1. Field of the Invention
The present invention relates to sheet pile, systems, and methods for the subterranean support of underground conduits.
2. Description of the Related Art
Particularly in urban environments, when it is necessary to lay water or sewer pipe, construction crews will often encounter buried electrical, telephone, and/or fiber optic cables. These cables are typically encased in a conduit structure, such as a clay tile or raceway that has a plurality of longitudinal holes through which the cables are pulled. In order to create a unitary subterranean support structure for the cables, individual raceway sections are placed end-to-end and mortared together. In order to lay another conduit, such as water or sewer pipes that must be buried below the freeze line, it is necessary to excavate beneath the raceway and the cables contained therein. When excavation occurs beneath the raceway, the raceway must be supported to prevent the raceway from collapsing into the excavated hole.
Currently, in order to support the raceway during and after excavation, the individual raceway tiles are jack hammered, causing the raceway tiles to break apart and expose the cables positioned therein. The exposed cables are then supported by one or more beams extending above the excavated hole. Once the water or sewer pipe is laid, the hole is backfilled and a concrete form is built around the cables. The form is filled with concrete and the concrete is allowed to harden. As a result, the cables are encased within the concrete and are protected from future damage. While this process is effective, it is also time consuming and expensive. Additionally, once the cables are encased in concrete, it is no longer possible to pull new cables through the raceway or to easily extract existing cables from the raceway.
The present invention relates to sheet pile, systems, and methods for the subterranean support of underground conduits. For purposes of the present invention, the term “conduit” includes elongate structures, such as raceways or conduits for wires, cables and optical fibers, pipes, cables, and the like. In one exemplary embodiment, the present invention includes a plurality of individual curved sheet piles that are positioned beneath an underground conduit, such as a raceway, to support the conduit during excavation. In one exemplary embodiment, the individual sections of curved sheet pile are interfit and/or interconnected. This allows the individual sections to work in combination with one another to support the conduit. Specifically, opposing ends of a length of interfit and/or interconnected curved sheet piles extend into unexcavated soil on both sides of an excavated hole to form a bridge across the hole that supports the conduit and any soil or other subterranean material positioned above the curved sheet pile.
In one exemplary embodiment, each section of curved sheet pile includes a flange extending from the lower surface of the curved sheet pile. In this embodiment, the flange extends beyond the edge of the curved sheet pile and forms a support surface configured to support an adjacent section of curved sheet pile. The flange has a radius of curvature substantially identical to the radius of curvature of the curved sheet pile. In this manner, with a first section of curved sheet pile positioned beneath a conduit, a second section of curved sheet pile may be advanced beneath the conduit at a position adjacent to the first section of curved sheet pile, such that the lower surface of the second section of curved sheet pile is positioned atop and supported by the support surface of the flange of the first section of curved sheet pile to form a junction between the first and second sections of curved sheet pile. This process can then be repeated until enough sections of curved sheet pile have been positioned beneath the conduit to sufficiently span the excavation site.
By positioning and supporting the lower surface of the second section of curved sheet pile atop the support surface of the first section of curved sheet pile, the flange of the first section of curved sheet pile acts as a seal to prevent the passage of subterranean material between the adjacent sections of curved sheet pile. In addition, the flange of the first section of curved sheet pile provides a guide to facilitate alignment of the second section of curved sheet pile during insertion and also compensates for misalignment of the second section of curved sheet pile relative to the first section of curved sheet pile.
In another exemplary embodiment, each section of curved sheet pile includes a first flange extending from the lower surface of the curved sheet pile and extending beyond a first edge of the curved sheet pile and a second flange extending from the upper surface of the curved sheet pile and extending beyond a second, opposing edge of the curved sheet pile. With this configuration, adjacent sections of curved sheet pile may be interfit with one another. For example, the edge of a first section of curved sheet pile having a flange extending from a lower surface of the first section of curved sheet pile is positioned to extend beneath a second section of curved sheet pile along the edge of the second section of curved sheet pile that has a flange extending from its upper surface. By positioning the first and second sections of curved sheet pile in this manner, the flange of the first section of curved sheet pile will extend beneath and support the second section of curved sheet pile, while the flange extending from the second section of curved sheet pile will extend over the upper surface of the first section of curved sheet pile. In this manner, an interfitting connection is formed between the adjacent sections of curved sheet pile.
