Compacting machine and method of monitoring compacting member of compacting machine

A compacting machine includes a frame supporting a compacting member and a monitoring system. The monitoring system includes a sensor, a computer-readable medium bearing a compacting member monitoring program, a controller, and an interface device in communication with the controller. The sensor is arranged with the compacting member to sense a parameter of its ground-engaging surface and to generate a surface parameter signal indicative of the parameter. The controller is in communication with the sensor to receive the surface parameter signal therefrom and is configured to execute the compacting member monitoring program. The compacting member monitoring program is configured to determine whether a piece of the material being compacted becomes adhered to the ground-engaging surface based upon the surface parameter signal satisfying a condition and to produce, through the interface device, an indicator alerting the operator once the surface parameter signal satisfies the condition.

TECHNICAL FIELD

This patent disclosure relates generally to systems and methods for monitoring a compacting machine and, more particularly, to systems and methods for monitoring a ground-engaging surface of a compacting member of a compacting machine performing a compacting operation at a worksite.

BACKGROUND

Asphalt paving involves depositing a mat of paving material such as hot asphalt on a bed and then compacting the asphalt to a uniform thickness and consistency. Compactors use different configurations for the compacting process. Some compactors use a steel drum with vibrators. Other compactors use separate wheels, while others use a combination of separate wheels and drums.

During compaction, the compacting member can tend to collect pieces of the material being compacted on its ground-engaging surface via adhesion between the material being compacted and the compacting member. Pneumatic and vibratory asphalt compactors distribute water or other fluids on the tire and drum surface to help prevent asphalt material from sticking to them. When material does stick to the tire or drum, it can produce indentations in the road surface with every rotation or possibly cause more material to be pulled up from the asphalt mat. These indentations or holes in the road surface are undesirable. Often the machine operator does not see the material stuck to the tire or drum until it has caused multiple indentations.

U.S. Pat. No. 9,367,042 is entitled, “Machine Alert When Stopping on Hot Asphalt” and is directed to an alert system in equipment used in an asphalt paving environment, such as a compactor, that signals an operator when the equipment is stopped on hot asphalt, potentially over-compacting the area where the equipment is located. The alert system includes a surface temperature sensor so that the alert is only activated when there is a risk of over-compaction because the asphalt is still above a threshold temperature. The alert system may also include a timer so that the operator is not signaled during routine stopping associated with changing direction during compacting operations.

It will be appreciated that this background description has been created by the inventors to aid the reader, and is not to be taken as an indication that any of the indicated problems were themselves appreciated in the art. While the described principles can, in some aspects and embodiments, alleviate the problems inherent in other systems, it will be appreciated that the scope of the protected innovation is defined by the attached claims, and not by the ability of any disclosed feature to solve any specific problem noted herein.

SUMMARY

In one aspect of the present disclosure, embodiments of a compacting machine for compacting a material are described. In one embodiment, the compacting machine includes a frame, a compacting member, and a monitoring system.

The compacting member is mounted to the frame. The compacting member has a ground-engaging surface.

The monitoring system is supported by the frame and includes a sensor, a non-transitory computer-readable medium, a controller, and an interface device. The sensor is arranged with the compacting member to sense a parameter of the ground-engaging surface. The sensor is configured to generate a surface parameter signal indicative of the parameter of the ground-engaging surface sensed by the sensor. The non-transitory computer-readable medium bears a compacting member monitoring program. The controller is in communication with the sensor to receive the surface parameter signal from the sensor. The controller is in operable arrangement with the non-transitory computer-readable medium such that the controller is configured to execute the compacting member monitoring program contained thereon. The interface device is in communication with the controller.

The compacting member monitoring program includes a ground-engaging surface monitoring module and a messaging module. The ground-engaging surface monitoring module is configured to monitor for a piece of the material being adhered to the ground-engaging surface based upon the surface parameter signal from the sensor satisfying a condition. The messaging module is configured to produce, through the interface device, an indicator that the piece of the material adhered to the ground-engaging surface once the surface parameter signal satisfies the condition.

In another aspect of the present disclosure, embodiments are described of a method of monitoring a compacting member of a compacting machine for compacting a material. In one embodiment, a method of monitoring a compacting member of a compacting machine for compacting a material is used with a compacting member that includes a ground-engaging surface.

A parameter of the ground-engaging surface is sensed with a sensor to generate a surface parameter signal indicative of the parameter of the ground-engaging surface sensed by the sensor. The surface parameter signal is transmitted to a controller. The controller is used to execute a compacting member monitoring program stored upon a non-transitory computer-readable medium to determine whether a piece of the material is adhered to the ground-engaging surface using the surface parameter signal. In response to the compacting member monitoring program determining the piece of the material is adhered to the ground-engaging surface, the controller is used to execute the compacting member monitoring program to provide, through an interface device, an indicator that the piece of the material adhered to the ground-engaging surface.

