1. Field
The present invention relates generally to road paving equipment. More specifically, embodiments of the present invention concern a pavement coating system configured to spray a mastic material to a road.
2. Discussion of Prior Art
Paving construction and repair vehicles have long been used to dispense one or more types of flowable pavement coating materials onto an existing roadway. For instance, conventional paving vehicles are well known for laying, spreading, and screeding a layer of bituminous asphalt onto a roadway. Other conventional vehicles comprise a distributing vehicle that is configured to spray a liquified tack coat material onto an existing asphalt road surface.
Yet further, other known vehicles are configured to spray a friction mastic material that includes a liquid asphalt emulsion, aggregate, and one or more polymers. The mastic mixture is generally sprayed onto the surface of a paved road to extend the usable life of the road.
However, conventional paving construction and repair vehicles have various deficiencies. For instance, conventional vehicles that spray friction mastic material are difficult and expensive to use. For example, these conventional vehicles generally carry a large volume of mastic material that must be strained during the spraying process to separate aggregate particles and congealed clumps of material from the mastic to be sprayed and to store the separated particles and clumps in a straining basket. The process of removing the separated particles and clumps from the vehicle is notoriously time consuming and requires the use heavy machinery to lift and move the basket and material from the vehicle.
Another deficiency associated with conventional distributing vehicles is that sprayed material is easily wasted because of the difficulty associated with positioning and advancing the vehicle. For instance, the spray boom of prior art distributing vehicles is difficult to align precisely with the side margin of the roadway.
The following brief summary is provided to indicate the nature of the subject matter disclosed herein. While certain aspects of the present invention are described below, the summary is not intended to limit the scope of the present invention.
Embodiments of the present invention provide a pavement coating system that does not suffer from the problems and limitations of the prior art material distributing vehicles set forth above.
A first aspect of the present invention concerns a coating applicator vehicle configured to selectively discharge a flowable pavement coating material onto a roadway. The coating applicator vehicle broadly includes a rolling chassis and a spray bar assembly. The rolling chassis is operable to be advanced in a forward direction along the roadway. The spray bar assembly is supported by the rolling chassis and extends transversely to the forward direction to selectively discharge coating material along a lateral direction. The spray bar assembly includes a shiftable spray boom, spray nozzles, and a frame mounted relative to the chassis. The spray boom presents an elongated chamber to receive and carry the coating material laterally. The spray nozzles fluidly communicate with the chamber to receive a flow of the coating material from the spray boom and discharge the coating material. The spray boom is shiftably supported by the frame to move laterally relative to the rolling chassis.
A second aspect of the present invention concerns a spray bar assembly operable to be mounted on and advanced in a forward direction with a vehicle to discharge flowable pavement coating material onto a roadway, where the material includes a liquid emulsion and aggregate. The spray bar assembly broadly includes a shiftable spray boom and a plurality of spray nozzles. The spray boom presents an elongated chamber to receive and carry the coating material laterally. The spray nozzles fluidly communicate with the chamber to receive a flow of coating material from the spray boom and to discharge the flow of coating material. The spray nozzles are mounted relative to the spray boom and spaced along a lateral line that extends along the length of the spray boom, with each pair of adjacent spray nozzles being separated by a spacing dimension. Each of the spray nozzles discharges the coating material in a generally planar fan pattern that impinges the roadway along a laterally extending spray line. The line defines a maximum fan width dimension greater than the spacing dimension. The spray nozzles are positioned so that the spray line associated with each spray nozzle extends at an acute angle relative to the lateral direction, with the fan patterns of adjacent spray nozzles overlapping one another without intersecting.
This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the detailed description. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. Other aspects and advantages of the present invention will be apparent from the following detailed description of the embodiments and the accompanying drawing figures.
Preferred embodiments of the invention are described in detail below with reference to the attached drawing figures, wherein:
The drawing figures do not limit the present invention to the specific embodiments disclosed and described herein. The drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the preferred embodiment.
Turning initially to
It will also be appreciated that the depicted vehicle 20 could be used to dispense one or more other types of flowable pavement coating materials. For instance, the vehicle 20 could be configured to spray a tack coat material (e.g., onto an existing asphalt surface). The vehicle 20 preferably includes a rolling chassis 22, a cab 24, a drive train (not shown), a storage tank 26, and a spraying assembly 28.
