Concrete mixer vehicles are configured to receive, mix, and transport wet concrete or a combination of ingredients that when mixed form wet concrete to a job site. To prevent the concrete from setting, concrete mixing vehicles include a rotatable mixing drum that continually mixes the concrete disposed therein. The drum rotation speed may be passively controlled, potentially leading to arriving at a job site with the concrete having undesirable properties.
One embodiment relates to a concrete mixer vehicle. The concrete mixer vehicle includes a chassis, a drum assembly coupled to the chassis, a mixture sensor, and a control system. The drum assembly includes a drum and a drive system coupled to the drum. The drum is configured to receive drum contents including ingredients of a concrete mixture. The drive system is configured to rotate the drum to agitate the drum contents. The mixture sensor is positioned within the drum to engage with the drum contents to facilitate acquiring drum contents data indicative of a property of the drum contents. The control system is configured to control the drive system to rotate the drum at a first, unmixed speed following receipt of the ingredients of the concrete mixture by the drum at a loading location; acquire the drum contents data from the mixture sensor and monitor the property of the drum contents as the drum rotates; and control the drive system to rotate the drum at a second, mixed speed in response to determining that the property of the drum contents indicates that the ingredients have been sufficiently mixed.
Another embodiment relates to a drum system. The drum system includes a drum assembly, a mixture sensor, and a control system. The drum assembly includes a drum and a drive system coupled to the drum. The drum is configured to receive drum contents including ingredients of a concrete mixture. The drive system is configured to rotate the drum to agitate the drum contents. The mixture sensor is positioned within the drum to engage with the drum contents to facilitate acquiring drum contents data indicative of a property of the drum contents. The control system is configured to control the drive system to rotate the drum at a first, unmixed speed following receipt of the ingredients of the concrete mixture by the drum; acquire the drum contents data from the mixture sensor and monitor the property of the drum contents as the drum rotates; and control the drive system to rotate the drum at a second, mixed speed in response to determining that the property of the drum contents indicates that the ingredients have been sufficiently mixed.
Still another embodiment relates to a drum control system. The drum control system includes a mixture sensor and a controller. The mixture sensor is configured to be positioned within a drum to engage with drum contents to facilitate acquiring drum contents data indicative of a property of the drum contents. The controller is configured to control a drive system to rotate the drum at a first, unmixed speed following receipt of the drum contents by the drum where the drum contents including ingredients of a concrete mixture; acquire the drum contents data from the mixture sensor and monitor the property of the drum contents as the drum rotates; and control the drive system to rotate the drum at a second, mixed speed in response to determining that the property of the drum contents indicates that the ingredients have been sufficiently mixed.
The invention is capable of other embodiments and of being carried out in various ways. Alternative exemplary embodiments relate to other features and combinations of features as may be recited in the claims.
The disclosure will become more fully understood from the following detailed description, taken in conjunction with the accompanying figures, wherein like reference numerals refer to like elements, in which:
Before turning to the figures, which illustrate the exemplary embodiments in detail, it should be understood that the present application is not limited to the details or methodology set forth in the description or illustrated in the figures. It should also be understood that the terminology is for the purpose of description only and should not be regarded as limiting.
According to an exemplary embodiment, a concrete mixing vehicle includes a drum assembly having a mixing drum, a drive system, and a drum control system. The drum control system may be configured to control the drive system to rotate the mixing drum. Traditional drum control systems may be configured to passively control the rotation and rotational speed of the mixing drum (e.g., at a preset speed, at a preset speed ratio that varies with the engine speed, etc.).
According to an exemplary embodiment, the drum control system of the present disclosure is configured to actively control the rotation and/or rotational speed of the mixing drum to provide and/or maintain target properties for the concrete (e.g., a desired consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, etc.) during transportation and/or upon arrival at the job site. By way of example, the drum control system may be configured to monitor the properties of the concrete within the mixing drum (e.g., with a sensor, etc.) and adaptably adjust the rotational speed of the mixing drum to provide concrete having desired or target properties (e.g., in response to the current properties of the concrete approaching and/or reaching the target properties, etc.). The drum control system may monitor the concrete property (e.g., slump, etc.), adjust (e.g., increase, etc.) the drum speed in response to an indication that the property is at, approaching, or above a target level (e.g., a slump at, approaching, or above a target slump level, etc.), and adjust (e.g., decrease, etc.) the drum speed in response to an indication that the property is at, approaching, or below the target level. By way of example, the system may be configured to increase the drum speed in response to an indication that the concrete within the drum is at a six (6) slump and decrease the drum speed in response to an indication that the concrete within the drum is at a four (4) slump. The system may be configured to further decrease drum speed, add water or another substance, etc. to keep the concrete within the drum at the target level. In some embodiments, the drum control system is configured to additionally or alternatively control the rotation and/or rotational speed of the mixing drum based on actual and/or anticipated driving behavior and/or road parameters (e.g., acceleration, deceleration, road grades, speed limit changes, stop signs, traffic lights, road curvature, traffic information, traffic patterns, etc.; to prevent concrete from spilling out of the mixing drum; to maintain a desired speed of the mixing drum as the engine speed varies; etc.).
According to an exemplary embodiment, the drum control system of the present disclosure is configured to additionally or alternatively predict a property of a mixture within the mixing drum at delivery based on various data. The various data may include delivery data (e.g., a delivery location, a delivery time, a delivery route, etc.), initial properties of the mixture (e.g., a weight of the mixture, a volume of the mixture, a constituent makeup of the mixture, an initial slump, an initial viscosity, mixed, unmixed, mixed status, etc.), target properties for the mixture (e.g., a desired consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, etc.), environment data (e.g., an ambient temperature, a relative humidity, wind speed, elevation, precipitation characteristics, road attributes, traffic information/patterns, etc.), mixture data (e.g., current properties of the mixture, etc.), and/or GPS data (e.g., unscheduled stops, road attributes, traffic information/patterns, travel time updates, etc.). The drum control system may be further configured to selectively and/or adaptively control a pump of the drive system (e.g., a throttling element thereof, etc.) to adjust a speed of the mixing drum and provide a target drum speed for the mixing drum (e.g., to achieve a target property for the mixture, based on the predicted delivery properties, etc.).
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In one embodiment, the throttling element of the pump 122 is movable between a stroked position (e.g., a maximum stroke position, a partially stroked position, etc.) and a destroked position (e.g., a minimum stoke position, a partially destroked position, etc.). According to an exemplary embodiment, an actuator is coupled to the throttling element of the pump 122. The actuator may be positioned to move the throttling element between the stroked position and the destroked position. The drum control system 150 may be configured to generate a first command signal and a second command signal. The first command signal may engage the actuator to move the throttling element of the pump 122 into the destroked position, thereby decreasing the pump stroke. The second command signal may engage the actuator to move the throttling element of the pump 122 into the stroked position, thereby increasing the pump stroke.
According to another exemplary embodiment, a valve is positioned to facilitate movement of the throttling element between the stroked position and the destroked position. In one embodiment, the valve includes a resilient member (e.g., a spring, etc.) configured to bias the throttling element in the destroked position (e.g., by biasing movable elements of the valve into positions where a hydraulic circuit actuates the throttling element into the destroked positions, etc.). Pressure from fluid flowing through the pump 122 may overcome the resilient member to actuate the throttling element into the stroked position (e.g., by actuating movable elements of the valve into positions where a hydraulic circuit actuates the throttling element into the stroked position, etc.).
In other embodiments, the drum actuator 126 is or includes an internal combustion engine. In such embodiments, the fluid reservoir 124 may be configured to store liquid and/or gaseous fuel (e.g., gasoline, diesel, propane, natural gas, hydrogen, etc.), and the pump 122 may be configured as a fuel pump. In still other embodiments, the drum actuator 126 is or includes an electric motor. In such embodiments, the fluid reservoir 124 may be an energy storage device (e.g., a battery, a capacitor, etc.) configured to store and provide chemical and/or electrical energy. The drum drive system 120 may not include the pump 122 in such embodiments. According to an exemplary embodiment, the drum actuator 126 is mounted to the concrete mixing truck 10 at the same angle as the axis 104 of the mixing drum 102 (e.g., such that the output of drum actuator 126 rotates about an axis parallel to the axis 104, etc.).
