EP1891272B1 - Material transfer vehicle for use in asphalt paving - Google Patents
Material transfer vehicle for use in asphalt paving Download PDFInfo
- Publication number
- EP1891272B1 EP1891272B1 EP06838985A EP06838985A EP1891272B1 EP 1891272 B1 EP1891272 B1 EP 1891272B1 EP 06838985 A EP06838985 A EP 06838985A EP 06838985 A EP06838985 A EP 06838985A EP 1891272 B1 EP1891272 B1 EP 1891272B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- auger blade
- material transfer
- transfer vehicle
- outside sidewall
- paver
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Not-in-force
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Classifications
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- E—FIXED CONSTRUCTIONS
- E01—CONSTRUCTION OF ROADS, RAILWAYS, OR BRIDGES
- E01C—CONSTRUCTION OF, OR SURFACES FOR, ROADS, SPORTS GROUNDS, OR THE LIKE; MACHINES OR AUXILIARY TOOLS FOR CONSTRUCTION OR REPAIR
- E01C19/00—Machines, tools or auxiliary devices for preparing or distributing paving materials, for working the placed materials, or for forming, consolidating, or finishing the paving
- E01C19/48—Machines, tools or auxiliary devices for preparing or distributing paving materials, for working the placed materials, or for forming, consolidating, or finishing the paving for laying-down the materials and consolidating them, or finishing the surface, e.g. slip forms therefor, forming kerbs or gutters in a continuous operation in situ
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- E—FIXED CONSTRUCTIONS
- E01—CONSTRUCTION OF ROADS, RAILWAYS, OR BRIDGES
- E01C—CONSTRUCTION OF, OR SURFACES FOR, ROADS, SPORTS GROUNDS, OR THE LIKE; MACHINES OR AUXILIARY TOOLS FOR CONSTRUCTION OR REPAIR
- E01C2301/00—Machine characteristics, parts or accessories not otherwise provided for
- E01C2301/02—Feeding devices for pavers
- E01C2301/04—Independent shuttles
Definitions
- the present invention relates generally to a self-propelled vehicle that is adapted for transferring asphalt from a supply truck to an asphalt paving machine.
- Paving of roadways with asphalt is generally carried out by an asphalt paving machine and a number of supply trucks which transport the asphalt from an asphalt production plant to the paving machine.
- the paving machine generally is self-propelled and driven by a wheeled or tracked drive system.
- a hopper is located at the front end of the machine to receive asphalt from a truck, and a floating screed is located at the rear end of the machine to form the asphalt mat.
- a conveyor system typically comprised of slat conveyors and screw augers delivers the asphalt from the hopper to the road base just ahead of the screed.
- a typical asphalt paving machine has a hopper with a capacity of 5-15 tons, whereas a typical dump-type delivery truck has a capacity of about 20 tons.
- the front of the paving machine is usually provided with rollers which are adapted to engage the rear tires of a delivery truck. This arrangement enables asphalt to be transferred from the truck to the asphalt paving machine by positioning the delivery truck in front of the paving machine and raising the dump bed of the truck to dump the asphalt into the hopper as the paving machine pushes the truck along in front of it. Because the delivery truck usually carries more asphalt than the hopper can receive at one time, the paving machine may push the delivery truck along for several minutes while its conveyor system transports the asphalt out of the hopper to the roadway in front of the screed.
- the material transfer vehicle can rapidly shuttle between delivery trucks at a pick-up point and a paving machine that is laying an asphalt mat so that there is less likelihood that the paving machine will have to stop paving because of a lack of asphalt.
- the improved vehicle of the invention provides a material transfer vehicle which does not require three conveyors as does the prior art vehicle. Consequently, the improved vehicle of the invention is somewhat less complex and may have a significantly reduced weight.
- An advantage of a preferred embodiment of the invention is that it provides a four-wheeled material transfer vehicle in which both front and rear wheels are steerable for improved maneuverability.
- Another advantage of a preferred embodiment of the invention is that it provides such a vehicle with improved asphalt remixing capability in the surge bin.
- aggregate materials refers to crushed stone and other particulate materials that are used in the production of asphalt, such as, for example, crushed limestone and other types of crushed stone, crushed or comminuted recycled asphalt paving materials, crushed, shredded or comminuted shingles and other asphalt binder-containing products, shredded or comminuted mineral and cellulosic fibers, gravel, sand, lime and other particulate additives.
- asphalt binder refers to a dark brown to black solid or semi-solid cementious material which gradually liquefies when heated, in which the predominating constituents are bitumens, all of which occur in the solid or semi-solid form in nature or are obtained by refining petroleum, which is used in the production of asphalt.
- asphalt refers to a bituminous paving mixture that is comprised of asphalt binder and any of various aggregate materials, and which is used for paving purposes.
- asphalt paving machine As used herein, the terms “ asphalt paving machine”, “paving machine”, “paver” and similar terms refer to a finishing machine for applying asphalt to form an asphalt mat on a roadway, parking lot or similar surface.
- An asphalt paying machine is typically a self-propelled vehicle having a hopper at one end for receiving asphalt and a screed at the other end for forming an asphalt mat.
- asphalt mat refers to a layer of asphalt such as is applied by an asphalt paving machine to produce a roadway, parking lot or similar surface.
- delivery truck As used herein, the terms “delivery truck”, “truck” and similar terms refer to a vehicle for transporting asphalt along a roadway, which vehicle is adapted to transfer asphalt to a hopper that is mounted on a material transfer vehicle or a paving machine.
- forward when used in connection with a material transfer vehicle, a component of such vehicle or a position on such a vehicle, refer to the end of the machine nearest the truck-receiving hopper.
- backward when used in connection with such a vehicle, component or position, refer to the end of the vehicle opposite the front end.
- rotary actuator and similar terms refers to an electric, hydraulic or electro-hydraulic device that generates force that is directed along an arc.
- linear actuator refers to an electric, hydraulic or electro-hydraulic device that generates force that is directed in a straight line.
- a linear actuator is a hydraulic cylinder which includes a cylinder, a piston within the cylinder, and a rod attached to the piston. By increasing the pressure within the cylinder on one side of the piston (over that on the opposite side of the piston), the rod will extend from the cylinder or retract into the cylinder.
- actuator refers to a rotary actuator and/or a linear actuator.
- the invention comprises a material transfer vehicle for transporting asphalt from a delivery truck to a paving machine.
- This vehicle includes a frame and a vehicle drive system which is operatively attached to the frame and adapted to drive the vehicle.
- a turret is rotatably mounted on the frame, and a surge bin, which is adapted to contain a quantity of asphalt, is mounted on the turret
- the surge bin has a front side and a rear side with a discharge opening in the rear side.
- the vehicle also includes a truck-unloading conveyor that is mounted on the frame.
- the truck-unloading conveyor has an inlet end and an outlet end which is adjacent to the front side of the surge bin.
- the truck-unloading conveyor is adapted to move asphalt from the inlet end to the discharge end.
- the vehicle also includes a paver-loading conveyor that is mounted on the turret.
- the paver-loading conveyor has an inlet end extending into the discharge opening on the rear side of the surge bin, and an outlet end, and it is adapted to move asphalt from the inlet end to the outlet end.
- the material transfer vehicle has a frame supported by at least four steerable wheels.
- three steering modes are provided: (1) front wheel steering; (2) coordinated front and rear wheel steering for obtaining a shorter turning radius; and (3) coordinated front and rear wheel steering for obtaining sideways, or "crab" motion.
- the preferred embodiment also includes a forward-mounted operator station and a rear-view camera mounted on the underside of the paver-loading conveyor.
- the preferred embodiment also includes a transverse mixing auger in the surge bin having auger blades with varied pitch and/or diameter.
- the preferred embodiment of the invention also includes a paver-loading conveyor that is adapted pivot between a lowered position and a raised position that is about 25° above the horizontal.
- FIG. 1 shows self-propelled material transfer vehicle 10 which is described in U.S. Patents No. 4,818,139 , No. 5,015,120 and No. 5,035,534 in association with asphalt paving machine 12 and conventional delivery truck 16.
- Paving machine 12 includes hopper 14 which has been expanded by providing front wall 14a and side walls 14b of increased height.
- Paving machine 12 also includes vibratory screed 15 and conventional conveyor system comprising longitudinally disposed conveyors 19a and transversely disposed screw auger 19b for delivering the asphalt from hopper 14 to a position just in advance of screed 15 where it is discharged onto the surface to be paved.
- Conventional delivery truck 16 includes a pivotally mounted bed 17 with a tailgate 18, and is adapted to deliver asphalt from a remote source to material transport vehicle 10.
- Vehicle 10 includes frame 20 that is supported on the roadway surface by first wheel set 21 and second wheel set 22. Each of the wheel sets is driven by a hydraulic motor (not shown) that is supplied with fluid under pressure by one or more hydraulic pumps (also not shown). An engine (also not shown) provides the motive force for the hydraulic pumps.
