Guide systems and methods for diesel hammers

Description

TECHNICAL FIELD

The present invention relates to diesel hammers for pile driving and, in particular, to guide systems and methods that simplify the process of adapting a diesel hammer to different support structures having different geometries.

BACKGROUND

A diesel hammer is a pile driver having a housing and a ram. The ram is forced up by diesel combustion and falls within the housing to impact a pile and drive the pile into the earth. Conventionally, a support system supports the diesel hammer above the pile as the ram is driving the pile such that the driving force is applied along the axis of the pile. As the diesel hammer drives the pile, the support system interacts with a guide system that guides the diesel hammer such that a housing thereof moves with the pile along the pile axis.

Support systems for the diesel hammer come in a variety of configurations. Conventionally, the guide system for the diesel hammer is modified to adapt to a particular diesel hammer to a particular configuration of support system.

The need exists for a guide systems and methods for diesel hammers that may be easily reconfigured to allow a particular support system to accommodate a particular diesel hammer.

SUMMARY

The present invention may be embodied as a guide system for allowing a diesel hammer to be supported by a plurality of support systems comprising a primary channel system and a pair of first channel adapter assemblies. The primary channel system is rigidly connected to the diesel hammer to define a pair of primary channels and a primary spacing distance between the primary channels. Each of the pair of first channel adapter assemblies defines a first secondary channel. The guide system operates in a first configuration and in a second configuration. In the first configuration, portions of a first support system of the plurality of support systems are received within the primary channels. In the second configuration, each of the first channel adapter assemblies is detachably attached to the primary channel system such that the first channel adapter assemblies define a first secondary spacing distance between the first secondary channels, the first secondary spacing distance is different from the primary spacing distance, and portions of a second support system of the plurality of support systems are received within the first secondary channels.

The present invention may also be embodied as a method of supporting a diesel hammer from a plurality of support systems comprising the following steps. A primary channel system is rigidly connected to the diesel hammer to define a pair of primary channels and a primary spacing distance between the primary channels. A pair of first channel adapter assemblies is provided, and each first channel adapter assembly defines a first secondary channel. In a first configuration, portions of a first support system of the plurality of support systems are received within the primary channels. In a second configuration, each of the first channel adapter assemblies is detachably attached to the primary channel system such that the first channel adapter assemblies define a first secondary spacing distance between the first secondary channels, the first secondary spacing distance is different from the primary spacing distance, and portions of a second support system of the plurality of support systems are received within the first secondary channels.

The present invention may also be embodied as a guide system for allowing a diesel hammer to be supported by first, second, and third support systems. The guide system comprises a primary channel system, a pair of first channel adapter assemblies, and a pair of second channel adapter assemblies. The primary channel system is rigidly connected to the diesel hammer to define a pair of primary channels and a primary spacing distance between the primary channels. Each of the first channel adapter assemblies defines first secondary channel. Each of the second channel adapter assemblies defines a second secondary channel. The guide system operates in first, second, and third configuration. In the first configuration, portions of the first support system are received within the primary channels. In the second configuration, each of the first secondary channel adapter assemblies is detachably attached to the primary channel system such that the first channel adapter assemblies define a first secondary spacing distance between the first secondary channels, the first secondary spacing distance is different from the primary spacing distance, and portions of the second support system are received within the first secondary channels. In the third configuration, each of the second channel adapter assemblies is detachably attached to the primary channel system such that the second channel adapter assemblies define a second secondary spacing distance between the first secondary channels, the second secondary spacing distance is different from the primary spacing distance and the first secondary spacing distance, and portions of the third support system are received within the second secondary channels.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a first example configuration of a first example diesel hammer system of the present invention;

FIG. 2 is a bottom plan view of the first example diesel hammer in the first configuration;

FIG. 3 is a somewhat schematic section view of the first example diesel hammer in the first configuration;

FIG. 4 is a perspective view of a second example diesel hammer system of the present invention;

FIG. 5 is a bottom plan view of the second example diesel hammer system;

FIG. 6 is a first side elevation view of a first example channel adapter assembly of a first example channel adapter system used by the second example diesel hammer;

FIG. 7 is a second side elevation view of the first example channel adapter assembly of the first example channel adapter system used by the second example diesel hammer;

FIG. 8 is a somewhat schematic exploded section view of a portion of the second example diesel hammer;

FIG. 9 is a somewhat schematic section view of a portion of the second example diesel hammer;

FIG. 10 is a somewhat schematic section view of a portion of a third example diesel hammer using a second example channel adapter assembly;

FIG. 11 is a first side elevation view of a fourth example channel adapter assembly of a third example channel adapter system that may be used by a diesel hammer system such as the first and second example diesel hammer systems;

FIG. 12 is a second side elevation view of the fourth example channel adapter assembly;

FIG. 13 is a third side elevation view of the fourth example channel adapter assembly;

FIG. 14 is a somewhat schematic exploded section view of a portion of the fourth example channel adapter assembly as used with the first example diesel hammer;

FIG. 15 is a somewhat schematic section view of a portion of the fourth example channel adapter assembly as used with the first example diesel hammer;

FIG. 16 is a first side elevation view of a fifth example channel adapter assembly of a fourth example channel adapter system that may be used by a diesel hammer system such as the first and second example diesel hammer systems;

FIG. 17 is a second side elevation view of the fifth example channel adapter assembly;

FIG. 18 is a third side elevation view of the fifth example channel adapter assembly;

FIG. 19 is a somewhat schematic section view of a portion of the fifth example channel adapter assembly as used with the first example diesel hammer; and

FIG. 20 is a somewhat schematic section view of a portion of a sixth example diesel hammer system employing a fifth example channel adapter assembly.

DETAILED DESCRIPTION

Referring initially to FIG. 1 of the drawings, depicted therein is a first example diesel hammer system 20 constructed in accordance with, and embodying, the principles of the present invention. The example diesel hammer assembly 20 is shown in FIGS. 1-3 in a first configuration. The first example diesel hammer system 20 comprises a ram housing 22, a ram displacement system 24, and a primary channel system 26. The ram displacement system 24 comprises an actuator 30, a carriage 32, and carriage rails 34. The ram housing 22 and ram displacement system 24 are or may be conventional and will be described herein only to that extent necessary for a complete understanding of the present invention.

A ram (not shown) is supported for up and down movement within the housing 22 during operation of the diesel hammer 20 to drive a pile (not shown). The primary channel system 26 is configured to allow the ram housing 22 to be held in an upright position during pile driving operation but also to allow the ram housing 22 to move down relative to the earth as the pile is driven into the earth.