Further and alternative aspects and features of the disclosed principles will be appreciated from the following detailed description and the accompanying drawings. As will be appreciated, systems and methods for monitoring a compacting member of a compacting machine and compacting machines incorporating the same which are disclosed herein are capable of being carried out in other and different embodiments, and capable of being modified in various respects. Accordingly, it is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and do not restrict the scope of the appended claims.

DETAILED DESCRIPTION

Embodiments of compaction machines and systems and methods for monitoring a compacting member of a compacting machine at a worksite are disclosed herein. In embodiments, a parameter of a ground-engaging surface of the compacting member is monitored while the compacting machine is being used at a worksite to perform a compacting operation to determine whether a piece of material being compacted becomes adhered to the ground-engaging surface of the compacting member. In embodiments, a suitable detection device is used to monitor the parameter of the ground-engaging surface as the compacting machine performs compacting operations.

In embodiments, suitable detection techniques include, but are not limited to, optical detection configured to monitor for color differences on the ground-engaging surface of the compacting member (e.g., asphalt is black, whereas the ground-engaging surface of a compacting member in the form of a drum can be gray or silver); optical detection to monitor for reflectance variations on the ground-engaging surface of the compacting member (e.g., the ground-engaging surface of the compacting member can be relatively more shiny than a piece of asphalt stuck thereto, especially when water is applied to the ground-engaging surface to help prevent a sticking condition); and laser/distance measurement detection to monitor for irregularities on the ground-engaging surface of the compacting member. It will be appreciated that, in other embodiments, other suitable detection techniques can be used to monitor a parameter of the ground-engaging surface of the compacting member to determine whether a piece of the material being compacted is adhered thereto.

In embodiments, once the system determines that a piece of the material being compacted has adhered to the ground-engaging surface of the compacting member, the system can be configured to issue an indicator alert to the operator of the compacting machine that material is stuck to the compacting member. The issuance of the indicator alert can allow the operator to remove the adhered material relatively quickly to help reduce continuing to compact the material with the adhered material interposed between the compacting member and the material being compacted so that the damage to the finished surface is reduced.

Turning now to the Figures, there is shown inFIG. 1an exemplary embodiment of a compacting machine10constructed according to principles of the present disclosure which includes an embodiment of a system for monitoring a compacting member of the compacting machine. In the illustrated embodiment, the compacting machine10is in the form of a vibratory compactor machine.

The compacting machine10can be used in situations where loose surface material, characterized as material which can be further packed or densified, is disposed over the surface. As the compacting machine10travels over the surface, vibrational forces generated by the compacting machine10imparted to the surface, acting in cooperation with the weight of the compacting machine10, compress the loose material to a state of greater compaction and density. The compacting machine10may make one or more passes over the surface to provide a desired level of compaction. The vibrational forces imparted to the surface may be determined based on properties of the work material, such as temperature. In one application, the loose material can be freshly-deposited asphalt that is to be compacted into roadways or similar hardtop surfaces. However, in other applications, the material may be soil, gravel, sand, landfill trash, concrete, combinations thereof, or other material capable of being compacted.

In other embodiments, the principles disclosed herein can be incorporated and used with other suitable machines. In other embodiments, the compacting machine10can have different forms, such as any other compacting machine known to those skilled in the art including soil compactors, asphalt compactors, utility compactors, pneumatic compactors, vibratory compactors, self-propelled two-wheel and four-wheel compactors, and tow-behind systems, for example. For example, in embodiments, the compactor machine comprises a vibratory compactor machine having one or more roller drums that are in rolling contact with a surface to be compacted. In embodiments, the compacting machine10includes a single compacting member.

The compacting machine10illustrated inFIG. 1includes a frame12, first and second compacting members14,16, an operator compartment18, an embodiment of a monitoring system25constructed according to principles of the present disclosure, an autonomous control module28, and first and second clearing devices34,36respectively associated with the first and second compacting members14,16.

The frame12includes structural members of the compacting machine10that can be used to support other systems of the compacting machine10that enable the compacting machine10to function. In embodiments, the frame12can have any suitable configuration as will be appreciated by one skilled in the art.

To propel the compacting machine10over the surface, a power system, such as an engine40, can also be mounted to the frame12and can be configured to generate power to move the compacting machine10. One or more other implements (not shown) may be connected to the compacting machine10. Such implements can be used for a variety of tasks, including, for example, loading, lifting, and brushing, and may include, for example, buckets, forked lifting devices, brushes, grapples, cutters, shears, blades, breakers/hammers, augers, and any other implement known in the art.

