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    • 专利摘要:
    system and method for synchronized control of a harvester and transport vehicle a control system and method are presented for synchronized control of a harvester (10) and a transport vehicle (20) during the moving unloading operation. The control system can maintain a desired lateral distance (lad) between the harvester (10) and the transport vehicle (20) using the career information that is used to drive the harvester (10). In addition, the control system may also place the transport vehicle (20) in proper alignment with the harvester (10) using the same harrow information.
    公开号:BR112013021136B1
    申请号:R112013021136-9
    申请日:2012-02-15
    公开日:2018-11-06
    发明作者:Guoping Wang;Todd Aznavorian;Arun Natarajan;Kousha Moaveninejad
    申请人:Cnh Industrial America Llc;
    IPC主号:
    专利说明:

    (54) Title: SYSTEM AND METHOD FOR SYNCHRONIZED CONTROL OF A HARVESTER AND TRANSPORT VEHICLE (51) Int.CI .: A01D 41/127; A01D 43/08; G05D 1/02.
    (30) Unionist Priority: 02/18/2011 US 61 / 444,464; 06/29/2011 US 13 / 171,620.
    (73) Holder (s): CNH INDUSTRIAL AMÉRICA LLC.
    (72) Inventorfes): GUOPING WANG; TODD AZNAVORIAN; ARUN NATARAJAN; KOUSHA MOAVENINEJAD.
    (86) PCT Application: PCT EP2012052568 of 02/15/2012 (87) PCT Publication: WO 2012/110545 of 08/23/2012 (85) Date of the Beginning of the National Phase: 08/19/2013 (57) Summary: SYSTEM AND METHOD FOR SYNCHRONIZED CONTROL OF A HARVESTER AND TRANSPORT VEHICLE A control system and method are presented for synchronized control of a harvester (10) and a transport vehicle (20) during the unloading operation in motion. The control system can maintain a desired lateral distance (LAD) between the harvester (10) and the transport vehicle (20) using the career information that is used to drive the harvester (10). In addition, the control system can also place the transport vehicle (20) in appropriate alignment with the harvester (10) using the same information as the harvester.
    1/22 “SYSTEM AND METHOD FOR SYNCHRONIZED CONTROL OF A HARVESTER AND TRANSPORT VEHICLE”
    Technical field
    The present application relates, in general, to a system and method to automate or synchronize the control of a harvester and transport vehicle dealing with the “unloading in motion” operation. The present application relates more specifically to a control system and method for controlling the lateral position and the longitudinal position of the transport vehicle in relation to the harvester during the “unloading in motion” operation.
    Previous technique
    Harvesters or harvesting machines collect the harvest material, treat the harvest material, for example, remove any unwanted portions or waste and unload the harvest material. Harvesters can unload the crop material, either continuously as with a forage harvester or after intermediate storage as with a combination, for a transport or transfer vehicle. The transport vehicle can be a tractor or truck pulling a cart, wagon or trailer or a truck or other vehicle capable of transporting the harvested material. The harvested harvest material is loaded onto the transport vehicle via a harvest unloading or unloading device, such as a discharge pipe or auger, associated with the harvester.
    During the harvester's “moving in unload” operation, the harvested harvest material is transferred from the harvester to the transport vehicle while both vehicles are moving. The transport vehicle can then move to and / or behind the harvester during the unloading operation in motion. Moving discharge operation is necessary for a forage harvester, as long as the forage harvester constantly unloads the harvested crop material. While the moving unloading operation is not required for a combination due to the intermediate storage capacity of the combined, the moving unloading operation is generally used for a combined to maximize the operating efficiency of the combined.
    To effectively implement the unloading operation while in motion, the operation of the harvester and the transport vehicle is coordinated to maintain the relative distance between the harvester and the transport vehicle within an acceptable range. For maintaining the relative distance of the harvester and the transport vehicle within an acceptable range, the position and orientation of the harvester discharge pipe and the position of the transport vehicle, specifically the portion of the transport vehicle that receives the harvest material , relative to the position of the harvester unloading tube are kept within an acceptable distance range to allow the unloading operation in motion of the harvester, that is, the material from the unloaded crop can be supplied into the transport vehicle without loss to the soil. That is, the crop material discharged is directed to collection in the transport vehicle and
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    2/22 substantially does not lose direction to the transport vehicle and falls to the ground resulting in waste or loss of crop material. In order to maintain an acceptable distance range between the harvester and the transport vehicle, both the lateral distance (side by side) and the longitudinal distance (from front to rear) between the harvester and the transport vehicle must be maintained. within acceptable ranges.
    Some control systems used for unloading operations in motion can determine the lateral position of the transport vehicle as a function of the harvester's position plus an index. Although this type of control system can be effective when the harvester moves in a straight line, unacceptable deviations in the lateral distance can occur when the harvester changes position abruptly and the control system cannot adjust the position of the fast transport vehicle. enough to prevent loss of crop material. Furthermore, the control system can only provide a destination point for the transport vehicle that is approaching the mobile harvester, which can result in imprecise initial alignment of the harvester and the transport vehicle and 15 delays in the operation of the harvester. discharge in motion.
    Therefore, what is needed is a system and method to control the lateral distance between a harvester and a transport vehicle during a moving unloading operation and to assist a transport vehicle in approaching a mobile harvester to minimize disruption in operation discharge in motion.
    Revelation of the invention
    The present order is directed to a system and method for the automatic or synchronized control of a harvester and a transport vehicle during unloading operations in motion.
    The present application relates to a method for controlling a transport vehicle 25 as set forth in claim 1 of the appended claims.
    The present application further relates to a control system for synchronizing the control of a harvester and a transport vehicle as presented in claim 11 of the attached claims.
    The first communication device and the second communication device communicate between a reaper controller area network and a transport vehicle controller area network.
    Each of the first and second controllers can include a user interface.
    Each user interface can include a message box to display messages and a control button to initiate actions by the corresponding controller.
    The transport vehicle and the harvester can be in the wireless communication range with the exchange of heartbeat messages by the transport vehicle control system and the harvester control system.
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    3/22
    The adjusted career can be substantially parallel to the active career.
    The harvester control system can send a control configuration command message to the transport vehicle control system using the first communication device, the control configuration command message includes information on at least one in a row main, a career type, an active career, a career width, a shift in the harvester's communication tube or a shift in the position of the discharge tube.
    The present application also relates to a method for controlling a transport vehicle to bring the transport vehicle into alignment with a harvester for unloading operation 10 in motion. The method includes determining the position and speed for the transport vehicle, determining the speed and active career for the harvester and calculating an adjusted career for the transport vehicle based on the active career for the harvester. The method also includes calculating a trajectory for the transport vehicle to move from the transport vehicle's position to the adjusted row. The path includes a straight line component and an arc component. The arc component is tangent to both the straight line component and the adjusted row. The method further includes providing the calculated trajectory for a controller for the transport vehicle and controlling the transport vehicle to follow the calculated trajectory with the controller's commands.
