A method and apparatus for cultivating vegetation at an inhospitable location includes rooting immature vegetation in a mat combined with a super absorbent polymer (“SAP”) and, in embodiments, fertilizer, sand, and/or soil; providing a water reservoir below grade at the inhospitable location; placing the mat at the inhospitable location over the water reservoir; extending at least one wick from the mat to the water reservoir; and covering the mat with a perforated, transparent or semi-transparent cover. The wick can be infused with nutrients and/or fertilizer. Hollow tubes can extend downward from the mat to enable excess water to flow into the reservoir. The hollow tubes can surround the wicks. The transparent cover can be placed on or suspended above the mat. SAP, seeds, and/or fertilizer can be placed between mats in a stack. A water distribution system can be included for supplying additional water to the water reservoir.

Technologies and techniques that reduce cost and time for propagation, transplantation and harvesting of Vetiver Grass for multiple applications. Tools, equipment, systems and processes to propagate, transplant and harvest Vetiver Grass that will promote the rapid implementation of sustainable, large-scale Vetiver plantations in wealthy and impoverished countries alike.

Technologies and techniques that reduce cost and time for propagation, transplantation and harvesting of Vetiver Grass for multiple applications. Tools, equipment, systems and processes to propagate, transplant and harvest Vetiver Grass that will promote the rapid implementation of sustainable, large-scale Vetiver plantations in wealthy and impoverished countries alike.

Provided is a seeder assembly for an aerial vehicle as shown and described. The distribution assembly includes a frame selectively attachable to an aerial vehicle and at least one distribution device attached to the frame. The distribution device having a body defining a cavity to receive a plurality of products and a barrel to discharge the plurality of products. A control device configured to communicate with the aerial vehicle and the distribution device to coordinate the timing that products are discharged and a spacing of a subsequent discharged product relative to the speed of the aerial vehicle. A system, method, and cartridge device associated with the distribution assembly are also contemplated by this disclosure.

Provided is a seeder assembly for an aerial vehicle as shown and described. The distribution assembly includes a frame selectively attachable to an aerial vehicle and at least one distribution device attached to the frame. The distribution device having a body defining a cavity to receive a plurality of products and a barrel to discharge the plurality of products. A control device configured to communicate with the aerial vehicle and the distribution device to coordinate the timing that products are discharged and a spacing of a subsequent discharged product relative to the speed of the aerial vehicle. A system, method, and cartridge device associated with the distribution assembly are also contemplated by this disclosure.

A system for calibrating load sensors installed on an agricultural implement. The system includes a load sensor provided in operative association with a ground engaging tool and configured to capture load data indicative of a load applied to the ground-engaging tool. The system also includes a controller communicatively coupled to the load sensor configured to determine first and second load values based on the load data received from the load sensor when the down force actuator is disposed at first and second actuator positions so as to apply first and second down forces, respectively, against the ground engaging tool. The controller is also configured to determine a relationship between the first and second load values and corresponding force values associated with the first down force and the second down force.

A system for calibrating load sensors installed on an agricultural implement. The system includes a load sensor provided in operative association with a ground engaging tool and configured to capture load data indicative of a load applied to the ground-engaging tool. The system also includes a controller communicatively coupled to the load sensor configured to determine first and second load values based on the load data received from the load sensor when the down force actuator is disposed at first and second actuator positions so as to apply first and second down forces, respectively, against the ground engaging tool. The controller is also configured to determine a relationship between the first and second load values and corresponding force values associated with the first down force and the second down force.

The present invention provides biodegradable projectiles for toy launchers that contain viable seeds. When lost outdoors the projectiles do not pollute the environment but instead degrade naturally and the seeds grow into plants that enhance the landscape.

The present invention provides biodegradable projectiles for toy launchers that contain viable seeds. When lost outdoors the projectiles do not pollute the environment but instead degrade naturally and the seeds grow into plants that enhance the landscape.

A farm lease system and a lease management method that enables a user to lease a farmable area to grow a crop. The farm lease system includes a leasing unit (10) and a management and control unit (20). The leasing unit (10) includes a planting selection module (12), the planting selection module (12) can offer and allow selection of the type or types of the crop. The management and control unit (20) matches and controls growth of the crop according to the selected result of the planting selection module.