- Vehicle 10 includes surge bin 23 that is mounted on frame 20 and includes transverse auger 24 that is employed to mix the asphalt in the surge bin in order to minimize segregation or separation of the aggregate portion of the asphalt by size.
- Vehicle 10 also includes truck-receiving hopper 25 and truck-unloading conveyor 26 for receiving asphalt from delivery truck 16 and conveying it to the surge bin.
- Hopper 25 is generally of the same width as truck bed 17 and is adjustable in length so that the contents of truck 16 can be easily and quickly emptied into the hopper.
- Conveyor 26 is of the drag-slat type and is adapted to quickly convey an entire truckload of asphalt into surge bin 23.
- Drag-slat type discharge conveyor 28 is located along the sloped side of surge bin 23 opposite truck-unloading conveyor 26 and is adapted to convey asphalt out of the surge bin to chute 30 which is associated with paver-loading conveyor 32. Asphalt conveyed out of the surge bin by conveyor 28 falls through chute 30 and onto paver-loading conveyor 32.
- Paver-loading conveyor 32 is of the belt-type and is mounted for vertical pivotal movement about pivot 34 as raised and lowered by hydraulic lift cylinder 36. Conveyor 32 is also adapted for side-to-side movement about a vertical axis (not shown) that extends through hopper 30 by operation of another hydraulic cylinder (also not shown). Vehicle 10 is operated by an operator located at operator station 38.
- vehicle 40 includes frame 42 that is supported on the roadway surface by first wheel set 44 and second wheel set 46. Each wheel of a wheel set is connected to an axle that is driven by a hydraulic motor (not shown) which is supplied with fluid under pressure by one or more hydraulic pumps (also not shown). An engine (located behind grate 48) provides the motive force for the hydraulic pumps.
- Vehicle 40 includes surge bin 50 that is mounted on the frame and includes transverse auger 52 that is employed to mix the asphalt in the surge bin in order to minimize segregation or separation of the aggregate portion of the asphalt by size.
- Vehicle 40 also includes truck-receiving hopper 54 and truck-unloading conveyor 56 for receiving asphalt from a delivery truck such as truck 16 and conveying it to the surge bin.
- Hopper 54 is generally of the same width as truck bed 17 and is adjustable in length so that the contents of truck 16 can be easily and quickly emptied into the hopper.
- Conveyor 56 is of the drag-slat type and is adapted to quickly convey an entire truckload of asphalt into surge bin 50.
- Another drag-slat type discharge conveyor (not shown, but similar to conveyor 28 of vehicle 10) is located along the sloped side of surge bin 50 opposite truck-unloading conveyor 56 and is adapted to convey asphalt out of the surge bin to chute 58 which is associated with paver-loading conveyor 60.
- Paver-loading conveyor 60 is of the belt-type and is mounted for vertical pivotal movement as raised and lowered by hydraulic lift cylinder 62. Conveyor 60 is also adapted for side-to-side movement about a vertical axis by operation of another hydraulic cylinder (also not shown). Vehicle 40 is operated by an operator located at operator station 64.
- FIG. 4-18 and 20-22 A first embodiment of the invention is illustrated in Figures 4-18 and 20-22 .
- self-propelled material transport vehicle 100 includes frame 102 having a front end at 104 and a rear end at 106.
- Vehicle 100 includes a vehicle drive system which is operatively attached to frame 102 and adapted to drive the vehicle along a roadway surface.
- the vehicle drive system includes a front wheel set comprised of left front wheel 108 and right front wheel 109 and a rear wheel set comprised of left rear wheel 110 and right rear wheel 111.
- each wheel set is comprised of a pair of wheels with pneumatic tires; however, other wheel sets such as are known to those having ordinary skill in the art to which the invention relates may alternatively be used.
- Each wheel of a wheel set is connected to an axle that is driven by a hydraulic motor (not shown) which is supplied with fluid under pressure by one or more hydraulic pumps (also not shown).
- This hydrostatic drive system is similar to the hydrostatic drive systems of vehicles 10 and 40.
- An engine located in compartment 112 provides the motive force for the hydraulic pumps.
- three steering modes are provided: (a) front wheel steering where front wheels 108 and 109 are steerable in the manner of an automobile and rear wheels 110 and 111 are set to roll in a line that is parallel to longitudinal frame axis 114 of the vehicle; (b) coordinated front and rear wheel steering to pivot the vehicle such as for example, by turning the front wheels to the right and simultaneously turning the rear wheels to the left to reduce the turning radius of the vehicle; and (c) coordinated front and rear wheel steering to move the vehicle in a non-pivoting manner, i.e. "crabwise", by turning both the front and the rear wheels in the same direction to move the vehicle along a line that is not parallel to frame axis 114.
- the hydrostatic drive system of vehicle 100 permit differential fluid flow between the front and rear drive subsystems, and that it can be set or "locked" to provide equal flow to the front and rear drive subsystems to improve vehicle stability on loose or muddy terrain.
- a vehicle drive system may include a valve arrangement in the hydraulic fluid lines to the hydraulic motors to permit flow of hydraulic fluid at the same rate to the front and rear hydraulic motors or to permit differential flow of hydraulic fluid (i.e. at a different rate) to the front and rear hydraulic motors, as selected by the operator.
- truck-unloading conveyor 116 having inlet end 118 and outlet end 120.
- Truck receiving hopper 122 is mounted on the inlet end of truck-unloading conveyor for receiving asphalt from a delivery truck such as truck 16.
- Hopper 122 is generally of the same width as truck bed 17 and is adjustable in length so that the contents of a delivery truck can be easily and quickly emptied into the hopper.
- Conveyor 116 is preferably of the drag-slat type and is adapted to quickly convey an entire truckload of asphalt from the inlet end to the outlet end and into surge bin 124.
- Surge bin 124 is adapted to contain a quantity of asphalt and has a front side 126 and a rear side 128. Rear side 128 of surge bin 124 has a discharge opening to receive the inlet end of paver-loading conveyor 130.
- Surge bin 124 and paver-loading conveyor 130 are mounted on turret 132 which is rotatably mounted on frame 102 so as to rotate about turret axis 134.
- surge bin 124, engine compartment 112 and paver-loading conveyor 130 are all mounted on rotatable turret 132 (best shown in Figure 4 ).
- turret 132 is rotated to the left and right of frame axis 114 by the action of a pair of actuators (one of which, hydraulic cylinder 136, is shown in Figure 4 ) which are connected between rear side 128 of surge bin 124 and a bracket (not shown) on the frame adjacent to the rear wheel set.
- the turret may be rotated from an angle ⁇ of about 45° to the left of frame axis 114 (best shown in Figure 12 ) through an angle of about 45° to the right of frame axis 114.
- Rotation of turret 132 to the left side of axis 114 is illustrated in Figures 10-13 .
- Paver-loading conveyor 130 Extending from the discharge opening at the bottom of rear side 128 of preferred surge bin.124 is paver-loading conveyor 130.
- Paver-loading conveyor 130 has an inlet end 138 (shown in Figure 18 ) and an outlet end 140.
- Paver-loading conveyor 130 is mounted on turret 132, either directly or indirectly (by attachment to the surge bin).
- Paver-loading conveyor 130 is preferably of the drag-slat type, and is adapted to transport asphalt from inlet end 138 in surge bin 124 to outlet end 140 and into the hopper of a paving machine (such as hopper 14 of paving machine 12, shown in Figure 1 ).
- paver-loading conveyor 130 is pivotally attached to the turret (or to the surge bin), so that paver-loading conveyor 130 may be pivoted between a lowered position that is preferably about 12° above the horizontal (shown in Figures 14-17 ) and a raised position that is about 25° above the horizontal. It is also preferred that the paver-loading conveyor be pivoted between the lowered position and the raised position by a pair of actuators such as hydraulic cylinders 142 and 144 that are connected between rear side 128 of the surge bin and the paver-loading conveyor.
- Figures 14-17 also show truck-unloading conveyor 116 in a raised travel position, which is accomplished by means known to those having ordinary skill in the art to which the invention relates.
- a transverse mixing auger is mounted in the lower portion of preferred surge bin 124 between left outside sidewall 146 and right outside sidewall 148. Equidistant between the left outside sidewall and the right outside sidewall is a centerline (not shown, but which is coplanar with paver-loader conveyor axis 150, shown in Figure 5 ).
- the transverse mixing auger includes a plurality of auger blades mounted on shaft 152 for rotation about transverse axis 154.
- the transverse mixing auger includes left-side set 156 of auger blades, which is located between the surge bin centerline and left outside sidewall 146, and right-side set 158 of auger blades, which is located between the centerline and right outside sidewall 148.
- inlet end 138 of paver-loading conveyor 130 is located between the left-side set of auger blades and the right-side set of auger blades.
- auger blade 160 in left-side set 156 that is located nearest the centerline has a diameter greater than that of auger blade 162 in the left-side set that is nearest left outside sidewall 146.
- the diameter of each auger blade in left-side set 156 is greater than the diameter of the adjacent auger blade in the left-side set that is located nearer to left outside sidewall 146.