The example primary channel system 26 comprises a pair of primary guide members 40. The example primary guide members 40 are secured to the ram housing 22 by first mounting brackets 42, second mounting brackets 44, and third mounting brackets 46. During normal use of the example pile driving system 20, the first, second, and third mounting brackets 42, 44, and 46 will be connected to an upper end, a middle portion, and a lower end of the ram housing 22, respectively. Typically, the primary guide members 40 are rigidly connected to the mounting brackets 42, 44, and 46 by welding or the like, while the mounting brackets 42, 44, and 46 are rigidly connected to the ram housing 22 by welding or the like.

The example primary channel system 26 comprises two identical guide members 40, and the guide members 40 and mounting brackets 42, 44, and 46 are symmetrically arranged on opposite sides of the ram housing 22. However, more than two guide members and/or guide members of different dimensions may be used as part of a support system of the present invention.

Each of the example guide members 40 comprises a main guide wall 50, a first side guide wall 52, a second side guide wall 54, and flared surfaces 56 formed on both ends of the side guide walls 52 and 54. Primary mounting holes 60 are formed in the main guide walls 50. The example primary mounting holes 60 are arranged in pairs 62, and the pairs 62 are grouped to define a primary hole pattern 64. The primary channel members 40 define primary channels 70 between the guide walls 50, 52, and 54. Each of the primary channels 70 defines a primary channel width 72 and a primary channel depth 74.

As perhaps best shown in FIG. 3, the example mounting brackets 42, 44, and 46 support the primary channel members 40 such that reference planes defined by the guide walls 50, 52, and 54 are parallel to a longitudinal ram axis A of the ram housing 22. Further, the mounting brackets 42, 44, and 46 support the primary channel members 40 such that the main guide walls 50 of each of the example guide members 40 are spaced the same distance from the ram axis A and thus each define a primary offset distance 76 indicating a distance between the primary channel members 40 and a closest portion of the outer surface of the ram housing 22. The primary channel members 40 further define a primary channel spacing distance 78 between the primary channels 70.

FIG. 2 illustrates that a first support member 80 is arranged at least partly within each of the primary channels 70. The first support members 80 are identical and define a substantially rectangular cross-sectional shape as shown in FIG. 2. The support members 80 are rigid members that are supported in parallel relative to each other; the support members 80 may be made of solid material but are more likely made of hollow rectangular tubing. In any event, the first support members 80 define a first support width 82 and a first support depth 84. Further, the first support members 80 are spaced from each other by a first support spacing distance 86.

The first support width 82, first support depth 84, and first support spacing distance 86 will be predetermined for a particular situation. The first support width 82 will determine the primary channel width 72, the first support depth 84 will determine the primary channel depth 74, and the first support spacing distance 86 will determine the primary channel spacing distance 78. In particular, the primary channel width 72 will be slightly larger than the first support width 82, the primary channel depth 74 will be sufficient to engage the first support depth 84 dimensions of the support members 80 to allow the support members 80 to engage the primary channel members 40 to hold the diesel hammer system 20 substantially upright or vertical, and the primary channel spacing distance 78 will be slightly smaller than the first support spacing distance 86.

In use, the support members 80 are sized, dimensioned, and arranged to maintain the diesel hammer system 20 in a substantially upright or vertical orientation during normal operation of the diesel hammer system 20. In particular, the support members 80 will typically be held by a vehicle or crane (not shown) capable of supporting the support members 80 and diesel hammer system 20 in a substantially upright or vertical orientation relative to a desired location at which the pile is to be driven. The vehicle or crane for supporting the support members 80 is or may be conventional and will not be described herein in detail.

Turning now to FIGS. 4-9 illustrate a second diesel hammer system 120 comprising the example diesel hammer system 20 arranged in a second configuration with a first example channel adapter system 122. The first example channel adapter system 122 comprises a first channel adapter assembly 124 and a second channel adapter system 126. The first and second channel adapter assemblies 124 and 126 are identical.

In particular, each of the example first and second channel adapter assemblies 124 and 126 comprises a secondary channel member 130, a base member 132, one or more standoff members 134, and at least one bolt assembly 136. The example secondary channel members 130 are identical and each comprises a main guide wall 140, a first side guide wall 142, a second side guide wall 144, and flared surfaces 146 formed on each end of the first and second side guide walls 142 and 144. Secondary mounting holes 150 are formed in the main guide walls 140. The mounting holes 150 are arranged in pairs 152, and the pairs 152 are grouped to define a first secondary hole pattern 154. The example bolt assembly or assemblies 136 each comprises a bolt 156 and a nut 158. The example standoff members 134 rigidly connect the secondary channel member 130 to the base member 132 such that the main guide wall 140 is substantially parallel to a reference plane defined by the base member 132.

The example first and second channel adapter assemblies 124 and 126 further comprise web members 160, first lateral braces 162, second lateral braces 164, third lateral braces 166, first longitudinal braces 170, second longitudinal braces 172, and third longitudinal braces 174. Each web member 160 is rigidly connected to the base member 132 and one or more of the standoff members 134. The example lateral braces 162, 164, and 166 are each rigidly connected to one of the standoff members 134 and the secondary channel member 130. The example longitudinal braces 170, 172, and 174 are rigidly connected to one of the standoff members 134, one of the web members 160, and one of the lateral braces 162, 164, or 166.

As shown in FIG. 8, the secondary channel members 130 define secondary channel 180 defining a secondary channel width 182 and a secondary channel depth 184.

To form the second diesel hammer system 120, the first and second channel adapter assemblies 124 and 126 are arranged such that the base members 132 thereof are each within one of the primary channels 70 with the secondary mounting holes 150 aligned with the primary mounting holes 60. In particular, the primary hole pattern 64 and secondary hole pattern 154 are sufficiently similar such that the bolts 156 may be inserted through the aligned holes 60 and 150. Rotating the nuts 158 relative to the bolts 156 allows the bolt assemblies 136 to be formed, thereby rigidly connecting the base members 132, and thus the first and second adapter assemblies 124 and 126, to the diesel hammer system 20.

Further, the primary hole pattern 64 and secondary hole pattern 154 are configured such that, when the first and second adapter assemblies 124 and 126 are rigidly connected to the diesel hammer system 20, the secondary channels 180 are substantially aligned with the primary channels 70 and with the ram axis A. The primary channel offset distance 76 and space between the secondary channel members 130 and the base members 132 allow the bolts 156 and nuts 158 to be inserted through the holes 60 and 150 and assembly of the bolt assemblies 136.

With the first and second adapter assemblies 124 and 126 rigidly connected to the diesel hammer system 20, the web members 160 inhibit movement of the secondary channel members 130 along the ram axis or twisting of the secondary channel members 130 relative to the ram axis A. The lateral braces 162, 164, and 166 engage portions of the diesel hammer system 20, in this case the mounting brackets 42, 44, and 46, respectively, to inhibit lateral or tangential movement of the secondary channel members 130 relative to the ram axis A. The longitudinal braces 170, 172, and 174 inhibit movement of the secondary channel members 130 along the ram axis or twisting of the secondary channel members 130 relative to the ram axis A. The longitudinal braces 170, 172, and 174 further inhibit movement of the lateral braces 162, 164, and 166 in a direction generally along the ram axis A.