Advantageously, by using sections of curved sheet pile with each section having a first flange extending from the lower surface of the curved sheet pile and extending beyond a first edge of the curved sheet pile and a second flange extending from the upper surface of the curved sheet pile and extending beyond a second, opposing edge of the curved sheet pile, the flanges add width to the curved sheet pile that prevents the passage of subterranean material between adjacent sections of the curved sheet pile, facilitate alignment of adjacent sections of curved sheet pile, and prevent the formation of a gap between adjacent sections of curved sheet pile. In addition, the first section of curved sheet pile that is inserted may be gripped and inserted from either of its two opposing sides. Further, these sections of curved sheet pile provide for an interconnection and interlocking between adjacent sections of curved sheet pile that facilitates the transfer of loading between adjacent sections of the curved sheet pile. This allows the individual sections of curved sheet pile to cooperate and act as a unitary structure for supporting a conduit. Further, by acting as a unitary structure, the sections of curved sheet pile may be substantially simultaneously lifted without the need to lift each individual section of curved sheet pile independently. The flanges also stiffen the individual sections of curved sheet pile, which makes the individual sections more resistant to bending during insertion.
In another exemplary embodiment, the curved sheet pile may include a plate secured to an upper surface of the curved sheet pile and extending between opposing edges thereof. The plate extends from upper surface of the curved sheet pile in a radially inwardly direction toward the center of the radius of curvature of the curved sheet pile. The plate is positioned adjacent to the end of the curved sheet pile that is gripped during the insertion of the curved sheet pile beneath the conduit. In this manner, the plate acts to push subterranean material that falls onto the curved sheet pile during insertion of the curved sheet pile back into position beneath the conduit. This prevents the loss of a substantial amount of subterranean material during insertion of the curved sheet pile and helps to facilitate the support of the conduit by the curved sheet pile by compacting the subterranean material.
Once a plurality of sections of curved sheet pile have been inserted beneath a conduit and connected to one another, such as with interfitting flanges, the curved sheet pile may be connected to a support system including support beams extending across the excavated opening. For example, a pair of beams may be positioned to span the excavated opening with the opposing ends of the beams supported on the ground above the excavated opening. Support rods may be positioned to extend through and/or from the beams and into the excavated opening. In one exemplary embodiment, the support rods include a J-hook configured for receipt within an opening the curved sheet pile. In one exemplary embodiment, the J-hooks are inserted through the openings in the curved sheet pile in a first orientation and are then rotated ninety degrees to position a portion of the curved sheet pile on the J-hook. By using a plurality of rods, the individual sections of curved sheet pile may be connected to the beams to provide a support structure for the curved sheet pile and, correspondingly, the conduit extending above the curved sheet pile and below the beam.
In one exemplary embodiment, curved sheet pile is driven underneath an existing conduit using a pile driver guided hydraulically by an excavator or other heavy machinery. For purposes of the present invention, the phrase “pile driver” includes vibratory pile drivers, impact pile drivers, hydraulic pile drivers, and hydrostatic jacking mechanisms. By vibrating the curved sheet piles, the soil is placed in suspension, which allows the piles to be directed through the soil along an accurate path that has a curvature that substantially matches the radius of curvature of the piles. In one exemplary embodiment, the pile is inserted along an accurate path substantially automatically by using a machine control program that controls the position of the curved sheet pile during insertion into the soil. Once the pile is positioned as desired, each individual pile sheet can be welded to another to form a unitary structure. Additionally, as indicated above, the curved sheet piles may have interconnecting features that interlock with one another to secure adjacent sections of pile to one another.