The rolling chassis 22 is conventional and includes an elongated chassis frame 30 and wheels 32 mounted on the chassis frame 30. The chassis frame 30 extends longitudinally to present front and back ends 34,36. The chassis frame 30 supports the cab 24 at the front end 34, a rear deck 38 at the back end 36, and the storage tank 36 between the front and back ends 34,36. The rear deck 38 is preferably fixed to the back end 36 of the chassis frame 30. As will be discussed, a spray bar assembly 40 is preferably attached to and supported by the rear deck 38 adjacent the back end 36 of the frame 30. In the usual manner, the vehicle 20 is advanced along a forward direction F while spraying the flowable pavement coating material along a lateral application spray pattern P (see
As will be discussed in greater detail, the spraying assembly 28 is operable to pump flowable pavement coating material from the tank 26, strain the pumped material, and dispense the material onto the roadway. The spraying assembly 28 preferably includes the spray bar assembly 40, suction and pressure strainer assemblies 42,44, and pump 46.
Turning to
The spray bar frame 50 is preferably shiftable vertically, relative to the rolling chassis 22 along an upright direction. The spray bar frame 50 is preferably configured to support the spray boom 48 relative to the rolling chassis 22 and to selectively position the spray boom 48 vertically above the pavement. The spray bar frame 50 includes an elongated slider housing 52 that extends laterally, mounting collars 54 attached to the slider housing 52, and a boom shift cylinder 56 (see
The mounting collars 54 are interconnected by an elongated collar bracket (not shown). Each collar 54 presents a smooth, generally square bore that slidably receives the tubular body 58. Thus, the collars 54 are preferably permitted to slide laterally relative to the tubular body 58. Because the spray boom 48 interconnects the arms 60, both the arms 60 and the spray boom 48 can move laterally relative to the chassis 22 of the vehicle 20. This slider mechanism preferably permits the entire spray boom 48 to slide laterally (also referred to as “side shift”).
The slider mechanism preferably allows the entire spray boom 48 to slide a distance S from a centered position to one laterally endmost shift position. The distance S is preferably about ten inches (10″). Thus, the total lateral travel of the spray boom 48 from one laterally endmost shift position to the opposite laterally endmost shift position is preferably about twenty inches (20″). However, the illustrated slider mechanism could allow either a smaller or greater amount of lateral boom travel.
The boom shift cylinder 56 includes a cylinder housing 62 and a piston 64. The cylinder housing 62 is fixed to the collar bracket (not shown) that extends between the collars 54. The piston 64 of the boom shift cylinder 56 is drivingly attached to one end of the tubular body 58. Extension and retraction of the piston 64 causes the tubular body 58 to slide through the collars 54. Thus, movement of the piston 64 causes the tubular body 58 and the spray boom 48 to shift laterally relative to the chassis 22 of the vehicle 20.
This mechanism for lateral shifting of the spray boom 48 is preferred so that the entire spray boom 48 can be precisely laterally positioned relative to the pavement (e.g., to align one end of the spray boom 48 with an edge of the pavement) without having to change the lateral position of the vehicle 20. This mechanism also permits the spray boom 48 to be laterally aligned with the pavement without having to adjust the width of the spray boom 48.
The boom shift cylinder 56 is conventional and preferably comprises a hydraulic cylinder. However, an alternative drive motor (such as an alternative hydraulic cylinder) could be used to shift the entire spray boom 48. Furthermore, it will be appreciated that other components of the lateral shifting mechanism could be alternatively configured to shift the spray boom 48 laterally. Yet further, for some aspects of the present invention, the vehicle 20 could be devoid of a mechanism to shift the entire spray boom 48 laterally relative to the vehicle 20.
Turning to
The links 68 each present a fixed length. However, the turnbuckle links 70 each comprise a turnbuckle mechanism to adjust the length of the turnbuckle link 70. However, the fixed link 68 and/or turnbuckle links 70 could be alternatively configured without departing from the scope of the present invention.
The forward ends of the links 68,70 are pivotally attached to mounting brackets 74 fixed to the frame 30. Thus, the links 68,70, support brackets 72, mounting brackets 74, and spray bar frame 50 cooperatively form a four-bar linkage that permits the spray bar frame 50 to shift vertically relative to the chassis frame 30.