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In one embodiment, energy flows along a second power path defined from the engine 16, through the transmission 18 and the power takeoff unit 32, and into the pump 122 when the clutch 34 is engaged. When the clutch 34 is disengaged, energy flows from the engine 16, through the transmission 18, and into the power takeoff unit 32. The clutch 34 selectively couples the pump 122 to the engine 16, according to an exemplary embodiment. In one embodiment, energy along the first flow path is used to drive the wheels 22 of the concrete mixing truck 10, and energy along the second flow path is used to operate the drum drive system 120 (e.g., power the pump 122 to drive the drum actuator 126 to thereby rotate the mixing drum 102, etc.). Energy may flow along the first flow path during normal operation of the concrete mixing truck 10 and selectively flow along the second flow path. By way of example, the clutch 34 may be engaged such that energy flows along the second flow path when the pump 122 is used to drive the mixing drum 102. When the pump 122 is not used to drive the mixing drum 102 (e.g., when the mixing drum 102 is empty, etc.), the clutch 34 may be selectively disengaged, thereby conserving energy.
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In some embodiments, the sensors 140 include one or more drive system sensors. The drive system sensors may be variously positioned on, around, and/or within one or more components of the drum drive system 120 to acquire drive system data. The drive system data may be indicative of one or more operating characteristics of the drum drive system 120. The operating characteristic may include a speed of the mixing drum 102, a direction of rotation of the mixing drum 102, a pressure associated with the pump 122 (e.g., a hydraulic pressure, an inlet pressure, an outlet pressure, etc.), another hydraulic system pressure, and/or other operating characteristics of the drum drive system 120.
In some embodiments, the sensor 140 includes one or more environment sensors. The environment sensors may be variously positioned on, around, and/or within the concrete mixing truck 10 to acquire environment data. The environment data may be indicative of an environmental characteristic (e.g., external to the mixing drum 102, etc.). The environmental characteristics may include an ambient temperature, a relative humidity, wind speed, elevation, precipitation characteristics (e.g., rain, snow, fog, etc.), road attributes, traffic information/patterns, etc. The environment sensors may include a temperature sensor, a barometer or other pressure sensor, a humidity sensor, a pitot tube, an altimeter, an accelerometer, a camera, a proximity sensor, and/or other sensors configured to acquire information about the environment external to the mixing drum 102.
By way of example, during operation, the mixing drum 102 may be loaded with a concrete mixture through the hopper 110. The drum drive system 120 may be operated to rotate the mixing drum 102 in a first direction to mix and agitate the concrete mixture contained in the mixing drum 102 with the mixing element. Water and/or chemicals may be pumped into the mixing drum 102 through the injection port 130 to provide a desired property of the concrete mixture and/or to prevent the concrete mixture from setting within the mixing drum 102. The concrete mixing truck 10 may transport the mixture to a job site (e.g., a construction site, etc.). During such transportation, the drum control system 150 may be configured to selectively and/or adaptively control the drum drive system 120 (e.g., the pump 122 to increase or decrease a speed of the drum actuator 126, etc.) to provide a target drum speed. The drum control system 150 may be configured to control the drum drive system 120 based on mixture data acquired by the sensors 140 such that the concrete mixture within the mixing drum 102 has one or more desired or target properties (e.g., a desired consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, etc.) during transportation and/or upon arrival at the job site. Upon arrival at the job site with the concrete mixture having the one or more desired properties, the drum drive system 120 may be operated to rotate the mixing drum 102 in an opposing second direction. The rotation of the mixing element in the opposing second direction may cause the mixing element to carry the concrete mixture out of the mixing drum 102. The chute 112 of the drum assembly 100 may be used to dispense and guide the concrete mixture away from the frame 12 of the concrete mixing truck 10 to the concrete mixture's destination (e.g., a concrete form, a wheelbarrow, a concrete pump machine, etc.).
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The drum assembly controller 160 may be implemented as a general-purpose processor, an application specific integrated circuit (ASIC), one or more field programmable gate arrays (FPGAs), a digital-signal-processor (DSP), circuits containing one or more processing components, circuitry for supporting a microprocessor, a group of processing components, or other suitable electronic processing components. According to the exemplary embodiment shown in
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The operator input may be used by an operator to provide commands and/or information (e.g., initial properties of the mixture, target properties for the mixture, delivery data for the mixture, etc.) to at least one of the clutch 34, the drum drive system 120, the injection port 130, the I/O module 170, the GPS module 172, the concrete property module 174, and the GPS 190. The operator input may include one or more buttons, knobs, touchscreens, switches, levers, joysticks, pedals, a steering wheel, and/or handles. The operator input may facilitate manual control of some or all aspects of the operation of the concrete mixing truck 10. It should be understood that any type of display or input controls may be implemented with the systems and methods described herein.
The I/O module 170 may be configured to receive information regarding initial properties of the mixture and/or target properties for the mixture from the user interface 188, from a customer device, and/or from a device of the concrete plant. The initial properties of the mixture may include a weight of the mixture, a volume of the mixture (e.g., yards of concrete, etc.), a constituent makeup of the mixture (e.g., amount of cementitious material, aggregate, sand, water content, air entrainers, water reducers, set retarders, set accelerators, superplasticizers, corrosion inhibitors, coloring, calcium chloride, minerals, etc.), an initial slump, an initial viscosity, and/or any other properties known about the mixture prior to and/or upon entry thereof into the mixing drum 102. The target properties for the mixture may include a desired consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, and/or still other properties. As shown in
The I/O module 170 may be configured to receive a target drum life for the mixing drum 102 (e.g., a number of yards and mix of concrete the mixing drum 102 is designed to receive throughout an operating lifetime thereof, a number of yards of concrete the mixing drum 102 is designed to receive throughout an operating lifetime thereof without regard for the particular mix of the concrete, an operational life of the mixing element within the mixing drum 102, a relationship between mixing element degradation and operational time, etc.) and/or a type of the mixing drum 102 (e.g., capacity, shape, manufacturer, a front discharge mixing drum, a rear discharge mixing drum, a thickness of a sidewall or other portion of the mixing drum 102, type and/or identity of materials the mixing drum 102 is manufactured from, dimensional characteristics, etc.) from the user interface 188 and/or from a device of the concrete plant. In some embodiments, at least one of the target drum life and the type of the mixing drum 102 are predefined within the drum assembly controller 160 (e.g., the memory 166, the drive module 182, etc.).
The I/O module 170 may be configured receive delivery data regarding a delivery time, a delivery location (e.g., address of a job site, etc.), and/or a delivery route (e.g., based on road load parameters, etc.) for the mixture from the user interface 188. As shown in
The GPS data may additionally or alternatively include road attributes at and/or ahead of a current location of the concrete mixing truck 10. The road attributes may include road grade, road curvature, speed limits, stop sign locations, traffic light locations, road classifications (e.g., arterial, collector, local, etc.), on/off ramp locations, altitude, etc. The road attributes may be utilized and/or monitored to detect changes therein (e.g., changes in elevation, etc.). In some embodiments, the GPS module 172 is configured to record road attributes (e.g., road grades, stop light locations, stop sign locations, altitude, etc.) without or in addition to receiving the GPS data from the GPS 190. In such embodiments, the GPS module 172 may be configured to learn as the concrete mixing truck 10 is driving along various routes such that the road attributes are known when the same route is encountered or will be encountered in the future. The GPS data may additionally or alternatively provide information regarding traffic information and/or traffic patterns at and/or ahead of the concrete mixing truck 10. The concrete mixing truck 10 may include various sensors (e.g., accelerometers, gyroscopes, inclinometers, cameras, barometric or other pressure sensors, altimeters, environment sensors, etc.) variously positioned on, around, and/or within the concrete mixing truck 10 to acquire at least some of the road attributes. The sensors may also be configured to provide information regarding traffic information and/or traffic patterns (e.g., a vehicle slowing down, obstacles in the road, etc.). As shown in
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The sensor module 176 may be configured to analyze the mixture data to determine various properties of the mixture (e.g., slump, mix status, etc.). By way of example, the sensor module 176 may employ a fluids and/or physics model configured to analyze various measurable characteristics of the mixture (e.g., velocity, acceleration, viscosity, air contents, surface tension, etc.) to estimate the slump of the mixture (e.g., slump may not be directly measured, etc.). For example, the slump may be determined based on the flow characteristics of the mixture within the mixing drum 102 as the mixing drum 102 rotates.