- auger blade 164 in right-side set 158 that is located nearest the centerline has a diameter greater than that of auger blade 166 in the right-side set that is nearest right outside sidewall 148.
- each auger blade in right-side set 158 is greater than the diameter of the adjacent auger blade in the right-side set that is located nearer to right outside sidewall 148.
- FIG 19 illustrates an alternative transverse mixing auger that is mounted in the lower portion of surge bin 224, which is interchangeable with surge bin 124 on vehicle 100.
- This alternative mixing auger is mounted between left outside sidewall 246 and right outside sidewall 248 of surge bin 224. Equidistant between the left outside sidewall and the right outside sidewall is a centerline (not shown).
- This mixing auger includes a plurality of auger blades mounted on a shaft for rotation about transverse axis 254.
- This alternative mixing auger includes left-side set 256 of auger blades, which is located between the surge bin centerline and left outside sidewall 246, and right-side set 258 of auger blades, which is located between the centerline and right outside sidewall 248.
- the inlet end of paver-loading conveyor 230 (which is essentially identical to conveyor 130) is located between the left-side set of auger blades and the right-side set of auger blades.
- the auger blades of the alternative mixing auger having a varied diameter across the surge bin in the same way that the diameter of the auger blades varies across surge bin 124 of Figure 18 .
- the pitch (indicated at 260) between the auger blade in the left-side set that is located nearest the centerline and the adjacent auger blade in the left-side set is greater than the pitch (indicated at 262) between the auger blade in the left-side set that is located nearest the left outside sidewall and the adjacent auger blade in the left-side set.
- the pitch between each auger blade in the left-side set and the adjacent auger blade that is nearer the centerline is greater than the pitch between such auger blade and the adjacent auger blade nearer the left outside sidewall.
- the pitch between the auger blade in the right-side set that is located nearest the centerline and the adjacent auger blade in the right-side set is greater than the pitch between the auger blade in the right-side set that is located nearest the right outside sidewall and the adjacent auger blade in the right-side set. It is also preferred that except for the auger blade located adjacent to the right outside sidewall, the pitch between each auger blade in the right-side set and the adjacent auger blade that is nearer the centerline is greater than the pitch between such auger blade and the adjacent auger blade nearer the right outside sidewall.
- This alternative mixing auger has auger blades with varied diameter and pitch across the surge bin, which would also serve to minimize segregation and separation of aggregate materials of various particle sizes.
- preferred vehicle 100 also includes a forward-mounted operator station, (shown schematically at 168) which is mounted above truck-unloading conveyor 116 on supports 170 and 172 that are attached to frame 102.
- operator station 168 is located in front of the front wheel set. Since the operator's station of this embodiment of the invention is located on the front portion of the vehicle, it is also preferred that a rear-view camera 174 be provided which is mounted on the underside of paver-loading conveyor 130, and that the operator's station include a monitor (not shown) for displaying an image from camera 174.
- steering of the front wheel set is operated by a conventional steering wheel (not shown) and steering for the rear wheel set is operated by a joystick that is located on a control console (not shown) in operator's station 168.
- the preferred joystick for steering the rear wheel set has positions for steering left, steering right and centering the rear wheel set (so that the wheels of this wheel set are parallel to frame axis 114). By turning the steering wheel to the left or right and leaving the joystick in the neutral (or centered) position, the vehicle can be maneuvered like a conventional automobile.
- the vehicle By turning the steering wheel to the left and shifting the joystick to the right (or by turning the steering wheel to the right and shifting the joystick to the left), the vehicle will steer in the direction the steering wheel is turned but with a smaller turning radius than if the rear wheels remain centered.
- the vehicle By turning the steering wheel to the left and shifting the joystick to the left (or by turning the steering wheel to the right and shifting the joystick to the right), the vehicle will move in a "crab-wise" manner in a direction that is oblique to the frame axis.
- this circuit includes a conventional steering unit 176 which controls the flow of fluid to left front steering cylinder 178 and right front steering cylinder 180.
- a conventional hydraulic solenoid valve 182 controls the flow of fluid to left rear steering cylinder 184 and right rear steering cylinder 186.
- a position sensor valve 188 also shown in
- energizing switch 192 (by shifting the rear steering joystick to the left) allows four-way, three-position directional solenoid valve 182 to direct flow to the piston side of cylinder 184 and to the rod side of cylinder 186 to steer the rear wheel set to the left, while energizing switch 194 (by shifting the rear steering joystick to the right) allows four-way, three-position directional solenoid valve 182 to direct flow to the piston side of cylinder 186 and the rod side of cylinder 184 to steer the rear wheel set to the right.
- rear steering centering switch 196 which is preferably operated by a button on the joystick, is energized, two-way poppet solenoid valve 193 directs flow through position sensor valve 188 to position hold valve 198, which causes left rear steering cylinder 184 and right rear steering cylinder 186 to center the rear wheel set so that the rear wheels are aligned with the frame axis. If the joystick is shifted either to the left or the right without engaging rear steering centering switch 196, position hold valve 198 will maintain the left-steered or right-steered position of the rear wheel set until the joystick is shifted in the other direction or centering switch 196 is energized.
- FIGS 23-26 illustrate a second embodiment of the invention.
- self-propelled material transport vehicle 200 includes frame 202 having a front end at 204 and a rear end at 206.
- Vehicle 200 includes a vehicle drive system which is operatively attached to frame 202 and is adapted to drive the vehicle along a roadway surface.
- This vehicle drive system includes a front wheel set comprised of left front wheel 208 and right front wheel 209 and a rear wheel set comprised of left rear wheel 210 and right rear wheel 211.
- Each wheel of a wheel set is connected to an axle that is driven by a hydraulic motor (not shown) which is supplied with fluid under pressure by one or more hydraulic pumps (also not shown).
- This hydrostatic drive system is similar to the hydrostatic drive systems of vehicles 10, 40 and 100.
- An engine located in compartment 212 provides the motive force for the hydraulic pumps.
- vehicle 200 also includes truck-unloading conveyor 216 having inlet end 218 and outlet end 220.
- Truck receiving hopper 222 is mounted on the inlet end of truck-unloading conveyor for receiving asphalt from a delivery truck such as truck 16.
- Hopper 222 is generally of the same width as truck bed 17 and is adjustable in length so that the contents of a delivery truck can be easily and quickly emptied into the hopper.
- Conveyor 216 is preferably of the drag-slat type and is adapted to quickly convey an entire truckload of asphalt from the inlet end to the outlet end and into surge bin 223.
- Surge bin 223 is adapted to contain a quantity of asphalt and has a front side 226 and a rear side 228.
- Rear side 228 of surge bin 223 has a discharge opening to receive the inlet end of paver-loading conveyor 229.
- Surge bin 223 and paver-loading conveyor 229 are mounted on turret 232 which is rotatably mounted on frame 202 so as to rotate about turret axis 234.
- engine compartment 212 is mounted on frame 202, instead of on the turret.
- a transverse mixing auger (not shown, but which may be similar to those illustrated in Figures 18 and 19 in connection with the description of vehicle 100) is mounted in the lower portion of preferred surge bin 223 between left outside sidewall 245 and right outside sidewall 247. Equidistant between the left outside sidewall and the right outside sidewall is a centerline (not shown, but which is coplanar with paver-loader conveyor axis 250, shown in Figure 26 ).
- the transverse mixing auger includes a plurality of auger blades mounted on a shaft (not shown) for rotation about transverse axis 254.
- the transverse mixing auger may include a left-side set of auger blades (not shown), which is located between the surge bin centerline and left outside sidewall 245, and a right-side set of auger blades (also not shown), which is located between the centerline and right outside sidewall 247.
- Paver-loading conveyor 229 Extending from the discharge opening at the bottom of rear side 228 of preferred surge bin 223 is paver-loading conveyor 229.
- Paver-loading conveyor 229 has an inlet end (similar to inlet end 138 of conveyor 130 of vehicle 100), and an outlet end 240.
- the paver-loading conveyor is mounted on the turret, either directly or indirectly (by being attached to the surge bin).
- the inlet end of paver-loading conveyor 229 is pivotally attached to the turret (or to the surge bin) so as to be located between the left-side set of auger blades and the right-side set of auger blades (similar to the location of inlet end 138 of paver-loading conveyor 130 which is illustrated in Figure 18 ).
- Paver-loading conveyor 229 is preferably of the drag-slat type, and is adapted to transport asphalt from its inlet end in surge bin 223 to outlet end 240 and into the hopper of a paving machine (such as hopper 14 of paving machine 12, shown in Figure 1 ).
- paver-loading conveyor 229 is adapted to be pivoted between a lowered position that is preferably about 12° above the horizontal (not shown, but similar to the lowered position of paver-loading conveyor 130 of vehicle that is shown in Figures 14-17 ) and a raised position that is about 25° above the horizontal. It is also preferred that the paver-loader conveyor be pivoted between the lowered position and the.raised position by an actuator comprising hydraulic cylinder 242 that is connected between rear side 228 of the surge bin and the paver-loader conveyor.