Further, with the first and second adapter assemblies 124 and 126 rigidly connected to the diesel hammer system 20, the secondary channel members 130 define a secondary channel offset distance 186 from the outer surface of the ram housing 22. And when both of the first and second adapter assemblies 124 and 126 are rigidly connected to the diesel hammer system 20, the secondary channel channels 180 define a secondary channel spacing distance 188.

FIG. 5 illustrates that a second support member 190 is arranged at least partly within each of the secondary channels 180. The second support members 190 are identical and define a substantially rectangular cross-sectional shape as shown in FIG. 5. Like the example support members 80 described above, the example support members 190 are solid or hollow rigid members that define a second support width 192 and a second support depth 194 and are supported in parallel relative to each other. Further, the second support members 190 are spaced from each other by a second support spacing distance 196.

The second support width 192, second support depth 194, and second support spacing distance 196 will be predetermined for a particular situation. The second support width 192 will determine the secondary channel width 182, the second support depth 194 will determine the secondary channel depth 184, and the second support spacing distance 196 will determine the secondary channel spacing distance 188. In particular, the secondary channel width 182 will be slightly smaller than the second support width 192, the primary channel depth 184 will be sufficient to engage the second support depth 194 dimensions of the support members 190 to allow the support members 190 to engage the primary channel members 130 to hold the diesel hammer system 120 substantially upright or vertical, and the secondary channel spacing distance 188 will be slightly smaller than the second support spacing distance 196.

In use, the support members 190 are sized, dimensioned, and arranged to maintain the diesel hammer system 120 in a substantially upright or vertical orientation during normal operation of the diesel hammer system 120. In particular, the support members 190 will typically be held by a vehicle or crane (not shown) capable of supporting the support members 80 and diesel hammer system 20 in a substantially upright or vertical orientation relative to a desired location at which the pile is to be driven. The vehicle or crane for supporting the support members 80 is or may be conventional and will not be described herein in detail. However, different support systems (e.g., vehicle or crane) may define the second support width 192, the second support depth 194, and the second support spacing distance 196.

The rail adapter system 122 thus allows the diesel hammer system 20 to be converted into the diesel hammer system 120 as appropriate for use with the support members 190 simply by forming the bolt assemblies 136 as described above. The rail adapter system 122 allows the diesel hammer system 120 to be converted back into the diesel hammer system 20 appropriate for use with the support members 80 simply by disassembling the bolt assemblies 136 and removing the first and second channel adapter assemblies 124 and 126.

FIG. 10 illustrates a portion of a third example diesel hammer system 220 that may be formed using a second example rail adapter system 222 of the present invention. The second example rail adapter system 222 comprises a first channel adapter assembly 224 and a second example rail adapter assembly (not visible in FIG. 10). FIG. 10 further illustrates that, instead of a single U-shaped rigid member forming the primary channel, the third example diesel hammer system 220 comprises a pair (only one pair shown in FIG. 10) of first and second L-shaped rigid members 226 and 228 rigidly secured relative to the ram housing 22.

Each of the example first and second channel adapter assemblies 224 comprises a secondary channel member 230, a base member 232, one or more standoff members 234, and at least one bolt assembly 236. The example secondary channel members 230 are identical and each comprises a main guide wall 240, a first side guide wall 242, and a second side guide wall 244. Secondary mounting holes 250 are formed in the base member 232. The mounting holes 250 are arranged in pairs, and the pairs are grouped to define a secondary hole pattern. The example bolt assembly or assemblies 236 each comprises a bolt 256 and a nut 258. The example standoff members 234 rigidly connect the secondary channel member 230 to the base member 232 such that the main guide wall 240 is substantially parallel to a reference plane defined by the base member 232.

The example first and second channel adapter assemblies 224 further comprise web members 260. While not shown in FIG. 10, lateral and/or longitudinal braces may also be used with the channel adapter assemblies 224. FIG. 10 further illustrates that each pair of the rigid members 226 and 228 defines a primary channel 270 (only one channel visible in FIG. 10). The primary channels 270 each define a primary channel width 272 and a primary channel depth 274. The primary channel members 226 and 228 define a primary channel offset distance 276. As with the primary channels described above, a primary channel spacing distance separates the two primary channels 270. Each of the rigid members 226 and 228 defines a primary mounting hole 278. The example standoff members 234 are shorter than the standoff members 134 and thus define a shorter second channel spacing distance than the secondary channel spacing distance 188 described above.

To form the third diesel hammer system 220, the first and second channel adapter assemblies 224 are arranged such that the base members 232 thereof are each within one of the primary channels 270 with the secondary mounting holes 250 aligned with primary mounting holes 278 formed in the primary channel members 226 and 228. Rotating the nuts 258 relative to the bolts 256 allows the bolt assemblies 236 to be formed, thereby rigidly connecting the base members 232, and thus the first and second adapter assemblies 224, to the primary channel members 226 and 228, and thus to the diesel ram housing 22.

Each secondary channel member 230 defines a secondary channel 280 defining a secondary channel width 282 and a secondary channel depth 284. Each secondary channel member 230 further defines a secondary channel offset distance 286 when secured relative to the diesel housing 22. Further, when secured relative to the diesel housing 22, the secondary channels 280 define a secondary channel spacing distance.

The rail adapter system 222 thus allows the diesel hammer system 20 with the pairs of L-shaped channel members 226 and 228 to be converted into the diesel hammer system 220 as appropriate for use with support members appropriate for the secondary channel spacing distance simply by forming the bolt assemblies 236 as described above. The rail adapter system 222 allows the diesel hammer system 220 to be converted back into the diesel hammer system 20 appropriate for use with the support members 80 simply by disassembling the bolt assemblies 236 and removing the first and second channel adapter assemblies 224.

FIGS. 11-15 illustrate portions of a fourth example diesel hammer system 320 comprising a third example rail adapter system 322. The fourth example diesel hammer system 320 incorporates the example diesel hammer system 20 comprising the primary channel members 40 as described above. The third example rail adapter system 322 comprises first and second channel adapter assemblies 324 (only one visible in FIGS. 11-15).