According to an exemplary embodiment, the concrete property module 174 is configured to receive, interpret, and/or record at least one of the engine data (e.g., engine speed, etc.), the initial mixture properties (e.g., a weight of the mixture, a volume of the mixture, a constituent makeup of the mixture, etc.), the GPS data (e.g., road attributes, traffic information, etc.), the mixture data (e.g., current properties of the mixture, etc.), and/or the environment data to predict delivery properties for the mixture within the mixing drum 102. The concrete property module 174 may be further configured to selectively and/or adaptively control the drive speed of the drum drive system 120 to achieve the target properties (e.g., a desired consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, etc.) for the mixture during transport and/or upon arrival at the destination and/or maintain the target properties if achieved prior to arriving at the destination based on the various data.
The prediction module 178 may be configured to predict delivery properties for the mixture based on the initial properties, the target properties, the delivery data, the environment data, the GPS data, the drive system data, and/or the mixture data. The prediction module 178 may be configured to additionally or alternatively predict the delivery properties for the mixture based on a current state of the mixing drum 102 or components thereof. The prediction module 178 may be configured to additionally or alternatively predict the delivery properties for the mixture based on a current state of the mixing drum 102 or components thereof relative to one or more associated target life values (e.g., where the mixing drum 102 is at in its life cycle, where mixing elements or other components of the mixing drum 102 are at in their life cycle, mint, like-new, average, poor, degraded, etc.). The prediction module 178 may be configured to additionally or alternatively predict the delivery properties for the mixture based on the type of the mixing drum 102. By way of example, the prediction module 178 may be configured to determine the current state (e.g., the amount of degradation, etc.) of the mixing drum 102 and/or components thereof (e.g., the mixing element, the fin, etc.). The prediction module 178 may determine the current state (e.g., using a degradation profile, etc.) based on a time of use, an amount of mixture mixed during the time of use (e.g., yards of mixture, etc.), an average rotational speed of the mixing drum 102, a rotational speed profile of the mixing drum 102 (e.g., a history of speed over time, etc.), and/or still other operational characteristics of the mixing drum 102. According to an exemplary embodiment, the current state of the mixing drum 102 affects the properties of the mixture.
In some embodiments, the prediction module 178 is configured to provide an indication of the predicted delivery properties for the mixture to the I/O module 170 such that the indication may be displayed to the operator on the user interface 188. In some embodiments, the indication is sent to a plant device at a concrete plant and/or a device of a customer. The prediction module 178 may be configured to continuously and/or periodically update the prediction during transit based on various adjustments performed by the mixing drum 102 and/or other devices, and/or based on external characteristics. By way of example, the prediction may be updated as the rotational speed of the mixing drum 102 is adaptively controlled. By way of another example, the prediction may be updated as water and/or chemicals are injected into the mixing drum 102. By way of another example, the prediction may be updated as the current properties of the mixture change. By way of still another example, the prediction may be updated as the environmental characteristics (e.g., ambient temperature, altitude, humidity, etc.) change. By way of yet another example, the prediction may be updated as the travel time to the destination changes (e.g., due to accidents, traffic jams, road conditions, detours, etc.).
The recording module 180 may be configured to record the delivery data, the initial properties, the target properties, the predicted delivery properties, the adjustments, the environment data, the mixture data, the GPS data, and/or actual delivery data (e.g., measured by the operator and/or quality personnel and/or the mixture sensor at delivery, etc.) to facilitate generating and/or updating a prediction algorithm stored within and operated by the prediction module 178. Such generation and/or updating of the prediction algorithm may facilitate providing more accurate prediction and/or control of a mixture's properties during future deliveries. Additionally, once a sufficient amount of data has been compiled, the prediction algorithm may facilitate the elimination of the mixture sensor from the mixing drum 102. By way of example, the initial properties of the mixture may be determined with the sensor 140, provide by an operator of the plant, determined with sensors at the plant and provided to the drum assembly controller 160, and/or determined using look-up tables (e.g., based on the compiled data, etc.) with the drum assembly controller 160 and/or thereafter provided to the drum assembly controller 160. The predicted delivery properties and/or the mixture data may then be determined by the prediction module 178 using the prediction algorithm based on the initial properties, various adjustments performed during transit, the environmental data, and/or the GPS data (e.g., using the previously recorded data, look-up tables, etc.) without measurement thereof with a sensor. Such removal of the mixture sensor may reduce the cost to manufacture and operate the concrete mixing truck 10.
In some embodiments, the prediction module 178 and/or the recording module 180 are additionally or alternatively remotely positioned relative to the drum assembly controller 160 and/or the concrete mixing truck 10 (e.g., in a remote monitoring and/or command system, etc.). By way of example, the prediction module 178 and/or the recording module 180 may be remotely positioned on a server system and operate as a cloud-based system (e.g., a remote monitoring and/or command system, etc.) for the concrete mixing truck 10. As such, the data recordation, analysis, and/or determinations made by the drum assembly controller 160 described herein may be additionally or alternatively performed remotely from the concrete mixing truck 10 and then communicated to the drum assembly controller 160 (e.g., the drive module 182, the injection module 184, etc.) for implementation.
As an example, the drum assembly controller 160 may include a communications interface 186 that facilitates long-range wireless communication with a remote monitoring and/or command system 192. The remote monitoring and/or command system 192 may include a processing circuit having a processor and a memory, and a communications interface (e.g., like the processing circuit 162, the communications interface 186, etc. of the drum assembly controller 160). The communications interface of the remote monitoring and/or command system 192 may be configured to receive various information and/or data (e.g., the initial properties, the target properties, the environment data, the GPS data, the mixture data, the en route data, information regarding adjustments made by the drum assembly 100, the drive system data, etc.) from the drum assembly controller 160 and/or other external systems (e.g., a weather service, a topography service, a GPS service, a user input device, a batching system, etc.). The remote monitoring and/or command system 192 may record and analyze the various information and data and perform the functions of the prediction module 178 and/or the recording module 180 described herein. The remote monitoring and/or command system 192 may further be configured to provide commands to the drum assembly controller 160 for the drive module 182 and/or the injection module 184 to implement (e.g., speed commands, injection commands, etc.). Therefore, any of the functions performed by the drum assembly controller 160 described herein may be remotely controlled by the remote monitoring and/or command system 192.
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The drive module 182 may be configured to transmit the speed command to the drum drive system 120 (e.g., to the pump 122, while the clutch 34 is engaged, etc.) to selectively and/or adaptively control the drive speed of the mixing drum 102. In some embodiments, the drive module 182 is configured to modulate the flow from the pump 122 (e.g., by controlling the angle/position of the throttling element thereof, etc.) to control the drive speed of the drum actuator 126 based on the engine speed as indicated by the engine data. By way of example, the drive module 182 may be configured to actively control the pump 122 as the concrete mixing truck 10 is driving such that as the engine speed changes, the drive speed of the mixing drum 102 remains at a desired or target drive speed. In one example, the drive module 182 may decrease the angle of the throttling element as the engine speed increases such that the pump 122 maintains a constant output to maintain the target drive speed of the mixing drum 102. In another example, the drive module 182 may increase the angle of the throttling element as the engine speed decreases such that the pump 122 maintains a constant output to maintain the target drive speed of the mixing drum 102.
By way of another example, the drive module 182 may actively control the pump 122 in response to actual and/or anticipated accelerations and/or decelerations of the concrete mixing truck 10. In an rear-discharge vehicle example, the drive module 182 may maintain or increase the angle of the throttling element as the concrete mixing truck 10 accelerates such that the output of the pump 122 increases, thereby causing the drive speed of the mixing drum 102 to increase. Such an increase in the drive speed of the mixing drum 102 may cause the mixing element of the mixing drum 102 to drive the mixture contained therein forward, preventing the mixture from spilling out of the rear of the mixing drum 102. In a front-discharge vehicle example, the drive module 182 may increase the angle of the throttling element as the concrete mixing truck 10 decelerates such that the output of the pump 122 increases, thereby causing the drive speed of the mixing drum 102 to maintain constant or increase. Such an increase in the drive speed of the mixing drum 102 may cause the mixing element of the mixing drum 102 to drive the mixture contained therein rearward, preventing the mixture from spilling out of the front of the mixing drum 102.