Each of the first and second compacting members14,16is mounted to the frame12. Each of the first and second compacting members14,16has a ground-engaging surface45. The first and second compacting members14,16are configured to compact the material over which the compacting machine10is propelled. In embodiments, to transfer motive power from the engine40to the surface upon which the first and second compacting members14,16are resting, the engine40can operatively drive and rotate only the first compacting member14, only the second compacting member16, or both the first and second compacting members14,16, through an appropriate power train.

In the illustrated embodiment, each of the first and second compacting members14,16comprises a drum rotatably mounted to the frame12. Both of the first and second compacting members14,16are rotatably coupled to frame12so that the first and second compacting members14,16are in rolling contact with the surface material as the compacting machine10travels over the material being compacted.

It will be appreciated that, in embodiments, the first compacting member14can have the same or different construction as the second compacting member16. In the illustrated embodiment, the first and second compacting members14,16have the same construction comprising an elongated, hollow cylinder with a cylindrical drum shell that encloses an interior volume. The cylindrical roller drum extends along and defines a cylindrical drum axis. To withstand being in rolling contact with and compacting the surface material, the drum shell can be made from a thick, rigid material such as cast iron or steel in embodiments.

In other embodiments, the compacting member can have a different construction, such as a rubber tire, for example. In embodiments, the compacting machine10can include a single roller drum and rubber tires (not shown) configured to contact the material being compacted.

Both the first compacting member14and the second compacting member16can have a vibratory mechanism50associated therewith. WhileFIG. 1shows both the first and second compacting members14,16being associated with vibratory mechanisms50, in other embodiments, only one of the first and second compacting members14,16has the vibratory mechanism50. In still other embodiments, a single vibratory mechanism50or multiple vibratory mechanisms50can be located at different locations on the compacting machine10. In embodiments, the vibratory mechanism50can have any suitable construction, as will be appreciated by one skilled in the art. In embodiments, the vibratory mechanism50can comprise a variable vibratory mechanism that is configured to impart a range of different vibrations.

The compacting machine10is adapted to be controlled by an operator. The operator compartment18is supported by the frame12and is configured to hold one or more operators therein during operation of the compacting machine10. As shown inFIG. 1, the operator compartment18is mounted on top of the frame12, from which an operator may control and direct operation of the compacting machine10. Additionally, a steering apparatus52and similar controls can be located within the operator compartment18.

Referring toFIG. 1, the compacting machine10includes an embodiment of a compacting member monitoring system25constructed according to principles of the present disclosure. The monitoring system25is configured to monitor both of the first and second compacting members14,16for a sticking condition in which the material being compacted adheres to the ground-engaging surface45of one or both of the first and second compacting members14,16. In embodiments, the monitoring system25is configured to detect when a piece of material becomes adhered to the ground-engaging surface45of at least one of the first and second compacting members14,16when a sensor detects the sticking condition has been satisfied. In embodiments, the determination of whether the condition has been satisfied is computed according to a predetermined technique.

The monitoring system25is supported by the frame12. The illustrated monitoring system25includes first and second sensors100,101respectively associated with the ground-engaging surface45of each of the first and second compacting members14,16, a controller104, a non-transitory computer-readable medium105, an interface device107, a data storage device108, and a communication device110.

The first and second sensors100,101are mounted to the frame12such that they are arranged with the first and second compacting members14,16, respectively, to sense a parameter of the ground-engaging surface45. The first and second sensors100,101are each configured to generate a surface parameter signal indicative of the parameter of the ground-engaging surface of the first and second compacting members14,16respectively sensed by the first and second sensors100,101.

The controller104is in communication with the first and second sensors100,101to receive the respective surface parameter signal from the first and second sensors100,101. The controller104is in operable arrangement with the non-transitory computer-readable medium105such that the controller104is configured to execute a compacting member monitoring program contained thereon. The compacting member monitoring program is configured to determine whether a piece of the material being compacted becomes adhered to the ground-engaging surface45of either (or both) of the first and second compacting members14,16.

The interface device107is mounted within the operator compartment18. The interface device107is in communication with the controller104. The interface device107is configured to produce an alert transmitted by the compacting member monitoring program via the controller104once the compacting member monitoring program has determined that a piece of the material being compacted has become adhered to at least one of the ground-engaging surfaces45of the first and second compacting members14,16.

The data storage device108is in communication with the controller104. The data storage device108is configured to store therein data used by the compacting member monitoring program105when it is being executed by the controller104.