In one exemplary embodiment, the curved sheet pile is inserted beneath a conduit using a vibratory pile driver that rotates about a fixed pivot element on an excavator or other heavy machine for positioning the pile driver to advance the curved sheet pile along a fixed arc. Preferably, the distance between the fixed pivot element and clamps that secure the curved sheet pile to the pile driver is the same as the radius of curvature of the curved sheet pile. When the curved sheet pile is secured to the pile driver by the clamps, the center of the radius of curvature of the curved sheet pile lies substantially on the rotational axis of the fixed pivot element. As a result, the curved sheet pile may be advanced beneath a conduit, such as a raceway, without the need to move or further adjust the position of either the articulated boom of the excavator or the vibratory pile driver during placement of the curved sheet pile. By limiting the movement of the vibratory pile driver to rotation about a fixed pivot element during insertion of the curved sheet pile, the need for the operator of the excavator to simultaneously adjust the elevation and/or alignment of the vibratory pile driver during insertion of the curved sheet pile is eliminated.
Advantageously, by utilizing curved sheet pile, the need to jackhammer a conduit, such as a raceway or otherwise destroy the conduit to expose and support wires or other items extending through the conduit is eliminated. The curved sheet pile also provides for pyramidic loading, i.e., the curved sheet pile forces the subterranean material inward toward the center of the radius of curvature of the curved sheet pile, that helps to prevent the subterranean material above the curved sheet pile from collapsing. Further, use of curved sheet pile to support a conduit does not prevent the subsequent pulling or extraction of wires or other items through the conduit. Moreover, the present method also reduces both the cost and time necessary to support the conduit during excavation.
In one form thereof, the present invention provides a section of curved sheet pile adapted to be driven underneath a conduit buried underground. The curved sheet pile includes a body having an upper surface, a lower surface, a gripping edge, a leading edge, and opposing side edges extending between the gripping edge and the leading edge. The body includes a body radius of curvature extending between the gripping edge and the leading edge. The gripping edge, the leading edge, and the opposing side edges cooperate to define a perimeter of the body. And, a first flange extends outwardly from one of the opposing side edges of the body and extends beyond the perimeter of the body. The first flange has a support surface offset from the upper surface of the body. The first flange has a flange radius of curvature that is substantially identical to the body radius of curvature.
The above-mentioned and other features and advantages of this invention, and the manner of attaining them, will become more apparent and the invention itself will be better understood by reference to the following description of embodiments of the invention taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplifications set out herein illustrate preferred embodiments of the invention and such exemplifications are not to be construed as limiting the scope of the invention in any manner.
Referring to
As shown in
While described and depicted herein as a vibratory pile driver, pile driver 22 may be a non-vibratory pile driver that relies substantially entirely on hydraulic force to advance curved sheet pile 10 into subterranean material 18. In one exemplary embodiment, pile driver 22 relies on the hydraulic fluid pumped by excavator 20 to drive curved sheet pile 10 into subterranean material 18. Further, while described and depicted herein as being used in conjunction with excavator 20, any of the pile drivers disclosed herein, such as pile driver 22, may be used in conjunction with any heavy machinery capable of lifting the pile driver and providing hydraulic fluid thereto. In other embodiments, the pile drivers disclosed herein may be used with heavy machinery that does not supply hydraulic fluid to the pile drivers, but, instead, relies on a separate pump system to provide hydraulic fluid to the pile drivers. Additionally, pile driver 22 may be manipulated independently of excavator 20 and may incorporate features of pile driver 52 described in detail below.
As shown in
Returning to
Once a plurality of sections of curved sheet pile 10 is inserted beneath conduit 12, the individual sections of curved sheet pile 10 may be welded together. Alternatively or additionally, as discussed in detail below, the individual sections of curved sheet pile 10 may be interlocked with one another. Referring to
Advantageously, by utilizing sections of curved sheet pile, such as those described in detail herein, pyramidic loading of subterranean material 18 is provided. Specifically, due to the accurate shape of the curved sheet pile, the load of subterranean material 18 is directed inwardly toward the center of the radius of curvature of the curved sheet pile. As a result of the pyramidic loading, subterranean material 18 is forced inwardly upon itself, which compacts subterranean material 18 and helps to prevent it from collapsing into trench 16 or otherwise failing to support conduit 12.