- turret 232 is rotated to the left and right of frame axis 214 by the action of a pair of actuators (one of which, hydraulic cylinder 23 6, is shown in Figures 23 and 25 ) which are connected between rear side 228 of surge bin 223 and a bracket (not shown) on the frame adjacent to the rear wheel set.
- a pair of actuators one of which, hydraulic cylinder 23 6, is shown in Figures 23 and 25
- the turret may be rotated from an angle ⁇ of about 45° to the left of frame axis 214 (shown in Figure 26 ) through an angle of about 45° to the right of frame axis 214.
- Vehicle 200 also includes a forward-mounted operator station, (shown schematically at 268) which is mounted above truck-unloading conveyor 216 on supports (including stairway support 270) that are attached to frame 202.
- operator station 268 is located in front of the , front wheel set. Since the operator's station of this embodiment of the invention is located on the front portion of the vehicle, it is also preferred that a rear-view camera 274 be provided which is mounted on the underside of paver-loading conveyor 229, and that the operator's station include a monitor (not shown) for displaying an image from camera 274.
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Abstract
Description
- The present invention relates generally to a self-propelled vehicle that is adapted for transferring asphalt from a supply truck to an asphalt paving machine.
- Paving of roadways with asphalt is generally carried out by an asphalt paving machine and a number of supply trucks which transport the asphalt from an asphalt production plant to the paving machine. The paving machine generally is self-propelled and driven by a wheeled or tracked drive system. A hopper is located at the front end of the machine to receive asphalt from a truck, and a floating screed is located at the rear end of the machine to form the asphalt mat. A conveyor system typically comprised of slat conveyors and screw augers delivers the asphalt from the hopper to the road base just ahead of the screed.
- A typical asphalt paving machine has a hopper with a capacity of 5-15 tons, whereas a typical dump-type delivery truck has a capacity of about 20 tons. The front of the paving machine is usually provided with rollers which are adapted to engage the rear tires of a delivery truck. This arrangement enables asphalt to be transferred from the truck to the asphalt paving machine by positioning the delivery truck in front of the paving machine and raising the dump bed of the truck to dump the asphalt into the hopper as the paving machine pushes the truck along in front of it. Because the delivery truck usually carries more asphalt than the hopper can receive at one time, the paving machine may push the delivery truck along for several minutes while its conveyor system transports the asphalt out of the hopper to the roadway in front of the screed.
- Sometimes, problems may arise when operating the paving machine and the delivery trucks in this manner. Because of traffic conditions and other unforeseen delays, it is not uncommon for the paving machine to empty its hopper of asphalt before a loaded delivery truck is available to begin dumping its asphalt into the hopper. When this occurs, the paving machine must stop paving and await the arrival of another delivery truck. Even if one or more loaded delivery trucks are available to dump asphalt into the paving machine hopper, it may be necessary to stop the paving machine. Sometimes, it is simply impossible for the truck drivers to remove an empty delivery truck from engagement with the front of the paving machine and to maneuver a loaded truck into position to dump into the hopper before the hopper is emptied.
- As is known to those having ordinary skill in the art to which the invention relates, when a paving machine stops, even for a short time, the screed will tend to settle into the freshly laid asphalt mat. Then, when the paving machine resumes its forward motion, the screed will tend to ride upwardly momentarily, thus depositing an excessive amount of material. Consequently, stopping of the paving machine causes a depression and a bump in the surface of the asphalt mat, resulting in an uneven pavement surface. Consequently, in recent years, material transfer vehicles have been employed to shuttle asphalt between the delivery trucks and the paving machine. Such a material transfer vehicle is described in various embodiments in
U.S. Patents No. 4,818,139 , No.5,015,120 and No.5,035,534 , which are incorporated herein by reference. These patents describe a self-propelled material transfer vehicle which includes a large-rapacity truck-receiving hopper and a large-capacity truck-unloading conveyor extending from this hopper to a surge bin that is sized to hold the entire load of a delivery truck. A conveyor in the surge bin is adapted to transfer asphalt to a paver-loading conveyor that is pivotable about an essentially vertical axis so that the transfer vehicle can be positioned alongside an asphalt paving machine that is laying an asphalt mat and rapidly discharge a truckload of asphalt into the paver's hopper. Because of its rapid loading and unloading capabilities, the material transfer vehicle can rapidly shuttle between delivery trucks at a pick-up point and a paving machine that is laying an asphalt mat so that there is less likelihood that the paving machine will have to stop paving because of a lack of asphalt. - Although this material transfer vehicle has met with much commercial success, it would be desirable if its weight could be reduced, and if other advantageous features could be incorporated into an improved material transfer vehicle.
- Among the advantages of the invention is that it provides a material transfer vehicle which does not require three conveyors as does the prior art vehicle. Consequently, the improved vehicle of the invention is somewhat less complex and may have a significantly reduced weight. An advantage of a preferred embodiment of the invention is that it provides a four-wheeled material transfer vehicle in which both front and rear wheels are steerable for improved maneuverability. Another advantage of a preferred embodiment of the invention is that it provides such a vehicle with improved asphalt remixing capability in the surge bin.
- Other advantages and features of this invention will become apparent from an examination of the drawings and the ensuing description.
- As used herein, the term "aggregate materials" refers to crushed stone and other particulate materials that are used in the production of asphalt, such as, for example, crushed limestone and other types of crushed stone, crushed or comminuted recycled asphalt paving materials, crushed, shredded or comminuted shingles and other asphalt binder-containing products, shredded or comminuted mineral and cellulosic fibers, gravel, sand, lime and other particulate additives.
- As used herein, the term "asphalt binder" refers to a dark brown to black solid or semi-solid cementious material which gradually liquefies when heated, in which the predominating constituents are bitumens, all of which occur in the solid or semi-solid form in nature or are obtained by refining petroleum, which is used in the production of asphalt.
- As used herein, the term "asphalt" refers to a bituminous paving mixture that is comprised of asphalt binder and any of various aggregate materials, and which is used for paving purposes.
- As used herein, the terms "asphalt paving machine", "paving machine", "paver" and similar terms refer to a finishing machine for applying asphalt to form an asphalt mat on a roadway, parking lot or similar surface. An asphalt paying machine is typically a self-propelled vehicle having a hopper at one end for receiving asphalt and a screed at the other end for forming an asphalt mat.
- As used herein, the term "asphalt mat" refers to a layer of asphalt such as is applied by an asphalt paving machine to produce a roadway, parking lot or similar surface.
- As used herein, the terms "delivery truck", "truck" and similar terms refer to a vehicle for transporting asphalt along a roadway, which vehicle is adapted to transfer asphalt to a hopper that is mounted on a material transfer vehicle or a paving machine.
- As used herein, the terms "forward", "front" and similar terms, when used in connection with a material transfer vehicle, a component of such vehicle or a position on such a vehicle, refer to the end of the machine nearest the truck-receiving hopper. The terms "backward", "rear" and similar terms, when used in connection with such a vehicle, component or position, refer to the end of the vehicle opposite the front end.
- As used herein, the term "rotary actuator" and similar terms refers to an electric, hydraulic or electro-hydraulic device that generates force that is directed along an arc.
- As used herein, the term "linear actuator" and similar terms refers to an electric, hydraulic or electro-hydraulic device that generates force that is directed in a straight line. One common example of a linear actuator is a hydraulic cylinder which includes a cylinder, a piston within the cylinder, and a rod attached to the piston. By increasing the pressure within the cylinder on one side of the piston (over that on the opposite side of the piston), the rod will extend from the cylinder or retract into the cylinder.
- As used herein, the term "actuator" and similar terms refers to a rotary actuator and/or a linear actuator.
- The invention comprises a material transfer vehicle for transporting asphalt from a delivery truck to a paving machine. This vehicle includes a frame and a vehicle drive system which is operatively attached to the frame and adapted to drive the vehicle. A turret is rotatably mounted on the frame, and a surge bin, which is adapted to contain a quantity of asphalt, is mounted on the turret The surge bin has a front side and a rear side with a discharge opening in the rear side. The vehicle also includes a truck-unloading conveyor that is mounted on the frame. The truck-unloading conveyor has an inlet end and an outlet end which is adjacent to the front side of the surge bin. The truck-unloading conveyor is adapted to move asphalt from the inlet end to the discharge end. The vehicle also includes a paver-loading conveyor that is mounted on the turret. The paver-loading conveyor has an inlet end extending into the discharge opening on the rear side of the surge bin, and an outlet end, and it is adapted to move asphalt from the inlet end to the outlet end. In a preferred embodiment of the invention, the material transfer vehicle has a frame supported by at least four steerable wheels. In this embodiment of the invention, three steering modes are provided: (1) front wheel steering; (2) coordinated front and rear wheel steering for obtaining a shorter turning radius; and (3) coordinated front and rear wheel steering for obtaining sideways, or "crab" motion. The preferred embodiment also includes a forward-mounted operator station and a rear-view camera mounted on the underside of the paver-loading conveyor. The preferred embodiment also includes a transverse mixing auger in the surge bin having auger blades with varied pitch and/or diameter. The preferred embodiment of the invention also includes a paver-loading conveyor that is adapted pivot between a lowered position and a raised position that is about 25° above the horizontal.