The compacting member monitoring program105includes a ground-engaging surface monitoring module and a messaging module. The ground-engaging surface monitoring module is configured to monitor for a piece of the material being adhered to the ground-engaging surface45of each of the first and second compacting members14,16based upon the surface parameter signal from the respective sensor100,101satisfying a condition. The messaging module is configured to produce, through the interface device107, an indicator alerting the operator that the piece of the material has become adhered to the affected ground-engaging surface45once the surface parameter signal satisfies the condition. In embodiments, the indicator can be configured to indicate which one of the first and second compacting members14,16has the piece of material stuck thereto.

In the illustrated embodiment, the compacting machine10is also configured to be operated autonomously, and is provided with the autonomous control module28for that purpose. The autonomous control module28is configured to autonomously control operation of the compacting machine10.

In embodiments, the autonomous control module28can include a suitable geolocation unit configured to generate a location signal indicative of a location of the compacting machine10for use by the autonomous control module28. In embodiments, the geolocation unit can comprise any suitable device configured to determine the location of the compacting machine10and to send a location signal indicative of an absolute location (including, e.g., latitude, longitude, and altitude information) of the compacting machine10to the autonomous control module28. For example, in embodiments, the geolocation unit comprises a Global Positioning System (GPS) receiver. In embodiments, the GPS receiver is configured to generate a location signal that includes a latitudinal position and a longitudinal position.

In other embodiments, the geolocation unit can comprise a portion of an Inertial Reference System (IRS), a local tracking system, or another known locating system that receives or determines positional information associated with the compacting machine10. Suitable technologies for geolocation include, but are not limited to, the U.S. Global Positioning System, the Russian GLONASS satellite-based system, the European Galileo satellite-based system, and radio-positioning systems provided by Locata Corporation of Canberra, Australia, for example. In embodiments, the geolocation unit can be configured to receive and process geolocation signals from multiple systems to generate the location signal sent to the autonomous control module28.

In some embodiments, the location signal generated by the geolocation unit can be conveyed to a remotely-located central station via the communication device110to convey signals indicative of the received or determined positional information of the compacting machine10for further processing by a remote operator. The remote operator of the compacting machine10can control the movement of the compacting machine10based on the determined geolocation signal. Control commands may be issued through the communication device110or any other suitable communication network as is known in the art.

Further, the autonomous control module28can be configured to autonomously operate the compacting machine10according to a set of instructions. The set of instructions can be located on the autonomous control module28onboard the compacting machine10or can be issued by a remotely-located central station through the communication device110, for instance.

The controller104is in communication with the autonomous control module28. In embodiments, the messaging module of the compacting member monitoring program105is configured to transmit a sticking condition signal via the controller104to the autonomous control module28once the surface parameter signal of one of the first and second sensors100,101satisfies the condition.

The autonomous control module28can be configured to perform an asphalt-sticking control operation of the compacting machine10in response to receiving the sticking condition signal from the controller104. For example, in embodiments, the asphalt-sticking control operation of the compacting machine10comprises at least one of terminating operation of the compacting machine10and shutting down the engine40of the compacting machine10.

In other embodiments, the asphalt-sticking control operation of the compacting machine10comprises using the autonomous control module28to maneuver the compacting machine10along an exit path off the material. In embodiments, the autonomous control module28is in communication with a geolocation unit that can detect the location of the compacting machine10within a compacting area designated for material compaction. Upon receiving the sticking condition signal from the controller104, the autonomous control module28can calculate an exit path that moves the compacting machine10outside of the perimeter of the compacting area using the geolocation unit. In embodiments, the autonomous control module28can calculate the exit path to be the shortest practical route.

In the illustrated embodiment, the first and second clearing devices34,36are respectively associated with the first and second compacting members14,16. Each clearing device34,36is mounted to the frame12proximate the compacting member14,16with which it is associated. The controller104is in communication with both of the clearing devices34,36.

In embodiments, the messaging module of the compacting member monitoring program105is configured to transmit a command signal via the controller104to the clearing device34,36associated with the compacting member14,16having a piece of material stuck thereto to perform the clearing operation once the surface parameter signal from the sensor100,101satisfies the condition. Each clearing device34,36is configured to selectively perform a clearing operation in response to the command signal from the controller104to remove the material adhered to the ground-engaging surface45of the affected compacting member14,16.

In embodiments, the first and second clearing device34,36can have the same construction, or be different form each other. In embodiments, any suitable clearing device can be used.

For example, in embodiments, each clearing device34,36comprises a supply of fluid and a sprayer in fluid communication with the supply of fluid. The sprayer can be configured to selectively direct a pressurized spray of fluid upon the ground-engaging surface45of the compacting member14,16having a piece of material adhered thereto once the command signal is received from the controller104.