    An advantage of the present application is the improved accuracy during a moving unloading operation 20 as a result of automatic or synchronized control of the harvester and the transport vehicle. Improvements in accuracy are derived from automatic or synchronized control, ensuring that all crop material being discharged is directed to the transport vehicle.
    Another advantage of the present order is the ability to allow more farmers 25 to carry out unloading operations on the move as a result of automatic or synchronized control that reduces the level of expertise required for harvester and transport vehicle operators.
    Brief description of the drawings
    Figure 1 shows a schematic top view of a modality of a combine harvester 30 and transport vehicle during the unloading operation in motion,
    Figure 2 shows a rear view of a modifier of a combine harvester and transport vehicle during the unloading operation while
    Figure 3 shows a mode of a main row, combined row row and set row of the tractor used with a V2V 35 automatic guidance control system,
    Figures 4A and 4B schematically show the display screen modalities for a combine and a transport vehicle associated with a control system.
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    4/22 automatic V2V orientation,
    Figures 5A and 5B show flowcharts of modalities of the control processes implemented by the harvester and transport vehicle for a V2V automatic guidance control system,
    Figures 6A and 6B schematically show control system modalities for the main control algorithms in Figures 5A and 5B,
    Figure 7 shows different variations of the reaper and transport vehicle display screens when starting the automatic V2V guidance control,
    Figures 8-10 show flowcharts of the modalities of the control processes 10 for the control system of figure 6A,
    Figures 11-13 show flowcharts of modalities of the control processes for the control system of figure 6B and
    Figures 14A and 14B show different transition paths for the V2V tractor under the control of automatic V2V guidance.
    Whenever possible, the same reference numbers will be used by all drawings to refer to the same or similar parts.
    Best mode for carrying out the invention
    In this order, a vehicle-to-vehicle (V2V) operation refers to a moving unloading operation from the harvester, and a combined V2V and 20V2V tractor refers to a harvester and transport vehicle performing the unloading operation. moving the harvester.
    Figures 1 and 2 show the relative positions of a combine 10 and transport vehicle 20 during a moving or V2V unloading operation. In an exemplary mode, the V2V 10 combine or combine and the V2V 20 25 transport vehicle or tractor can be controlled by an automatic guidance control system (s) based on the global positioning system (GPS) in order to maintain a desired lateral distance (LAD) and a desired longitudinal distance (LOD) between the combine 10 and the transport vehicle 20. An exemplary model of the reference points used to measure the desired lateral distance and the desired longitudinal distance is shown in the figure 1. However, any 30 reference points suitable for measuring lateral distance and longitudinal distance can be used. The desired lateral distance and the desired longitudinal distance can both be pre-selected distances, more or less a predetermined offset that ensures that the harvest material discharged from the harvester 10 is received and stored by the transport vehicle 20. As shown in figure 1 , the lateral distance error limits (LADEL) 35 define the maximum and minimum lateral distances that can be used for unloading in motion. The pre-selected lateral and longitudinal distances and the corresponding indexes can be related to the harvesters and
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    5/22 private transport vehicles being used, specifically the size of the storage area in the transport vehicle and an estimate of the release distance of the harvest material from the harvester discharge tube to the transport vehicle.
    The harvester 10 can have: a controller 12 that includes a display unit or user interface and a navigation controller; a GPS device 14 that includes an antenna and receiver and a wireless communication unit or device (WCU) 16 that can include a power control switch. Similarly, the transport vehicle 20 may have: a controller 22 which may include a display or user interface unit, a navigation controller and vehicle control unit for tractor vehicle (TV2V); a GPS device 24 that can include an antenna and receiver and a wireless communication unit or device (WCU) 26 that can include a power control switch. Controllers can be used to control the operation and / or direction of the combine 10 and / or the transport vehicle 20, regardless of the machine on which the controller can be installed. The GPS device can be used to determine the position of the harvester 10 or transport vehicle 20 and the wireless communication device can be used to send and receive information, data signals and control between the harvester 10 and the transport vehicle 20.
    In the exemplary embodiment shown in Figure 1, the transport vehicle 20 can include a pull device 21 and a loading receptacle 23. A pull-out angle sensor 25 can be used to determine the relative angle or pull-out angle between the pull-out device pull 21 and the loading receptacle 23. As shown in figure 1, the pull device 21 can be a tractor and the loading receptacle 23 can be a wagon. However, in other embodiments, the traction vehicle 21 may be a truck or other self-propelled vehicle sufficient to carry the loading receptacle 23 and the loading receptacle 23 may be a grain cart, box or other similar storage / transportation vehicle. In another embodiment, the transport vehicle 20 may be a truck, semi-trailer truck, tractor-trailer or other similar self-propelled container vehicle.
    With reference now to figure 2, the combine harvester 10 has a discharge pipe or tube 18 that extends transversely and fully disposed when it discharges the material from the crop 100 through the discharge boot 30 and into the transport vehicle 20. A boot 30 can take any convenient and suitable shape. In an exemplary embodiment, boot 30 may be generally cylindrical, but may be straighter with edges, or in the shape of a venturi, etc. The opening of the discharge pipe or tube 18 at its distal end is sealed at the periphery by a joint element 11 that hinges the portion 32 of the boot 30, the portion 32 of which interfaces with the distal end of the discharge pipe or tube 18. The joint element 11 can be rounded or spherical, but it can also be cylindrical on the horizontal geometric axis, as long as the interface between
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    6/22 the pipe or tube 18 and the boot 30 are properly sealed. Angled angled from portion 32 of boot 30 is an end of tube 31 of boot 30. The signals from controller 12 of the combine harvester 10 move through conduits 47 to control the actuators 40, whose actuators 40 can pivot the boot 30 upwardly and down and from side to side in relation to the pipe or discharge pipe 18, via a spherical joint 11. The joint 11 also serves to seal the interface at the end 32 of the boot 30.
    Controllers 12, 22 can include a microprocessor, a non-volatile memory, an interface card, an analog to digital (A / D) converter and a digital to analog (D / A) converter to control the operation of the harvester and / or the transport vehicle. Controllers 12, 22 can execute one or more control algorithms to control the operation, orientation and / or direction of the harvester 10 and / or the transport vehicle 20 and to implement harvester pipe control. In one embodiment, the control algorithm (s) can be computer programs or software stored in the non-volatile memory of the controllers 12, 22 and may include a series of instructions executable by the corresponding microprocessor of the controllers 12, 22. Although it is preferred that the control algorithm is personified in a computer program (s) and executed by the microprocessor, it must be understood that the control algorithm can be implemented and executed using digital and / or analog hardware by those skilled in the art. If the hardware is used to execute the control algorithm, the corresponding configuration of the controllers 12, 22 can be changed to incorporate the necessary components and to remove any components that may no longer be needed.