Referring to
Similarly, pin 43 is received through a first opening in plate 62, an opening formed in arm 28 of articulated boom 24, and through an opening in plate 64 to secure arm 28 of articulated boom 24 to pile driver 52. A pin or any other known fastener may also be used to secure pin 43 in position and prevent translation of pin 43 relative to plates 62, 64. With pin 43 secured in this position, pin 43 forms a first fixed pivot element about which pile driver 52 may be rotated relative to articulated boom 24. Specifically, pin 43, in the form of a first fixed pivot element, defines insertion axis IA about which pile driver 52 may be rotated. By actuating hydraulic cylinder 34, a force is applied to pile driver 52 by cylinder 34 via pin 43, which causes pile driver 52 to rotate about insertion axis IA of the first fixed pivot element formed by pin 43. While pin 43 is described and depicted herein as forming the first fixed pivot element about which pile driver 52 is rotatable, any known mechanism for creating an axis of rotation, such as a worm gear mechanism, may be used to form the first fixed pivot element.
Referring to
In addition to rotation about first body axis of rotation BA1, the lower portion of body 56 is rotatable relative to head portion 54 through 360 degrees about second body axis of rotation BA2, shown in
Referring again to
Vibration generator 58 operates by utilizing a pair of opposing eccentric weights (not shown) configured to rotate in opposing directions. As the eccentric weights are rotated in opposite directions, vibration is transmitted to clamps 106. Additionally, any vibration that may be generated in the direction of side plates 94, 96 of the lower portion of body 54 may be substantially reduced by synchronizing the rotation of the eccentric weights. While vibration generator 58 is described herein as generating vibration utilizing a pair of eccentric weights, any known mechanism for generating vibration may be utilized. Additionally, as indicated above and depending on soil conditions, vibration generator 58 may be absent from hydraulic pile driver 52 and pile driver 52 may utilize hydraulic power generated by excavator 20 or a separate hydraulic pump (not shown) to advance curved sheet pile into subterranean material 18 without the need for vibration generator 58.
As shown in
By advancing clamp surface 108 in the direction of second clamp surface 110, distance D between first and second clamp surfaces 108, 110 is decreased. For example, with clamps 106 in the open position, an edge of curved sheet pile 10 may be advanced through the opening defined between first and second clamp surfaces 108, 110. Then, clamp surface 108 may be advanced in the direction of clamp surface 110. As clamp surface 108 advances toward clamp surface 110, clamp surface 108 will contact curved sheet pile 10. Clamp surface 108 may continue to advance until curved sheet pile 10 is gripped between clamp surfaces 108, 110, such that any movement of pile driver 52 will result in corresponding movement of curved sheet pile 10. Additionally, in one exemplary embodiment, clamp surfaces 108, 110 are substantially planar and extend along a plane that is substantially perpendicular to second body axis of rotation BA2 (
Additionally, clamps 106 are positioned such that, with clamp surfaces 108, 110 in a closed position, i.e., in contact with one another, clamp surfaces 108, 110 are spaced an insertion distance ID from insertion axis IA of pile driver 52, as shown in
In addition to grasping and inserting curved sheet pile 10, pile drivers 22, 52 may be used to insert alternative curved sheet pile designs. Referring to
Referring to
By positioning and supporting lower surface 126 of an adjacent section of curved sheet pile 112 atop support surface 136 of flange 132 of a section of curved sheet pile 112, flange 132 acts as a seal to prevent the passage of subterranean material 18 between the adjacent sections of curved sheet pile 112. In addition, flange 132 also provides a guide to facilitate alignment of adjacent sections of curved sheet pile 112 during insertion and also compensates for misalignment of individual sections of curved sheet pile 112.
