Robotic platform and method for performing multiple functions in agricultural systems
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A01C-021/00
A01C-023/02
출원번호
US-0837786
(2013-03-15)
등록번호
US-9288938
(2016-03-22)
발명자
/ 주소
Cavender-Bares, Kent
Bares, Charles C.
출원인 / 주소
ROWBOT SYSTEMS LLC
대리인 / 주소
Patterson Thuente Pedersen, P.A.
인용정보
피인용 횟수 :
5인용 특허 :
86
초록▼
An autonomous vehicle platform system and method configured to perform various in-season management tasks, including selectively applying fertilizer, mapping growth zones and seeding cover crop within an agricultural field, while self-navigating between rows of planted crops and beneath the canopy o
An autonomous vehicle platform system and method configured to perform various in-season management tasks, including selectively applying fertilizer, mapping growth zones and seeding cover crop within an agricultural field, while self-navigating between rows of planted crops and beneath the canopy of the planted crops on the uneven terrain of an agricultural field, allowing for an ideal in-season application of fertilizer to occur once the planted crop is well established and growing rapidly, in an effort to limit the loss of fertilizer.
대표청구항▼
1. An autonomous vehicle platform system for selectively applying fertilizer in an agricultural field having adjacent rows of annual crops planted so as to provide a conventional annual crop row spacing between said adjacent rows of planted annual crops of not more than 36 inches, while self-navigat
1. An autonomous vehicle platform system for selectively applying fertilizer in an agricultural field having adjacent rows of annual crops planted so as to provide a conventional annual crop row spacing between said adjacent rows of planted annual crops of not more than 36 inches, while self-navigating entirely within the space between adjacent rows of planted annual crops, comprising: one or more unmanned, autonomous vehicle platforms, wherein each autonomous vehicle platform includes a base operably coupled to a plurality of ground engaging wheels, each autonomous vehicle platform having a first lateral side and a second lateral side, wherein the first and second lateral sides oppose one another and are separated by a distance defining the width of the autonomous vehicle platform, the width so dimensioned as to be receivable within said space between adjacent rows of planted annual crops as the autonomous vehicle platform transits along the space between adjacent rows of planted annual crops, wherein each autonomous vehicle platform is programmed with a self-direction program to autonomously navigate the autonomous vehicle platform between a pair of adjacent rows of annual crops, and to avoid other autonomous vehicle platforms, while selectively applying fertilizer within the agricultural field. 2. The autonomous vehicle platform system of claim 1, further comprising one or more refilling stations, wherein each autonomous vehicle platform is programmed to compare the status of autonomous vehicle platform criteria to a programmed threshold and to navigate to the refilling station for servicing based on said comparison. 3. The autonomous vehicle platform system of claim 1, wherein each autonomous vehicle platform includes a user interface configured to transmit data to a user of the autonomous vehicle platform, and further configured to receive command data from the user of the autonomous vehicle platform from a remote location for selectively overriding the self-direction program. 4. The autonomous vehicle platform system of claim 1, wherein fertilizer is applied to at least one of the space substantially between adjacent rows of planted annual crops, the space beyond adjacent rows of planted annual crops including the space between neighboring rows of planted annual crops, and a combination thereof. 5. The autonomous vehicle platform system of claim 4, wherein the fertilizer is applied using a spiked drum. 6. The autonomous vehicle platform system of claim 1, wherein the fertilizer is in a liquid form. 7. The autonomous vehicle platform system of claim 6, wherein the fertilizer is applied by spraying fertilizer into a cut made in the soil by a coulter. 8. The autonomous vehicle platform system of claim 1, wherein the fertilizer is applied proximate to the base of the planted annual crops. 9. The autonomous vehicle platform system of claim 1, wherein the fertilizer is in pellet form. 10. The autonomous vehicle platform system of claim 9, wherein the pellet is injected into the soil. 11. A method for fertilizing within an agricultural field having adjacent rows of annual crops planted so as to provide a conventional annual crop row spacing between said adjacent rows of planted annual crops of not more than 36-inches, with one or more autonomous vehicle platforms, comprising: positioning one or more refilling stations proximate to the agricultural field;delivering the one or more unmanned, autonomous vehicle platforms to the agricultural field, wherein each autonomous vehicle platform is programmed with a self-direction program;orienting the one or more autonomous vehicle platforms to the one or more refilling stations; andactivating the self-direction program of each autonomous vehicle platform to autonomously navigate the entire autonomous vehicle platform entirely within said space between the adjacent rows of planted annual crops, and to avoid other autonomous vehicle platforms, while selectively applying fertilizer within the agricultural field, and to compare the status of autonomous vehicle platform criteria to a programmed threshold and to navigate to the one or more refilling stations for servicing based on said comparison. 12. The method for fertilizing of claim 11, wherein the self-direction program can be selectively overridden remotely through a user interface for each autonomous vehicle platform. 13. The method for fertilizing of claim 11, wherein the self-direction program directs each autonomous vehicle platform to apply fertilizer substantially between the rows of planted annual crops in the agricultural field. 14. The method for fertilizing of claim 13, wherein the fertilizer is applied using a spiked drum. 15. The method for fertilizing of claim 11, wherein liquid fertilizer is sprayed into a cut made in the soil by a coulter. 16. The method for fertilizing of claim 11, wherein the fertilizer is applied proximate to the base of the planted annual crops. 17. The method for fertilizing of claim 11, wherein the fertilizer is in pellet form. 18. The method for fertilizing of claim 11, wherein the pellet is injected into the soil. 19. An unmanned, autonomous vehicle platform for selectively applying fertilizer to the soil of an agricultural field having adjacent rows of annual crops planted so as to provide a conventional annual crop row in between said adjacent rows of planted annual crop of not more than 36 inches, while self-navigating entirely within the space between adjacent rows of planted annual crops, comprising: a vehicle base having a first lateral side and a second lateral side, wherein the first and second lateral sides oppose one another and are separated by a distance defining the width of the autonomous vehicle platform, the width so dimensioned as to be insertable through said space between adjacent rows of planted annual crops as the autonomous vehicle platform transits along the space between adjacent rows of planted annual crops;a plurality of wheels;at least one powertrain fixedly coupled to the vehicle base and operably coupled to at least one of the plurality of wheels;a fertilization module;a navigation module communicatively coupled to a crop row locating mechanism for gauging the location of the autonomous vehicle platform with respect to each of said adjacent rows of planted annual crops as said autonomous vehicle platform transits along said space between adjacent rows of planted annual crops;a microprocessor in communication with the fertilization module and the navigation module, programmed with a self-direction program to autonomously navigate the autonomous vehicle platform while selectively applying fertilizer based in part on data communicated from the crop row locating mechanism; anda user interface in communication with the microprocessor, configured to transmit microprocessor data to a user of the autonomous vehicle platform, and further configured to receive command data from the user of the autonomous vehicle platform for selectively overriding the self-direction program.
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