    In addition, controllers 12, 22 can be connected or incorporate a display unit or user interface that allows an operator of the combine 10 or transport vehicle 20 to interact with controllers 12, 22. The operator can select and enter commands to controllers 12, 22 via the display unit or the user interface. In addition, the display unit or the user interface can display messages and information from the controllers 12, 22 regarding the operational status of the harvester 10 and / or the transport vehicle 20. The display units or user interfaces can be located locally on controllers 12,22 or, alternatively, display units or user interfaces can be located remotely from controllers 12, 22. In another exemplary embodiment, controllers 12, 22 can each include one or more sub-controllers under the control of a main controller. Each subcontroller and the main controller can be configured similar to controllers 12, 22.
    In an exemplary mode, controllers 12, 22 can run an automatic V2V guidance control system that can automatically drive a V2V tractor to follow the motion path of a combined V2V during operations
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    7/22 moving discharge from the harvester. The automatic guidance control system can steer the V2V tractor in a controlled manner during the harvester's unloading operations to maintain the lateral distance between the V2V tractor and the combined V2V tractor within the specified error limits of the lateral distance . In order to steer the V2V tractor, the automatic guidance control system can provide control signals to a steering control valve to adjust the steering position of the V2V tractor (and finally the trajectory of the V2V tractor) and receive signals from a steering sensor to determine the current steering position of the V2V tractor.
    The V2V automatic guidance control system can also be used to automatically direct the combined V2V based on predetermined careers in a field or area where the harvester's unloading operation is taking place. Figure 3 shows a main row, the combined row row and the adjusted row tractor of a field. A main row (MS) recorded from a given pattern, a straight line or a curve, that is, any type of suitable self-guided row pattern, is stored in a non-volatile memory within controller 12. The main row can be recorded in terms of GPS coordinates of career path points. In an exemplary modality, the same main career can be used as a reference line for automatic guidance operations in both planting and harvesting the crop.
    When the V2V combination is operating, the display unit of the controller 12 generates several rows around the current location of the V2V combination that are parallel to the main row. The distance between two adjacent parallel rows can be equal to the combined row width, or cutting width, starting from the main row. When a V2V operation is activated, the parallel path closest to the combined location is selected as the active combined path (CAS).
    In an exemplary embodiment, the V2V automatic guidance control system can use the combined direction of the combined or the automatic direction of the combined to direct the combined V2V in the active career of the combined during unloading operations in motion. Manual steering of the combined V2V by the operator may be allowed on a temporary basis during the unloading operation on the move, as long as the position of the combined V2V does not deviate from the active career of the combined by a distance that would result in the lateral distance between the combined V2V and the V2V tractor staying outside the error limits of the lateral distance.
    The WCUs in the combined V2V and V2V tractor provide wireless communications between the two vehicles. The V2V Combine Controller can wirelessly send data about the active career of the combined and the course of the combined to the V2V tractor to inform and notify the V2V tractor of the current travel path of the V2V combined.
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    8/22
    The V2V tractor controller can receive data on the combined row and generate a tractor adjusted row (TAS) that is parallel to and offset from the combined row by the required lateral distance or lateral offset parameter. The V2V tractor navigation controller then controls the automatic steering of the V2V 5 tractor to follow the adjusted row of the tractor and therefore maintain a required lateral distance between the combined V2V and the V2V tractor.
    Figures 4A and 4B show exemplary modalities of the user interface touch screens for the combined V2V and V2V tractor. The touch screens of the user interface can be part of the corresponding display unit for the combined V2V and 10 the V2V tractor. Figure 4A shows a combined V2V 40 user interface. The combined V2V 40 user interface can include a wireless communication icon (the antenna symbol) and an associated text message box 42, a radio button. multifunctional V2V control 44, an associated text message box 46 for the multifunctional V2V control button and a discharge condition text message box 15 48.0 wireless communication icon and associated message box 42 alert the operator information about the state of wireless communication. The discharge condition text message box 48 may display a message “Ready for discharge” with a green background or a message “Discharge not ready” with a gray or red background. In addition to the combined V2V 40 user interface, the controller may include a bell (not shown 20) to produce audible signals for the operator.
    Figure 4B shows a V2V 41 tractor user interface. The V2V 41 tractor user interface can include a wireless communication icon (the antenna symbol) and an associated text message box 43, a control button multifunctional V2V 45, an associated text message box 47 for the multifunctional V2V control button25 and a discharge condition text message box 49. The wireless communication icon and associated message box 43 alert the vehicle operator on the status of wireless communication. The discharge condition 49 text message box may display a message “Ready for discharge” with a green background or a message “Discharge not ready” with a gray or red background. In addition to the combined V2V 41 user interface, the controller can include a bell (not shown) to produce audible signals for the operator.
    Figures 5A and 5B show flowcharts for the V2V automatic guidance control system as implemented by the combined V2V and the V2V tractor. Flowcharts are run once at each time step, such as a time step of 35 0.2 seconds or other time values. Figure 5A shows the flow chart for the automatic V2V guidance system as implemented by the combined V2V. At each time step, the process begins with the combined V2V controller checking the
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    9/22 tractor V2V pulse message (step 50). If the combined V2V controller receives the tractor's V2V heartbeat message via wireless communication, the message of which indicates that it is possible to dedicate itself to operating the V2V, the combined V2V controller displays a message “V2V tractor on range ”in box 42 of the V2V 40 combined 5 user interface (step 52) and then executes the combined V2V main control algorithm (step 54). However, if the V2V combination controller does not receive the V2V heartbeat message from the tractor or there is no wireless communication between the V2V combination and the V2V tractor, the V2V combination controller clears the message “V2V tractor in range ”in box 42 of the combined V2V user interface 40 (step 58) and 10 then runs the combined V2V main control algorithm (step 54). At the end of the process at each time step, the combined V2V controller sends a combined V2V heartbeat message (step 56) which is transmitted by the combined wireless communication unit (WCU) 16 and waits for the next time to return to the beginning of the process (step 50).
    Figure 5B shows the flow chart for the automatic V2V guidance system as implemented by the V2V tractor. At each time step, the process begins with the V2V tractor controller checking the combined V2V heartbeat message (step 51). If the V2V tractor controller receives the combined V2V heartbeat message via wireless communication, the message of which indicates that it is possible to dedicate20 to V2V operation, the V2V tractor controller displays a message “Combined V2V in range ”In box 43 of the V2V 41 tractor user interface (step 53) and then executes the tractor's V2V main control algorithm (step 55). However, if the V2V tractor controller does not receive the combined V2V heartbeat message or there is no wireless communication between the V2V tractor and the V2V combined, the V2V tractor controller clears the “Combined from V2V in range ”in box 43 of the V2V 41 tractor user interface (step 59) and then executes the tractor's V2V main control algorithm (step 55). At the end of the process at each time step, the V2V tractor controller sends a V2V heartbeat message from the tractor (step 57) which is transmitted by the tractor's wireless communication unit (WCU) 26 and waits for the next step of time 30 to return to the beginning of the process (step 51).