Referring to
Referring to
Advantageously, in addition to the benefits of curved sheet pile 112 identified above, flanges 132, 142, curved sheet pile 140 allows for the creation of an interconnection and interlocking between adjacent sections of curved sheet pile 140 that facilitates the transfer of loading between adjacent sections of curved sheet pile 140. This allows individual sections of curved sheet pile 140 to cooperate with one another and to act as a unitary structure for supporting a conduit. Further, by acting as a unitary structure, sections of curved sheet pile 140 may be substantially simultaneously lifted without the need to lift each individual section of curved sheet pile 140 independently. Flanges 132, 142 also stiffen each individual section of curved sheet pile 140, which makes each individual section of curved sheet pile 140 more resistant to bending during insertion.
Referring to
Referring to
By utilizing curved sheet pile 10, as shown in
By interconnecting individual sections of curved sheet pile 10 with one another, the need to weld adjacent sections of curved sheet pile 10 together may be substantially lessened and/or eliminated. However, individual sections of curved sheet pile may still be welded together to provide additional strength and support to the entire structure. Additionally, while the description of the interconnection of curved sheet pile 10 is described as advancing solid curved rod 168 through C-shaped channel 164, the same interconnected can be accomplished by positioning C-shaped channel 164 adjacent curved rod 168 and advancing C-shaped channel 164 defined by curved rod 162 along solid curved rod 168.
Referring to
Referring to
Curved bar 174 interacts in a substantially similar manner with hollow curved rod 162 as solid curved rod 168 of curved sheet pile 10. For example, curved bar 174 has a height HI that is substantially less than inner diameter D2 of hollow curved rod 162 that defines C-shaped channel 164. Thus, in a substantially similar manner as described in detail above with specific reference to curved sheet pile 10, individual sections of curved sheet pile 172 may be interconnected to one another. Specifically, to interconnect adjacent sections of curved sheet pile 172, a first section of curved sheet pile 172 is positioned beneath conduit 12 in the manner described in detail herein. Once a first section of curved sheet pile 172 is in position, a second section of curved sheet pile 172 is aligned with solid curved bar 174 of the second section of curved sheet pile 172 positioned adjacent C-shaped channel 164 of the first section of curved sheet pile 172.
By advancing the second section of curved sheet pile 172 along an arc having a radius of curvature substantially similar to the radius of curvature of curved sheet pile 172, curved bar 174 of the second section of curved sheet pile 172 is advanced through C-shaped channel 164 of curved rod 162 of the first section of curved sheet pile 172. Once the second sheet of curved sheet pile 172 is in the desired position, the process can be repeated for additional sections of curved sheet pile 172 until a sufficient support structure is created by the interconnected sections of curved sheet pile 172. Additionally, while the description of the interconnecting of curved sheet pile 172 is described as advancing curved bar 174 through C-shaped channel 164, the same interconnection can be accomplished by positioning C-shaped channel 154 adjacent curved bar 174 and advancing C-shaped channel 164 defined by curved rod 162 along curved bar 174.
