The present disclosure relates to an onion growing method, and more particularly, to an onion growing method that includes the steps of: (a) allowing onions to be dormant; (b) breaking the dormancy of the onions; (c) planting the onions of which dormancy is broken in a field; (d) growing the planted onions to produce a plurality of stems and bulbs divided from the respective onions; and (e) harvesting the plurality of stems and bulbs. According to the present disclosure, the onion growing method does not have any limitation in growth time unlike a conventional onion growing method, reduces a period of growth, and drastically increasing onion yield to raise a farmer's profits. Also, the onion growing method stably supplies onion stems and leaves, thereby providing various profits through onions.

A dispensing machine dispenses a material on a field. A blockage is detected, and an initial blockage location, where the blockage started, is identified. A blockage characterization system identifies characteristics of the blockage, and a control signal generator generates control signals based upon the detected blockage, and the characteristics of the blockage.

A dispensing machine dispenses a material on a field. A blockage is detected, and an initial blockage location, where the blockage started, is identified. A blockage characterization system identifies characteristics of the blockage, and a control signal generator generates control signals based upon the detected blockage, and the characteristics of the blockage.

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.

The present invention discloses a method for safe production of rice on soil mildly and moderately polluted by heavy metals. The method includes applying a passivator before transplanting rice seedlings to reduce activity of heavy metals in soil, and then spraying a foliar barrier from the peak tillering stage to the booting stage of rice and at the filling stage of rice; the passivator includes bentonite, gypsum powder, lime, a biochar, an iron-based biochar, a slow-release iron-based biochar, an iron-sulfur-silicon composite biochar, a heavy metal cadmium passivator and a cadmium-arsenic synchronous passivator for activating sulfur reducing bacteria in paddy soil; and the foliar barrier includes an acid silica sol, a selenium-silicon composite sol, a cerium composite silica sol, a ferrous modified selenium sol. The method can also include applying a nitrate nitrogen fertilizer at the seedling stage of rice, and/or applying a phosphorus potassium fertilizer at the tillering stage of rice.

A planting method for morels is disclosed, including the following steps of: (1) preparing spawns; (2) flipping the spawns; (3) managing the humidity; and (4) fruiting for harvesting. The planting method is simple, is easy to learn and promote, has a high yield, and requires few spawns, thereby reducing planting costs and product costs.

A directional garlic seed throwing mechanism includes a base, a rotating device, a vision sensor, a seed throwing guide plate, a seed guide pipe and a plurality of bulbil adjusting devices. The rotating device includes a rotating motor detachably connected to the base and a turntable connected to an output end of the rotating motor. The seed throwing guide plate is arranged on the turntable to enable garlic seeds of seed containing bowls to fall into the seed guide pipe. The seed guide pipe has an upper port right below the bulbil adjusting devices and arranged on the base. An even number of the bulbil adjusting devices are fixed on the turntable uniformly and symmetrically and include the seed containing bowls and bulbil direction control devices for driving the bowls to rotate 180 degrees.

Methods of characterizing distinct plant varieties involve planting the plant varieties in one or more field plots. Each field plot includes one or more crop rotation zones, one or more maturity zones within the rotation zones, one or more nitrogen exposure zones within the maturity zones, and one or more population zones. Methods further involve extracting growth data from the plant varieties after a growing period. Systems for characterizing distinct plant varieties include one or more field plots and a database configured to store growth data extracted from the plant varieties after a growing period.

A seed activation system includes a shattering layer applied to an outer surface of a seed. The shattering layer forms a water-resistant coating around the seed that prevents the seed from germinating. An activation mechanism for transmitting electromagnetic energy is provided such that the shattering layer is compromised to break the water-resistant coating. The seed is then able to receive water and germinate. A seed activation method includes applying a shattering layer to an outer surface of a seed. The shattering layer forms a water-resistant coating around the seed that prevents the seed from germinating. The method further includes planting the seed in a soil, selecting an activation time, and activating the seed at the activation time by transmitting electromagnetic energy into the soil such that the shattering layer is compromised thereby breaking the water-resistant coating. The seed is then able to receive water for germinating.