The illustrated spray bar assembly 40 also includes a hanger frame 76 that is operable to support the spray bar frame 50 and other equipment (such as material hoses). The hanger frame 76 includes a pair of hanger arms 78 and a lateral beam 80 (see
The hanger frame 76 further includes hanger links 82 that interconnect the hanger frame 76 and the spray bar frame 50. In particular, upper ends 84 of each hanger link 82 are pivotally attached to the corresponding hanger arm 78 between the ends thereof (see
Preferably, the spray bar assembly 40 and the hanger frame 76 are removably mounted with quick-connect pins 88 that permit the spray bar assembly 40 to be quickly attached and removed from the vehicle 20 (see
The spray bar assembly 40 further includes the hydraulic lift cylinder 90 to provide a motor operable to shift the spray bar frame 50 and the spray boom 48 vertically relative to the rolling chassis 22. The lift cylinder 90 includes a cylinder housing 94 and a piston 96. The cylinder housing 94 is mounted to the chassis frame 30 so that the piston 96 extends longitudinally along and projects rearwardly of the chassis frame 30. The end of the piston 96 is pivotally attached to one of the hanger arms 78 at a pivot joint 98 spaced from the ends of the one hanger arm 78. Thus, as the piston 96 is hydraulically extended and retracted relative to the housing 94, the hanger frame 76 correspondingly pivots up and down relative to the chassis frame 30. Consequently, extension and retraction of the piston 96 preferably causes corresponding up and down vertical shifting movement of the spray bar frame 50 and the spray boom 48. The lift cylinder 90 is preferably conventional and comprises a hydraulic cylinder, although an alternative powered motor could be used to selectively raise and lower the spray bar assembly 40.
Turning to
The illustrated spray boom 48 is preferably configured so that the boom sections 100,102 extend along a common lateral direction and are generally parallel to one another and to the common lateral direction. However, it is within the scope of the present invention where one or more of the boom sections 100,102 is alternatively positioned.
Preferably, the slide mechanism 104 permits the extendable boom sections 102 to slide relative to the central boom section 100 along the common lateral direction. In the illustrated embodiment, the boom sections 102 are preferably slidable between a retracted position (see
For some aspects of the present invention, the boom sections 100,102 could be alternatively shiftably attached to one another. For instance, the extendable boom sections 102 could be pivotally mounted relative to the central boom section 100 so that the boom sections 102 are swingable relative to the central boom section 100 (e.g., between a retracted position and an outermost deployed position).
The chamber inlets 112a,b are preferably fluidly connected to corresponding supply hoses 118a,b (see
Again, the extendable boom sections 100,102 are slidable between retracted and outermost deployed positions such that the spray boom 48 has an adjustable boom width B (see
In the retracted position, the vehicle 20 preferably presents a maximum vehicle width that is less than two and one half meters (2.5 m), which is the maximum legal vehicle width allowed by law in a number of foreign countries.
Referring again to
Each valve 122 preferably comprises a ball valve although, for some aspects of the present invention, the valves 122 could be alternatively configured to selectively fluidly interconnect the chamber 110 and the corresponding nozzle 120. Each spray nozzle 120 is preferably fluidly connected to the chamber 110a,b of the corresponding boom section 100,102 by one of the valves 122. Thus, the flow of coating material through each spray nozzle 120 is preferably controlled by the corresponding valve 122 (i.e., by opening or closing the valve 122).
Each spray nozzle 120 preferably discharges coating material in a generally planar fan pattern. The illustrated spray nozzles 120 each present an orifice (not shown) with an orifice diameter dimension that ranges from about five sixteenths of an inch ( 5/16″) to about one half of an inch (½″) and, more preferably, is about three eighths of an inch (⅜″). The orifice diameter dimension is preferably about twice the size of the maximum aggregate size allowed by the strainer systems of the vehicle 20 to pass to the spray boom 48. Thus, because the strainer assemblies preferably permit a maximum aggregate size of about three sixteenths of an inch ( 3/16″) to pass through to the spray boom 48, the more preferred orifice diameter dimension is about three eighths of an inch (⅜″).
Each spray nozzle 120 preferably discharges the coating material in a generally planar fan pattern that impinges the roadway along a laterally extending spray line L (see
The illustrated spray nozzles 120 are preferably arranged so that the spray line L is at an acute angle relative to the common lateral direction of the boom sections 100,102. In other words, the spray nozzles 120 are preferably arranged so that a line perpendicular to the spray line L and the forward direction F cooperatively define an acute spray angle α (see
The spray nozzles 120 are also preferably oriented so that the spray lines L associated with each boom section 100,102 are generally parallel to one another. For instance, the spray lines L produced by the spray nozzles 120 of the central boom section 100 are generally parallel to each other. Thus, for each boom section 100, adjacent pairs of spray nozzles form spray lines L that define an offset distance D (see
The spray nozzles 120 each preferably present a maximum fan width dimension WS (see
The spray nozzles 120 associated with each of the boom sections 100,102 are preferably spaced in series to form a corresponding lateral line of spray nozzles 120 (see
Preferably, the lateral lines of spray nozzles 120 are generally parallel to one another and substantially perpendicular to the forward direction F. Furthermore, each lateral line of spray nozzles 120 in the illustrated embodiment is substantially parallel to the corresponding boom section 100,102 that supports and fluidly communicates the spray nozzles 120. However, it is within the scope of the present invention the lateral lines of spray nozzles 120 are alternatively oriented.