- In order to facilitate an understanding of the invention, the preferred embodiments of the invention are illustrated in the drawings, and a detailed description thereof follows. It is not intended, however, that the invention be limited to the particular embodiments described or illustrated herein. Various modifications and alternative embodiments such as would ordinarily occur to one skilled in the art to which the invention relates are also contemplated and included within the scope of the invention described and claimed herein.
- The presently preferred embodiments of the invention are illustrated in the accompanying drawings, in which:
-
Figure 1 is a side view of a conventional material transfer vehicle in association with an asphalt delivery truck and an asphalt paving machine. -
Figure 2 is a side view of another conventional material transfer vehicle. -
Figure 3 is a top view of the vehicle ofFigure 2 . -
Figure 4 is a side view of a first embodiment of the invention showing the paver-loading conveyor in an elevated position. -
Figure 5 is a top view of the embodiment ofFigure 4 showing the paver-loading conveyor in an elevated position. -
Figure 6 is a bottom view of the embodiment ofFigures 4-5 showing the paver-loading conveyor in an elevated position. -
Figure 7 is a front view of the embodiment ofFigures 4-6 showing the paver-loading conveyor in an elevated position. -
Figure 8 is a rear view of the embodiment ofFigures 4-7 showing the paver-loading conveyor in an elevated position. -
Figure 9 is a rear perspective view of the embodiment ofFigures 4-8 showing the paver-loading conveyor in an elevated position. -
Figure 10 is a side view of the embodiment ofFigures 4-9 showing the turret in a rotated position. -
Figure 11 is a rear perspective view of the embodiment ofFigures 4-10 showing the turret in a rotated position. -
Figure 12 is a top view of the embodiment ofFigures 4-11 showing the turret in a rotated position. -
Figure 13 is a rear view of the embodiment ofFigures 4-12 showing the turret in a rotated position. -
Figure 14 is a side view of the embodiment ofFigures 4-13 showing the paver-loading conveyor in a lowered position and the truck-unloading conveyor in a raised or travel position. -
Figure 15 is a top view of the embodiment ofFigures 4-14 showing the paver-loading conveyor in a lowered position and the truck-unloading conveyor in a raised or travel position. -
Figure 16 is a bottom view of the embodiment ofFigures 4-15 showing the paver-loading conveyor in a lowered position and the truck-unloading conveyor in a raised or travel position. -
Figure 17 is a rear perspective view of the embodiment ofFigures 4-16 showing the paver-loading conveyor in a lowered position and the truck-unloading conveyor in a raised or travel position. -
Figure 18 is a partial sectional view through the surge bin of the embodiment ofFigures 4-17 , taken through line 18-18 ofFigure 5 , showing a preferred embodiment of the transverse mixing auger in the surge bin. -
Figure 19 is a partial sectional view through a surge bin similar to that ofFigure 18 , showing an alternative embodiment of the transverse mixing auger in the surge bin. -
Figure 20 is a schematic illustration of the hydraulic circuit for the steering system of the embodiment ofFigures 4-18 . -
Figure 21 is a schematic illustration of the electrical switching for the rear steering components of the embodiment ofFigures 4-18 and20 . -
Figure 22 is a perspective view of a portion of the components of the rear steering subsystem of the embodiment ofFigures 4-18 and20-21 . -
Figure 23 is a side view of a second embodiment of the invention showing the paver-loading conveyor in an elevated position. -
Figure 24 is a front perspective view of the embodiment ofFigure 23 showing the paver-loading conveyor in an elevated position. -
Figure 25 is a rear perspective view of the embodiment ofFigures 23-24 showing the paver-loading conveyor in an elevated position. -
Figure 26 is a top view of the embodiment ofFigures 23-25 showing the turret in a rotated position. -
Figure 1 shows self-propelled material transfer vehicle 10 which is described inU.S. Patents No. 4,818,139 , No.5,015,120 and No.5,035,534 in association withasphalt paving machine 12 andconventional delivery truck 16. Pavingmachine 12 includes hopper 14 which has been expanded by providing front wall 14a andside walls 14b of increased height. Pavingmachine 12 also includesvibratory screed 15 and conventional conveyor system comprising longitudinally disposed conveyors 19a and transversely disposed screw auger 19b for delivering the asphalt from hopper 14 to a position just in advance ofscreed 15 where it is discharged onto the surface to be paved.Conventional delivery truck 16 includes a pivotally mountedbed 17 with atailgate 18, and is adapted to deliver asphalt from a remote source to material transport vehicle 10. - Vehicle 10 includes frame 20 that is supported on the roadway surface by first wheel set 21 and second wheel set 22. Each of the wheel sets is driven by a hydraulic motor (not shown) that is supplied with fluid under pressure by one or more hydraulic pumps (also not shown). An engine (also not shown) provides the motive force for the hydraulic pumps. Vehicle 10 includes
surge bin 23 that is mounted on frame 20 and includes transverse auger 24 that is employed to mix the asphalt in the surge bin in order to minimize segregation or separation of the aggregate portion of the asphalt by size. Vehicle 10 also includes truck-receiving hopper 25 and truck-unloadingconveyor 26 for receiving asphalt fromdelivery truck 16 and conveying it to the surge bin. Hopper 25 is generally of the same width astruck bed 17 and is adjustable in length so that the contents oftruck 16 can be easily and quickly emptied into the hopper.Conveyor 26 is of the drag-slat type and is adapted to quickly convey an entire truckload of asphalt intosurge bin 23. Drag-slattype discharge conveyor 28 is located along the sloped side ofsurge bin 23 opposite truck-unloadingconveyor 26 and is adapted to convey asphalt out of the surge bin tochute 30 which is associated with paver-loading conveyor 32. Asphalt conveyed out of the surge bin byconveyor 28 falls throughchute 30 and onto paver-loading conveyor 32. Paver-loading conveyor 32 is of the belt-type and is mounted for vertical pivotal movement about pivot 34 as raised and lowered byhydraulic lift cylinder 36.Conveyor 32 is also adapted for side-to-side movement about a vertical axis (not shown) that extends throughhopper 30 by operation of another hydraulic cylinder (also not shown). Vehicle 10 is operated by an operator located at operator station 38. - A modified version of vehicle 10 is illustrated in
Figures 2 and 3 . As shown therein,vehicle 40 includesframe 42 that is supported on the roadway surface by first wheel set 44 and second wheel set 46. Each wheel of a wheel set is connected to an axle that is driven by a hydraulic motor (not shown) which is supplied with fluid under pressure by one or more hydraulic pumps (also not shown). An engine (located behind grate 48) provides the motive force for the hydraulic pumps.Vehicle 40 includessurge bin 50 that is mounted on the frame and includestransverse auger 52 that is employed to mix the asphalt in the surge bin in order to minimize segregation or separation of the aggregate portion of the asphalt by size.Vehicle 40 also includes truck-receivinghopper 54 and truck-unloading conveyor 56 for receiving asphalt from a delivery truck such astruck 16 and conveying it to the surge bin.Hopper 54 is generally of the same width astruck bed 17 and is adjustable in length so that the contents oftruck 16 can be easily and quickly emptied into the hopper. Conveyor 56 is of the drag-slat type and is adapted to quickly convey an entire truckload of asphalt intosurge bin 50. Another drag-slat type discharge conveyor (not shown, but similar toconveyor 28 of vehicle 10) is located along the sloped side ofsurge bin 50 opposite truck-unloading conveyor 56 and is adapted to convey asphalt out of the surge bin to chute 58 which is associated with paver-loading conveyor 60. Asphalt conveyed out of the surge bin by the surge bin conveyor falls through chute 58 and onto paver-loading conveyor 60. Paver-loading conveyor 60 is of the belt-type and is mounted for vertical pivotal movement as raised and lowered byhydraulic lift cylinder 62.Conveyor 60 is also adapted for side-to-side movement about a vertical axis by operation of another hydraulic cylinder (also not shown).Vehicle 40 is operated by an operator located atoperator station 64. - A first embodiment of the invention is illustrated in
Figures 4-18 and20-22 . As shown inFigures 4-17 , self-propelledmaterial transport vehicle 100 includesframe 102 having a front end at 104 and a rear end at 106.Vehicle 100 includes a vehicle drive system which is operatively attached to frame 102 and adapted to drive the vehicle along a roadway surface. As shown inFigures 4-17 , the vehicle drive system includes a front wheel set comprised of leftfront wheel 108 and rightfront wheel 109 and a rear wheel set comprised of leftrear wheel 110 and right rear wheel 111. Preferably, as illustrated in the drawings, each wheel set is comprised of a pair of wheels with pneumatic tires; however, other wheel sets such as are known to those having ordinary skill in the art to which the invention relates may alternatively be used. Each wheel of a wheel set is connected to an axle that is driven by a hydraulic motor (not shown) which is supplied with fluid under pressure by one or more hydraulic pumps (also not shown). This hydrostatic drive system is similar to the hydrostatic drive systems ofvehicles 10 and 40. An engine (located in compartment 112) provides the motive force for the hydraulic pumps. In this embodiment of the invention (as described in more detail hereinafter), three steering modes are provided: (a) front wheel steering wherefront wheels rear wheels 110 and 111 are set to roll in a line that is parallel tolongitudinal frame axis 114 of the vehicle; (b) coordinated front and rear wheel steering to pivot the vehicle such as for example, by turning the front wheels to the right and simultaneously turning the rear wheels to the left to reduce the turning radius of the vehicle; and (c) coordinated front and rear wheel steering to move the vehicle in a non-pivoting manner, i.e. "crabwise", by turning both the front and the rear wheels in the same direction to move the vehicle along a line that is not parallel to frameaxis 114. - It is also preferred that the hydrostatic drive system of
