The present invention relates to methods and apparatus for inserting elongate members into the earth and, more particularly, to diesel hammers that create pile driving forces by combusting diesel fuel.
For certain construction projects, elongate members such as piles, anchor members, caissons, and mandrels for inserting wick drain material must be placed into the earth. It is well-known that such rigid members may often be driven into the earth without prior excavation. The term “piles” will be used herein to refer to the elongate rigid members typically driven into the earth.
One system for driving piles is conventionally referred to as a diesel ram for driving the pile and as a piston for compressing diesel fuel. Diesel fuel is injected into a combustion chamber below the ram member as the ram member drops. The dropping ram member engages an anvil member that transfers the load of the ram member to the pile to drive the pile. At the same time, the diesel fuel ignites, forcing the ram member and the anvil member in opposite directions. The anvil member further drives the pile, while the ram member begins a new combustion cycle.
An important factor in the operation of a diesel hammer is the quantity of diesel fuel injected into the combustion chamber because the ignition of the diesel fuel directly determines the driving forces applied to the pile. In particular, the quantity of diesel fuel determines both the forces on the anvil member both at the point of ignition and, because it affects how high the ram member goes, when the ram member impacts the anvil member on the compression stroke prior to ignition.
Conventional diesel hammers employ a variable fuel pump having a fuel chamber, a control pulley, and a control rope. The fuel chamber stores the fuel to be delivered to the combustion chamber. The angular orientation of the control pulley determines the effective volume of the fuel chamber. The control rope extends partly around the control pulley such that pulling on either end of the control rope causes the control pulley to rotate and change its angular orientation. Conventional variable fuel pumps require an operator to stand on the ground adjacent to the diesel hammer and pull the control rope to adjust the effective volume of the fuel chamber. The process of adjusting the amount of fuel delivered to the combustion chamber is thus cumbersome and conventional variable fuel pumps are typically placed in one setting and left there during the driving process.
The need thus exists for improved variable fuel pumps for diesel hammers.
Submitted herewith are portions of operations manuals for diesel hammers depicting the basic operation of diesel hammers and the fuel pumps used by commercially available diesel hammers. These references employ a control rope and control pulley to change the amount of fuel delivered to the combustion chamber as generally described in the BACKGROUND section of this application.
The present invention may be embodied as a diesel hammer system for driving a pile. The diesel hammer system comprises a housing, an anvil member supported by the housing, a clamp assembly adapted to connect the anvil member to the pile, and a ram member disposed within the housing. A fuel pump system injects fuel into a combustion chamber defined by the housing, anvil member, and the ram member. A coupling system detachably engages the ram member to raise the ram member from an impact position to an upper position, the coupling system comprising a t2igger member that, when engaged, causes the coupling system to release, the ram member. A trigger projection mounted is on the housing to engage the trigger member to cause the coupling system to release the ram member at the upper position.
The diesel hammer further comprises a pre-trigger system comprising a pre-trigger member movable between an extended position and a retracted position. When the pre-trigger member is in the extended position, the pre-trigger member engages the trigger member as the ram member moves from the impact position towards the upper position to cause the coupling system to release the ram member at a pre-trigger position. When the pre-trigger member is in the retracted position, the pre-trigger member does not engage the trigger member as the ram member moves from the impact position to the upper position.
When the pre-trigger member is in the retracted position, the ram member moves from the impact position to the upper position and back to the impact position such that the ram member acts on the pump piston through the pump lever to force fuel out of the fuel chamber and into the combustion chamber. When the pre-trigger member is in the extended position, movement of the ram member from the impact position to the pre-trigger position and back to the impact position does not cause fuel to be forced out of the fuel chamber and into the combustion chamber.
FIGS. 13A-F are somewhat schematic section views of yet another exemplary diesel hammer of the present invention; and
The first section of the following discussion will describe the basic construction and operation of diesel hammer pile driving systems. The next section will contain will be a more detailed discussion of prior art variable fuel pumps. The following section will contain a discussion of the variable fuel pump of the present invention.
Turning to the drawing, depicted at 20 in
The diesel hammer system 20 comprises a ram member 30, an anvil member 32, a housing member 34, a clamp assembly 36, and a fuel pump system 38. The ram member 30 is guided by the housing member 34 for movement between a lower position (
A combustion chamber 40 is formed within the housing member 34 between a lower surface 42 of the ram member 30 and an upper surface 44 of the anvil member 32. Seals 50 and 52 are arranged in gaps 54 and 56 between an inner surface 46 of the housing member 34 and the ram and anvil members 30 and 32, respectively. When the seals 50 and 52 function properly, fluid is substantially prevented from flowing out of the combustion chamber 40 through these gaps 54 and 56.