The spray nozzles 120 are preferably positioned so that adjacent spray nozzles 120 cooperatively define a spacing dimension W (see
Again, the spray bar assembly 40 preferably includes valve cylinders 124 to control opening and closing of the valves 122. In the usual manner, each valve cylinder 124 includes a cylinder housing 126 and an elongated piston 128 (see
For the central boom section 100, each valve 122 is operably connected to one of the valve cylinders 124. More particularly, the housing 126 of each valve cylinder 124 is pivotally attached to the central boom section 100, with the piston 128 being pivotally attached to a handle 130 of the valve 122 (see
The spray bar assembly 40 also includes valve links 132a,b (see
For each of the extendable boom sections 102, the valve cylinder 124 is operably connected to the valve handle 130 of a middle one of the valves 122. Specifically, the housing 126 of each valve cylinder 124 is pivotally attached to the corresponding extendable boom section 102, with the piston 128 being pivotally attached to the valve handle 130 of the middle valve 122. Thus, as the piston 128 of a corresponding boom section 102 extends and retracts, the associated valve handles 130 open and close the respective valves 122 at the same time.
The spray bar assembly 40 further includes boom extension cylinders 136 that are used to selectively extend and retract the extendable boom sections 102 (see
When the spray boom 48 is in the retracted position, spray nozzles 120 of the extendable boom sections 102 are substantially laterally aligned with the spray nozzles 120 of the central boom section 100. Thus, when retracted, the valves 122 of the extendable boom sections 102 are preferably closed (i.e., so that only the valves 122 of the central boom section 100 are open). This configuration is preferred to avoid applying too much coating material on any area of the pavement.
When the spray boom 48 is in the extended position, the valves 122 of the boom sections 102 can all be opened. Because of the locations of spray nozzles 120 in the extended position, the spray nozzles 120 are all operated to provide uniform coverage of coating material.
When one of the extendable boom sections 102 is intermediately located between the extended and retracted positions, the valves 122 of the extendable boom section 102 are all opened. At the same time, at least one of the valves 122 of the central boom section 100 is closed, depending how much the extendable boom section overlaps the central boom section. For instance, if the extendable boom section 102 is intermediately positioned so that an inboard one of the spray nozzles 120 of the extendable boom section 102 is laterally aligned with an outboard one of the spray nozzles 120 of the central boom section 100, the valve 122 corresponding to the outboard spray nozzle 120 of the central boom section 100 is closed. Similarly, if the extendable boom section 102 is intermediately positioned so that two inboard spray nozzles 120 of the extendable boom section 102 are laterally aligned with two outboard nozzles 120 of the central boom section 100, the valves 122 corresponding to the outboard spray nozzles 120 of the central boom section 100 are closed. This configuration is preferred so as to avoid applying too much coating material on any area of the pavement.
In the illustrated embodiment, selective opening and closing of the valves 122 of the central boom section 100 when one or both of the extendable boom sections 102 are in an intermediate position can be done manually by the operator. However, as will be discussed, the spraying assembly 28 preferably includes a control system 144 (see
Turning to
The pump 46 preferably comprises a progressive cavity pump powered by a hydraulic motor 150. The pump 46 has an operating pressure that is preferably greater than about twenty pounds per square inch (20 psi) and preferably less than about fifty pounds per square inch (50 psi). Although the configuration of the illustrated pump 46 is operable to pump material at greater pressures, the spraying assembly 28 of the present invention is efficiently configured to operate even when the pump 46 discharges material at relatively low pressures, preferably less than fifty pounds per square inch (50 psi). While the spraying assembly 28 preferably uses the illustrated progressive cavity pump to pump coating material, it is within the ambit of the present invention where an alternative pump (such as a piston pump) is used. However, the progressive cavity pump has been found to be more durable than other pumps. The pump 46 preferably defines a pump inlet 152 and a pump outlet 154 (see
The illustrated pump 46 is preferably calibrated to pump a known volume (or mass) of material for one complete pump revolution. Because the control system 144 is programmed to retain the calibrated ratio of pumped material volume (or mass) per revolution of the pump (a single pump revolution is also referred to as a “pump count” or “count”), the processor can calculate the volumetric flow rate (and/or mass flow rate) of material transmitted by the pump 46. Thus, the pump 46 is preferably calibrated so that a range of volumetric flow rates (and/or mass flow rates) of the pump 46 are associated with a corresponding range of pump counts. Preferably, the pump 46 is calibrated so that the error in the actual pump mass flow rate per count produced by the pump 46 (compared to the expected mass flow rate per count) is less than two percent (2%).