vehicle 100 permit differential fluid flow between the front and rear drive subsystems, and that it can be set or "locked" to provide equal flow to the front and rear drive subsystems to improve vehicle stability on loose or muddy terrain. Such a vehicle drive system may include a valve arrangement in the hydraulic fluid lines to the hydraulic motors to permit flow of hydraulic fluid at the same rate to the front and rear hydraulic motors or to permit differential flow of hydraulic fluid (i.e. at a different rate) to the front and rear hydraulic motors, as selected by the operator. - The preferred embodiment of
vehicle 100 also includes truck-unloadingconveyor 116 having inlet end 118 and outlet end 120.Truck receiving hopper 122 is mounted on the inlet end of truck-unloading conveyor for receiving asphalt from a delivery truck such astruck 16.Hopper 122 is generally of the same width astruck bed 17 and is adjustable in length so that the contents of a delivery truck can be easily and quickly emptied into the hopper.Conveyor 116 is preferably of the drag-slat type and is adapted to quickly convey an entire truckload of asphalt from the inlet end to the outlet end and intosurge bin 124.Surge bin 124 is adapted to contain a quantity of asphalt and has afront side 126 and arear side 128.Rear side 128 ofsurge bin 124 has a discharge opening to receive the inlet end of paver-loading conveyor 130. -
Surge bin 124 and paver-loading conveyor 130 are mounted onturret 132 which is rotatably mounted onframe 102 so as to rotate aboutturret axis 134. In the embodiment of the invention illustrated inFigures 4-17 ,surge bin 124,engine compartment 112 and paver-loading conveyor 130 are all mounted on rotatable turret 132 (best shown inFigure 4 ). In this embodiment of the invention,turret 132 is rotated to the left and right offrame axis 114 by the action of a pair of actuators (one of which, hydraulic cylinder 136, is shown inFigure 4 ) which are connected betweenrear side 128 ofsurge bin 124 and a bracket (not shown) on the frame adjacent to the rear wheel set. Preferably, by coordinating the extension and retraction of these linear actuators (including cylinder 136), the turret may be rotated from an angle θ of about 45° to the left of frame axis 114 (best shown inFigure 12 ) through an angle of about 45° to the right offrame axis 114. Rotation ofturret 132 to the left side ofaxis 114 is illustrated inFigures 10-13 . - Extending from the discharge opening at the bottom of
rear side 128 of preferred surge bin.124 is paver-loading conveyor 130. Paver-loading conveyor 130 has an inlet end 138 (shown inFigure 18 ) and anoutlet end 140. Paver-loading conveyor 130 is mounted onturret 132, either directly or indirectly (by attachment to the surge bin). Paver-loading conveyor 130 is preferably of the drag-slat type, and is adapted to transport asphalt frominlet end 138 insurge bin 124 to outlet end 140 and into the hopper of a paving machine (such as hopper 14 of pavingmachine 12, shown inFigure 1 ). Preferably, the inlet end of paver-loading conveyor 130 is pivotally attached to the turret (or to the surge bin), so that paver-loading conveyor 130 may be pivoted between a lowered position that is preferably about 12° above the horizontal (shown inFigures 14-17 ) and a raised position that is about 25° above the horizontal. It is also preferred that the paver-loading conveyor be pivoted between the lowered position and the raised position by a pair of actuators such ashydraulic cylinders rear side 128 of the surge bin and the paver-loading conveyor.Figures 14-17 also show truck-unloadingconveyor 116 in a raised travel position, which is accomplished by means known to those having ordinary skill in the art to which the invention relates. - As shown in
Figures 5 and18 , a transverse mixing auger is mounted in the lower portion ofpreferred surge bin 124 between leftoutside sidewall 146 and rightoutside sidewall 148. Equidistant between the left outside sidewall and the right outside sidewall is a centerline (not shown, but which is coplanar with paver-loader conveyor axis 150, shown inFigure 5 ). The transverse mixing auger includes a plurality of auger blades mounted onshaft 152 for rotation abouttransverse axis 154. The transverse mixing auger includes left-side set 156 of auger blades, which is located between the surge bin centerline and leftoutside sidewall 146, and right-side set 158 of auger blades, which is located between the centerline and rightoutside sidewall 148. Preferably, as shown inFigure 18 ,inlet end 138 of paver-loading conveyor 130 is located between the left-side set of auger blades and the right-side set of auger blades. - It is also preferred that
auger blade 160 in left-side set 156 that is located nearest the centerline has a diameter greater than that ofauger blade 162 in the left-side set that is nearest left outsidesidewall 146. Preferably, as shown inFigure 18 , except forauger blade 162 that is located adjacent to leftoutside sidewall 146, the diameter of each auger blade in left-side set 156 is greater than the diameter of the adjacent auger blade in the left-side set that is located nearer to left outsidesidewall 146. It is also preferred thatauger blade 164 in right-side set 158 that is located nearest the centerline has a diameter greater than that ofauger blade 166 in the right-side set that is nearest rightoutside sidewall 148. Furthermore, it is also preferred that except forauger blade 166 that is located adjacent to rightoutside sidewall 148, the diameter of each auger blade in right-side set 158 is greater than the diameter of the adjacent auger blade in the right-side set that is located nearer to rightoutside sidewall 148. By providing the preferred transverse mixing auger with auger blades having a varied diameter across the surge bin, segregation and separation of aggregate material in the asphalt mix is minimized. -
Figure 19 illustrates an alternative transverse mixing auger that is mounted in the lower portion ofsurge bin 224, which is interchangeable withsurge bin 124 onvehicle 100. This alternative mixing auger is mounted between leftoutside sidewall 246 and rightoutside sidewall 248 ofsurge bin 224. Equidistant between the left outside sidewall and the right outside sidewall is a centerline (not shown). This mixing auger includes a plurality of auger blades mounted on a shaft for rotation abouttransverse axis 254. This alternative mixing auger includes left-side set 256 of auger blades, which is located between the surge bin centerline and leftoutside sidewall 246, and right-side set 258 of auger blades, which is located between the centerline and rightoutside sidewall 248. Preferably, as shown inFigure 19 , the inlet end of paver-loading conveyor 230 (which is essentially identical to conveyor 130) is located between the left-side set of auger blades and the right-side set of auger blades. As can be seen by comparingFigure 19 and Figure 18 , the auger blades of the alternative mixing auger having a varied diameter across the surge bin in the same way that the diameter of the auger blades varies acrosssurge bin 124 ofFigure 18 . However, it is also preferred in this alternative embodiment that the pitch (indicated at 260) between the auger blade in the left-side set that is located nearest the centerline and the adjacent auger blade in the left-side set is greater than the pitch (indicated at 262) between the auger blade in the left-side set that is located nearest the left outside sidewall and the adjacent auger blade in the left-side set. In fact, it is especially preferred that except for the auger blade located adjacent to the left outside sidewall, the pitch between each auger blade in the left-side set and the adjacent auger blade that is nearer the centerline is greater than the pitch between such auger blade and the adjacent auger blade nearer the left outside sidewall. Similarly, it is preferred that the pitch between the auger blade in the right-side set that is located nearest the centerline and the adjacent auger blade in the right-side set is greater than the pitch between the auger blade in the right-side set that is located nearest the right outside sidewall and the adjacent auger blade in the right-side set. It is also preferred that except for the auger blade located adjacent to the right outside sidewall, the pitch between each auger blade in the right-side set and the adjacent auger blade that is nearer the centerline is greater than the pitch between such auger blade and the adjacent auger blade nearer the right outside sidewall. This alternative mixing auger has auger blades with varied diameter and pitch across the surge bin, which would also serve to minimize segregation and separation of aggregate materials of various particle sizes. - Referring again to
Figures 4-17 ,preferred vehicle 100 also includes a forward-mounted operator station, (shown schematically at 168) which is mounted above truck-unloadingconveyor 116 onsupports operator station 168 is located in front of the front wheel set. Since the operator's station of this embodiment of the invention is located on the front portion of the vehicle, it is also preferred that a rear-view camera 174 be provided which is mounted on the underside of paver-loading conveyor 130, and that the operator's station include a monitor (not shown) for displaying an image fromcamera 174. - Preferably, steering of the front wheel set is operated by a conventional steering wheel (not shown) and steering for the rear wheel set is operated by a joystick that is located on a control console (not shown) in operator's