In some embodiments, the drive module 182 is configured to modulate the flow out the pump 122 to control the drive speed of the drum actuator 126 based on the GPS data. By way of example, the drive module 182 may actively control the pump 122 as the concrete mixing truck 10 encounters and/or anticipates that the concrete mixing truck 10 will encounter various different road parameters. In one example, the GPS data may indicate a road grade increase ahead (e.g., a hill, etc.). In an rear-discharge vehicle example, the drive module 182 may increase the angle of the throttling element as the concrete mixing truck 10 approaches a hill such that the output of the pump 122 increases, thereby causing the drive speed of the mixing drum 102 to increase. Such an increase in the drive speed of the mixing drum 102 may cause the mixing element of the mixing drum 102 to drive the mixture contained therein forward, preventing the mixture from spilling out of the rear of the mixing drum 102.
In another example, the GPS data may indicate a stop light, a stop sign, a slowing vehicle, and/or other obstacles are ahead of the concrete mixing truck 10. In a front-discharge vehicle example, the drive module 182 may increase the angle of the throttling element in preparation for the deceleration of the concrete mixing truck 10 such that the output of the pump 122 increases, thereby causing the drive speed of the mixing drum 102 to increase. Such an increase in the drive speed of the mixing drum 102 may cause the mixing element of the mixing drum 102 to drive the mixture contained therein rearward, preventing the mixture from spilling out of the front of the mixing drum 102. In a rear-discharge vehicle example, the drive module 182 may increase the angle of the throttling element in preparation for the acceleration of the concrete mixing truck 10 after slowing down and/or stopping such that the output of the pump 122 increases, thereby causing the drive speed of the mixing drum 102 to increase. Such an increase in the drive speed of the mixing drum 102 may cause the mixing element of the mixing drum 102 to drive the mixture contained therein forward, preventing the mixture from spilling out of the rear of the mixing drum 102.
In yet another example, the GPS data may indicate that the concrete mixing truck 10 is (i) approaching and/or traveling on an off ramp and/or (ii) approaching and/or traveling on a corner or curvature in the road. The drive module 182 may decrease the angle of the throttling element in response to the indication such that the output of the pump 122 decreases, thereby causing the drive speed of the mixing drum 102 to decrease. In other embodiments, the drive module 182 otherwise decreases the drive speed of the mixing drum 102 in response to the indication. Such a decrease in the drive speed of the mixing drum 102 may further stabilize the concrete mixing truck 10 while cornering and/or exiting from highways (e.g., taking an off ramp, etc.).
In some embodiments, the drive module 182 is configured to modulate the flow from the pump 122 to selectively and/or adaptively control the drive speed of the drum actuator 126 based on the initial properties of the mixture, the predicted delivery properties (e.g., determined based on the initial properties, the delivery data, the environment data, the mixture data, the GPS data, the engine data, the target properties, the drum life of the mixing drum 102, the type of the mixing drum 102, etc.), and/or the mixture data indicating the current properties to provide the target properties (e.g., a desired consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, etc.). In some embodiments, the drive module 182 is additionally or alternatively configured to modulate the flow from the pump 122 to selectively and/or adaptively control the drive speed of the drum actuator 126 based on the target drum life for the mixing drum 102 and/or the type of the mixing drum 102. According to an exemplary embodiment, increasing the drive speed of the drum actuator 126 increases the rotational speed of the mixing drum 102. The increase in the rotational speed of the mixing drum 102 may increase the temperature of the mixture (e.g., reducing the water content thereof, etc.), and decrease the slump while increasing the viscosity of the mixture at an increased rate (e.g., relative to a lower rotational speed, etc.). According to an exemplary embodiment, a reduced drive speed of the drum actuator 126 provides a decreased rotational speed for the mixing drum 102. The decrease in the rotational speed of the mixing drum 102 may provide a constant or decreased temperature of the mixture and (i) maintain the slump and viscosity of the mixture or (ii) decrease the slump while increasing the viscosity at a reduced rate (e.g., relative to a higher rotational speed, etc.).
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In some embodiments, the injection module 184 is configured to selectively control the valve of the injection port 130 to adaptively modulate an amount of water and/or chemicals that are injected into the mixing drum 102 before, during, and/or after transit. Such injection of water and/or chemicals may be used to supplement and/or replace adaptively controlling the drive speed of the mixing drum 102 to provide the target properties for the mixture. Such injection may be limited to a threshold amount of water and/or chemicals, and/or limited based on GPS location of the concrete mixing truck 10. By way of example, the injection module 184 may be configured to prevent an operator of the concrete mixing truck 10 and/or the drum control system 150 from introducing more than a predetermined, threshold amount of water and/or chemicals to the mixture (e.g., indicated by a concrete plant, indicated by the target properties, etc.) to inhibit saturating the mixture with liquid. By way of another example, injection module 184 may be configured to prevent an operator of the concrete mixing truck 10 and/or the drum control system 150 from introducing water and/or chemicals to the mixture based on the GPS location of the concrete mixing truck 10. For example, the injection module 184 may selectively prevent the injection of water and/or chemicals after the concrete mixing truck 10 arrives at a job site.
By way of example, the drive module 182 may be configured to selectively and/or adaptively control the drive speed of the drum actuator 126 such that the target properties for the mixture are achieved upon arrival of the concrete mixing truck 10 at the destination. As an example, the mixing drum 102 may be filled with a concrete mixture. At least some of the initial properties of the concrete mixture may be entered manually by an operator using the user interface 188 and/or at least some of the initial properties of the concrete mixture may be acquired by the sensors 140. The operator may enter target properties for the concrete mixture (e.g., customer desired properties, etc.) and/or a desired destination for the concrete mixture using the user interface 188. The concrete property module 174 may be configured to determine a target drive speed for the mixing drum 102 based on (i) the distance, travel time, and/or road parameters between the current location of the concrete mixing truck 10 and the destination (e.g., indicated by the GPS data, etc.), (ii) the initial properties of the concrete mixture (e.g., manually entered, measured, etc.), and/or (iii) the target properties for the concrete mixture upon arrival. The drive module 182 may then engage the clutch 34 using the clutch command (e.g., if the concrete mixing truck 10 includes the clutch 34, etc.) and provide the speed command to the drum drive system 120 to operate the drum actuator at the target drive speed. During transit, the concrete property module 174 may be configured to (i) periodically or continually monitor the mixture data with the sensors 140 indicating the current properties of the concrete mixture to adjust the target drive speed (e.g., to a second drive speed, etc.) if the target properties are being approached too quickly (e.g., slow down the mixing drum 102, etc.) or too slowly (e.g., speed up the mixing drum 102, etc.) and/or (ii) adjust the target drive speed (e.g., to a second drive speed, etc.) based on the engine data and/or the GPS data (e.g., during acceleration, during deceleration, when encountering hills, when encountering stop signs or stop lights, when encountering traffic, when encountering curves, when encountering on/off ramps, to keep the concrete mixture within the mixing drum 102, to further stabilize the concrete mixing truck 10, etc.). In some embodiments, the concrete property module 174 is configured to change (e.g., modify, alter, reduce, increase, etc.) the drive speed of the mixing drum 102 while measurement of the properties of the concrete mixture is being performed by the sensors 140.
By way of another example, the drive module 182 may be configured to selectively and/or adaptively control the drive speed of the drum actuator 126 to maintain the target properties for the mixture if achieved prior to the concrete mixing truck 10 arriving at the destination. As an example, the mixing drum 102 may be filed with a concrete mixture. At least some of the initial properties of the concrete mixture may be entered manually by an operator using the user interface 188 and/or at least some of the initial properties of the concrete mixture may be acquired by the sensors 140. The operator may enter target properties for the concrete mixture (e.g., customer desired properties, etc.). The concrete property module 174 may be configured to determine a target drive speed for the mixing drum 102 based on (i) the initial properties of the concrete mixture (e.g., manually entered, measured, etc.) and (ii) the target properties for the concrete mixture. The drive module 182 may then engage the clutch 34 using the clutch command (e.g., if the concrete mixing truck 10 includes the clutch 34, etc.) and provide the speed command to the drum drive system 120 to operate the drum actuator at the target drive speed. During transit, the concrete property module 174 may be configured to (i) periodically or continually monitor the mixture data with the sensors 140 indicating the current properties of the concrete mixture to adjust the target drive speed if the target properties are being approached too quickly (e.g., slow down the mixing drum 102, etc.) or too slowly (e.g., speed up the mixing drum 102, etc.) and/or (ii) adjust the target drive speed based on the engine data and/or the GPS data (e.g., during acceleration, during deceleration, when encountering hills, when encountering stop signs or stop lights, when encountering traffic, when encountering curves, when encountering on/off ramps, to keep the concrete mixture within the mixing drum 102, to further stabilize the concrete mixing truck 10, etc.). Once the target properties are reached or about to be reached, as indicated by sensor inputs, the concrete property module 174 may be configured to determine and operate the drum drive system 120 at a second target drive speed to achieve and/or maintain the target properties (e.g., to prevent overshoot, to prevent reducing the slump too much, to prevent increasing the viscosity too much, from a concrete plant, etc.).