The pump 46 is preferably configured to be calibrated without discharging pavement coating material from the spray nozzles 120. Instead, the spraying assembly 28 includes an auxiliary hose (not shown) that is removably fluidly connected relative to the pump 46 so that the pump outlet 46 fluidly communicates with the auxiliary hose. The pump 46 can be operated by the control system 144 to discharge, while operating at a set rotational speed, a volume of material into a container (not shown) for a predetermined number of pump counts. The mass of material in the container is then measured (e.g., by weighing the container and material). The material can then be returned to the tank 26 or another storage container.
This process is preferably repeated several times to discharge and measure the output volumes (mass) of the pump 46. As a result, the calibration process produces a calibration scale factor to be used at any pump rotational speed to calculate the output volume (mass) of pavement coating material.
The suction strainer assembly 42 preferably includes a fluid manifold 156 and two (2) suction strainer baskets 158 (see
The fluid manifold 156 presents a strainer inlet 160 and strainer outlet 162 of the suction strainer assembly 42 (see
The fluid manifold 156 includes a diverter 167 that presents the strainer inlet 160 and fluidly communicates with two (2) passages 168 of the manifold 156 (see
The passages 168 preferably extend between the chambers 164,166 in parallel with one another. That is, the passages 168 provide two separate paths for fluid to move between the strainer inlet 160 and the strainer outlet 162.
The suction strainer baskets 158 each preferably include a mesh body 170 and a handle 172 (see
The basket chamber 173a of each basket 158 preferably defines a basket volume dimension that ranges from about one gallon to about five gallons. However, for some aspects of the present invention, the basket volume could fall outside of this range.
The suction strainer baskets 158 are removably mounted in the fluid manifold 156 (see
The fluid manifold 156 and each strainer basket 158 cooperatively define a manifold axis A1 along which the strainer basket 158 is manually slidable into and out of the passage 168 (see
The suction strainer assembly 42 is preferably configured so that an operator can manually lift and remove each of the strainer baskets 158, and any coating material in the baskets 158, from the fluid manifold 156 while standing on the ground alongside the vehicle 20. That is, the operator can lift and remove each strainer basket 158, and any coating material in the basket 158, while standing next to the vehicle 20 without the assistance of powered machinery. As a result, the suction strainer assembly 42 is particularly configured for convenient and quick manual disposal of material caught in the suction strainer assembly 42.
The suction strainer assembly 42 is preferably fluidly connected upstream of the pump 46 so that the strainer outlet 162 fluidly communicates with the pump inlet 152. In particular, the spraying assembly 28 includes a pump intake manifold 176 (see
The suction strainer assembly 42 is also fluidly connected to the tank 26 via a tank discharge valve 177 and a tank discharge line 178 (see
The pump 46 draws coating material from the tank 26 and through the suction strainer assembly 42, with material flowing through at least one of the two suction strainer baskets 158.
The pressure strainer assembly 44 preferably includes a fluid manifold 179 and two (2) pressure strainer baskets 180 (see
The fluid manifold 179 presents a strainer inlet 182 and a strainer outlet 184 of the pressure strainer assembly 44 (see
The fluid manifold 179 includes a diverter 189 that presents the strainer inlet 182 and fluidly communicates with two (2) passages 190 of the manifold 179 (see
The passages 190 extend between the chambers 186,188 in parallel with one another. That is, the passages 190 provide two separate paths for fluid to move between the strainer inlet 182 and the strainer outlet 184.
The pressure strainer baskets 180 each preferably include a mesh body 192 and a handle 194 (see
The basket chamber 193a of each basket 180 preferably defines a basket volume dimension that ranges from about one gallon to about five gallons. However, for some aspects of the present invention, the basket volume could fall outside of this range.
The pressure strainer baskets 180 are removably mounted in the fluid manifold 179. More specifically, each pressure strainer basket 180 is secured in a corresponding one of the passages 168 so that fluid must flow through at least one of the strainer baskets 180 to pass between the chambers 186,188. The fluid manifold 179 includes strainer covers 196 that can be selectively removed to permit the strainer baskets 180 to be accessed and removed from the fluid manifold 179 (e.g., to permit cleaning of the strainer basket 180 and/or the inside of the fluid manifold 179). Each of the illustrated strainer baskets 180 is preferably removable independently of the other strainer basket 180.