station 168. The preferred joystick for steering the rear wheel set has positions for steering left, steering right and centering the rear wheel set (so that the wheels of this wheel set are parallel to frame axis 114). By turning the steering wheel to the left or right and leaving the joystick in the neutral (or centered) position, the vehicle can be maneuvered like a conventional automobile. By turning the steering wheel to the left and shifting the joystick to the right (or by turning the steering wheel to the right and shifting the joystick to the left), the vehicle will steer in the direction the steering wheel is turned but with a smaller turning radius than if the rear wheels remain centered. By turning the steering wheel to the left and shifting the joystick to the left (or by turning the steering wheel to the right and shifting the joystick to the right), the vehicle will move in a "crab-wise" manner in a direction that is oblique to the frame axis. - Referring now to
Figure 20 , the hydraulic circuit for the preferred steering system ofvehicle 100 is illustrated. As shown therein, this circuit includes aconventional steering unit 176 which controls the flow of fluid to leftfront steering cylinder 178 and rightfront steering cylinder 180. A conventionalhydraulic solenoid valve 182 controls the flow of fluid to leftrear steering cylinder 184 and rightrear steering cylinder 186. A position sensor valve 188 (also shown in - Warren, New Jersey, is linked by
linkage 190 to the steering yoke connection point for the rear wheel set in order to sense the angular position of the rear wheel set with respect to the frame. Referring now toFigures 20 and 21 , it can be seen that energizing switch 192 (by shifting the rear steering joystick to the left) allows four-way, three-positiondirectional solenoid valve 182 to direct flow to the piston side ofcylinder 184 and to the rod side ofcylinder 186 to steer the rear wheel set to the left, while energizing switch 194 (by shifting the rear steering joystick to the right) allows four-way, three-positiondirectional solenoid valve 182 to direct flow to the piston side ofcylinder 186 and the rod side ofcylinder 184 to steer the rear wheel set to the right. When rearsteering centering switch 196, which is preferably operated by a button on the joystick, is energized, two-waypoppet solenoid valve 193 directs flow throughposition sensor valve 188 to positionhold valve 198, which causes leftrear steering cylinder 184 and rightrear steering cylinder 186 to center the rear wheel set so that the rear wheels are aligned with the frame axis. If the joystick is shifted either to the left or the right without engaging rearsteering centering switch 196, position holdvalve 198 will maintain the left-steered or right-steered position of the rear wheel set until the joystick is shifted in the other direction or centeringswitch 196 is energized. -
Figures 23-26 illustrate a second embodiment of the invention. As shown therein, self-propelledmaterial transport vehicle 200 includesframe 202 having a front end at 204 and a rear end at 206.Vehicle 200 includes a vehicle drive system which is operatively attached to frame 202 and is adapted to drive the vehicle along a roadway surface. This vehicle drive system includes a front wheel set comprised of leftfront wheel 208 and rightfront wheel 209 and a rear wheel set comprised of leftrear wheel 210 and rightrear wheel 211. Each wheel of a wheel set is connected to an axle that is driven by a hydraulic motor (not shown) which is supplied with fluid under pressure by one or more hydraulic pumps (also not shown). This hydrostatic drive system is similar to the hydrostatic drive systems ofvehicles vehicle 100. - The preferred embodiment of
vehicle 200 also includes truck-unloadingconveyor 216 having inlet end 218 andoutlet end 220.Truck receiving hopper 222 is mounted on the inlet end of truck-unloading conveyor for receiving asphalt from a delivery truck such astruck 16.Hopper 222 is generally of the same width astruck bed 17 and is adjustable in length so that the contents of a delivery truck can be easily and quickly emptied into the hopper.Conveyor 216 is preferably of the drag-slat type and is adapted to quickly convey an entire truckload of asphalt from the inlet end to the outlet end and intosurge bin 223.Surge bin 223 is adapted to contain a quantity of asphalt and has afront side 226 and arear side 228.Rear side 228 ofsurge bin 223 has a discharge opening to receive the inlet end of paver-loading conveyor 229.Surge bin 223 and paver-loading conveyor 229 are mounted onturret 232 which is rotatably mounted onframe 202 so as to rotate aboutturret axis 234. In the embodiment of the invention illustrated inFigures 23-26 ,engine compartment 212 is mounted onframe 202, instead of on the turret. - A transverse mixing auger (not shown, but which may be similar to those illustrated in
Figures 18 and 19 in connection with the description of vehicle 100) is mounted in the lower portion ofpreferred surge bin 223 between leftoutside sidewall 245 and rightoutside sidewall 247. Equidistant between the left outside sidewall and the right outside sidewall is a centerline (not shown, but which is coplanar with paver-loader conveyor axis 250, shown inFigure 26 ). The transverse mixing auger includes a plurality of auger blades mounted on a shaft (not shown) for rotation abouttransverse axis 254. The transverse mixing auger may include a left-side set of auger blades (not shown), which is located between the surge bin centerline and leftoutside sidewall 245, and a right-side set of auger blades (also not shown), which is located between the centerline and rightoutside sidewall 247. - Extending from the discharge opening at the bottom of
rear side 228 ofpreferred surge bin 223 is paver-loading conveyor 229. Paver-loading conveyor 229 has an inlet end (similar to inlet end 138 ofconveyor 130 of vehicle 100), and anoutlet end 240. The paver-loading conveyor is mounted on the turret, either directly or indirectly (by being attached to the surge bin). Preferably, the inlet end of paver-loading conveyor 229 is pivotally attached to the turret (or to the surge bin) so as to be located between the left-side set of auger blades and the right-side set of auger blades (similar to the location ofinlet end 138 of paver-loading conveyor 130 which is illustrated inFigure 18 ). Paver-loading conveyor 229 is preferably of the drag-slat type, and is adapted to transport asphalt from its inlet end insurge bin 223 to outlet end 240 and into the hopper of a paving machine (such as hopper 14 of pavingmachine 12, shown inFigure 1 ). Preferably, paver-loading conveyor 229 is adapted to be pivoted between a lowered position that is preferably about 12° above the horizontal (not shown, but similar to the lowered position of paver-loading conveyor 130 of vehicle that is shown inFigures 14-17 ) and a raised position that is about 25° above the horizontal. It is also preferred that the paver-loader conveyor be pivoted between the lowered position and the.raised position by an actuator comprisinghydraulic cylinder 242 that is connected betweenrear side 228 of the surge bin and the paver-loader conveyor. - In this embodiment of the invention,
turret 232 is rotated to the left and right offrame axis 214 by the action of a pair of actuators (one of which,hydraulic cylinder 23 6, is shown inFigures 23 and25 ) which are connected betweenrear side 228 ofsurge bin 223 and a bracket (not shown) on the frame adjacent to the rear wheel set. Preferably, by coordinating the extension and retraction of these linear actuators (including cylinder 236), the turret may be rotated from an angle θ of about 45° to the left of frame axis 214 (shown inFigure 26 ) through an angle of about 45° to the right offrame axis 214. -
Vehicle 200 also includes a forward-mounted operator station, (shown schematically at 268) which is mounted above truck-unloadingconveyor 216 on supports (including stairway support 270) that are attached to frame 202. Preferably,operator station 268 is located in front of the , front wheel set. Since the operator's station of this embodiment of the invention is located on the front portion of the vehicle, it is also preferred that a rear-view camera 274 be provided which is mounted on the underside of paver-loading conveyor 229, and that the operator's station include a monitor (not shown) for displaying an image fromcamera 274. - Although this description contains many specifics, these should not be construed as limiting the scope of the invention but as merely providing illustrations of some of the presently preferred embodiments thereof, as well as the best mode contemplated by the inventors of carrying out the invention. The invention, as described herein, is susceptible to various modifications and adaptations, as would be understood by those having ordinary skill in the art to which the invention relates, and the same are intended to be comprehended within the meaning and range of equivalents of the appended claims.
Claims (20)
- A material transfer vehicle (100,200) for transporting asphalt from a delivery truck to a paving machine, which vehicle comprises:(a) a frame (102,202) having a first end and a second end;(b) a vehicle drive system which is operatively attached to the frame and adapted to drive the vehicle;(c) a surge bin (124,223):(i) that has a front side (126,226);(ii) that has a rear side (128,228);(iii) that is adapted to contain a quantity of asphalt;(d) a truck-unloading conveyor (116,216):(i) that is mounted on the frame (102,202);(ii) that has an inlet end (118,218);(iii) that has an outlet end (120,220) which is adjacent to the front side (126,226) of the surge bin (124,223);(iv) that is adapted to move asphalt from the inlet end to the outlet end;(e) a paver-loading conveyor (130,229):(i) that has an inlet end (138);(ii) that has a outlet end (140,240);(iii) that is adapted to move asphalt from the inlet end to the outlet end.characterised in that it comprises a turret (132, 232) that is rotatably mounted on the frame, the surge bin and the paver-loading conveyor are mounted on said turret, the surge bin has a discharge opening in the rear side, and the inlet end of the paver-loading conveyor extends into this discharge opening.