Referring now to
At step 508, the controller is configured to determine a target drive speed for the mixing drum based on the initial properties and the target properties of the mixture. In other embodiments, the target speed is predetermined and sent to the controller from the batching system at the concrete plant. At step 510, the controller is configured to operate the mixing drum (e.g., with the drum drive system 120, etc.) at the target drive speed. At step 512, the controller is configured to monitor the current properties of the mixture using the sensor. In some embodiments, the controller is additionally or alternatively configured to estimate the current properties of the mixture (e.g., in embodiments where the concrete mixing truck 10 does not include a mixture sensor, the mixture data may be determined using a prediction algorithm based on the initial properties, various adjustments performed during transit, the environmental data, and/or the GPS data without measurement thereof with a sensor, etc.). At step 514, the controller is configured to adjust the target drive speed to a second target drive speed based on the current properties approaching and/or reaching the target properties (e.g., to prevent overshoot, etc.). In some embodiments, the controller is additionally or alternatively configured to control an amount of water injected into the mixing drum to supplement or replace adaptively controlling the drive speed of the mixing drum to provide the target properties for the mixture. Such injection may be limited to a threshold amount of water and/or limited based on the GPS location of the mixing truck.
Referring now to
At step 608, the controller is configured to receive a desired destination for the mixture (e.g., from an operator using the user interface 188, etc.). At step 610, the controller is configured to receive GPS data indicating a travel distance, a travel time, traffic information, traffic patterns, and/or road parameters (e.g., from the GPS 190, etc.) between a current location and the desired destination. At step 612, the controller is configured to determine a target drive speed for the mixing drum based on the initial properties for the mixture, the target properties of the mixture, and/or the GPS data. In other embodiments, the target speed is predetermined and sent to the controller from the batching system at the concrete plant. At step 614, the controller is configured to operate the mixing drum (e.g., with the drum drive system 120, etc.) at the target drive speed.
At step 616, the controller is configured to monitor the current properties of the mixture using the sensor. In some embodiments, the controller is additionally or alternatively configured to estimate the current properties of the mixture (e.g., in embodiments where the concrete mixing truck 10 does not include a mixture sensor, the mixture data may be determined using a prediction algorithm based on the initial properties, various adjustments performed during transit, the environmental data, and/or the GPS data without measurement thereof with a sensor, etc.). At step 618, the controller is configured to receive engine data indicating a speed and/or acceleration (or deceleration) of an engine (e.g., the engine 16, etc.) of the mixing vehicle. At step 620, the controller is configured to adjust the target drive speed to a second target drive speed based on (i) the current properties approaching and/or reaching the target properties (e.g., to prevent overshoot, etc.), (ii) the GPS data (e.g., hills, stop signs, stop lights, traffic, etc.), and/or (iii) the engine data (e.g., acceleration, deceleration, etc.). In some embodiments, the controller is additionally or alternatively configured to control an amount of water injected into the mixing drum to supplement or replace adaptively controlling the drive speed of the mixing drum to provide the target properties for the mixture. Such injection may be limited to a threshold amount of water and/or limited based on the GPS location of the mixing truck.
Referring now to
At step 702, a controller (e.g., the drum assembly controller 160, the remote monitoring and/or command system 192, etc.) is configured to receive delivery data for the mixture. The delivery data may include a delivery time, a delivery location, and/or a delivery route. In some embodiments, the controller receives at least a portion of the delivery data from a user input (e.g., using the user interface 188, etc.). The delivery data may be provided by an operator of the mixing vehicle, an employee at a concrete plant, and/or a customer and transmitted to the controller (e.g., remotely, wirelessly, via a wired connection, onboard the mixing vehicle, etc.). In some embodiments, the controller receives at least a portion of the delivery data from a GPS (e.g., the GPS 190, etc.).
At step 704, the controller is configured to receive initial properties of the mixture. The initial properties of the mixture may include a weight of the mixture, a volume of the mixture, a constituent makeup of the mixture (e.g., amount of cementitious material, aggregate, sand, water content, air entrainers, water reducers, set retarders, set accelerators, superplasticizers, corrosion inhibitors, coloring, calcium chloride, minerals, etc.), an initial slump of the mixture, an initial viscosity of the mixture, and/or any other properties known about the mixture prior to and/or upon entry into the mixing drum. In some embodiments, the controller receives at least a portion of the initial properties from a user input (e.g., using the user interface 188, etc.). The initial properties may be input by an operator of the mixing vehicle and/or an employee at a concrete plant (e.g., remotely, wirelessly, via a wired connection, onboard the mixing vehicle, etc.). In some embodiments, the controller receives at least a portion of the initial properties from a sensor (e.g., a mixture sensor positioned within the mixing drum, the sensor 140, etc.).
According to an exemplary embodiment, the controller is configured to receive environment data. The environment data may be indicative of an environmental characteristic. The environmental characteristics may include an ambient temperature, a relative humidity, wind speed, elevation, precipitation characteristics (e.g., rain, snow, fog, etc.), traffic information/patterns, road attributes, etc. In some embodiments, the controller receives at least a portion of the environment data from a user input (e.g., using the user interface 188, etc.). The environment data may be input by an operator of the mixing vehicle and/or an employee at a concrete plant (e.g., remotely, wirelessly, via a wired connection, onboard the mixing vehicle, etc.). In some embodiments, the controller receives at least a portion of the environment data from a sensor (e.g., a temperature sensor, a barometer or other pressure sensor, a humidity sensor, a pitot tube, an altimeter, an accelerometer, a camera, a proximity sensor, a sensor positioned on the mixing vehicle, the sensor 140, etc.). In some embodiments, the controller receives at least a portion of the environment data from an internet based service (e.g., a weather and/or topography service that is accessed by and/or provided to the controller and based on current location of the mixing vehicle, etc.).
At step 706, the controller is configured to receive target properties for the mixture. The target properties for the mixture may include a consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, and/or still other properties desired for the mixture. According to an exemplary embodiment, the controller receives the target properties from a user input (e.g., using the user interface 188, etc.). The target properties may be provided by an operator of the mixing vehicle, an employee at a concrete plant, and/or a customer (e.g., remotely, wirelessly, via a wired connection, onboard the mixing vehicle, etc.). In some embodiments, at least a portion of the initial properties and/or target properties are predefined within batching software (e.g., a standard initial property in batching software associated with the concrete plant, a standard target property in batching software associated with the concrete plant, software associated with the memory 166 and/or the concrete property module 174 of the drum assembly controller 160, etc.). In some embodiments, the controller is configured to determine and operate the mixing drum (e.g., with the drum drive system 120, etc.) at an initial drive speed based on the initial properties of the mixture, the delivery data, the environment data, and/or the target properties for the mixture. In other embodiments, the initial drive speed is predetermined and sent to the controller from the batching system at the concrete plant. In some embodiments, the controller is configured to additionally or alternatively determine and operate the mixing drum at the initial drive speed based on a target drum life for the mixing drum (e.g., a number of yards and mix of concrete the mixing drum is designed to receive throughout an operating lifetime thereof, a number of yards of concrete the mixing drum is designed to receive throughout an operating lifetime thereof without regard for the particular mix of the concrete, etc.) and/or a type of the mixing drum (e.g., capacity, shape, manufacturer, a front discharge mixing drum, a rear discharge mixing drum, a thickness of a sidewall or other portion of the mixing drum, type and/or identity of materials the mixing drum is manufactured from, dimensional characteristics, etc.).