Each of the example first and second channel adapter assemblies 324 comprises a secondary channel member 330, a base member 332, and at least one bolt assembly 336. The example secondary channel members 330 are identical and each comprises a main guide wall 340, a first side guide wall 342, and a second side guide wall 344. Main access openings 346 are formed in the main guide wall 340. The example base member 332 is a hollow structure defining a base wall 350, a spaced wall 352, and standoff walls 354. Secondary access openings 356 are formed in the spaced wall 352, while secondary mounting holes 358 are formed in the base wall 350. The mounting holes 358 are arranged in pairs, and the pairs are grouped to define a secondary hole pattern. On each of the access openings 346 and 356 are arranged adjacent to each mounting hole 358. The example bolt assembly or assemblies 336 each comprises a bolt 360 and a nut 362.

To form the fourth diesel hammer system 320, the first and second channel adapter assemblies 324 are arranged such that the base members 332 thereof are each within one of the primary channels 70 with the secondary mounting holes 358 aligned with primary mounting holes 60 formed in the primary channel member 40. The bolts 360 are inserted into the secondary mounting holes 358 by first passing through the access openings 346 and 356. With the bolts 360 in place as shown in FIG. 15, rotating the nuts 362 relative to the bolts 360 allows the bolt assemblies 336 to be formed, thereby rigidly connecting the base members 332, and thus the first and second adapter assemblies 324, to the primary channel members 40, and thus to the diesel housing 22.

Each secondary channel member 330 defines a secondary channel width 370, a secondary channel depth 372, a secondary channel offset distance 374 when secured relative to the diesel housing 22. Further, when secured relative to the diesel housing 22, the secondary channels 330 define a secondary channel spacing distance.

The rail adapter system 322 thus allows the diesel hammer system 20 to be converted into the diesel hammer system 320 as appropriate for use with support members appropriate for the secondary channel spacing distance defined by the secondary channel members 330 simply by forming the bolt assemblies 336 as described above. The rail adapter system 322 allows the diesel hammer system 320 to be converted back into the diesel hammer system 20 appropriate for use with the support members 80 simply by disassembling the bolt assemblies 336 and removing the first and second channel adapter assemblies 324.

FIGS. 16-19 illustrate portions of a fifth example diesel hammer system 420 comprising a fourth example rail adapter system 422. The fifth example diesel hammer system 420 incorporates the example diesel hammer system 20 comprising the primary channel members 40 as described above. The fourth example rail adapter system 422 comprises first and second channel adapter assemblies 424 (only one visible in FIGS. 16-19).

Each of the example first and second channel adapter assemblies 424 comprises a secondary channel member 430, a base member 432, a spacing member 434, and at least one bolt assembly 436. The example secondary channel members 430 are identical and each comprises a main guide wall 440, a first side guide wall 442, and a second side guide wall 444. Main access openings 446 are formed in the main guide wall 440. The spacing member 434 is simply a rigid plate rigidly connected between the secondary channel member 430 and the base member 432 and defines a plate access opening 448. The example base member 432 is a hollow structure defining a base wall 450, a spaced wall 452, and standoff walls 454. Secondary access openings 456 are formed in the spaced wall 452, while secondary mounting holes 458 are formed in the base wall 450. The mounting holes 458 are arranged in pairs, and the pairs are grouped to define a secondary hole pattern. One each of the access openings 446, 448, and 456 are arranged adjacent to each of the mounting holes 458. The example bolt assembly or assemblies 436 each comprises a bolt 460 and a nut 462.

To form the fifth diesel hammer system 420, the first and second channel adapter assemblies 424 are arranged such that the base members 432 thereof are each within one of the primary channels 70 with the secondary mounting holes 458 aligned with primary mounting holes 60 formed in the primary channel member 40. The bolts 460 are inserted into the primary mounting holes 458 by first passing through the access openings 446, 448, and 456. With the bolts 460 in place as shown in FIG. 19, rotating the nuts 462 relative to the bolts 460 allows the bolt assemblies 436 to be formed, thereby rigidly connecting the base members 432, and thus the first and second adapter assemblies 424, to the primary channel members 40, and thus to the diesel housing 22.

Each secondary channel member 430 defines a secondary channel width 470, a secondary channel depth 472, a secondary channel offset distance 474 when secured relative to the diesel housing 22. Further, when secured relative to the diesel housing 22, the secondary channels 430 define a secondary channel spacing distance.

The rail adapter system 422 thus allows the diesel hammer system 20 to be converted into the diesel hammer system 420 as appropriate for use with support members appropriate for the secondary channel spacing distance defined by the secondary channel members 430 simply by forming the bolt assemblies 436 as described above. The rail adapter system 422 allows the diesel hammer system 420 to be converted back into the diesel hammer system 20 appropriate for use with the support members 80 simply by disassembling the bolt assemblies 436 and removing the first and second channel adapter assemblies 424.

FIG. 20 illustrates a portions of a sixth example diesel hammer system 520 comprising a fifth example rail adapter system 522. The sixth example diesel hammer system 520 incorporates the example diesel hammer system 20 comprising the primary channel members 40 as described above. The fifth example rail adapter system 522 comprises first and second channel adapter assemblies 524 (only one visible in FIG. 20).

Each of the example first and second channel adapter assemblies 524 comprises a secondary channel member 530, a base member 532, a spacing member 534, and at least one bolt assembly 536. The example secondary channel members 530 are identical and each comprises a main guide wall 540, a first side guide wall 542, and a second side guide wall 544. Main access openings 546 are formed in the main guide wall 540. The spacing member 534 is simply a rigid plate rigidly connected between the secondary channel member 530 and the base member 532 and defines a plate access opening 548. The example base member 532 is a hollow structure defining a base wall 550, a spaced wall 552, and standoff walls 554. Secondary access openings 556 are formed in the spaced wall 552, while secondary mounting holes 558 are formed in the base wall 550. The mounting holes 558 are arranged in pairs, and the pairs are grouped to define a secondary hole pattern. One each of the access openings 546, 548, and 556 are arranged adjacent to each of the mounting holes 558. The example bolt assembly or assemblies 536 each comprises a bolt 560 and a nut 562.

To form the sixth diesel hammer system 520, the first and second channel adapter assemblies 524 are arranged such that the base members 532 thereof are each within one of the primary channels 70 with the secondary mounting holes 558 aligned with primary mounting holes 60 formed in the primary channel member 40. The bolts 560 are inserted into the primary mounting holes 558 by first passing through the access openings 546, 548, and 556. With the bolts 560 in place as shown in FIG. 20, rotating the nuts 562 relative to the bolts 560 allows the bolt assemblies 536 to be formed, thereby rigidly connecting the base members 532, and thus the first and second adapter assemblies 524, to the primary channel members 40, and thus to the diesel housing 22.

Each secondary channel member 530 defines a secondary channel width 570, a secondary channel depth 572, a secondary channel offset distance 574 when secured relative to the diesel housing 22. Further, when secured relative to the diesel housing 22, the secondary channels 530 define a secondary channel spacing distance.