- The material transfer vehicle of claim 1 which includes a truck receiving hopper (122,222) that is mounted on the inlet end of the truck-unloading conveyor (116,226).
- The material transfer vehicle of claim 1 which includes an operator's station (168,268) that is mounted above the truck-unloading conveyor (116,216).
- The material transfer vehicle of claim 1 wherein the surge bin includes:(a) a left outside sidewall (146), a right outside sidewall (148), and a centerline that is equidistant from the left outside sidewall and the right outside sidewall;(b) a transverse mixing auger that is mounted in the lower portion of the surge bin between the left outside sidewall and the right outside sidewall, said transverse mixing auger comprising:(i) a shaft (152) mounted for rotation about an axis of rotation within the surge bin;(ii) a plurality of auger blades mounted on the shaft, including a left-side set (156) of auger blades located between the centerline and the left outside wall, and a right-side set (158) of auger blades located between the centerline and the right outside sidewall, wherein the auger blade (160) in the left-side set that is located nearest the centerline has a diameter greater than that of the auger blade in the left-side set that is nearest the left outside sidewall (162), and the auger blade (164) in the right-side set that is located nearest the centerline has a diameter greater than that of the auger blade (166) in the right-side set that is nearest the right outside sidewall.
- The material transfer vehicle of claim 4 wherein the inlet end (138) of the paver-loading conveyor (130) is located between the left-side set (156) of auger blades and the right-side set (158) of auger blades.
- The material transfer vehicle (100) of claim 4 wherein:(a) except for the auger blade (165) located adjacent to the left outside sidewall, the diameter of each auger blade in the left-side set is greater than the diameter of the adjacent auger blade in the left-side set that is located nearer to the left outside sidewall;(b) except for the auger blade (162) located adjacent to the right outside sidewall, the diameter of each auger blade in the right-side set is greater than the diameter of the adjacent auger blade in the right-side set that is located nearer to the right outside sidewall.
- The material transfer vehicle of claim 4 wherein:(a) the pitch (260) between the auger blade (160) in the left-side set that is located nearest the centerline and the adjacent auger blade in the left-side set is greater than the pitch (262) between the auger blade (162) in the left-side set that is located nearest the left outside sidewall and the adjacent auger blade in the left-side set;(b) the pitch between the auger blade in the right-side set that is located nearest the centerline and the adjacent auger blade in the right-side set is greater than the pitch between the auger blade in the right-side set that is located nearest the right outside sidewall and the adjacent auger blade in the right-side set.
- The material transfer vehicle of claim 7 wherein:(a) except for the auger blade located adjacent to the left outside sidewall, the pitch between each auger blade in the left-side set and the adjacent auger blade that is nearer the centerline is greater than the pitch between such auger blade and the adjacent auger blade nearer the left outside sidewall;(b) except for the auger blade located adjacent to the right outside sidewall, the pitch between each auger blade in the right-side set and the adjacent auger blade that is nearer the centerline is greater than the pitch between such auger blade and the adjacent auger blade nearer the right outside sidewall.
- The material transfer vehicle of claim 1:(a) wherein the paver-loading conveyor (130,229) is adapted to be pivoted between a lowered position and a raised position;(b) which includes means for pivoting the paver-loading conveyor between the lowered position and the raised position.
- The material transfer vehicle of claim 9 wherein the paver-loading conveyor (130,229) is adapted to be pivoted between a lowered position and a raised position that is about 25° above the horizontal.
- The material transfer vehicle of claim 9 wherein the means for pivoting the paver-loading conveyor between the lowered position and the raised position comprises an actuator (142,144,242) that is connected between the surge bin and the paver-loading conveyor.
- The material transfer vehicle of claim 1:(a) wherein turret is adapted to be rotated between a left position and a right position;(b) which includes means for rotating the turret between the left position and the right position.
- The material transfer vehicle of claim 12 wherein:(a) the frame includes a longitudinal axis;(b) the turret (132,232) is adapted to be rotated between a left position that is about 45° to the left of the longitudinal axis of the frame and a right position that is about 45° to the right of the longitudinal axis of the frame.
- The material transfer vehicle of claim 12 wherein the means for rotating the turret between the left position and the right position comprises an actuator (236) that is connected between the frame (202) and the surge bin (223).
- The material transfer vehicle of claim 1 wherein the vehicle drive system includes:(a) a front wheel set that is mounted on the front end of the frame;(b) a rear wheel set that is mounted on the rear end of the frame;(c) an engine for supplying power to drive the front wheel set and the rear wheel set.
- The material transfer vehicle of claim 15 which includes:(a) an operator's station that is located in front of the front wheel set;(b) a rear-view camera that is mounted on the paver-loading conveyor.
- The material transfer vehicle of claim 15 wherein the engine is mounted on the turret.
- The material transfer vehicle of claim 15:(a) wherein the front wheel set is steerable;(b) wherein the rear wheel set is steerable;(c) which includes a steering system by which the front wheel set alone can be steered, or the front wheel set and rear wheel set can be steered simultaneously.
- The material transfer vehicle of claim 18 wherein the steering system includes an actuator that is operatively attached to the front wheel set and an actuator that is operatively attached to the rear wheel set.
- The material transfer vehicle of claim 18 wherein the steering system includes means for allowing the rear wheel set to be steerable or centered at the option of the operator.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PCT/US2006/046346 WO2007117287A1 (en) | 2006-03-10 | 2006-12-06 | Material transfer vehicle for use in asphalt paving |
Publications (2)
Publication Number | Publication Date |
---|---|
EP1891272A1 EP1891272A1 (en) | 2008-02-27 |
EP1891272B1 true EP1891272B1 (en) | 2008-09-24 |
Family
ID=38581426
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP06838985A Not-in-force EP1891272B1 (en) | 2006-12-06 | 2006-12-06 | Material transfer vehicle for use in asphalt paving |
Country Status (7)
Country | Link |
---|---|
EP (1) | EP1891272B1 (en) |
CN (1) | CN101273172B (en) |
AT (1) | ATE409250T1 (en) |
CA (1) | CA2591166C (en) |
DE (1) | DE602006002890D1 (en) |
ES (1) | ES2313686T3 (en) |
NO (1) | NO335981B1 (en) |
Families Citing this family (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
AU2015369821B2 (en) * | 2014-12-22 | 2019-03-28 | Roadtec, Inc. | Material transfer vehicle having an expandable truck-receiving hopper |
AU2018278095B2 (en) * | 2017-06-01 | 2020-02-27 | Roadtec, Inc. | Quick-change attachment for material transfer vehicle |
US11560676B2 (en) * | 2019-02-13 | 2023-01-24 | Caterpillar Paving Products Inc. | Determine optimal frequency to load haul truck |
CN111681522B (en) * | 2020-01-17 | 2024-08-27 | 石家庄安瑞科气体机械有限公司 | CNG transportation semitrailer fire control teaching equipment |
CN111519495B (en) * | 2020-04-07 | 2021-08-31 | 江苏集萃道路工程技术与装备研究所有限公司 | Material lifting device for on-site remixer |
Family Cites Families (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
NL8402831A (en) * | 1984-09-14 | 1986-04-01 | Zijlstra & Bolhuis Bv | SWIVEL BOX FILLER. |
US4818139A (en) * | 1987-08-25 | 1989-04-04 | Barber-Greene Company | Methods and apparatus for making an asphalt-aggregate pavement |
DE19821090A1 (en) * | 1998-05-12 | 1999-12-02 | Abg Allg Baumaschinen Gmbh | Paver |
CN2732808Y (en) * | 2004-08-23 | 2005-10-12 | 徐州工程机械科技股份有限公司路面机械分公司 | Asphalt concrete transferring equipment for road spreading machine |
-
2006
- 2006-12-06 CN CN200680015260XA patent/CN101273172B/en not_active Expired - Fee Related
- 2006-12-06 ES ES06838985T patent/ES2313686T3/en active Active
- 2006-12-06 CA CA2591166A patent/CA2591166C/en not_active Expired - Fee Related
- 2006-12-06 DE DE602006002890T patent/DE602006002890D1/en active Active
- 2006-12-06 EP EP06838985A patent/EP1891272B1/en not_active Not-in-force
- 2006-12-06 AT AT06838985T patent/ATE409250T1/en not_active IP Right Cessation
-
2008
- 2008-09-25 NO NO20084097A patent/NO335981B1/en not_active IP Right Cessation
Also Published As
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NO20084097L (en) | 2008-09-25 |
ATE409250T1 (en) | 2008-10-15 |
NO335981B1 (en) | 2015-04-07 |
EP1891272A1 (en) | 2008-02-27 |
CN101273172A (en) | 2008-09-24 |
ES2313686T3 (en) | 2009-03-01 |
CA2591166C (en) | 2010-08-03 |
CN101273172B (en) | 2010-10-13 |
CA2591166A1 (en) | 2008-06-06 |
DE602006002890D1 (en) | 2008-11-06 |
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