    Figures 6A and 6B show modalities of the control systems for the combined V2V main control algorithm and the tractor's V2V main control algorithm. Figure 6A shows a control system or controller for the V2V control operation in the combined V2V. The control system for the V2V control operation in the V2V combi 35 starts in an idle state 60. If the V2V control button 44 is enabled depending on the V2V preconditions, which include the V2V heartbeat message of the tractor and the quality of the GPS signal, and the operator selects the “Engage V2V” command
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    10/22 of the V2V control button 44, the control system then enters a control configuration state 62. If control configuration state 62 determines that V2V operation can occur, then the control system switches to engaged state 64 and V2V operation begins. However, if control configuration state 62 determines that V2V operation cannot take place, then the control system returns to idle state 60. Additionally, since the control system is in engaged state 64, the control system The control can return to idle state 60 in response to the occurrence of a system failure or the selection of the “Disengage V2V” command from the V2V control button 44 by the operator.
    Figure 6B shows a control system or controller for the V2V control operation on the V2V tractor. The control system for the V2V control operation on the V2V tractor starts in an idle state 61. If the operator selects the “Accept V2V” command from the V2V 45 control button, the control system then enters a control configuration 63. If the control configuration state 63 determines that V2V operation can occur, then the control system switches to engaged state 65 and the V2V operation begins. However, if control configuration state 63 determines that V2V operation cannot occur, then the control system returns to idle state 61. Additionally, once the control system is in engaged state 65, the control system The control can return to the idle state 61 in response to the occurrence of a system failure or the selection of the “Disengage V2V” command from the V2V 45 control button by the operator.
    Figure 7 shows different functions for V2V control buttons 44, 45 with associated text messages in message boxes 46, 47 for different events or control states during the engagement of V2V operation. The engagement of the V2V operation starts at A with the V2V control button 44 showing “Engage V2V”. If the “Engage V2V” command is selected by the combined operator, a V2V control configuration command is sent from the combined V2V to the V2V tractor. When the V2V control configuration command is received, the operation proceeds to B with message box 47 displaying “Accept V2V control from combined ” and the V2V 45 control button showing “Accept V2V”. In addition, when the V2V control configuration command is sent, the operation also proceeds to C with message box 46 showing “Wait for V2V configuration”. If the “Accept V2V” command is selected by the tractor operator, a V2V control configuration response is sent from the V2V tractor to the combined V2V.
    In an exemplary embodiment, the V2V control configuration command message may include the following information: main row, type of row, active row, row width, offset of the combined communication tube and
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    11/22 displacement of the pipe or discharge pipe position. The V2V control configuration response message is confirmation from the V2V tractor in response to a V2V control configuration command. If a V2V control configuration is successful by the V2V tractor, a positive confirmation along with data about the current V2V control configuration for the V2V tractor is sent. If a V2V control configuration is not successful, a negative acknowledgment is sent.
    When the V2V control configuration response is received and the necessary initialization steps have been completed, the combined V2V operation proceeds to E with message box 46 showing “V2V engaged” and the V2V control button 44 10 showing "Disengage V2V". In addition, when the V2V control configuration response is sent, operation of the V2V tractor continues to D with message box 47 displaying “Wait for V2V configuration”. After the V2V operation has been engaged in the combined V2V, an active row command can be sent to the V2V tractor and the operation can proceed to F with message box 47 showing “V2V engaged” and the control button V2V 45 displaying “Disengage V2V”. After the V2V operation has been engaged on the V2V tractor, a response from the active row can be sent to the combined V2V.
    In an exemplary mode, the command message of the V2V active row can include the following data: active row, row pruning distance and row distance 20. The command message of the active V2V row can be sent once every time step when the V2V control is engaged. The V2V row response message is a confirmation from the V2V tractor in response to the V2V row row command message.
    In an exemplary mode, the V2V control buttons 44, 45 can have multiple functions25 depending on the V2V machine and the V2V status during operation. In the idle state, the combined V2V control button function can be “Engage V2V” to initiate a V2V control. After the V2V tractor receives a V2V control configuration command from the combined V2V, the tractor's V2V control button function can be “Accept V2V” for the V2V tractor operator to accept a V2V 30 control by combined V2V. In the engaged state, the function of the V2V control button is changed to “Disengage V2V” to end the V2V control. In another exemplary modality, in the engaged state, a manual steering operation of the V2V tractor also ends the V2V control.
    In an exemplary mode, after the combined V2V and V2V 35 tractor are in the engaged state, the “Ready for unloading” alert message is displayed in message boxes 48, 49 when the required V2V side distance and the longitudinal distances are both satisfied within the error limits. Otherwise, a message from
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    12/22 “Discharge not ready” is displayed in message boxes 48, 49. For manual control of the V2V combined discharge tube swing and discharge auger coupling / disengagement, the discharge condition messages in the message 48 provide notification to the combined operator to assist the operator with regulation associated with the performance of manual operations to prevent loss of crop material. For automatic control of the balance of the combined discharge tube and / or automatic control of the coupling / disengagement of the discharge auger, the control signal that generates the discharge condition messages can also trigger the automatic actions of the tube and / or auger. discharge. For the V2V tractor operator, the discharge condition messages are for information only and no action is taken. In an exemplary embodiment, the combined GPS position message can be sent from the combined V2V to the V2V tractor to calculate the actual lateral and longitudinal distance between the combined V2V and the V2V tractor.
    Figure 8 shows a control process for the idle control state of the combination of figure 6A. The combined control idle state 60 can receive information about the quality of the GPS signal and the tractor's V2V heartbeat message as V2V preconditions and can enable or disable the V2V control button 44 based on this information or based at the operator control input on the V2V 44 control button.