The rail adapter system 522 thus allows the diesel hammer system 20 to be converted into the diesel hammer system 520 as appropriate for use with support members appropriate for the secondary channel spacing distance defined by the secondary channel members 530 simply by forming the bolt assemblies 536 as described above. The rail adapter system 522 allows the diesel hammer system 520 to be converted back into the diesel hammer system 20 appropriate for use with the support members 80 simply by disassembling the bolt assemblies 536 and removing the first and second channel adapter assemblies 524.

As can be seen by a comparison of FIGS. 19 and 20, the structure of the first and second channel adapter assemblies 524 is similar to that of the first and second channel adapter assemblies 424 described above. However, by appropriate selection of geometry of the base members 432,532 and spacing members 434,534, different channel offset distances and secondary channel spacing distances can be obtained for a particular set of support members similar to, but with different geometry than, the example support members 80 and 190 described above.

Claims

1. A guide system for allowing a diesel hammer to be supported by a plurality of support systems, the guide system comprising: a primary channel system rigidly connected to the diesel hammer to define a pair of primary channels, anda primary spacing distance between the primary channels;a pair of first channel adapter assemblies each defining a first secondary channel; whereinthe guide system operates in a first configuration in which portions of a first support system of the plurality of support systems are received within the primary channels, andin a second configuration in which each of the first channel adapter assemblies is detachably attached to the primary channel system such that the first channel adapter assemblies define a first secondary spacing distance between the first secondary channels,the first secondary spacing distance is different from the primary spacing distance, andportions of a second support system of the plurality of support systems are received within the first secondary channels.
2. A guide system as recited in claim 1, further comprising a plurality of connecting assemblies, in which the plurality of connecting assemblies are arranged to detachably attach the first channel adapter assemblies to the primary channel system.
3. A guide system as recited in claim 2, in which the primary channel system is rigidly connected to the diesel hammer to define a primary offset distance, where the primary offset distance is predetermined to allow assembly of the plurality of connecting assemblies.
4. A guide system as recited in claim 1, further comprising: a pair of second channel adapter assemblies each defining a second secondary channel; whereinthe guide system further operates in a third configuration in which each of the second channel adapter assemblies is detachably attached to one of the primary guide members such that the second channel adapter assemblies define a second secondary spacing distance between the second secondary channels, the second secondary spacing distance is different from the primary spacing distance and from the first secondary spacing distance, andportions of a third support system of the plurality of support systems are received within the second secondary channels.
5. A guide system as recited in claim 4, further comprising at least one bolt assembly, in which: the primary channel system comprises first and second guide members, where each guide member definesone of the primary channels, andat least one primary mounting hole; andeach first channel adapter assembly comprises: a first secondary channel member;a first base member defining at least one first secondary mounting hole; andat least one first standoff member rigidly connected between the first base member and the first secondary channel member;each second channel adapter assembly comprises: a second secondary channel member;a second base member defining at least one second secondary mounting hole; andat least one second standoff member rigidly connected between the second base member and the second secondary channel member; whereinin the second configuration, each first secondary mounting hole is aligned with one primary mounting hole;the at least one bolt assembly is extended through each aligned primary mounting hole and first secondary mounting hole; andat least a portion of the at least one bolt assembly is arranged between the first base member and the first secondary channel member;in the third configuration, each second secondary mounting hole is aligned with one primary mounting hole;the at least one bolt assembly is extended through each aligned primary mounting hole and second secondary mounting hole; andat least a portion of the at least one bolt assembly is arranged between the second base member and the second secondary channel member.
6. A guide system as recited in claim 1, further comprising at least one bolt assembly, in which: the primary channel system comprises first and second guide members, where each guide member definesone of the primary channels, andat least one primary mounting hole; andeach first channel adapter assembly comprises: a first secondary channel membera base member defining a first secondary mounting hole, andat least one standoff member rigidly connected between the base member and the secondary channel member; whereinin the second configuration, each first secondary mounting hole is aligned with one primary mounting hole;the at least one bolt assembly is extended through each aligned primary mounting hole and secondary mounting hole; andat least a portion of the at least one bolt assembly is arranged between the base member and the first secondary channel member.
7. A method of supporting a diesel hammer from a plurality of support systems comprising the steps of: rigidly connecting a primary channel system to the diesel hammer to define a pair of primary channels, anda primary spacing distance between the primary channels;providing a pair of first channel adapter assemblies each defining a first secondary channel;operating in a first configuration in which portions of a first support system of the plurality of support systems are received within the primary channels, andin a second configuration in which each of the first channel adapter assemblies is detachably attached to the primary channel system such that the first channel adapter assemblies define a first secondary spacing distance between the first secondary channels,the first secondary spacing distance is different from the primary spacing distance, andportions of a second support system of the plurality of support systems are received within the first secondary channels.
8. A method as recited in claim 7, further comprising the step of arranging a plurality of connecting assemblies to detachably attach the first channel adapter assemblies to the primary channel system.
9. A method as recited in claim 8, further comprising the steps of: predetermining a primary offset distance between sufficient to allow assembly of the plurality of connecting assemblies; andrigidly connecting the primary channel system to the diesel hammer to define the primary offset distance.
10. A method as recited in claim 7, further comprising the steps of: providing a pair of second channel adapter assemblies each defining a second secondary channel; andoperating in a third configuration in which each of the second channel adapter assemblies is detachably attached to one of the primary guide members such that the second channel adapter assemblies define a second secondary spacing distance between the second secondary channels,the second secondary spacing distance is different from the primary spacing distance and from the first secondary spacing distance, andportions of a third support system of the plurality of support systems are received within the second secondary channels.
11. A method as recited in claim 10, in which: the step of rigidly connecting the primary channel system to the diesel hammer comprises the steps of providing first and second guide members, where each guide member defines one of the primary channels, andat least one primary mounting hole; andrigidly connecting the first and second guide members to the diesel hammer;the step of providing the first channel adapter assemblies comprises the steps of providing a first secondary channel member;providing a first base member defining at least one first secondary mounting hole; andrigidly connecting at least one first standoff member between the first base member and the first secondary channel member;the step of providing the second channel adapter assemblies comprises the steps of providing a second secondary channel member;providing a second base member defining at least one second secondary mounting hole; andrigidly connecting at least one second standoff member between the second base member and the second secondary channel member; whereinin the second configuration, each first secondary mounting hole is aligned with one primary mounting hole;at least one bolt assembly is extended through each aligned primary mounting hole and first secondary mounting hole; andat least a portion of the at least one bolt assembly is arranged between the first base member and the first secondary channel member.in the third configuration, each second secondary mounting hole is aligned with one primary mounting hole;at least one bolt assembly is extended through each aligned primary mounting hole and second secondary mounting hole; andat least a portion of the at least one bolt assembly is arranged between the second base member and the second secondary channel member.
12. A method as recited in claim 7, in which: the step of rigidly connecting the primary channel system to the diesel hammer comprises the steps of providing first and second guide members, where each guide member defines one of the primary channels, andat least one primary mounting hole, andrigidly connecting the first and second guide members to the diesel hammer; andthe step of providing the first channel adapter assemblies comprises the steps of providing a first secondary channel member;providing a base member defining a first secondary mounting hole;rigidly connecting at least one standoff member between the base member and the secondary channel member; whereinin the second configuration, each first secondary mounting hole is aligned with one primary mounting hole;the at least one bolt assembly is extended through each aligned primary mounting hole and secondary mounting hole; andat least a portion of the at least one bolt assembly is arranged between the base member and the first secondary channel member.
13. A guide system for allowing a diesel hammer to be supported by first, second, and third support systems, the guide system comprising: a primary channel system rigidly connected to the diesel hammer to define a pair of primary channels,a primary spacing distance between the primary channels;a pair of first channel adapter assemblies each defining a first secondary channel; anda pair of second channel adapter assemblies each defining a second secondary channel; whereinthe guide system operates in a first configuration in which portions of the first support system are received within the primary channels,in a second configuration in which each of the first secondary channel adapter assemblies is detachably attached to the primary channel system such that the first channel adapter assemblies define a first secondary spacing distance between the first secondary channels,the first secondary spacing distance is different from the primary spacing distance, andportions of the second support system are received within the first secondary channels, andin a third configuration in which each of the second channel adapter assemblies is detachably attached to the primary channel system such that the second channel adapter assemblies define a second secondary spacing distance between the first secondary channels,the second secondary spacing distance is different from the primary spacing distance and the first secondary spacing distance, andportions of the third support system are received within the second secondary channels.
14. A guide system as recited in claim 13, further comprising a plurality of connecting assemblies, in which the plurality of connecting assemblies are arranged to detachably attach the first channel adapter assemblies to the primary channel system.
15. A guide system as recited in claim 14, in which the primary channel system is rigidly connected to the diesel hammer to define a primary offset distance, where the primary offset distance is predetermined to allow assembly of the plurality of connecting assemblies.
16. A guide system as recited in claim 13, further comprising at least one bolt assembly, in which: the primary channel system comprises first and second guide members, where each guide member definesone of the primary channels, andat least one primary mounting hole; andeach first channel adapter assembly comprises: a first secondary channel member;a first base member defining at least one first secondary mounting hole; andat least one first standoff member rigidly connected between the first base member and the first secondary channel member;each second channel adapter assembly comprises: a second secondary channel member;a second base member defining at least one second secondary mounting hole; andat least one second standoff member rigidly connected between the second base member and the second secondary channel member; whereinin the second configuration, each first secondary mounting hole is aligned with one primary mounting hole;the at least one bolt assembly is extended through each aligned primary mounting hole and first secondary mounting hole; andat least a portion of the at least one bolt assembly is arranged between the first base member and the first secondary channel member;in the third configuration, each second secondary mounting hole is aligned with one primary mounting hole;the at least one bolt assembly is extended through each aligned primary mounting hole and second secondary mounting hole; andat least a portion of the at least one bolt assembly is arranged between the second base member and the second secondary channel member.