The fluid manifold 179 and each strainer basket 180 cooperatively define a manifold axis A2 along which the strainer basket 180 is manually slidable into and out of the passage 190. In the illustrated embodiment, the manifold axis A2 is preferably angled upwardly from the lateral direction at an acute angle (not shown), which is substantially identical to an acute angle θ (see
Also in the illustrated strainer configuration, each pair of axes A1 are generally parallel to each other and each pair of axes A2 are generally parallel to each other. Furthermore, the axes A1 are preferably parallel to the axes A2. However, the strainer assemblies 42,44 could be alternatively configured.
The pressure strainer assembly 44 is preferably configured so that an operator can manually lift and remove each of the strainer baskets 180, and any coating material in the baskets 180, from the fluid manifold 179 while standing on the ground alongside the vehicle 20. That is, the operator can lift and remove each strainer basket 180, and any coating material in the basket 180, while standing next to the vehicle 20 without the assistance of powered machinery. As a result, the pressure strainer assembly 44 is particularly configured for convenient and quick manual disposal of material caught in the pressure strainer assembly 42.
The pressure strainer assembly 44 is preferably fluidly connected downstream of the pump 46 so that the strainer inlet 182 is fluidly connected to the pump outlet 154 with a pump discharge tube 198. Specifically, the pump discharge tube 198 is fluidly connected to the outlet 154 of the pump 46 and the inlet 182 of the pressure strainer assembly 44. Thus, the pump 46 is operable to pump coating material from the pump outlet 154 through the pressure strainer assembly 44, with material flowing through at least one of the two pressure strainer baskets 158.
While the illustrated spraying assembly 28 includes a single pump 46, it is within the scope of the present invention for the spraying assembly 28 to include multiple pumps. For instance, as disclosed in the above-incorporated ‘ ’xyz application, an alternative spraying assembly 28 could include a pair of pumps that operate in parallel with one another and cooperatively move material through the strainer assemblies 42,44.
It will be appreciated that one or both of the strainer assemblies 42,44 could be alternatively configured without departing from the scope of the present invention. Furthermore, while the illustrated spraying assembly 28 preferably includes both of the strainer assemblies 42,44, it is within the ambit of the present invention where only one of the strainer assemblies 42,44 is used (e.g., for spraying operation).
Turning to
The boom supply valves 206a,b are configured to selectively permit the flow of pressurized coating material to the boom sections 100,102. Each boom supply valve 206a,b comprises a manually operable valve with a fractional turn handle. The boom supply valves 206a,b are fluidly connected to corresponding supply hoses 118a,b to selectively control the flow of coating material from the supply manifold 204 to corresponding supply hoses 118a,b. In particular, the boom supply valve 206a is operable when opened to permit the flow of coating material to supply hoses 118a and to the chamber 110a of the central boom section 100. Boom supply valve 206b is operable when opened to control the flow of coating material to supply hoses 118b and to the chambers 110b of corresponding extendable boom sections 102.
During spraying operation, the boom supply valves 206a,b are all preferably opened to permit coating material to flow to all of the boom sections 100,102. However, it is within the scope of the present invention where at least one of the boom supply valves 206a,b is closed during operation so that coating material is not supplied to at least one of the boom sections 100,102.
The vehicle 20 is preferably configured to permit convenient and efficient filling of the tank 26 with coating material. Preferably, such filling is generally conducted prior to any spraying operation. The vehicle 20 preferably includes a forward fill assembly 208 and an aft fill assembly 210 (see
The aft fill assembly 210 preferably includes a stub line 212, a manual fill valve 214, and a coupler end 216 that presents a fill port 218 (see
The coupler end 216 is configured to be removably attached to a powered material filling station (not shown). The filling station includes a supply tank (not shown), a pump (not shown) that pumps coating material from the supply tank, a fill supply hose (not shown) that discharges pressurized coating material from the pump. The fill supply hose includes a coupler end (not shown) that is coupled to the fill port 218 by removably connecting the coupler end of the fill supply hose to the coupler end 216 of the aft fill assembly 210. With the fill supply hose connected, coating material can be pumped from the supply tank to the supply line 202.