At step 708, the controller is configured to predict delivery properties for the mixture (i.e., predicted properties for the mixture upon arrival at the destination) based on the delivery data, the initial properties of the mixture, and/or the environmental data. In some embodiments, the controller is configured to additionally or alternatively predict the delivery properties for the mixture based on a target drum life for the mixing drum, a target life of one or more mixing drum components, a current state of the mixing drum (e.g., relative to the target drum life for the mixing drum, etc.), a current state of one or more mixing drum components (e.g., relative to the target life for the one or more mixing drum components, etc.), and/or the type of the mixing drum. At step 710, the controller is configured to provide an indication of the predicted delivery properties for the mixture. The predicted delivery properties may include a consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, and/or still other properties predicted for the mixture upon arrival at the destination (e.g., a job site, etc.). In some embodiments, the indication of the predicted delivery properties for the mixture is provided to an operator of the mixing vehicle (e.g., on the user interface 188 within the cab 14, etc.). In some embodiments, the indication of the predicted delivery properties for the mixture is provided to the batching system at the concrete plant (e.g., on a plant computer, etc.). In some embodiments, the indication of the predicted delivery properties for the mixture is provided to a customer (e.g., on a customer device, etc.).
At step 712, the controller is configured to provide an adjustment within predefined parameters based on the predicted delivery properties, the target properties, a target drum life for the mixing drum, a target life of one or more mixing drum components, a current state of the mixing drum (e.g., relative to the target drum life for the mixing drum, etc.), a current state of one or more mixing drum components (e.g., relative to the target life for the one or more mixing drum components, etc.), and/or the type of the mixing drum. In some embodiments, the adjustment includes adaptively controlling a speed at which a drive system (e.g., the drum drive system 120, etc.) rotates the mixing drum (e.g., from a first speed to a second, different speed, etc.). Such control of the rotational speed of the mixing drum may alter the properties of the mixture (e.g., to achieve the target properties for the mixture, etc.). By way of example, increasing the speed of mixing drum may increase the temperature of the mixture to (e.g., reducing the water content thereof, etc.), and decrease the slump while increasing the viscosity of the mixture at an increased rate (e.g., relative to a lower rotational speed, etc.). By way of another example, a reduced speed of the mixing drum may provide a constant or decreased temperature of the mixture and (i) maintain the slump and viscosity of the mixture or (ii) decrease the slump while increasing the viscosity at a reduced rate (e.g., relative to a higher rotational speed, etc.).
In some embodiments, the adjustment additionally or alternatively includes adaptively controlling an amount of water and/or chemicals injected from a reservoir into the mixing drum by an injection valve (e.g., the injection valve of the injection port 130, etc.). Such injection of water and/or chemicals may be used to supplement and/or replace adaptively controlling the speed of the mixing drum to provide the target properties for the mixture. Such injection may be limited to a threshold amount of water and/or chemicals, and/or limited based on GPS location of the mixing vehicle. By way of example, the controller may be configured to prevent an operator of the mixing vehicle and/or the control scheme from introducing more than a predetermined, threshold amount of water and/or chemicals into the mixture (e.g., indicated by a batching system at a concrete plant, indicated by the target properties, indicated by a customer, etc.) to inhibit saturating the mixture with liquid. By way of another example, the controller may be configured to prevent an operator of the mixing vehicle and/or the control scheme from introducing water and/or chemicals to the mixture based on the GPS location of the mixing vehicle. For example, the controller may selectively prevent the injection of water and/or chemicals after the mixing vehicle arrives at a job site.
At step 714, the controller is configured to receive en route data. The en route data may include the environment data (e.g., updated environment data, an environmental characteristic such as an ambient temperature, a relative humidity, wind speed, elevation, precipitation characteristics, traffic information/patterns, road attributes, etc.), mixture data, and/or GPS data. The controller may receive the mixture data from a sensor (e.g., a mixture sensor, the sensor 140, etc.) positioned within the mixing drum and/or estimate the mixture data. The mixture data may be indicative of one or more current properties of the mixture within the mixing drum. The controller may receive the GPS data from the GPS. The GPS data may include turn-by-turn driving instructions, travel distance, and/or travel time from a current location of the mixing vehicle to the destination. The GPS data may additionally or alternatively provide information regarding traffic information and/or traffic patterns at and/or ahead of the mixing vehicle. At step 716, the controller is configured to update the predicted delivery properties based on the adjustment performed and/or the en route data (e.g., the environment data, the mixture data, the GPS data, etc.).
At step 718, the controller is configured to determine whether delivery criteria has been satisfied (e.g., the delivery time has been reached, the mixing vehicle has arrived at the delivery location for the mixture, etc.). If the delivery criteria has not been satisfied, the controller is configured to repeat steps 710-716. Thus, the controller may be configured to continuously and/or periodically (e.g., every minute, two minutes, five minutes, ten minutes, etc.; every mile, two miles, five miles, ten miles, etc.) (i) provide indications of the predicted delivery properties, (ii) make adjustments based on the predicted delivery properties and/or the target properties, (iii) receive the en route data (e.g., the environment data, the mixture data, the GPS data, etc.), and (iv) update the predicted delivery properties based on the adjustments and/or the en route data.
If the delivery criteria has been satisfied, the controller is configured to provide an indication of the actual delivery properties of the mixture and/or the predicted delivery properties for the mixture. In some embodiments, the indication of the actual properties of the mixture is provided to an operator of the mixing vehicle (e.g., on the user interface 188 within the cab 14, etc.). In some embodiments, the indication of the actual delivery properties of the mixture is provided to a concrete plant (e.g., on a plant computer, the batching system etc.). In some embodiments, the indication of the actual delivery properties of the mixture is provided to a customer (e.g., on a customer device, etc.). The actual delivery properties may be acquired and transmitted to the controller by the sensor within the mixing drum and/or manually determined and entered into the user interface by the operator and/or a quality personnel. The actual delivery properties of the mixture and the predicted delivery properties for the mixture may be compared and used for further processing.
Referring now to
At step 802, a controller (e.g., the drum assembly controller 160, the remote monitoring and/or command system 192, etc.) is configured to receive and record delivery data for the mixture. The delivery data may include a delivery time, a delivery location, and/or a delivery route. In some embodiments, the controller receives at least a portion of the delivery data from a user input (e.g., using the user interface 188, etc.). The delivery data may be provided by an operator of the mixing vehicle, an employee at a concrete plant, and/or a customer and transmitted to the controller (e.g., remotely, wirelessly, via a wired connection, onboard the mixing vehicle, etc.). In some embodiments, the controller receives at least a portion of the delivery data from a GPS (e.g., the GPS 190, etc.).
At step 804, the controller is configured to receive and record initial properties of the mixture. The initial properties of the mixture may include a weight of the mixture, a volume of the mixture, a constituent makeup of the mixture (e.g., amount of cementitious material, aggregate, sand, water content, air entrainers, water reducers, set retarders, set accelerators, superplasticizers, corrosion inhibitors, coloring, calcium chloride, minerals, etc.), an initial slump of the mixture, an initial viscosity of the mixture, and/or any other properties known about the mixture prior to and/or upon entry into the mixing drum. In some embodiments, the controller receives at least a portion of the initial properties from a user input (e.g., using the user interface 188, etc.). The initial properties may be input by an operator of the mixing vehicle and/or an employee at a concrete plant (e.g., remotely, wirelessly, via a wired connection, onboard the mixing vehicle, etc.). In some embodiments, the controller receives at least a portion of the initial properties from a sensor (e.g., a mixture sensor positioned within the mixing drum, the sensor 140, etc.).
According to an exemplary embodiment, the controller is configured to receive and record environment data. The environment data may be indicative of an environmental characteristic. The environmental characteristics may include an ambient temperature, a relative humidity, wind speed, elevation, precipitation characteristics (e.g., rain, snow, fog, etc.), traffic information/patterns, road attributes, etc. In some embodiments, the controller receives at least a portion of the environment data from a user input (e.g., using the user interface 188, etc.). The environment data may be input by an operator of the mixing vehicle and/or an employee at a concrete plant (e.g., remotely, wirelessly, via a wired connection, onboard the mixing vehicle, etc.). In some embodiments, the controller receives at least a portion of the environment data from a sensor (e.g., a temperature sensor, a barometer or other pressure sensor, a humidity sensor, a pitot tube, an altimeter, a sensor positioned on the mixing vehicle, the sensor 140, etc.). In some embodiments, the controller receives at least a portion of the environment data from an internet based service (e.g., a weather and/or topography service that is accessed by and/or provided to the controller and based on current location of the mixing vehicle, etc.).