RELATED APPLICATIONS

This application U.S. patent application Ser. No. 15/376,446 filed Dec. 12, 2016 claims benefit of U.S. Provisional Application Ser. No. 62/267,048 filed Dec. 14, 2015, now expired, the contents of which are incorporated herein by reference.

US Referenced Citations (271)

Number	Name	Date	Kind
5015	Ingalls	Mar 1847	A
48515	Campbell et al.	Jul 1865	A
369176	Gerstein	Aug 1887	A
400209	Haskins	Mar 1889	A
628962	Speer	Jul 1899	A
999334	Pearson	Aug 1911	A
1128808	Manoogian	Feb 1915	A
1213800	Piper	Jan 1917	A
1288989	Rees	Dec 1918	A
1294154	Payne	Feb 1919	A
1322470	Schenk	Nov 1919	A
1348994	Heckle	Aug 1920	A
1464231	Yezek	Aug 1923	A
1654093	Reid	Dec 1927	A
1702349	Krell	Feb 1929	A
1748555	Kinney	Feb 1930	A
1762037	Taylor	Jun 1930	A
1769169	Thornley	Jul 1930	A
1787000	Hunt	Dec 1930	A
1903555	Robertson	Apr 1933	A
1914899	Syme	Jun 1933	A
1988173	Kersting	Jan 1935	A
2068045	Wohlmeyer	Jan 1937	A
2239024	Vance	Apr 1941	A
2577252	Kjellman	Dec 1951	A
2723532	Smith	Nov 1955	A
2755783	Kupka	Jul 1956	A
2804856	Spurlin	Sep 1957	A
2842972	Houdart	Jul 1958	A
2859628	Arko	Nov 1958	A
2882690	Frederick	Apr 1959	A
2904964	Kupka	Sep 1959	A
2952132	Urban	Sep 1960	A
3001515	Haage	Sep 1961	A
3004389	Muller	Oct 1961	A
3034304	Upson	May 1962	A
3094007	Luhrs	Jun 1963	A
3100382	Muller	Aug 1963	A
3101552	Tandler	Aug 1963	A
3106258	Muller	Oct 1963	A
3108503	Murek	Oct 1963	A
3115198	Kuss	Dec 1963	A
3149851	Adams	Sep 1964	A
3172485	Spannhake et al.	Mar 1965	A
3177029	Larson	Apr 1965	A
3193026	Kupka	Jul 1965	A
3227483	Guild et al.	Jan 1966	A
3243190	Peregrine	Mar 1966	A
3267677	Bollar	Aug 1966	A
3289774	Bodine, Jr.	Dec 1966	A
3300987	Maeda	Jan 1967	A
3313376	Holland	Apr 1967	A
3371727	Belousov et al.	Mar 1968	A
3381422	Olson	May 1968	A
3391435	Lebelle	Jul 1968	A
3394766	Lebelle	Jul 1968	A
3412813	Johnson	Nov 1968	A
3447423	Henry	Jun 1969	A
3450398	Barnes	Jun 1969	A
3460637	Schulin	Aug 1969	A
3513587	Artur	May 1970	A
3530947	Gendron	Sep 1970	A
3577645	Zurawski	May 1971	A
3583497	Kossowski et al.	Jun 1971	A
3616453	Philpot	Oct 1971	A
3620137	Prasse	Nov 1971	A
3638738	Varnell	Feb 1972	A
3679005	Inaba et al.	Jul 1972	A
3684037	Bodine	Aug 1972	A
3686877	Bodin	Aug 1972	A
3711161	Proctor et al.	Jan 1973	A
3720435	Leyn	Mar 1973	A
3734209	Haisch et al.	May 1973	A
3786874	Demichelis et al.	Jan 1974	A
3789930	Nishimura et al.	Feb 1974	A
3797585	Ludvigson	Mar 1974	A
3822969	Kummel	Jul 1974	A
3828864	Haverkamp et al.	Aug 1974	A
3854418	Bertin	Dec 1974	A
3861664	Durkee	Jan 1975	A
3865501	Kniep	Feb 1975	A
3871617	Majima	Mar 1975	A
3874244	Rasmussen et al.	Apr 1975	A
3891186	Thorsell	Jun 1975	A
3907042	Halwas et al.	Sep 1975	A
3952796	Larson	Apr 1976	A
3959557	Berry	May 1976	A
3967688	Inenaga et al.	Jul 1976	A
3975918	Jansz	Aug 1976	A
3991833	Ruppert	Nov 1976	A
3998063	Harders	Dec 1976	A
4018290	Schmidt	Apr 1977	A
4029158	Gerrish	Jun 1977	A
4033419	Pennington	Jul 1977	A
4067369	Harmon	Jan 1978	A
4076081	Schnell	Feb 1978	A
4082361	Lanfermann	Apr 1978	A
4099387	Frederick et al.	Jul 1978	A
4100974	Pepe	Jul 1978	A
4102408	Ludvigson	Jul 1978	A
4109475	Schnell	Aug 1978	A
4113034	Carlson	Sep 1978	A
4119159	Arentsen	Oct 1978	A
4143985	Axelsson et al.	Mar 1979	A
4154307	Gendron et al.	May 1979	A
4155600	Lanfermann et al.	May 1979	A
4166508	van den Berg	Sep 1979	A
4180047	Bertelson	Dec 1979	A
4187917	Bouyoucos	Feb 1980	A
4195698	Nakagawasai	Apr 1980	A
4248550	Blaschke et al.	Feb 1981	A
4262755	Kuhn	Apr 1981	A
4274761	Boguth	Jun 1981	A
4312413	Loftis	Jan 1982	A
4362216	Jansz	Dec 1982	A
4366870	Frederick	Jan 1983	A
4367800	Arentsen	Jan 1983	A
4375927	Kniep	Mar 1983	A
4380918	Killop	Apr 1983	A
4382475	Suzuki	May 1983	A
4397199	Jahn	Aug 1983	A
4421180	Fleishman et al.	Dec 1983	A
4428699	Juhola	Jan 1984	A
4430024	Guild et al.	Feb 1984	A
4436452	Bodine	Mar 1984	A
4455105	Juhola	Jun 1984	A
4465145	Kuhn	Aug 1984	A
4473123	Ranft et al.	Sep 1984	A
4497376	Kurylko	Feb 1985	A
4505614	Anschutz	Mar 1985	A
4519729	Clarke et al.	May 1985	A
4537527	Juhola et al.	Aug 1985	A
4547110	Davidson	Oct 1985	A
4553443	Rossfelder et al.	Nov 1985	A