To fill the tank 26 via the aft fill assembly 210, the coupler end of the fill supply hose is initially connected to the coupler end 216. If the boom supply valves 206a,b are open, the boom supply valves 206a,b are preferably closed prior to operating the filling station. Optionally, the tank discharge valve 177 can also be closed prior to filling the tank 26.
The operator can then operate the pump of the filling station so that coating material flows from the fill supply hose into the supply line 202. The coating material can then travel through the supply manifold 204 and into the tank 26.
The forward fill assembly 208 preferably includes a stub line 220, a manual fill valve 222, and a coupler end 224 that presents a fill port 226 (see
The coupler end 224 is configured to be removably attached to an unpowered material filling station (not shown). The unpowered filling station includes a supply tank (not shown) and a fill supply hose (not shown) that discharges coating material from the supply tank. However, the unpowered filling station does not include a pump. Rather, the pump 46 is preferably used to draw coating material from the supply tank of the filling station.
The fill supply hose includes a coupler end (not shown) that is coupled to the fill port 226 by removably connecting the coupler end of the fill supply hose to the coupler end 224 of the forward fill assembly 208. With the fill supply hose connected, coating material can be pumped from the supply tank to the pump intake manifold 176.
To fill the tank 26 via the forward fill assembly 208, the coupler end of the fill supply hose is initially connected to the coupler end 224. If the boom supply valves 206a,b are open, the boom supply valves 206a,b are preferably closed prior to operating the pump 46. Optionally, the tank discharge valve 177 can also be closed prior to filling the tank 26.
The operator can then operate the pump 46 so that coating material flows from the supply tank, through the pump intake manifold 176, and into the pump 46. The coating material can then travel through the pressure strainer assembly 44, the supply line 202, the supply manifold 204, and into the tank 26.
The pump 46 and strainer assemblies 42,44 of spraying assembly 28 are preferably configured to provide recirculation of coating material contained within the tank 26 and other components of the spraying assembly 28. Coating material within the tank 26 is preferably recirculated through the system during a period when coating material is not being sprayed. Recirculation restricts the coating material from becoming clumped and/or from hardening within the system.
To recirculate coating material, the tank discharge valve 177 is preferably opened. If the boom supply valves 206a,b are open, the boom supply valves 206a,b are preferably closed prior to operating the pump 46. If coating material is being recirculated without pumping additional coating material into the system, the fill valves of the fill assemblies are closed prior to operating the pump 46.
The operator can then operate the pump 46 so that coating material flows from the tank discharge valve 177, through the tank discharge line 178, the suction strainer assembly 42, the pump intake manifold 176, the pump 46, the pressure strainer assembly 44, the supply line 202, the supply manifold 204, and back into the tank 26.
It is also possible to recirculate coating material within the system while also pumping additional coating material into the system. For such an operation, the fill valve 214,222 of the corresponding fill assembly 208,210 used to permit the addition of coating material is opened to permit the introduction of additional coating material.
Turning to
The control system 144 preferably includes hydraulic valves (not shown) that are operably coupled to, respectively, the boom shift cylinder 56, lift cylinder 90, boom extension cylinders 136, and valve cylinders 124. Thus, the control system 144 is configured to control the piston position for each of the cylinders 56,90,124,136.
As discussed above, the illustrated pump 46 is preferably calibrated to pump a known mass or volume of material per pump count. The pump 46 can be operated by the control system 144 to discharge, while operating at a set rotational speed, a volume of material into a container (not shown) for a predetermined number of pump counts. The mass of material in the container is then measured (e.g., by weighing the container and material) to produce a calibration scale factor. The calibration scale factor is stored in the control system 144 and later used by the control system 144 during operation to correlate pump count with the output volume (mass) of pavement coating material.
The ground speed sensor 234 is attached to the chassis frame 30 to sense the ground travel speed of the vehicle 20. The sensor 234 preferably comprises a radar sensor, although other vehicle speed sensors could be used without departing from the scope of the present invention.
The rotation speed sensor 236 is operably coupled to the pump 46 and is configured to sense the rotational speed of the pump 46. The illustrated pump 46 is preferably calibrated to pump a known volume of material for one complete pump revolution. Because the control system 144 is programmed to retain calibration data ratios of pumped material volume per revolution of the pump, the processor can calculate the volumetric flow rate (and/or mass flow rate) of material transmitted by the pump 46 as a function of the pump rotational speed.
The processor element 228 is operably coupled to the sensors 234,236 to receive signals from the sensors corresponding to the sensed speed values. The processor element 228 is also preferably coupled to other sensors associated with the spraying system 28, and other components of the vehicle 20, to receive signals from those sensors about various operational parameters.