    The process for the combined idle control status begins by checking information about V2V precondition parameters, for example, the GPS signal quality and the tractor's V2V heartbeat message, to see if the necessary preconditions V2V are satisfied to allow V2V operation and update a V2V icon from the combined V2V 40 user interface (step 800). The V2V icon (not shown in figure 4A) can be, but is not limited to, a box with a text “V2V” on it and with a green background when the necessary V2V preconditions are met or the V2V icon can be a box with an “X” covering the V2V text and with a red background when the necessary V2V preconditions are not met. Next, a process decision is made based on whether the necessary V2V preconditions are satisfied to allow V2V operation (step 802). If the V2V preconditions are not met, the text message box 46 is cleared and the V2V control button 44 is disabled (step 804) and the process ends. Alternatively, if the V2V preconditions are satisfied, a determination is made as to whether the V2V control button 44 is active and displaying “Engage V2V” (step 806). If the V2V 44 control button is not active, the V2V 44 control button is activated and displays “Engage V2V” (step 808) and the process ends. Alternatively, if the V2V 44 control button is active, a determination is made as to whether the V2V 44 control button was pressed or selected (step 810). If the V2V 44 control button was not pressed or selected, the process ends. Alternatively, if the control button
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    13/22 of V2V 44 was pressed or selected, text message box 46 is updated to display “Wait for V2V configuration” and the V2V control button 44 showing “Engage V2V” is disabled (step 812). Then, the combined control configuration control state is started and the control configuration timer is reset (step 814) and 5 the process ends.
    Figure 9 shows a control process for the control configuration control state of figure 6A. For the combined control configuration control state 62, a V2V control configuration timer is reset at the end of the combined control idle state 60 and the range of the V2V control configuration 10 can be set to a value of predetermined time, for example, 15 seconds.
    The process for the combined control configuration control state begins by determining whether a V2V control configuration response message was received from the V2V tractor (step 900). If the V2V control configuration response message has not been received, a determination is made as to whether the V2V control configuration timer has expired (step 902). If the V2V control configuration timer has not expired, a V2V control configuration command message is sent to the V2V tractor (step 914) and the process ends. In an exemplary embodiment, the V2V control configuration command message may include one or more of the following: a unique identifier for the combined row (SUID) associated with the main row; career type; number of points in the main career; a starting point or first point for the main career curve; an end point or second point for the main career curve; observation distance; minimum curve radius; communication tube width; displacement of the communication tube; lateral displacement of the distal end of the discharge tube from the GPS position of the combined and longitudinal displacement of the distal end of the discharge tube from the GPS position of the combined.
    If the V2V control configuration timer has expired, text message box 46 is updated to “V2V configuration interval” (step 906) and the combined control idle state is engaged (step 910) and the process ends . If the V2V control configuration response message was received, a determination is made of 30 whether the V2V tractor configuration was successful and whether the V2V tractor configuration values agree with the combined configuration values of V2V (step 904). If the V2V tractor configuration was not successful and / or the V2V tractor configuration values do not agree with the combined V2V configuration values, the text message box 46 is updated to “V2V configuration failed” (step 908) and the combined control idle state 35 is started (step 910) and the process ends. Alternatively, if the V2V tractor configuration was successful and the V2V tractor configuration values agree with the combined V2V configuration values, the
    Petition 870180124732, of 9/3/2018, p. 31/44
    14/22 text message 46 is updated to display “V2V engaged” and the V2V control button 44 is activated and displays “Disengage V2V” (step 912). Then, the combined control state is started and the V2V engaged timer is restored (step 916) and the process ends.
    Figure 10 shows a control process for the engaged control state of the combination of figure 6A. In the combined control state of the combined 64, a V2V engaged timer is reset at the end of the combined control configuration control state. In addition, the very low quality interval of the GPS, the pulse message interval and the response message interval of the active V2V row can each be set to the same time value as the engaged V2V timer, for example , 1 second or they can be individually assigned with different time values. In addition, for the combined control state of the combined 64, the GPS quality must be at least Omnistar HP / XP (10 cm) or higher to engage V2V.
    The process for the combined control state of the combination begins by determining whether the GPS very low quality interval has expired (step 1000). If the very low GPS quality interval has expired, text message box 46 is updated to display “Very low GPS quality” (step 1002), the V2V control button 44 showing “Disengage V2V” is disabled (step 1024) and the combined control idle state is started (step 1030) and the process ends. Alternatively, if the very low quality GPS interval has not expired, a determination is made as to whether the tractor's V2V pulse message interval has expired (step 1004). If the tractor's V2V heartbeat message interval has expired, text message box 46 is updated to display “Loss of V2V communication” (step 1008), the V2V control button 44 displaying “Disengage V2V” is disabled (step 1024) and the combined control idle state is started (step 1030) and the process ends. Alternatively, if the tractor's V2V pulse message interval has not expired, a determination is made as to whether the V2V active row response message was received from the V2V tractor (step 1006).
    If the V2V active response message has not been received, a determination is made as to whether the V2V active response message interval has expired (step 1010). If the V2V active career response message interval has expired, text message box 46 is updated to display “Active career failure” (step 1016), the V2V control button 44 displaying “Disengage V2V” is disabled (step 1024) and the combined control idle state is started (step 1030) and the process ends. Alternatively, if the V2V active career response message interval has not expired, a determination is made as to whether the V2V control button 44 showing “Disengage V2V” has been pressed or selected (step 1014).
    If the response message from the active V2V career has been received, a
    Petition 870180124732, of 9/3/2018, p. 32/44
    15/22 determination of whether the response message was confirmed by the combined V2V (step 1012). If the reply message has not been confirmed, the text message box 46 is updated to display “Active row failure” (step 1016), the V2V control button 44 showing “Disengage V2V” is disabled (step 1024) and the combined control idle state is initiated (step 1030) and the process ends. Alternatively, if the response message has been confirmed, a determination is made as to whether the V2V control button 44 showing “Disengage V2V” has been pressed or selected (step 1014).
    If the V2V control button 44 showing “Disengage V2V” was pressed or selected, the text message box 46 is updated to display “V2V disengaged” (step 1020), the V2V control button 44 showing “Disengage V2V” is deactivated (step 1024) and the combined control idle state is started (step 1030) and the process ends. Alternatively, if the V2V control button 44 showing “Disengage V2V” was not pressed or selected, a determination is made as to whether “Disengage V2V” was selected on the V2V tractor (step 1018).
    If “Disengage V2V” was selected on the V2V tractor, the text message box 46 is updated to display “V2V disengaged” (step 1020), the V2V control button 44 displaying “Disengage V2V” is disabled (step 1024) and the combined control idle state is initiated (step 1030) and the process ends. Alternatively, if “Disengage V2V” was not selected on the V2V tractor, a determination is made as to whether the main row of the combined has been changed (step 1022). If the main row of the combined has not changed, a V2V active row command message is sent to the V2V tractor (step 1026) and the process ends. Alternatively, if the main career of the combined has changed, the text message box 46 can be updated to display “Wait for V2V configuration”, the V2V control button 44 showing “Disengage V2V” is disabled, the control status of the configuration control unit starts and the control setting timer is reset (step 1028) and the process ends.
    Figure 11 shows a control process for the tractor idle control status of figure 6B. The idle control status of the tractor 61 can receive information about the quality of the GPS signal and the combined V2V heartbeat message as V2V preconditions and can enable or disable the multifunctional V2V control button 45 based on this information or based on the operator control input on the V2V 45 control button.