4601615	Cavalli	Jul 1986	A
4603748	Rossfelder et al.	Aug 1986	A
4624325	Steiner	Nov 1986	A
4626138	Boyes	Dec 1986	A
4627768	Thomas et al.	Dec 1986	A
4632602	Hovnanian	Dec 1986	A
4637475	England et al.	Jan 1987	A
4645017	Bodine	Feb 1987	A
4687026	Westman	Aug 1987	A
4725167	Merjan	Feb 1988	A
4735270	Fenyvesi	Apr 1988	A
4755080	Cortlever et al.	Jul 1988	A
4757809	Koeneman et al.	Jul 1988	A
4758148	Jidell	Jul 1988	A
4768900	Burland	Sep 1988	A
4799557	Jacquemet	Jan 1989	A
4813814	Shibuta et al.	Mar 1989	A
4844661	Martin et al.	Jul 1989	A
4863312	Cavalli	Sep 1989	A
4915180	Schisler	Apr 1990	A
4961471	Ovens	Oct 1990	A
4974997	Sero et al.	Dec 1990	A
4989677	Lam	Feb 1991	A
4993500	Greene et al.	Feb 1991	A
5004055	Porritt et al.	Apr 1991	A
5018251	Brown	May 1991	A
5076090	Cetnarowski	Dec 1991	A
5088565	Evarts	Feb 1992	A
5107934	Atchison	Apr 1992	A
5117925	White	Jun 1992	A
5154667	Mauch et al.	Oct 1992	A
5161625	Seng	Nov 1992	A
5213449	Morris	May 1993	A
5253542	Houze	Oct 1993	A
RE34460	Ishiguro et al.	Nov 1993	E
5263544	White	Nov 1993	A
5281775	Gremillion	Jan 1994	A
5343002	Gremillion	Aug 1994	A
5355964	White	Oct 1994	A
5375897	Gazel-Anthoine	Dec 1994	A
5385218	Migliori	Jan 1995	A
5409070	Roussy	Apr 1995	A
5410879	Houze	May 1995	A
5423633	Verstraeten	Jun 1995	A
5439326	Goughnour et al.	Aug 1995	A
5526885	Kuvshinov et al.	Jun 1996	A
5529132	Evarts	Jun 1996	A
5540193	Achten et al.	Jul 1996	A
5540295	Serrette	Jul 1996	A
5544979	White	Aug 1996	A
5549168	Sadler et al.	Aug 1996	A
5551804	Breaux et al.	Sep 1996	A
5562169	Barrow	Oct 1996	A
5609380	White	Mar 1997	A
5653556	White	Aug 1997	A
5658091	Goughnour et al.	Aug 1997	A
5727639	Jeter	Mar 1998	A
5788419	Whitty, Jr. et al.	Aug 1998	A
5794716	White	Aug 1998	A
5806610	Sapozhnikov	Sep 1998	A
5811741	Coast et al.	Sep 1998	A
5836205	Meyer	Nov 1998	A
5860482	Gremillion et al.	Jan 1999	A
5918511	Sabbaghian et al.	Jul 1999	A
5924498	Nilsen	Jul 1999	A
5934835	Whitty, Jr. et al.	Aug 1999	A
6003619	Lange	Dec 1999	A
6039508	White	Mar 2000	A
6056070	Shinohara et al.	May 2000	A
6102133	Scheid et al.	Aug 2000	A
6129159	Scott et al.	Oct 2000	A
6129487	Bermingham et al.	Oct 2000	A
6135214	Last	Oct 2000	A
6155353	Ottestad	Dec 2000	A
6179527	Goughnour	Jan 2001	B1
6186043	Callies	Feb 2001	B1
6216394	Fenelon	Apr 2001	B1
6224294	Mansfield	May 2001	B1
6227767	Mosing et al.	May 2001	B1
6234260	Coast et al.	May 2001	B1
6250426	Lombard	Jun 2001	B1
6360829	Naber et al.	Mar 2002	B1
6364577	Haney	Apr 2002	B1
6378951	Bouyoucos et al.	Apr 2002	B1
6386295	Suver	May 2002	B1
6427402	White	Aug 2002	B1
6431795	White	Aug 2002	B2
6447036	White	Sep 2002	B1
6484553	Devers	Nov 2002	B1
6543966	White	Apr 2003	B2
6557647	White	May 2003	B2
6582158	Van Stein	Jun 2003	B1
6648556	White	Nov 2003	B1
6652194	Ingle	Nov 2003	B2
6672805	White	Jan 2004	B1
6691797	Hart	Feb 2004	B1
6732483	White	May 2004	B1
6736218	White	May 2004	B1
6752043	Carlson	Jun 2004	B2
6860338	Salesse et al.	Mar 2005	B2
6896448	White	May 2005	B1
6908262	White	Jun 2005	B1
6942430	Suver	Sep 2005	B1
6988564	White	Jan 2006	B2
7043806	Schrock et al.	May 2006	B2
7168890	Evarts	Jan 2007	B1
7392855	White	Jul 2008	B1
7404449	Bermingham et al.	Jul 2008	B2
7407343	van Halteren et al.	Aug 2008	B2
7591612	Wong	Sep 2009	B2
7694747	White	Apr 2010	B1
7708499	Evarts et al.	May 2010	B1
7726913	Sjogren	Jun 2010	B1
7824132	White	Nov 2010	B1
7854571	Evarts	Dec 2010	B1
7950877	Evarts	May 2011	B2
7972083	Jones	Jul 2011	B2
8070391	White	Dec 2011	B2
8181713	White	May 2012	B2
8186452	White et al.	May 2012	B1
8763719	White	Jul 2014	B2
20020139550	Mewes	Oct 2002	A1
20030143036	Larsen, Jr.	Jul 2003	A1
20050013675	Bengston et al.	Jan 2005	A1
20050232708	White	Oct 2005	A1
20060052818	Drake et al.	Mar 2006	A1
20060113456	Miller	Jun 2006	A1
20060216118	Wong	Sep 2006	A1
20080310923	Jinnings et al.	Dec 2008	A1
20090129870	Jones	May 2009	A1
20100303552	Yingling et al.	Dec 2010	A1
20110162859	White	Jul 2011	A1
20110243668	White	Oct 2011	A1
20110252610	Evarts	Oct 2011	A1
20120114424	White	May 2012	A1
20140231115	Heichel	Aug 2014	A1
20180002886	Cress et al.	Jan 2018	A1