In other embodiments, each clearing device34,36comprises a wiper blade movable over a range of travel between a stowed position, in which the wiper blade is in non-contacting relationship with the ground-engaging surface45of the compacting member14,16with which it is associated, and a wiping position, in which the wiper blade is in contacting relationship with the ground-engaging surface45of the compacting member14,16to remove the material adhered thereto. The wiper blade can be configured to move from the stowed position to the wiping position in response to receiving the command signal via any suitable technique. For example, in embodiments, at least one cylindrical actuators is provided to reciprocally move the wiper blade between the stowed position and the wiping position. Each such cylindrical actuator can be in communication with the controller104to receive the command signal therefrom.

Referring toFIG. 2, the first sensor100is shown disposed over the first compacting member14in diagrammatic fashion. It will be understood that the description of the first sensor100and the first compacting member14is also applicable to the second sensor101and the second compacting member16, which in the illustrated embodiment both have a respectively similar construction. One skilled in the art will understand that, in embodiments, any suitable sensor can be used to detect whether a piece75of the material being compacted has become adhered to the ground-engaging surface of the compacting member.

For example, in embodiments, the sensor100comprises a distance sensor configured to detect a topographic variation on the ground-engaging surface45of the compacting member14caused by the piece of the material being adhered to the ground-engaging surface. In embodiments, the sensor100comprises a laser distance sensor. The sensor100can be configured to scan the entire width W of the ground-engaging surface45with a linear scan77such that as the compacting member14rotates relative the frame12to which the sensor100is mounted, the sensor100scans the entire surface area of the ground-engaging surface45for every complete revolution of the compacting member14.

In other embodiments, the sensor100comprises an optical sensor. In embodiments, the optical sensor comprises a color sensor configured to detect a color variation on the ground-engaging surface45of the compacting member14caused by the piece75of the material being adhered to the ground-engaging surface45. For example, in embodiments, the ground-engaging surface45is made from a metal that is gray in color. When the compacting machine is compacting asphalt, the sensor100can be configured to detect a color variation between the gray color of the ground-engaging surface45and the black color of the asphalt being compacted such that if a piece75of the asphalt becomes adhered to the ground-engaging surface45, the sensor100is able to detect the color variation therebetween.

In other embodiments, the sensor100comprises another suitable optical sensor. For example, in embodiments, the optical sensor is in the form of a reflectance sensor that is configured to detect a reflection variation on the ground-engaging surface45of the compacting member14caused by the piece75of the material being adhered to the ground-engaging surface45. For example, in some embodiments, a spray of water is directed upon the ground-engaging surface45of the compacting member14to help prevent material from becoming adhered thereto. The sensor100can be configured to detect the reflectance variation between the relatively shiny ground-engaging surface45(which is wetted with water) and the relatively dull piece of material adhered to the ground-engaging surface45.

Referring toFIG. 3, there is shown a schematic and diagrammatic view of the compacting member monitoring system25of the compacting machine10. The first and second sensors100,101are respectively arranged with the first and second compacting members14,16to sense a designated parameter of the ground-engaging surface45of the respective compacting member14,16. Each of the sensors100,101is configured to generate a respective parameter signal indicative of the parameter sensed by the particular sensor100,101. In embodiments, the sensors100,101can comprise any suitable sensor configured to sense a parameter useful for detecting whether a piece of the material being compacted becomes adhered to the ground-engaging surface45of the compacting member14,16with which the sensor100,101is associated. In embodiments, the sensors100,101are configured to transmit a parameter signal substantially continuously to the controller104while the compacting machine10is moving.

The controller104is in operable communication with the sensors100,101to receive the respective parameter signals therefrom. The controller104is in operable arrangement with the non-transitory computer-readable medium105such that the controller104is configured to execute the compacting member monitoring program contained thereon. The controller104is also operably arranged with the autonomous control module28, the interface device107, the data storage device108, and the communication device110.

The controller104can include a processor120and be programmed with the compacting member monitoring program contained upon the non-transitory, tangible computer-readable storage medium105. When executed by the processor120, the compacting member monitoring program105provides the controller104with the functionality to monitor the compacting members14,16of the compacting machine10(based upon the readings from the sensors100,101) to determine whether a material being compacted has become adhered to one or both of the ground-engaging surfaces45of the compacting members14,16.

In embodiments, the processor120can generally include any component of an application that can receive input from a client or the interface device107, process the input, present the input to the compacting member monitoring program105, and present output from the processor120to a client (such as a remotely-located central processing unit), the autonomous control module28, the interface device107, and/or to the data storage device108, and execute logic for the compacting member monitoring program105. In embodiments, the controller104can include one or more processors that can execute instructions and process data to perform one or more functions associated with the compacting member monitoring system25. For instance, the controller104can execute software that enables the compacting member monitoring system25to request and/or receive data from outside of the compacting member monitoring system25, such as operational data pertaining to the compacting machine10from one or more other systems.