A fuel port 60 and an exhaust port 62 are formed in the housing member 34. The fuel port 60 is arranged to allow the fuel pump system 38 to inject fuel into the combustion chamber 40. The exhaust port 62 is arranged to allow exhaust gasses to be expelled from the combustion chamber 40 and to allow air to be drawn into the chamber 40.
The fuel pump system 38 comprises a pump lever 70. The pump lever 70 is biased into a ready position in which at least a portion of the pump lever 70 is within the housing member 34 (
The diesel hammer system 20 operates in a combustion cycle that will now be described with reference to
As the combustion cycle continues, the ram member 30 drops to a level where both the fuel port 60 and exhaust port 62 are covered by the ram member 30. At this point, the combustion chamber 40 is effectively sealed, and continued dropping of the ram member 30 compresses the air/fuel mixture within the combustion chamber 40.
Referring now to
When the system 20 is in the impact state, the diesel fuel within the combustion chamber 40 ignites in the highly compressed air. The explosion resulting from the ignition of the air/fuel mixture forces the ram member 30 up and the anvil member 32 down. This explosion thus further drives the pile member 22 into the ground.
After the ignition occurs, the anvil member 32 is raised to an upper position as shown in
As the ram member continues on to its upper position, fresh air is drawn into the combustion chamber 40 through the exhaust port 62. In addition, the ram member 30 disengages from the pump lever 70. As soon as the ram member 30 disengages from the pump lever, the bias on the pump lever 70 returns the pump lever 70 to the ready position from the pump position and the fuel system 38 readies another quantity of fuel for the next cycle.
After the ram member 30 reaches the upper position as shown in
Referring now to
The fuel pump cylinder assembly 124 comprises a fuel pump housing 130, a piston 132, and a pump spring 134. The fuel pump housing 130 defines a longitudinal axis B. The piston 132 comprises a piston head 140 and a piston shaft 142. The axis of the piston shaft 142 is aligned with the housing axis B such that the piston 132 moves along the housing axis B.
The fuel pump housing 130 defines a fuel pump chamber 150, and the piston head 140 divides the fuel pump chamber 150 into a fuel portion 152 and a reserve portion 154. A seal (not shown) prevents the flow of fluid between the fuel portion 152 and reserve portion 154.
The fuel source 122 is connected through a first conduit 160 to the fuel portion 152 of the fuel pump chamber 150. A first check valve 162 arranged in the first conduit 160 allows fluid to flow only from the source 122 to the fuel pump chamber 150. The fuel portion 152 of the fuel pump chamber 150 is also connected by a second conduit 164 to the fuel port 60 in the housing member 34. A second check valve 166 arranged in the second conduit 164 allows fluid to flow only from the fuel pump chamber 150 to the fuel port 60.
A spring landing 170 is formed on the fuel pump housing 130, and a spring retainer 172 is formed on the piston shaft 142. The pump spring 134 is a compression spring arranged between the spring landing 170 and the spring retainer 172. The pump spring 134 thus biases the spring retainer 172 away from the spring landing 170.
The fuel pump lever 126 is pivotably connected at one end to a pivot point 174 on the housing member 34. The pump lever 126 thus rotates between the ready (
Accordingly, rotational movement of the fuel pump lever 126 about the pivot point 174 is translated into displacement of the piston 132 along the housing axis B. In particular, clockwise rotation of the fuel pump lever 126 causes the pump head 140 to move within the pump chamber 150 to decrease the volume of the fuel portion 152 thereof, while counter-clockwise rotation of the fuel pump lever 126 allows the pump spring 134 to move the pump head 140 in the opposite direction, thereby increasing the volume of the fuel portion 152 of the pump chamber 150. The pump spring 134 thus assists movement of the fuel pump lever 126 in the clockwise direction and opposes movement of the fuel pump lever 126 in the counter-clockwise direction.
A comparison of
Further, as shown in
The amount of fuel delivered by the variable fuel pump system 120 is determined by the volume of the fuel portion 152 of the pump chamber 150. The travel limiting assembly 128 is used to adjust the angular position of the pump lever 126 when the lever 126 is in the ready position. Because the pump lever 126 is connected to the piston 132 as described above, the travel limiting assembly 128 thus determines the volume of the fuel portion 152.