As indicated above, pile driver 52 allows for curved sheet pile 10, 112, 140, 150, 172 to be inserted beneath a conduit by pivoting pile driver 52 about insertion axis IA (
Referring to
Specifically, as hydraulic cylinder 34 is extended, pile driver 52 is rotated about insertion axis IA. Advantageously, by selecting a section of curved sheet pile 112 having radius of curvature RA that is substantially identical to insertion distance ID of pile driver 52 and positioning clamps 106 such that the center of the radius of curvature of curved sheet pile 112 lies substantially on insertion axis IA, curved sheet pile may be inserted along an arc having a radius of curvature that is substantially identical to radius of curvature RA of curved sheet pile 112. By positioning clamps 106 such that insertion distance ID is substantially equal to radius of curvature RA of curved sheet pile 112 and center C of the radius of curvature of curved sheet pile 112 lies substantially on insertion axis IA, pile driver 52 may be actuated about insertion axis IA to allow pile driver 52 to position curved sheet pile 112 beneath a conduit without the need for any additional movement of pile driver 52 and/or articulated boom 24 of excavator 20. Stated another way, with insertion distance ID being substantially identical to radius of curvature RA of curved sheet pile 112, a point that lies substantially on insertion axis IA defines center C of radius of curvature RA of curved sheet pile 112, as shown in
Advantageously, by utilizing an insertion distance ID that is substantially identical to radius of curvature RA of curve sheet pile 112 and positioning center C of radius of curvature RA on insertion axis IA, pile driver 52 may be actuated to rotate about a single, stationary axis, i.e., insertion axis IA, to insert curved sheet pile 112 into subterranean material 18 and maintain the advancement of curved sheet pile 112 along an arc having the same curvature as curved sheet pile 112. This eliminates the need for the operator of excavator 20 to simultaneously manipulate the position of articulated boom 24 while pile driver 52 is being rotated in order to adjust the position of insertion axis IA to facilitate the insertion of curved sheet pile 112 along an accurate path having the same curvature as curved sheet pile 112. Stated another way, the present invention eliminates the need for the operator of the excavator to manipulate articulated boom 24 and/or pile driver 52 to attempt to maintain center C of radius of curvature RA of curved sheet pile 112 at a point that lies substantially on insertion axis IA of pile driver 52.
Referring to
While the insertion of cured sheet pile 10, 112, 140, 150, 172 is primarily described in detail herein with specific reference to pile driver 52, pile driver 22 may also be used to insert curved sheet pile 10, 112, 140, 150, 172 in a substantially similar manner as described in detail herein with respect to pile driver 52. However, in order to insert curved sheet pile 10, 112, 140, 150, 172 along an arc having the same radius as radius of curvature RA of curved sheet pile 10, 112, 140, 150, pile driver 22 must be rotated about pin 43 and the position of pile driver 22 must also be adjusted by excavator 20 during the insertion of curved sheet pile 10, 112, 140, 150, 172.
Referring to
In order to secure rods 184 to beams 182, threaded ends 186 of rods 184 are advanced through openings formed in beams 182. Specifically, threaded ends 186 of rods 184 are advanced through beams 182 from lower, ground contacting surfaces 192 of beams 182 until at least a portion of threaded ends 186 of rods 184 extend from upper surfaces 194 of beams 182. Threaded nuts 196 are then threadingly engaged with threaded ends 186 of rods 184 and advanced there along. Specifically, nuts 196 are advanced in the direction of upper surfaces 194 of beams 182 until nuts 196 firmly engage upper surfaces 194 of beams 182. For example, nuts 196 may be advanced until ends 198 of J-hooks 190 are in contact with lower surfaces 126 of sections of curved sheet pile 10, 112, 140, 150, 172. Once in this position, curved sheet pile 10, 112, 140, 150, 172 is sufficiently supported by beams 182 and rods 184. If desired, nuts 196 may continue to be advanced. As nuts 196 are advanced, rods 184 are corresponding advanced in the direction of beams 182. This causes curved sheet pile 10, 112, 140, 150, 172, which is now secured to rods 184, to be lifted in the direction of beams 182 to provide additional support to conduit 12. With respect to embodiments of the curved sheet pile, such as curved sheet pile 140, that include flanges 132, as the curved sheet pile is lifted, flanges 132 engage lower surfaces 126 of the adjacent sections of curved sheet pile to allow for the cooperative lifting of all of the sections of curved sheet pile.
The process for the securement of curved sheet pile 10, 112, 140, 150, 172 may be repeated as necessary to further secure individual sections of curved sheet pile 10, 112, 140, 150, 172 to support structure 180 or to secure additional sections of curved sheet pile 10, 112, 140, 150, 172 to support structure 180. Specifically, in one exemplary embodiment, curved sheet pile 10, 112, 140, 150, 172 is secured at each of openings 122 by rods 184 to beams 182. Alternatively, rods 184 may be secured to a support extending from beams 182 or to a connection point (not shown) formed on beams 182.