    The process begins by checking information about V2V precondition parameters, for example, GPS signal quality and V2V heartbeat message from the combined, to see if the required V2V preconditions are satisfied to allow V2V operation , and update a V2V icon from the V2V 41 tractor user interface (step 1100). The V2V icon (not shown in figure 4B) can be, but is not limited to, a box
    Petition 870180124732, of 9/3/2018, p. 33/44
    16/22 with the text “V2V” on it and with a green background when the necessary V2V preconditions are satisfied and the V2V icon can be a box with an “X” covering the V2V text and with a red background when the pre -V2V required conditions are not met. Next, a process decision is made based on whether the necessary V2V preconditions are satisfied to allow V2V operation (step 1102). If the V2V preconditions are not met, the text message box 47 is cleared and the V2V control button 45 showing “Accept V2V” is disabled (step 1112) and the process ends. Alternatively, if the V2V preconditions are met, a determination is made as to whether the V2V 45 control button is active and displaying “Accept V2V” (step 1104). If the V2V 45 control button 10 showing “Accept V2V” is not active, a determination is made as to whether the V2V control configuration command message was received from the combined V2V (step 1110). If the V2V control configuration command message was not received, the process ends. Alternatively, if the V2V control configuration command message was received, text box 47 is updated to display “Accept 15 V2V control” and the V2V 45 control button is activated and displays “Accept V2V” (step 1114) and the process ends. If the V2V 45 control button showing “Accept V2V” is active, a determination is made as to whether the V2V 45 control button showing “Accept V2V” was pressed or selected (step 1106). If the V2V 45 control button has not been pressed or selected, a determination is made as to whether the V2V combination is in the combined control configuration control state (step 1108). If the V2V combination is in the control configuration configuration control state, the process ends. Alternatively, if the combined V2V is not in the combined control configuration control state, the text message box 47 is cleared and the control button
    V2V 45 is deactivated (step 1112) and the process ends. If the V2V 45 control button was pressed or selected, the text message box 47 is updated to display “Wait for V2V configuration” and the V2V 45 control button showing “Accept V2V” is disabled (step 1116) . Then, the tractor control configuration control state is initiated and the V2V control configuration timer is restored (step 1118) and the process ends.
    Figure 12 shows a control process for the control configuration control status of the tractor of figure 6B. For the tractor control configuration control state 63, a V2V control configuration timer is reset at the end of the tractor's idle control state and the V2V control configuration interval can be set to a certain time value , such as 15 seconds.
    The process for the tractor control configuration control state begins by determining whether a V2V control configuration command message was received from the combined V2V (step 1200). If the command configuration message
    Petition 870180124732, of 9/3/2018, p. 34/44
    17/22 V2V control has not been received, a determination is made as to whether the combined V2V is in an engaged control state of the combined (step 1204). If the V2V combination is in an engaged control state of the combined, the text message box 47 is updated to display “V2V engaged” and the V2V control button 45 is activated and displays 5 “Disengage V2V” (step 1218 ). Then, the tractor's engaged control state is initiated and the V2V engaged timer is restored (step 1224) and the process ends. Alternatively, if the combined V2V is not in an engaged control state of the combined, a determination is made as to whether the V2V control configuration timer has expired (step 1208). If the V2V control setting timer has not expired, process 10 ends. Alternatively, if the V2V control configuration timer has expired, text message box 47 is updated to “V2V configuration interval” (step 1214) and the tractor idle control state is engaged (step 1222) and the process ends.
    If the V2V control configuration command message was received, a determination is made as to whether the type of row to be configured is a straight LR line (step 15 1202). If the type of row to be configured is not an LR straight line, a determination is made as to whether the V2V tractor has the main row recorded to be configured (step 1206). If the V2V tractor does not have the main row recorded to be configured, the text message box 47 is updated to “V2V configuration failed” (step 1210), a V2V control response message is sent to the combined V2V indicating that the V2V tractor configuration state has failed (step 1220) and the tractor idle control state is started (step 1222) and the process ends. If the row type to be configured is a straight LR line or if the V2V tractor has the main row recorded to be configured, the V2V tractor is configured for V2V control based on the V2V control configuration command ( step 1212). Then, a V2V control response message is sent to the combined V2V indicating that the configuration status of the V2V tractor is successful (step 1216) and the process ends. The tractor's V2V control configuration (step 1212) can include a determination of an adjusted tractor row and, if necessary, a determination of a TTT tractor transition path.
    Figure 13 shows a control process for the engaged control state of the tractor of figure 6B. In the tractor 65 engaged state, a V2V engaged timer is reset at the end of the tractor control configuration control state. In addition, the very low quality interval of the GPS, the pulse message interval and the command message interval of the active V2V row can each be set to the same time value as the engaged V2V timer, for example , 1 second 35 or they can be individually assigned with different time values. In addition, for the tractor's engaged control state 65, the GPS quality must be at least Omnistar HP / XP (10 cm) or higher to engage V2V.
    Petition 870180124732, of 9/3/2018, p. 35/44
    18/22
    The process for the tractor's engaged control state begins by determining whether the GPS very low quality interval has expired (step 1300). If the GPS very low quality interval has expired, the text message box 47 is updated to display “GPS very low quality” (step 1304), the V2V 45 control button displaying “Disengage 5 V2V” is disabled, the automatic guidance system of the V2V tractor is disengaged and the idle control state on the tractor is initiated (step 1328) and the process ends. Alternatively, if the very low quality GPS interval has not expired, a determination is made as to whether the combined V2V heartbeat message interval has expired (step 1302). If the combined V2V heartbeat message interval has expired, the text message box 47 is updated to display “Loss of V2V communication” (step 1308), the V2V control button 45 displaying “Disengage V2V” is deactivated, the V2V tractor automatic guidance system is disengaged and the tractor idle control status is initiated (step 1328) and the process ends. Alternatively, if the combined V2V heartbeat message interval has not expired, a determination is made as to whether the V2V active row command message was received from the combined V2V (step 1306).
    If the V2V row command message has not been received, a determination is made as to whether the V2V row command message interval has expired (step 1310). If the V2V active career reply message interval has expired, text message box 47 is updated to display “Active career interval” (step 20 1314), the V2V 45 control button displaying “Disengage V2V” is deactivated, the automatic guidance system of the V2V tractor is disengaged and the tractor idle control state is initiated (step 1328) and the process ends. Alternatively, if the V2V active row command message interval has not expired or if the V2V active row command message has been received, a determination is made as to whether the V2V 45 25 control button displaying “Disengage V2V” has been pressed or selected (step 1312).