The travel limiting assembly 128 comprises a link arm 180, a link spring 182, a cam member 184, a cam roller 186, a control pulley 188, and a control rope 190. The cam member 184 rotates about a cam axis C. The control pulley 188 is attached to the cam member 184 such that rotation of the pulley 188 causes rotation of the cam member 184 about the cam axis C. The control rope 190 engages the control pulley 188 such that pulling on either end of the control rope 190 causes the control pulley 188 to rotate, which in turn causes the cam member 184 to rotate about the cam axis C.
The cam member 184 is eccentric such that the distance between a cam surface 192 and the cam axis C varies from a first location 194 to a second location 196 on the cam surface 192. The cam roller 186 rides on the cam surface 192 such that the distance between the cam roller 186 and the cam axis C varies with angular rotation of the cam member 184. The cam axis C is fixed relative to the housing member 34; therefor, rotation of the cam member 184 causes the cam roller 186 to move relative to the housing member 34.
The link arm 180 is rigidly connected to the pump lever 126 such that the link arm 180 also rotates about the pivot point 174. The link arm 180 is arranged to apply a force on the cam roller 186 that holds the cam roller 186 against the cam surface 192, with the link spring 182 in compression between the link arm 180 and the cam roller 186.
A comparison of
The cam roller 186 in turn acts through the link spring 182 and link arm 180 to place the pump lever 126 in a first angular location (
The angular position of the cam member 184 thus determines the volume of the fuel portion 152 of the pump chamber 150 when the pump lever 126 is in the ready position; this relationship can be seen by comparing
As described above, pulling the ends of the control rope 190 determines the angular position of the cam member 184; the control rope 190 can thus be used to set the volume of the fuel portion 152 of the pump chamber 150.
Referring now to
Referring now to
Referring now to
The fuel pump system 220 comprises a source 222 of fuel, a fuel pump cylinder assembly 224, a fuel pump lever 226, and a travel limiting assembly 228. The pump lever 126 is used as the pump lever 70 described above. The fuel pump cylinder assembly 224 comprises a fuel pump housing 230, a piston 232, and a pump spring 234. The fuel pump housing 230 defines a longitudinal axis B. The piston 232 comprises a piston head 240 and a piston shaft 242. The axis of the piston shaft 242 is aligned with the housing axis B such that the piston 232 moves along the housing axis B.
The fuel pump housing 230 defines a fuel pump chamber 250, and the piston head 240 divides the fuel pump chamber 250 into a fuel portion 252 and a reserve portion 254. A seal (not shown) prevents the flow of fluid between the fuel portion 252 and reserve portion 254.
The fuel source 222 is connected through a first conduit 260 to the fuel portion 252 of the fuel pump chamber 250. A first check valve 262 arranged in the first conduit 260 allows fluid to flow only from the source 222 to the fuel pump chamber 250. The fuel portion 252 of the fuel pump chamber 250 is also connected by a second conduit 264 to the fuel port 60 in the housing member 34. A second check valve 266 arranged in the second conduit 264 allows fluid to flow only from the fuel pump chamber 250 to the fuel port 60.
A spring landing 270 is formed on the fuel pump housing 230, and a spring retainer 272 is formed on the piston shaft 242. The pump spring 234 is a compression spring arranged between the spring landing 270 and the spring retainer 272. The pump spring 234 thus biases the spring retainer 272 away from the spring landing 270.
The fuel pump lever 226 is pivotably connected at one end to a pivot point 274 on the housing member 34. The pump lever 226 thus rotates between the ready (
Accordingly, rotational movement of the fuel pump lever 226 about the pivot point 274 is translated into displacement of the piston 232 along the housing axis B. In particular, clockwise rotation of the fuel pump lever 226 causes the pump head 240 to move within the pump chamber 250 to decrease the volume of the fuel portion 252 thereof, while counter-clockwise rotation of the fuel pump lever 226 allows the pump spring 234 to move the pump head 240 in the opposite direction, thereby increasing the volume of the fuel portion 252 of the pump chamber 250. The pump spring 234 thus assists movement of the fuel pump lever 226 in the clockwise direction and opposes movement of the fuel pump lever 226 in the counter-clockwise direction.
