present invention may be embodied in forms other than those described above. The above-described systems are therefore to be considered in all respects illustrative and not restrictive.
This application claims priority of U.S. Provisional Patent Application Ser. No. 60/700,768 filed Jul. 20, 2005, the contents of which are incorporated herein by reference.
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