In another exemplary embodiment, support system 200 may be used to support sections of curved sheet pile 10, 112, 140, 150, 172. Support system 200 includes several components that are identical or substantially identical to support system 180 and identical reference numerals have been used to identify identical or substantially identical components therebetween. Referring to
Referring to
With J-hooks 190 positioned through openings 122 in curved sheet pile 202, threaded ends 186 of rods 184 are received within gap 216, such that a portion of threaded ends 186 extends above upper surfaces 194 of beams 204. Once in this position, threaded ends 186 are passed through opening 216 in support plates 206. Support plates 206 are sized to extend across gap 216 and to rest atop upper surfaces 194 of beams 204. Washers 208 are then received on threaded ends 186 and threaded nuts 196 threadingly engaged with threaded ends 186. Threaded nuts 196 are then advanced along threaded ends 186 in a direction toward upper surface 194 of beams 204 to capture support plates 206 between upper surfaces 194 of beams 204 and washers 208 and to secure curved sheet pile 202 to beams 204 via rods 184. This process may be repeated as necessary. Specifically, in one exemplary embodiment, curved sheet pile 202 is secured at each of openings 122 by rods 184 to beams 204.
Referring to
In order to properly insert sections of curved sheet pile 10, 112, 140, 150, 172, 202, a control system may be utilized. The control system may be substantially automatic and is designed to operate based on the location of conduit 12. Generally, cables are located in 12 inch by 18 inch raceways or conduits that are positioned an average of 5 feet below the ground surface. In some instances, recent survey information may be available. Depending on the age of the survey information, it may be necessary to verify the survey information, as a buried raceway, such as conduit 12, may move over time.
If a new survey is needed, a survey may be performed in one of several ways. For example a RTK GNNS receiver and data collector may be used to record the centerline of conduit 12. Alternatively, the measurements may be taken with a total station. As locating conduit 12 may be difficult, it is also possible to do the surveying after forming trench 16.
To locate conduit 12 remotely, several methods may be used. For example, a cable detector may be added to a survey system. Alternatively, ground penetrating radar may be used. The selection of the system for locating the raceways should be based on the size of the job and the time available. Generally, the surveyor can carry the equipment, the equipment may be mounted to an all terrain vehicle, or the equipment may mounted to a traditional vehicle. Once the data is collected, the data may be transmitted to a server using, for example, a GPRS/3G connection.
With the survey data collected, a three dimensional design for the control system is created. Additionally, if the survey data is forming a solid centerline, the three dimensional design can be done using an onboard control system, such as the onboard control system of excavator 20. If the three-dimensional design is not created using the onboard control system of excavator 20, the final design is uploaded to the onboard control system of excavator 20.
In addition to the centerline and/or outline of conduit 12, exclusion zones can be added to the three-dimensional design. For example, an exclusion zone, such as exclusion zone 14 depicted by a circle in
Based on the accuracy of the three-dimensional design data, a rough or accurate trench, such as trench 16 shown in
Once trench 16 is formed, manual evaluation of the position of conduit 12 relative to trench 16 should be performed. This ensures the accuracy of the model, i.e., that conduit 12 is actually positioned as indicated in the model. Once the position of conduit 12 is confirmed, pile sheets 10, 112, 140, 150, 172, 202 may be positioned beneath conduit 12 as described in detail above. With an individual pile sheet 10, 112, 140, 150, 172, 202 grasped by vibratory pile driver 20, the machine control system will guide the sheet into the right position and orientation. For example, after pile 10, 112, 140, 150, 172, 202 has been preliminarily positioned by the operator, the operator activates the automatic control system and the system maneuvers pile 10, 112, 140, 150, 172, 202 along its calculated trajectory. Specifically, the automatic control system will ensure that excavator 20 manipulates vibratory pile driver 22, 52 as needed to advance individual pile 10, 112, 140, 150, 172, 202 about an accurate path that has substantially the same radius of curvature as the radius of curvature of pile 10, 112, 140, 150, 172, 202. Additionally, individual sheets 10, 112, 140, 150, 172, 202 may be positioned and advanced to interlock with one another.