A comparison of
Further, as shown in
The amount of fuel delivered by the variable fuel pump system 220 is determined by the volume of the fuel portion 252 of the pump chamber 250. The travel limiting assembly 228 is used to adjust the angular position of the pump lever 226 when the lever 226 is in the ready position. Because the pump lever 226 is connected to the piston 232 as described above, the travel limiting assembly 228 thus determines the volume of the fuel portion 252.
The travel limiting assembly 228 comprises a link arm 280, a link spring 282, a cam member 284, a cam roller 286, a control pinion 288, and a control rack assembly 290. The cam member 284 rotates about a cam axis C. The control pinion 288 is attached to the cam member 284 such that rotation of the pulley 288 causes rotation of the cam member 284 about the cam axis C. The control rack assembly 290 engages the control pinion 288 to cause the control pinion 288 to rotate, which in turn causes the cam member 284 to rotate about the cam axis C.
The cam member 284 is eccentric such that the distance between a cam surface 292 and the cam axis C varies from a first location 294 to a second location 296 on the cam surface 292. The cam roller 286 rides on the cam surface 292 such that the distance between the cam roller 286 and the cam axis C varies with angular rotation of the cam member 284. The cam axis C is fixed relative to the housing member 34; therefor, rotation of the cam member 284 causes the cam roller 286 to move relative to the housing member 34.
The link arm 280 is rigidly connected to the pump lever 226 such that the link arm 280 also rotates about the pivot point 274. The link arm 280 is arranged to apply a force on the cam roller 286 that holds the cam roller 286 against the cam surface 292, with the link spring 282 in compression between the link arm 280 and the cam roller 286.
A comparison of
The cam roller 286 in turn acts through the link spring 282 and link arm 280 to place the pump lever 226 in a first angular location (
The angular position of the cam member 284 thus determines the volume of the fuel portion 252 of the pump chamber 250 when the pump lever 226 is in the ready position; this relationship can be seen by comparing
The control rack assembly 290 comprises a control rack 320 and a control cylinder assembly 322.
The control cylinder assembly 322 comprises a control cylinder housing 330 and a control piston 332 having a control piston head 334 and a control piston shaft 336. The control piston head 334 is arranged within the cylinder housing 330 to divide a control chamber 338 defined by the housing 330 into first and second portions 340 and 342. The application of hydraulic fluid to one or both of the control chamber portions 340 and 342 causes linear displacement of the control rack 320 along a path D.
The control rack 320 comprises a toothed surface portion 344, and the control pinion 288 comprises a toothed surface portion 346. The teeth on the surface portions 344 and 346 are designed to mate with each other. In addition, the control rack 320 is supported adjacent to the control pinion 288 such that these surfaces portions 340 and 342 engage each other. Accordingly, linear displacement of the control rack 320 along the path D causes rotation of the control pinion 288 about the cam axis C. Because the control pinion 288 is attached to the cam member 284, the rotation of the control pinion 288 causes rotation of the cam member 284.
Accordingly, the travel limiting assembly 228 allows the volume of the fuel portion 252 of the pump chamber 250 to be changed remotely by the appropriate application of hydraulic fluid to the cylinder assembly 322. A comparison of
Referring now to
The control cylinder assembly 350 comprises first and second ports 352 and 354 that allow hydraulic fluid to be introduced into the first and second control chamber portions 340 and 342, respectively. In particular, introducing fluid into the first control chamber portion 340 while allowing fluid to flow out of the second control chamber portion 342 causes the control piston 332 to move in a first direction along the axis D. Introducing fluid into the second control chamber portion 342 while allowing fluid to flow out of the first control chamber portion 340 causes the control piston 332 to move in a second (opposite) direction along the axis D. The conduits and hydraulic controls required to apply fluid to the first and second ports 352 and 354 are conventional and will not be described herein in detail.
Referring now to
The control cylinder assembly 360 comprises a port 362 that allows hydraulic fluid to be introduced into the first control chamber portion 340. In addition, a return spring 364 is arranged in the second control chamber portion 342 to oppose movement of the control piston 332 in a first direction along the axis D. Hydraulic fluid is introduced into the first control chamber portion 340 to cause the control piston 332 to move in the first direction along the axis D to a desired position. As long as a predetermined level of hydraulic pressure is maintained in the first control chamber portion 340, the control piston 332 will remain in the desired position. Releasing pressure within the first control chamber portion 340 allows the return spring 364 to move the control piston in a second (opposite) direction along the axis D. The conduits and hydraulic controls required to apply fluid to the first port 362 are conventional and will not be described herein in detail.