    If the V2V 45 control button showing “Disengage V2V” was pressed or selected, the text message box 47 is updated to display “V2V disengaged” (step 1322), the V2V 45 control button showing “Disengage V2V” is deactivated, the automatic V2V tractor guidance system is disengaged and the tractor idle control state 30 is initiated (step 1328) and the process ends. Alternatively, if the V2V 45 control button showing “Disengage V2V” has not been pressed or selected, a determination is made as to whether “Disengage V2V” was selected in the combined V2V (step 1316). If “Disengage V2V” was selected in the combined V2V, the text message box 47 is updated to display “V2V disengaged” (step 1322), the V2V control button 35 showing “Disengage V2V” is disabled, the system automatic guidance of the V2V tractor is disengaged and the tractor idle control state is initiated (step 1328) and the process ends.
    Petition 870180124732, of 9/3/2018, p. 36/44
    19/22
    Alternatively, if “Disengage V2V” was not selected in the combined V2V, a determination is made as to whether the oblique track error of the combined V2V is above a predefined limit (step 1318). If the V2V combined oblique track error is not above a predefined limit, a determination is made as to whether the V2V combined is in the combined control state (step 1320). If the V2V combination is not in the combined control state of the combination or the V2V combination oblique track error is above a predefined limit, the text message box 47 is updated to display “V2V disengaged” (step 1322) , the V2V 45 control button showing “Disengage V2V” is deactivated, the automatic guidance system of the V2V tractor is disengaged and the tractor idle control state is initiated (step 1328) and the process ends. If the combined V2V is in the combined control state of the combined, an automatic steering control of the V2V tractor is engaged or remains engaged to follow a transition path of the V2V TTT tractor if the tractor is distant from the combined or to follow a adjusted V2V career (step 1324). Then, a response message from the active V2V career is sent to the combined V2V (step 1326) and the process ends.
    In one embodiment, the messages displayed in the text message box 46 during the processes in figures 8-10 can be displayed, additionally or alternatively, in the text message box 42. In another embodiment, the messages displayed in the message box 42 text 47 during the processes of figures 11-13 can be displayed, additionally or alternatively, in the text message box 43.
    Figures 14A and 14B show different transition paths of the V2V tractor under the control of automatic V2V guidance. At the time of engaging the automatic V2V guidance control, if the V2V tractor is too far from the combined V2V or the travel difference between the combined V2V and the V2V tractor is greater than approximately 90 degrees, a trajectory of TTT tractor transition can be used to guide the V2V tractor to an appropriate position and course (or direction) for automatic guidance of the V2V tractor on the tractor's adjusted row. A TTT tractor transition path is generated and the coordinates of the path points are sent to the V2V tractor navigation controller. The V2V tractor navigation controller can then automatically steer the V2V tractor on the TTT tractor's transition path to the tractor's set row. The transition path of the TTT tractor can be time-dependent that includes a time variable, or time-independent.
    The generation of the TTT tractor transition path takes into account the adjusted tractor career (TAS), the combined V2V position, travel and speed, the V2V tractor position, travel and speed and the minimum curve radius of the V2V tractor. In one mode, the V2V tractor approaching the combined V2V on the TTT transition path can be operated at a higher rate of speed than the combined V2V. A transition path from
    Petition 870180124732, of 9/3/2018, p. 37/44
    20/22 TTT tractor can be, but is not limited to, a straight LR line plus an AC arc. The straight LR line can be aligned with a current tractor stroke. The AC arc can be tangent to both this straight line LR and TAS, and have a radius that is greater than the minimum curve radius of the V2V tractor. After a radius of the arc AC is selected, such as a radius that is 20% larger than the minimum curve radius, the transition path of the TTT tractor can be calculated simply in the case of a straight TAS, as shown in the figure 14B.
    In the case of a curved TAS as shown in figure 14A, an approximation of the straight LR line to a curved TAS section can be used as a linearized TAS section for the purpose of generating the TTT transition path. The linearized section of the 10 TAS can be behind, near or in front of the current location of the combined V2V. In an exemplary modality, to avoid the risk of equipment collision when the V2V tractor approaches the combined V2V, a linearized section of the TAS behind the combined can be used for purposes of generating the transition path.
    In an exemplary mode, wireless communications between the combined V2V 15 and the V2V tractor can be messages from the controller area network (CAN). Some examples of CAN messages include: combined V2V heartbeat, tractor V2V heartbeat, V2V control configuration command, V2V control configuration response, V2V active row command, V2V active row response and GPS position of the combined.
    In another exemplary modality, WCUs can include a manual power switch to control the power supply to the WCU and thus enable / disable V2V control. An operator of the equipment can turn off the WCU using the switch if the operator does not foresee a V2V operation during the day and does not wish to receive any alerts and messages related to V2V. A relay switch can be an alternative to the manual power switch. An operator presses an enable / disable button on the display unit and an electronic controller adjusts the on / off position of the relay switch in response to operator input to turn the WCU on / off. In another embodiment, the V2V unit can be a controller of the tractor's longitudinal position.
    In an exemplary embodiment, the V2V and 30 combined V2V tractor heartbeat messages can include information on the operational status of the V2V automatic guidance control system including the V2V status, GPS quality, steering mode , etc.
    In an exemplary embodiment, the bell can generate an audible sound, such as a beep whenever the wireless communication state changes or the discharge condition 35 changes. The bell can be included within the corresponding display unit.
    It should be understood that the application is not limited to the details or methodology presented in the following description or illustrated in the figures. It should also be understood that the
    Petition 870180124732, of 9/3/2018, p. 38/44
    21/22 phraseology and terminology used here are for the purpose of description only and should not be considered as limiting.
    The present application considers methods, systems and program products in any machine-readable means to carry out its operations. The modalities of the present application can be performed using existing computer processors or by a special use computer processor for an appropriate system or by a physically connected system.
    Modalities within the scope of the present application include program products comprising machine-readable means for transporting or having machine-executable instructions or the data structures stored therein. Machine-readable media can be any non-transitory media available that can be accessed by a computer or other special-purpose or general-purpose machine with a processor. For example, machine-readable media may include RAM, ROM, EPROM, EEPROM, CD-ROM or other optical disk storage, magnetic disk storage or other magnetic storage devices or any other medium that can be used to transport or store desired program code in the form of machine executable instructions or data structures and can be accessed by a computer or other special purpose or general purpose machine with a processor. When information is transferred or provided over a network or other communications connection (by physical, wireless or a combination of physical or wireless connection) to a machine, the machine appropriately views the connection as a machine-readable medium. Combinations of the above are also included within the scope of machine-readable media. Machine-executable instructions comprise, for example, instructions and data that make a general-purpose computer, special-purpose computer, or special-purpose processing machines perform a particular function or group of functions.
    Although the figures here may show a specific order of the method steps, the order of the steps may differ from what is represented. Also, two or more steps can be performed simultaneously or with partial concomitance. Variations in step performance may depend on the software and hardware systems chosen and the designer's choice. All such variations are within the scope of the order. Likewise, software implementations could be performed using standard programming techniques with rules-based logic and other logic to perform the various connection steps, processing steps, comparison steps and decision steps.