In embodiments, the controller104is configured to communicate to another processing unit, such as a central computer system with which a fleet of compacting machines having a compacting member monitoring system constructed according to principles of the present disclosure is in communication. In embodiments, the controller104is configured to transmit a material-sticking event signal to an off board processing unit. In embodiments, the material-sticking event signal can include data generated by the compacting member monitoring system25, including, e.g., parameter data and corresponding location data.

The non-transitory computer-readable medium105bears a compacting member monitoring program constructed according to principles of the present disclosure. In embodiments, the compacting member monitoring program105includes a graphical user interface. In embodiments, the compacting member monitoring program105is configured to monitor the parameter signals from the sensors100,101to determine whether the compacting machine10experiences a material-sticking condition. In embodiments, the compacting member monitoring program105is configured to track the locations at the worksite where such sticking conditions occur so that the material being compacted can be examined to confirm that it is not damaged or otherwise unsatisfactorily compacted. In embodiments, the compacting member monitoring program105is configured to carry out any method (or steps of a method) of monitoring a compacting member of a compacting machine10that follows principles of the present disclosure. In embodiments, the compacting member monitoring program105can include a monitoring module, a tracking module, and a messaging module.

The monitoring module can be configured to monitor the parameter signals from each of the sensors100,101for an occurrence of a material-sticking condition in which a piece of the material being compacted becomes adhered to at least one of the compacting members14,16. In embodiments, the monitoring module is configured to monitor for a material-sticking condition based upon a parameter exceeding a differential limit relative to a baseline value for the parameter stored in the data storage device108.

In embodiments, the monitoring module can be configured to monitor the parameter signal from each of the sensors100,101substantially continuously for an occurrence of a material-sticking condition. In embodiments, the monitoring module can be configured to monitor the parameter signal from each of the sensors100,101only when the compacting machine10is moving, such as when it is engaged in a compacting operation. In some embodiments, the monitoring module can use the location signal from the geolocation unit to determine whether the machine is moving. In still other embodiments, a velocity of the compacting machine10from an on-board module of the machine can be in communication with the controller104, and its velocity reading can be used by the monitoring module to determine whether the compacting machine10is moving.

In embodiments, the monitoring module of the compacting member monitoring program105is configured to determine whether a material-sticking condition has occurred based upon comparing the parameter signals from the sensors100,101to a database of parameter data stored in the data storage device108. In embodiments, a suitable statistical analysis technique applied to the database of parameter data can be used to monitor the parameter signals of the compacting machine10to determine whether a material-sticking condition has occurred.

The tracking module can be configured to track the location of the compacting machine10when the material-sticking condition occurred. In embodiments, the tracking module can use the data in the location signal from the geolocation unit to determine the location at which the material-sticking condition occurred. In embodiments, the tracking module can also store the time at which the compacting machine10experienced the material-sticking condition. In embodiments, the tracking module can be configured to store the location and/or time data relating to the material-sticking conditions experienced by the compacting machine10in the data storage device108.

In embodiments, the controller104is adapted to assemble an indicator (such as in the form of a first pop-up message) from data in the data storage device108in response to receiving an indication from the monitoring module of the compacting member monitoring program105that the compacting machine10has experienced a material-sticking condition. In embodiments, the messaging module can be configured to display, through the graphical user interface, an indicator in the interface device107indicating that the material-sticking condition occurred once the parameter signal satisfies a predetermined condition. The controller104can transmit the indicator to the interface device107for display to the operator125via the graphical user interface of the compacting member monitoring program105. In other embodiments, the indicator can be in the form of an audible sound emitted by a suitable speaker associated with the interface device107. In embodiments, the indicator can include data describing the material-sticking condition, including for example the location of the material-sticking condition (e.g., which one of the compacting members14,16is affected).

The interface device107is in operable communication with the controller104. The interface device107is configured to display the graphical user interface of the compacting member monitoring program105. In embodiments, the interface device107can be mounted within the operator compartment18of the compacting machine10. In embodiments, the interface device107is configured to emit sound, and the indicator produced by the messaging module comprises an audible indicator emitted by the interface device107.

The operator125can use the interface device107to receive information from the compacting member monitoring program105and to provide inputs to the controller104through the interface device107. The interface device107can be configured to provide the operator125with an operable interface to other systems of the compacting machine10.