Referring now to
The control cylinder assembly 370 comprises a port 372 that allows hydraulic fluid to be introduced into the first control chamber portion 340. In addition, a return spring 374 is arranged to engage the control rack 322 to oppose movement of the control piston 332 in a first direction along the axis D. Hydraulic fluid is introduced into the first control chamber portion 340 to cause the control piston 332 to move against the force of the spring 374 in the first direction along the axis D to a desired position. As long as a predetermined level of hydraulic pressure is maintained in the first control chamber portion 340, the control piston 332 will remain in the desired position. Releasing pressure within the first control chamber portion 340 allows the return spring 374 to move the control piston in a second (opposite) direction along the axis D. The conduits and hydraulic controls required to apply fluid to the first port 372 are conventional and will not be described herein in detail.
In any of the control cylinder assemblies 350, 360, and 370, the hydraulic fluid may be applied to the control ports from a location remote from the location of the hammer system 20. For example, an operator of the crane or other equipment that supports the hammer system 20 may be provided with a lever or button that may be pulled or depressed to apply hydraulic fluid to these control ports as described above. The operator need not be physically adjacent to the hammer system 20 to vary the amount of fuel required, so the operator is more likely to adjust the fuel setting as required by a particular situation. Referring now to
Referring now to
Referring now to FIGS. 13A-F, these figures illustrate that the diesel hammer system 20 conventionally comprises a line 430 from which is suspended 5 a coupling assembly 432. The coupling assembly 432 is detachably attached to an upper end of the ram member 30. Accordingly, lifting the line 430 lifts the ram member 30. In addition, the coupling assembly 434 conventionally comprises a trigger member 434 that, when properly displaced, detaches the coupling assembly 432 from the ram member 30. The coupling assembly 432 comprises a trigger projection 436 that extends from the housing member 34 to engage the trigger member 434 and release the ram member 30 from the coupling assembly 434. The coupling assembly 432 is conventional and will not be described herein in detail.
Conventionally, the trigger projection 436 is located to engage the trigger member 434 and cause the coupling assembly 434 to release the ram member 30 after the ram m % mber 30 has disengaged from the pump lever 70 and allowed the pump lever 70 to return to its ready position. In this case, the location of the trigger projection 436 ensures that fuel is injected into the fuel chamber 40 each time the line 430 is raised and the ram member 30 dropped.
In some situations, however, it is desirable to use the diesel hammer system 20 in a mode in which energy is applied to the pile 22 solely from the weight of the ram member 30 and not from the ignition of the fuel in the combustion chamber 40.
As shown in FIGS. 13A-F, the diesel hammer system 20 depicted therein comprises a pre-trigger system 450 that allows the diesel hammer system 20 to operate in a conventional ignition mode and in a ram mode. The pre-trigger system 450 comprises a pre-trigger member 452 mounted on the housing member 34. The pre-trigger member 452 is movable relative to the housing member 34 between a retracted position (FIGS. 13D-F) and an extended position (FIGS. 13A-C).
When the pre-trigger member 452 is in the retracted position, the diesel hammer system 20 incorporating the pre-trigger system 450 operates in a conventional ignition mode. As shown in
When the pre-trigger member 452 is in the extended position as shown in FIGS. 13A-C, the pre-trigger member 452 engages the trigger member 434 before the trigger member 434 reaches the trigger projection 436. More specifically, the pre-trigger member 452 is arranged such that, as shown in
The pre-trigger member 452 may be hand operated or, more conveniently, may be remotely operated by a hydraulic, pneumatic, or electrical actuator.
A diesel hammer system incorporating the pre-trigger system 450 may thus operate as a diesel hammer and as a conventional drop hammer. The user of such a diesel hammer system thus has more options when driving the piles 22 than with either a conventional diesel hammer system or a conventional drop hammer system.
Referring now to
From the foregoing, it should be clear that the present invention may be embodied in forms other than those described above. The above-described systems are therefore to be considered in all respects illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description. All changes that come within the meaning and scope of the claims are intended to be embraced therein.
This is a continuation of U.S. patent application Ser. No. 10/124,201filed Apr. 16, 2002, now U.S. Pat. No. 6,736,218, which claims priority of U.S. Provisional Patent Application Ser. No. 60/284,180, which was filed on Apr. 16, 2001.
Number | Date | Country | |
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60284180 | Apr 2001 | US |
Number | Date | Country | |
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Parent | 10124201 | Apr 2002 | US |
Child | 10848798 | May 2004 | US |