At step 806, the controller is configured to receive and record target properties for the mixture. The target properties for the mixture may include a consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, and/or still other properties desired for the mixture. According to an exemplary embodiment, the controller receives the target properties from a user input (e.g., using the user interface 188, etc.). The target properties may be provided by an operator of the mixing vehicle, an employee at a concrete plant, and/or a customer (e.g., remotely, wirelessly, via a wired connection, onboard the mixing vehicle, etc.). In some embodiments, at least a portion of the target properties are predefined within batching software (e.g., a standard initial property in batching software associated with the concrete plant, a standard target property in batching software associated with the concrete plant, software associated with the memory 166 and/or the concrete property module 174 of the drum assembly controller 160, etc.). In some embodiments, the controller is configured to determine and operate the mixing drum (e.g., with the drum drive system 120, etc.) at an initial drive speed based on the initial properties of the mixture, the delivery data, the environment data, and/or the target properties for the mixture. In other embodiments, the initial drive speed is predetermined and sent to the controller from the batching system at the concrete plant. In some embodiments, the controller is configured to additionally or alternatively determine and operate the mixing drum at the initial drive speed based on a target drum life for the mixing drum (e.g., a number of yards and mix of concrete the mixing drum is designed to receive throughout an operating lifetime thereof, a number of yards of concrete the mixing drum is designed to receive throughout an operating lifetime thereof without regard for the particular mix of the concrete, etc.) and/or a type of the mixing drum (e.g., capacity, shape, manufacturer, a front discharge mixing drum, a rear discharge mixing drum, a thickness of a sidewall or other portion of the mixing drum, type and/or identity of materials the mixing drum is manufactured from, dimensional characteristics, etc.).
At step 808, the controller is configured to predict and record delivery properties for the mixture (i.e., predicted properties for the mixture upon arrival at the destination) based on the delivery data, the initial properties of the mixture, and/or the environmental data. In some embodiments, the controller is configured to additionally or alternatively predict the delivery properties for the mixture based on a target drum life for the mixing drum, a target life of one or more mixing drum components, a current state of the mixing drum (e.g., relative to the target drum life for the mixing drum, etc.), a current state of one or more mixing drum components (e.g., relative to the target life for the one or more mixing drum components, etc.), and/or the type of the mixing drum. At step 810, the controller is configured to provide an indication of the predicted delivery properties for the mixture. The predicted delivery properties may include a consistency, mixture quality, amount of air entrainment, viscosity, slump, temperature, water content, and/or still other properties predicted for the mixture upon arrival at the destination (e.g., a job site, etc.). In some embodiments, the indication of the predicted delivery properties for the mixture is provided to an operator of the mixing vehicle (e.g., on the user interface 188 within the cab 14, etc.). In some embodiments, the indication of the predicted delivery properties for the mixture is provided to a concrete plant (e.g., on a plant computer, the batching system etc.). In some embodiments, the indication of the predicted delivery properties for the mixture is provided to a customer (e.g., on a customer device, etc.).
At step 812, the controller is configured to provide and record an adjustment within predefined parameters based on the predicted delivery properties, the target properties, a target drum life for the mixing drum, a target life of one or more mixing drum components, a current state of the mixing drum (e.g., relative to the target drum life for the mixing drum, etc.), a current state of one or more mixing drum components (e.g., relative to the target life for the one or more mixing drum components, etc.), and/or the type of the mixing drum. In some embodiments, the adjustment includes adaptively controlling a speed at which a drive system (e.g., the drum drive system 120, etc.) rotates the mixing drum (e.g., from a first speed to a second, different speed, etc.). Such control of the rotational speed of the mixing drum may alter the properties of the mixture (e.g., to achieve the target properties for the mixture, etc.). By way of example, increasing the speed of mixing drum may increase the temperature of the mixture (e.g., reducing the water content thereof, etc.), and decrease the slump while increasing the viscosity of the mixture at an increased rate (e.g., relative to a lower rotational speed, etc.). By way of another example, a reduced speed of the mixing drum may provide a constant or decreased temperature of the mixture and (i) maintain the slump and viscosity of the mixture or (ii) decrease the slump while increasing the viscosity at a reduced rate (e.g., relative to a higher rotational speed, etc.).
In some embodiments, the adjustment additionally or alternatively includes adaptively controlling an amount of water and/or chemicals injected from a reservoir into the mixing drum by an injection valve (e.g., the injection valve of the injection port 130, etc.). Such injection of water and/or chemicals may be used to supplement and/or replace adaptively controlling the speed of the mixing drum to provide the target properties for the mixture. Such injection may be limited to a threshold amount of water and/or chemicals, and/or limited based on GPS location of the mixing vehicle. By way of example, the controller may be configured to prevent an operator of the mixing vehicle and/or the control scheme from introducing more than a predetermined, threshold amount of water and/or chemicals into the mixture (e.g., indicated by a batching system at a concrete plant, indicated by the target properties, indicated by a customer, etc.) to inhibit saturating the mixture with liquid. By way of another example, the controller may be configured to prevent an operator of the mixing vehicle and/or the control scheme from introducing water and/or chemicals to the mixture based on the GPS location of the mixing vehicle. For example, the controller may selectively prevent the injection of water and/or chemicals after the mixing vehicle arrives at a job site.
At step 814, the controller is configured to receive and record en route data. The en route data may include the environment data (e.g., updated environment data, an environmental characteristic such as an ambient temperature, a relative humidity, wind speed, elevation, precipitation characteristics, traffic information/patterns, road attributes, etc.), mixture data, and/or GPS data. The controller may receive the mixture data from a sensor (e.g., a mixture sensor, the sensor 140, etc.) positioned within the mixing drum and/or estimate the mixture data. The mixture data may be indicative of one or more current properties of the mixture within the mixing drum. The controller may receive the GPS data from the GPS. The GPS data may include turn-by-turn driving instructions, travel distance, and/or travel time from a current location of the mixing vehicle to the destination. The GPS data may additionally or alternatively provide information regarding traffic information and/or traffic patterns at and/or ahead of the mixing vehicle. At step 816, the controller is configured to update and record the predicted delivery properties based on the adjustment performed and/or the en route data (e.g., the environment data, the mixture data, the GPS data, etc.).
At step 818, the controller is configured to determine whether delivery criteria has been satisfied (e.g., the delivery time has been reached, the mixing vehicle has arrived at the delivery location for the mixture, etc.). If the delivery criteria has not been satisfied, the controller is configured to repeat steps 810-816. Thus, the controller may be configured to continuously and/or periodically (e.g., every minute, two minutes, five minutes, ten minutes, etc.; every mile, two miles, five miles, ten miles, etc.) (i) provide indications of the predicted delivery properties, (ii) make and record adjustments based on the predicted delivery properties and/or the target properties, (iii) receive and record the en route data (e.g., the environment data, the mixture data, the GPS data, etc.), and (iv) update and record the predicted delivery properties based on the adjustments and/or the en route data. If the delivery criteria has been satisfied, the controller is configured to provide the indication of the predicted delivery properties for the mixture (step 820).
At step 822, the controller is configured to receive and record actual delivery properties of the mixture. In some embodiments, the controller receives at least a portion of the actual delivery properties from a user input (e.g., using the user interface 188, manually determined and entered, etc.). The actual properties may be provided by an operator of the mixing vehicle, a quality personnel, and/or a customer (e.g., remotely, wirelessly, via a wired connection, onboard the mixing vehicle, etc.). In some embodiments, the controller receives at least a portion of the actual properties from a sensor (e.g., a mixture sensor positioned within the mixing drum, the sensor 140, etc.). At step 824, the controller is configured to provide an indication of the actual delivery properties of the mixture. In some embodiments, the indication of the actual properties of the mixture is provided to an operator of the mixing vehicle (e.g., on the user interface 188 within the cab 14, etc.). In some embodiments, the indication of the actual delivery properties of the mixture is provided to a concrete plant (e.g., on a plant computer, a batching system, etc.). In some embodiments, the indication of the actual delivery properties of the mixture is provided to a customer (e.g., on a customer device, etc.).