    In further consideration of the drawings in that application and in the discussion of such drawings and the elements shown in them, it should also be understood and verified that, for the sake of clarity in the drawings, pluralities of generally similar elements positioned close to each other or extended along some distance can some
    Petition 870180124732, of 9/3/2018, p. 39/44
    22/22 times, if not often, be represented as one or more representative elements with extended dashed lines indicating the general extent of such similar elements. In such cases, the various elements thus represented can generally be considered to be generally as the representative element described and generally operable in a similar manner and for a similar purpose as the representative element described.
    Many of the fastening or connection processes and components used in the order are widely known and used and their exact nature or type is not necessary for an understanding of the order by a person skilled in the art. Also, any reference 10 here to the terms "left" or "right" is used as a matter of mere coincidence, and is determined by the position at the rear of the machine facing in its normal direction of movement.
    Petition 870180124732, of 9/3/2018, p. 40/44
    1/3
    权利要求:
    Claims (7)
    [1]
    1. Method of controlling a transport vehicle (20) to place the transport vehicle (20) in alignment with a combine (10) for the unloading operation in motion, the CHARACTERIZED method by the steps of:
    5 determine a position for the transport vehicle (20), determine an active career for the harvester (10), calculate an adjusted career for the transport vehicle (20) based on the active career for the harvester (10), calculate a trajectory for the transport vehicle (20) to travel from the determined position of the transport vehicle (20) to the adjusted row, the trajectory including a straight line component and an arc component, the arc component being tangent to both the component straight line and adjusted row and control the transport vehicle (20) to follow the calculated path with commands from a controller.
    2. Method, according to claim 1, CHARACTERIZED by the fact that calculating a path for the transport vehicle (20) includes calculating a radius for the arc component, the radius calculated for the arc component being greater than a minimum turning radius for the transport vehicle (20).
    3. Method, according to claim 2, CHARACTERIZED by the fact that the
    The radius calculated for the arc component is at least 20% greater than the minimum curve radius for the transport vehicle (20).
    4. Method according to any one of claims 1 to 3, CHARACTERIZED by the fact that calculating a trajectory for the transport vehicle (20) includes determining an approximation of the straight line to an adjusted row section, the
    25 arc point being tangent to the approach of the straight line.
    5. Method, according to claim 4, CHARACTERIZED by the fact that the approach of the straight line is located behind a current position of the harvester (10).
    6. Method, according to any preceding claim, CHARACTERIZED by the fact that calculating a trajectory for the transport vehicle (20) includes aligning the component
    30 straight line component with a stroke for the transport vehicle (20).
    7. Method, according to any preceding claim, still CHARACTERIZED by the fact that it transmits the active career to the transport vehicle (20) in a message from the reaper (10).
    8. Method, according to any preceding claim, still
    35 CHARACTERIZED by the fact that it starts the unloading operation in motion between the transport vehicle (20) and the harvester (10) in response to the transport vehicle (20) following the calculated trajectory and moving in the adjusted row.
    Petition 870180124732, of 9/3/2018, p. 16/44
    [2]
    2/3
    9. Method, according to claim 8, CHARACTERIZED by the fact that the adjusted career is substantially parallel to the active career.
    10. Method, according to any preceding claim, further CHARACTERIZED by determining whether the transport vehicle (20) and the harvester (10) are within the wireless communication range and in which to determine a position for the transport vehicle (20), determine an active career for the harvester (10), calculate an adjusted career for the transport vehicle (20), calculate a trajectory for the transport vehicle (20) and control the transport vehicle (20) to follow the calculated trajectory are executed in response to the transport vehicle (20) and harvester (10) being within the range of wireless communication.
    11. Control system to synchronize the control of a combine harvester (10) and a transport vehicle (20), the control system FEATURED by:
    a harvester control system comprising:
    a first device of the global positioning system (14) to determine a harvester position (10), a first controller (12) to control the operation of the harvester (10), the first controller (12) comprising a first microprocessor to perform a computer program to determine an active career for the harvester (10) using the harvester position (10) of the first device of the global positioning system (14) and using information related to a recorded main career and a career width reaper and a first communication device (16), a transport vehicle control system comprising:
    a second device of the global positioning system (24) for determining a position of a transport vehicle (20), a second controller (22) for controlling the operation of the transport vehicle (20), the second controller (22) comprising a second microprocessor to run a computer program to determine an adjusted career for the transport vehicle (20) based on the active career and a second communication device (26), the second communication device being configured and positioned to exchange information in a mode wirelessly with the first communication device (16), the second controller (22) calculates a path for the transport vehicle (20) based on the position of the transport vehicle (20) of the second device of the global positioning system (24 ), the determined set career and the first communication device (16) and the second communication device (26) being within the wireless communication range with a program computer controller run by the second microprocessor
    Petition 870180124732, of 9/3/2018, p. 17/44
    [3]
    3/3 and
    the second controller (22) transmits a control signal to control the transport vehicle (20) to follow the trajectory calculated with a computer program executed by the second microprocessor.
    [4]
    5 12. Control system, according to claim 11, CHARACTERIZED by the fact that the calculated path includes a straight line component and an arc component, the arc component being tangent to both the straight line component and the row adjusted.
    13. Control system, according to claim 12, CHARACTERIZED by
    [5]
    10 the fact that the arc component has a radius, the radius of the arc component being greater than a minimum curve radius for the transport vehicle (20).
    [6]
    14. Control system, according to claim 13, CHARACTERIZED by the fact that the radius for the arc component is at least 20% greater than the radius of the curve for the transport vehicle (20).
    [7]
    15. Control system, according to claim 12, CHARACTERIZED by the fact that the straight line component is aligned with the course for the transport vehicle (20).
    Petition 870180124732, of 9/3/2018, p. 18/44
    1/11
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    同族专利:
    公开号 | 公开日
    BR112013021136A2|2016-08-23|
    US8606454B2|2013-12-10|
    US20120215381A1|2012-08-23|
    EP2675264A1|2013-12-25|
    WO2012110545A1|2012-08-23|
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    法律状态:
    2018-02-20| B25D| Requested change of name of applicant approved|Owner name: CNH INDUSTRIAL AMERICA LLC (US) |
    2018-06-05| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]|
    2018-10-09| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2018-11-06| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 15/02/2012, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    US201161444464P| true| 2011-02-18|2011-02-18|
    US61/444.464|2011-02-18|
    US13/171.620|2011-06-29|
    US13/171,620|US8606454B2|2011-02-18|2011-06-29|System and method for synchronized control of a harvester and transport vehicle|
    PCT/EP2012/052568|WO2012110545A1|2011-02-18|2012-02-15|System and method for synchronized control of a harvester and transport vehicle|
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