The interface device107is coupled to the controller104to receive material-sticking data therefrom. In the illustrated embodiment, the interface device107is adapted to provide information in the form of visibly-displayed indicia. In embodiments, an audio device can be associated with the interface device107to provide audibly-perceptible information through a speaker. In embodiments, the compacting member monitoring program105can be configured such that the interface device107can display a graphical user interface generated by the compacting member monitoring program105and any suitable message compiled by the messaging module regarding the occurrence of a material-sticking condition of the compacting machine10.

The interface device107can include hardware and/or software components configured to allow the operator125to access information stored in the data storage device108. For example, the graphical user interface of the compacting member monitoring program105can include a data access interface configured to allow the operator125to access, configure, store, and/or download information to an off-board system or a receiver175, such as a computer, a personal digital assistant (PDA) or smart phone using a particularly-configured mobile application (“app”), a diagnostic tool, or any other type of data device. Moreover, the interface device107can be configured to allow the operator125to access and/or modify information, such as operational parameters, operating ranges, material-sticking condition event information for a variety of locations, and/or threshold levels associated with one or more material-sticking condition configurations, stored in the data storage device108.

In the illustrated embodiment, the interface device107is mounted within the operator compartment18(seeFIG. 1). In other embodiments, the interface device107can be located elsewhere, including a location remote from the compacting machine10.

Referring toFIG. 3, the illustrated embodiment of the interface device107comprises a liquid crystal display device150. In embodiments, the liquid crystal display device150can be mounted within a panel configuration in the operator compartment18or as a stand-alone device.

In embodiments, the interface device107can comprise another type of display, a console, a keyboard, push buttons, voice recognition devices, a laptop computer, speakers, and/or other interfaces, as will be appreciated by one skilled in the art. In embodiments, the interface device107can include any type of display device that presents information.

The illustrated liquid crystal display device150includes a display screen in the form of a touch screen155adapted to display information to the operator125of the compacting machine10and to receive instructions from the operator125for transmission to the controller104via finger touch input. The touch screen155can include a message display section adapted to selectively display a plurality of pop-up messages, such as those generated by the controller104using the compacting member monitoring program105. In other embodiments, the interface device107can include a different type of display screen, as will be appreciated by one skilled in the art.

The data storage device108is in operable communication with the controller104. The data storage device108can generally include any type of system for storing data in non-volatile storage. This includes, but is not limited to, systems based upon: magnetic, optical, and magneto-optical storage devices, as well as storage devices based on flash memory and/or battery-backed up memory. The data storage device108can include a removable memory module, or a fixed memory module, or a combination of removable and fixed memory modules. In embodiments, the data storage device108can include an on-board memory device and/or a remotely-located off-board memory device that can be placed in communication with the controller104via the communication device110.

The data storage device108can include one or more memory devices that store, organize, sort, filter, and/or arrange data used by the compacting member monitoring program105. For example, in embodiments, the data storage device108includes a database of material-sticking condition data for a worksite. In embodiments, the material-sticking condition data can include any information generated by the compacting member monitoring program105.

In embodiments, the data storage device108can be adapted to store message data for use by the messaging module of the compacting member monitoring program105in generating an indicator (such as in the form of at least one pop-up message). In embodiments, the data storage device108stores message data for a plurality of pop-up messages relating to material-sticking condition events.

In response to a command received from the interface device107, for example, the controller104can be used to display material-sticking condition data stored in the data storage device108through the graphical user interface of the compacting member monitoring program105via the interface device107. The information in the data storage device108can be selectively transmitted to the operator125via the interface device107and/or to the off-board receiver175via the communication device110.

The communication device110is in operable arrangement with the controller104to communicatively transmit information from the compacting member monitoring system25to a suitable, off-board device, such as the receiver175, for example. In embodiments, the communication device110is configured to transmit a material-sticking condition event signal from the controller104to the receiver175, which is unsupported by the frame12of the compacting machine10.

In embodiments, the communication device110can comprise any suitable equipment that facilitates the transmission of data between the compacting member monitoring system25and an off board device, such as the receiver175or a central computer system located remotely from the compacting machine10. In embodiments, the communication device110can include hardware and/or software configured to send and/or receive data through a wireless communication link180across a wireless networking platform such as, for example, a satellite communication system. Alternatively and/or additionally, the communication device110can include one or more broadband communication platforms configured to communicatively couple the compacting member monitoring system25to an off board system, such as, for example, cellular, Bluetooth, microwave, point-to-point wireless, point-to-multipoint wireless, multipoint-to-multipoint wireless, or any other appropriate communication platform for networking a number of components.

In embodiments, the communication device110can be configured to establish a direct data link with an external data storage device. In embodiments, the external data storage device can be a part of the central computer system or in the form of a portable device for downloading the data from the compacting member monitoring system25and uploading the information to the central computer system, for example. In embodiments, the communication device110can include a wired network, such as, for example, Ethernet, fiber optic, waveguide, or any other type of wired communication network.