According to an exemplary embodiment, the controller is configured to record the delivery data, the initial properties, the target properties, the predicted delivery properties, the adjustments, the en route data (e.g., the environment data, the mixture data, the GPS data, etc.), and/or the actual delivery data to facilitate generating and/or updating a prediction algorithm stored within and operated by the controller. Such generation and/or updating of the prediction algorithm may facilitate providing more accurate prediction and/or control of a mixture's properties in future deliveries. Additionally, once a sufficient amount of data has been compiled, the prediction algorithm may facilitate the removal of the mixture sensor from the mixing vehicle. By way of example, the initial properties of the mixture may be input by the batching system at the plant, determined with sensors at the plant, and/or determined using look-up tables (e.g., based on the compiled data, etc.). The predicted delivery properties and/or the mixture data may be determined based on the initial properties, various adjustments made during transit, the environmental data, and/or the GPS data (e.g., using the compiled data, look-up tables, etc.) without needing to be directly measured with a sensor. Such removal of the mixture sensor may thereby reduce the cost to manufacture and operate the mixing vehicle.
Referring now to
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According to an exemplary embodiment, the rear input device 220 includes a second control pad or rear control pad having various buttons (e.g., similar to the cab control pad 212 of the cab input device 210, etc.). The various buttons of the second control pad of the rear input device 220 may facilitate selecting one or more components to control (e.g., with the joystick 214, with the rear input device 220, etc.), selecting a mode of operation of the drum assembly 100, and/or activing/deactivating various components of the concrete mixing truck 10 from outside of the concrete mixing truck 10.
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In some embodiments, the display device 200 is additionally or alternatively configured to display at least one of a chute diagnostics GUI, a fuse diagnostics GUI, a drum diagnostics GUI, and/or other diagnostics GUIs to indicate the status, mode, and/or faults of various components of the concrete mixing truck 10. The chute diagnostics GUI may be configured to display the status and/or position of the chute 112 (e.g., up, down, angled left, angled right, centered, locked, unlocked, etc.) and information regarding the circuits thereof. The fuse diagnostics GUI may be configured to indicate whether each respective fuse of the concrete mixing truck 10 is either operational or blown. The drum diagnostics GUI may be configured to display any electrical issues with the drum assembly 100 such as shorts, open circuits, improper installation, etc. and/or display the mode, status, and/or operational parameters of components of the drum assembly 100 (e.g., activation of a drum stop solenoid, a drum charge solenoid, a drum discharge solenoid, etc.; a drum speed; a drum direction; etc.).
According to an exemplary embodiment, the command control and monitoring system is configured to facilitate diagnosing faults and identifying the probable location of the faults on concrete mixing truck 10. By way of example, when a fault is diagnosed by the command control and monitoring system, the display device 200 may provide a GUI having a graphical representation of the concrete mixing truck 10 (e.g., similar to that shown in
By way of example, the command control and monitoring system may be configured to monitor (i) the mixture sensors configured to acquire the mixture data for monitoring concrete properties of the mixture, (ii) the drive system sensors configured to acquire the drive system data for monitoring the operating characteristics of the drum drive system 120, (iii) the environment sensors configured to acquire environment data for monitoring environmental characteristics external to the mixing drum 102, and/or (iv) inputs and outputs used to control functions of the concrete mixing truck 10 (e.g., inputs and outputs of the drum drive system 120, the injector device of the injection port 130, the engine 16, etc.). The command control and monitoring system may be further configured to determine that there is a potential fault with one or more of the sensors (e.g., the mixture sensors, the environment sensors, the drive system sensors, etc.), the input, and/or the output. The command control and monitoring system may be further configured to provide a fault notification on the display device 200 indicating the potential fault location.
In some embodiments, the control and monitoring system is configured monitor a property of the mixture within the mixing drum 102 and provide an alert when the property begins to deviate from an expected or predicted value. For example, the control and monitoring system may be configured to determine that a property is changing at an increased rate or too slow of a rate, determine a potential fault location based on the property that is changing, and provide a fault notification that indicates the potential fault location. By way of example, the control and monitoring system may recognize that the slump of the mixture is increasing (e.g., becoming less viscous, more fluid, etc.). The control and monitoring system may therefore provide an alert that the slump is increasing at an alarming rate and provide an indication that the injection valve may have been left open or stuck (e.g., frozen open in the winter, etc.). The control and monitoring system may thereby provide an alert on the display device 200 to check the injection valve to stop the fluid injection and prevent the slump from increasing further from the target slump.
According to an exemplary embodiment, the display device 200 is portable and removable from the cab 14 (e.g., a tablet, a laptop, a smart device, etc.). The display device 200 may therefore be capable of capturing pictures of the failed or fault area/component (e.g., to be sent to a technician, etc.). The display device 200 may additionally or alternatively be capable of being brought to the area of the concrete mixing truck 10 where the fault originated and provide step-by-step instructions on how to diagnose and troubleshoot the problem. The instructions may be visually displayed and/or audibly provided by the display device 200. The display device 200 may be configured to display data sheets, prints, and/or schematics without having to search or request such information to facilitate the diagnosis and/or troubleshooting. The display device 200 may be configured to facilitate automatic ordering of replacement parts/components directly therefrom. Further, the display device 200 may facilitate remote diagnostics from a service/technician center.
As utilized herein, the terms “approximately”, “about”, “substantially”, and similar terms are intended to have a broad meaning in harmony with the common and accepted usage by those of ordinary skill in the art to which the subject matter of this disclosure pertains. It should be understood by those of skill in the art who review this disclosure that these terms are intended to allow a description of certain features described and claimed without restricting the scope of these features to the precise numerical ranges provided. Accordingly, these terms should be interpreted as indicating that insubstantial or inconsequential modifications or alterations of the subject matter described and claimed are considered to be within the scope of the invention as recited in the appended claims.
It should be noted that the term “exemplary” as used herein to describe various embodiments is intended to indicate that such embodiments are possible examples, representations, and/or illustrations of possible embodiments (and such term is not intended to connote that such embodiments are necessarily extraordinary or superlative examples).
The terms “coupled,” “connected,” and the like, as used herein, mean the joining of two members directly or indirectly to one another. Such joining may be stationary (e.g., permanent) or movable (e.g., removable, releasable, etc.). Such joining may be achieved with the two members or the two members and any additional intermediate members being integrally formed as a single unitary body with one another or with the two members or the two members and any additional intermediate members being attached to one another.
References herein to the positions of elements (e.g., “top,” “bottom,” “above,” “below,” etc.) are merely used to describe the orientation of various elements in the figures. It should be noted that the orientation of various elements may differ according to other exemplary embodiments, and that such variations are intended to be encompassed by the present disclosure.
Also, the term “or” is used in its inclusive sense (and not in its exclusive sense) so that when used, for example, to connect a list of elements, the term “or” means one, some, or all of the elements in the list. Conjunctive language such as the phrase “at least one of X, Y, and Z,” unless specifically stated otherwise, is otherwise understood with the context as used in general to convey that an item, term, etc. may be either X, Y, Z, X and Y, X and Z, Y and Z, or X, Y, and Z (i.e., any combination of X, Y, and Z). Thus, such conjunctive language is not generally intended to imply that certain embodiments require at least one of X, at least one of Y, and at least one of Z to each be present, unless otherwise indicated.
It is important to note that the construction and arrangement of the elements of the systems and methods as shown in the exemplary embodiments are illustrative only. Although only a few embodiments of the present disclosure have been described in detail, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited. For example, elements shown as integrally formed may be constructed of multiple parts or elements. It should be noted that the elements and/or assemblies of the components described herein may be constructed from any of a wide variety of materials that provide sufficient strength or durability, in any of a wide variety of colors, textures, and combinations. Accordingly, all such modifications are intended to be included within the scope of the present inventions. Other substitutions, modifications, changes, and omissions may be made in the design, operating conditions, and arrangement of the preferred and other exemplary embodiments without departing from scope of the present disclosure or from the spirit of the appended claims.
This application is a continuation of U.S. patent application Ser. No. 16/522,453, filed Jul. 25, 2019, which is a continuation of U.S. patent application Ser. No. 15/624,900, filed Jun. 16, 2017, which claims the benefit of U.S. Provisional Patent Application No. 62/351,891, filed Jun. 17, 2016, U.S. Provisional Patent Application No. 62/406,390, filed Oct. 10, 2016, and U.S. Provisional Patent Application No. 62/414,527, filed Oct. 28, 2016, all of which are incorporated herein by reference in their entireties.
Number | Date | Country | |
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62351891 | Jun 2016 | US | |
62406390 | Oct 2016 | US | |
62414527 | Oct 2016 | US |
Number | Date | Country | |
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Parent | 16522453 | Jul 2019 | US |
Child | 17462621 | US | |
Parent | 15624900 | Jun 2017 | US |
Child | 16522453 | US |