Foreign Referenced Citations (40)

Number	Date	Country
2538852	Mar 2003	CN
101182714	May 2008	CN
107558472	Jan 2018	CN
4010357	Oct 1990	DE
4414190	Jul 1995	DE
102006053482	Jun 2008	DE
0172960	May 1986	EP
362158	Apr 1990	EP
526743	Oct 1993	EP
838717	Mar 1939	FR
2560247	Aug 1985	FR
1066727	Apr 1967	GB
2003769	Mar 1979	GB
2023496	Jan 1980	GB
2028902	Mar 1980	GB
2043755	Oct 1980	GB
2060742	May 1981	GB
5494703	Jul 1979	JP
355098526	Jul 1980	JP
356034828	Apr 1981	JP
57169130	Oct 1982	JP
59228529	Dec 1984	JP
61221416	Oct 1986	JP
0258627	Feb 1990	JP
497015	Mar 1992	JP
473035	Jun 1992	JP
5246681	Sep 1993	JP
6136751	May 1994	JP
9328983	Dec 1997	JP
1020010044658	May 2001	KR
1020030017742	Apr 2003	KR
42349	Jan 1938	NL
65252	Feb 1950	NL
7710385	Mar 1978	NL
7707303	Jan 1979	NL
7805153	Nov 1979	NL
46428	Apr 1929	NO
1027357	Jul 1983	SU
8707673	Dec 1987	WO
8805843	Aug 1988	WO

Non-Patent Literature Citations (18)

Entry
USPTO, “Non-Final Office Action, U.S. Appl. No. 15/199,695, p. 218701,” dated Sep. 19, 2018, 18 pages.
“Kony Drain Board,” undated, 1 page.
“The 1st Report on the Treatment of Soft Foundation in Juck Hyun Industrial Site”, Ref. Nos. APE00854-APE00856, 1976, 3 pages.
American Piledriving Equipment, Inc., A series of photographs identified by Reference Nos. APE01147-APE01159, undated, 13 pages.
APE, “APE Model 8 Hydraulic Impact Hammer,” 2000, 1 page.
CCPIT Patent and Trademark Law Office, Office Action and Search Report, Application No. 201210346475.7, Apr. 27, 2015, 15 pages.
International Construction Equipment, Inc., “Diesel Pile Hammers” brochure, Ref. No. DH4-1288-5C, undated, 6 pages.
International Construction Equipment, Inc., “Hydraulic Vibratory Driver/Extractors for Piling and Caisson Work,” Ref. No. V7-0890-51, undated, 3 pages.
International Construction Equipment, Inc., “Hydraulic Vibratory Driver/Extractors for Piling and Caisson Work,” undated, 10 pages.
International Searching Authority, “International Search Report”, dated Jan. 28, 2011, 11 pages.
Japan Development Consultants, INC., “Castle Board Drain Method” Japanese language brochure, Ref. Nos. APE00857-APE00863, Aug. 1976, 6 pages.
Korean language documents identified by Ref. Nos. APE00864-APE00891, dates from 1982-1997, 28 pages.
MKT Corporation, “Operating, Maintenance and Parts Manual for MS350 and MS500 Single-Acting Pile Hammers,” 12 pages.
MKT Geotechnical Systems, Manual No. 01807: “Operating, Maintenance and Parts manual for MS350 and MS500 Single-Acting Pile Hammers,” undated, 12 pages.
Report identifying systems for driving mandrels carrying wick drain material into the earth, Ref. Nos. APE0510-APE0536, undated, 27 pages.
Schematic drawings, Ref. Nos. APE01038, APE01039, APE0339, undated, 2 pages.
Shanghai Jintai SEMW, undated, 8 pages.
www.mmsonline.com/columns/micro-keying-keeps-a-better-grip.aspx, Seibert, Stan, Modern Machine Shop: “Micro-Keying Keeps a Better Grip,” Aug. 1, 1992, 2 pages.

Related Publications (1)

	Number	Date	Country
	20170167104 A1	Jun 2017	US

Provisional Applications (1)

	Number	Date	Country
	62267048	Dec 2015	US

Guide systems and methods for diesel hammers

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