The user interface 232 is configured for an operator to input various predetermined operating parameters associated with a particular spraying operation. In the illustrated embodiment, the user interface 232 preferably permits the operator to input the predetermined application rate of pavement coating material applied to the roadway. The user interface 232 also preferably permits the operator to input a predetermined value of boom width B.
The illustrated user interface 232 is preferably installed in the cab 24 and is accessible by the vehicle operator (e.g., when advancing the vehicle 20). However, the vehicle 20 also includes another user interface that is similar to the user interface 232 and is mounted on the rear deck 38 of the vehicle 20.
Based upon the predetermined value of boom width B, the control system 144 is preferably programmed to move the extendable boom sections 100,102 to corresponding positions so that the spray boom 48 provides the corresponding boom width dimension. Additionally, the control system 144 is also preferably programmed to keep corresponding valves 122 open so that corresponding spray nozzles 120 are engaged and operable to spray across the boom width B.
Preferably, the processor element 228 is operably coupled to the pump 46 to control the rotational speed of the pump 46. The processor element 228 calculates a pump rotation speed setpoint value as a function of the user inputted values of predetermined application rate and boom width B. The processor element 228 also calculates the pump rotation speed setpoint value as a function of the sensed value of ground speed from the ground speed sensor 234. As the operator increases or decreases the ground speed of the vehicle 20, the processor element 228 automatically adjusts the rotational speed of the pump 46 to automatically maintain the predetermined application rate of pavement coating material.
In use, prior to engaging the spraying assembly 28, the vehicle operator preferably sets the predetermined application rate of pavement coating material to be achieved by spraying a flow of pavement coating material onto the roadway. Also prior to engaging the spraying assembly 28, the operator preferably sets the boom width B. If the spray boom 48 is not at the boom width B, the spray boom 48 can be adjusted automatically by the control system 144 or manually by the operator. The operator can then engage the spraying assembly 28 and begin advancing the vehicle 20 forwardly along the roadway.
As the vehicle 20 is being advanced, the control system 144 preferably determines the ground speed of the vehicle 20. In particular, the processor element 228 receives a ground speed signal from the ground speed sensor 234.
Also, as the vehicle 20 is being advanced, the control system 144 supplies power to and operates the pump 46 to discharge the flow of pavement coating material onto the roadway through the engaged spray nozzles 120 (i.e., the spray nozzles 120 associated with valves 122 that are kept open by the control system 144).
The pump 46 is preferably operated to maintain the predetermined application rate by adjusting the volumetric flow rate (or mass flow rate) of the pump 46 in response to a change in the sensed ground speed.
If the operator adjusts the boom width B during the spraying operation, the control system 144 preferably automatically adjusts the volumetric flow rate (or mass flow rate) of the pump 46 to maintain the predetermined application rate of coating material.
Although the above description presents features of preferred embodiments of the present invention, other preferred embodiments may also be created in keeping with the principles of the invention. Such other preferred embodiments may, for instance, be provided with features drawn from one or more of the embodiments described above. Yet further, such other preferred embodiments may include features from multiple embodiments described above, particularly where such features are compatible for use together despite having been presented independently as part of separate embodiments in the above description.
The preferred forms of the invention described above are to be used as illustration only, and should not be utilized in a limiting sense in interpreting the scope of the present invention. Obvious modifications to the exemplary embodiments, as hereinabove set forth, could be readily made by those skilled in the art without departing from the spirit of the present invention.
The inventors hereby state their intent to rely on the Doctrine of Equivalents to determine and assess the reasonably fair scope of the present invention as pertains to any apparatus not materially departing from but outside the literal scope of the invention as set forth in the following claims.
This application claims the benefit of U.S. Provisional Application Ser. No. 62/108,273, filed Jan. 27, 2015, entitled PAVEMENT COATING SYSTEM, which is hereby incorporated in its entirety by reference herein.
Number | Name | Date | Kind |
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5324136 | Reymonet et al. | Jun 1994 | A |
5522543 | Herzog | Jun 1996 | A |
5957621 | Clark, Jr. | Sep 1999 | A |
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20150337501 | Thieme | Nov 2015 | A1 |
Number | Date | Country |
---|---|---|
2659993 | Sep 1991 | FR |
Entry |
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Etnyre, Black-Topper® Centennial Asphalt Distributor, Manual No. M-114-07R (document dated Jul. 2009). |
Number | Date | Country | |
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20160215460 A1 | Jul 2016 | US |
Number | Date | Country | |
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62108273 | Jan 2015 | US |