In one exemplary embodiment, the control system is a distributed control system in which the sensors that determine the position of pile driver 22, 52 and the valve controllers that operate pile driver 22, 52 and articulated boom 24 of excavator 20 are connected to a display unit over a field bus, such as a CANopen bus. Additionally, the system master display unit is a display unit with a sufficient amount of random access memory, mass memory, a central processing unit, and graphical processing capabilities.
In order to determine the position of excavator 20, as needed to maneuver piles 10, 112, 140, 150, 172, 202 into position, a GNSS antenna may be used. In one exemplary embodiment, a single antenna system is used in which a machine heading is obtained by rotation of the machine body. Specifically, as the machine body rotates, the GNSS antenna creates an arc and/or ellipse depending on the plane orientation. From the arc and/or ellipse, a rotation center can be calculated and, as long as the machine is not moved, a direction from the current GNSS antenna to the rotation center of the arc and/or ellipse can be solved. From that, the actual heading of the machine can be determined.
In another exemplary embodiment, a dual antenna system is used. In this system, two antennas are positioned on excavator 20 and the direction between the antennas is constantly calculated. This provides a constant update on the relative position of the machine. Additionally, in other exemplary embodiments, three or more antenna systems can be used. In these cases, in addition to the direction of the machine, the pitch and the roll of the machine body can be calculated. In other exemplary embodiments, the pitch and the roll of the machine body is calculated using a single dual-axis inclinometer. In another exemplary embodiment, a robotic total station can be used instead of a GNSS system to determine the three-dimensional positioning of excavator 20.
In order to determine the position of vibratory pile drivers 22, 52, 2-D sensors may be used. In one exemplary embodiment, attachment sensors are positioned to determine the rotation of vibratory pile driver 22, 52 about second body axis of rotation BA2, shown in
In order to control the actuation of excavator 20 and, correspondingly, pile driver 22, 52, valve controllers may be used. The valve controllers may be actuated to control the trajectory of the insertion of piles 10, 112, 140, 150, 172, 202. Based on the sensor data identified above and the planned path for pile 10, 112, 140, 150, 172, 202, the system calculates target angle values for the next “time slot”. This method of calculation is also referred to as inverse kinematics. Thus, the trajectory of the inserted piles 10, 112, 140, 150, 172, 202 should be perpendicular to the longitudinal axis of the raceway. In three dimensions, there are an infinite number of vectors that are perpendicular to any given vector, all satisfying the equation α·α⊥=0. This system is designed to identify the vectors that are on the same plane defined partly by conduit 12 and advances piles 10, 112, 140, 150, 172, 202 along the same. Additionally, a height offset may be need. The height offset is essentially a copy of the raceway centerline moved to a different point on the Z-axis according to exclusion zone 14 and/or the planned distance between conduit 12 and the sheet pile. Thus, utilizing the desired vector and height offset, piles 10, 112, 140, 150, 172, 202 may be advanced into their desire positions substantially automatically utilizing a total control system.
Alternatively, with an area adjacent to the conduit that is sufficiently excavated, planar sheet pile may be driven horizontally underneath the conduit and secured together, such as with interlocking features defined by the planar sheet pile, to provide support to the conduit.
While this invention has been described as having a preferred design, the present invention can be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this invention pertains and which fall within the limits of the appended claims.
This application claims the benefit under Title 35 U.S.C. §119(e) of U.S. Provisional Patent Application Ser. No. 61/100,010, entitled METHOD AND APPARATUS FOR SUBTERRANEAN SUPPORT OF UNDERGROUND CONDUITS, filed on Aug. 25, 2008, and U.S. Provisional Patent Application Ser. No. 61/169,805, entitled SHEET PILING AND METHODS FOR THE SUBTERRANEAN SUPPORT OF UNDERGROUND CONDUITS, filed on Apr. 16, 2009, the entire disclosures of which are expressly incorporated by reference herein.
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