In embodiments, the communication device110uses a cellular network to transmit hazard event data to the receiver175which is in the form of a smart phone having a mobile app loaded thereon to visibly display the material-sticking condition data. In embodiments, the mobile app can be used to display the graphical user interface of the compacting member monitoring system25on the smart phone175to allow a user to input commands to the compacting member monitoring system25remotely using the smart phone175and to receive output therethrough in a manner similar to that using the interface device107.

In embodiments, the central computer system/receiver175is configured to perform additional material-sticking condition analysis remotely from the compacting machine10and to transmit the additional material-sticking condition data back to the compacting member monitoring system25for further use in operating the compacting machine10.

In embodiments, an embodiment of a compacting machine including a compacting member monitoring system constructed according to principles of the present disclosure can be used to carry out a method of monitoring a compacting member of a compacting machine in accordance with principles of the present disclosure to determine whether the compacting member has a piece of the material being compacted adhered thereto. Referring toFIG. 4, steps of an embodiment of a method300of monitoring a compacting member of a compacting machine following principles of the present disclosure are shown.

The method300of monitoring a compacting member of a compacting machine for compacting a material is used with a compacting member that includes a ground-engaging surface. A parameter of the ground-engaging surface is sensed with a sensor to generate a surface parameter signal indicative of the parameter of the ground-engaging surface sensed by the sensor (step310). The surface parameter signal is transmitted to a controller (step320). The controller is used to execute a compacting member monitoring program stored upon a non-transitory computer-readable medium to determine whether a piece of the material is adhered to the ground-engaging surface using the surface parameter signal (step330). In response to the compacting member monitoring program determining the piece of the material is adhered to the ground-engaging surface, the controller is used to execute the compacting member monitoring program to provide, through an interface device, an indicator that the piece of the material adhered to the ground-engaging surface (step340). In embodiments, the compacting member monitoring program determines whether a piece of the material is adhered to the ground-engaging surface using the surface parameter signal using any suitable detection technique, including any of those discussed above. In embodiments, the indicator comprises at least one of an audible indicator emitted by the interface device and a visual indicator displayed by the interface device via a graphical user interface.

In embodiments, a method following principles of the present disclosure further includes in response to the compacting member monitoring program determining the piece of the material is adhered to the ground-engaging surface, performing an autonomous control operation to change an operating parameter of the compacting machine.

In embodiments, a method of monitoring a compacting member of a compacting machine in accordance with principles of the present disclosure further includes, in response to the compacting member monitoring program determining the piece of the material is adhered to the ground-engaging surface, operating a clearing device to remove the material adhered to the ground-engaging surface.

In embodiments, the machine includes an operator compartment, and the interface device is mounted within the operator compartment. In embodiments, the method further includes displaying in the interface device, through the graphical user interface, a message containing loading condition data.

INDUSTRIAL APPLICABILITY

The industrial applicability of the embodiments of a compacting machine, a compacting member monitoring system, and a method of monitoring a compacting member of a compacting machine described herein will be readily appreciated from the foregoing discussion. The described principles are applicable to a variety of compacting machines and worksites. Using principles of the present disclosure, the occurrence of material sticking conditions upon one or more compacting members of a compacting machine performing a material compacting operation can be determined based upon the monitoring of a parameter of the ground-engaging surface of the compacting member(s) of the compacting machine when in service.

Furthermore, embodiments of a compacting member monitoring system constructed according to principles of the present disclosure can be used to identify a situation where the material being compacted becomes adhered to the ground-engaging surface of a compacting member of the compacting machine and, in response, perform a preventative measure to inhibit the negative impact produced by the material adhered to the ground-engaging surface and/or to perform a corrective measure to remove the piece of material stuck to the affected compacting member. In embodiments, the compacting member monitoring system can produce an alert indicator via an interface device for the operator of the compacting machine when it is determined that a piece of material has become adhered to the compacting member. In embodiments, the compacting machine can include an autonomous control module to automatically perform an asphalt-sticking control operation in response to the compacting member monitoring system determining a piece of material has become adhered to the compacting member.

It will be appreciated that the foregoing description provides examples of the disclosed system and technique. However, it is contemplated that other implementations of the disclosure may differ in detail from the foregoing examples. All references to the disclosure or examples thereof are intended to reference the particular example being discussed at that point and are not intended to imply any limitation as to the scope of the disclosure more generally. All language of distinction and disparagement with respect to certain features is intended to indicate a lack of preference for the features of interest, but not to exclude such from the scope of the disclosure entirely unless otherwise specifically indicated.