A tilling apparatus and a method of tilling soils which includes the use of a rotational shaft having a number of cutter assemblies located at spaced apart locations on the shaft in which each cutter assembly has a multitude of blades which rotate as the rotary shaft rotates to form a plurality of spaced apart trenches having the same spacing as the spacing of the cutters, and a width caused by the width of the blades. As the blades dig the trench, the soil contacted by the blades is granulated and is tossed about by the spinning blades so that some soil falls back into the trench and some falls along the periphery of the trench to form rows of aerated granules which promote enhanced growth of plants or seeds in the trench and along the edge of the trench to improve the yield of pasture having the trenches. Various attachments can be provided on the tilling apparatus, either in front of or towards the rear of the spinning blades for different purposes, such as rippers, seeders, levellers, or similar. The advantage of the tilling apparatus is that the soil is formed into granules which are used to form an aerated array of soil granules having enhanced growing properties for plants.

A machine that allows for processing the plant as much as the area where the plant requires and makes the seed bed ready for planting at once and in a single process, for plants planted in the range of 45-70 cm, such as corn, cotton, beet, sunflower, and beans in agricultural areas.

A hollow shaft drill bit (1109) and a solid or hollow shaft auger (409B) or a solid or perforated hollow shaft flexible screw feeder auger (1107) includes a perforated hollow or solid shaft feeder auger (409B) or flexible screw feeder auger hollow with perforations or solid (1107), a hollow shaft drilling auger (1200), a flexible conveyor flight screws (1300), a second perforated hollow shaft feeder auger (603A), a PLC (1405C), an AI robot (1505), a computer (1411C), an encoder (1605B), limit switches (1707), a feeder auger tube conduit (1305A), and a feeder auger motor (905B). The solid or perforated hollow shaft flexible screw feeder auger (1207) is detachably attached to the hollow shaft drilling auger (1200) to receive vibration and torque that are dampened by a coupling or disc coupling (121B or 1213) between a platform and a gearbox interface. The flexible conveyor flight screws (1300) enable functions of the solid or a first perforated hollow shaft feeder auger (1303A) to continue despite receiving torque. The feeder auger tube conduit (1305A) includes a distinct tube (1303C) within a diameter of a feeder auger tube conduit (1305C). The feeder auger motor (905B) upon receiving a signal from the AI robot (1505), the computer (1411C), and the PLC (1405C) enable the ascension of the feeder auger motor (905B) in concert with the encoder (1605B) or limit switches (1707).

An aperture assembly for use with a subsurface ejection vessel includes an electromagnet, a first dynamic aperture, a second dynamic aperture, a hollow shaft injection drill bit, a third dynamic aperture, collar perforations, and closed window apertures. The electromagnet actuates a closing of the first dynamic aperture. The electromagnet actuates an opening of the second dynamic aperture. The third dynamic aperture dynamically opens when triggered by a first pre-determined depth achievement counting by the encoder of the lead screw or distance traveled by a platform (505A) triggered by the limit switch that are communicated to the AI robot, the computer, and the PLC. The third dynamic aperture dynamically opens when the camera lens has a second pre-determined depth penetration of the hollow shaft injection drill bit and that the limit switch information is communicated to the computer, or the PLC.

An ultra high-pressure liquid jet soil processing system of an agricultural implement is provided. The ultra high-pressure liquid jet soil processing system includes a frame, an ultra high pressure liquid pump disposed on the frame, a set of ultra high-pressure lines fluidly connected to the ultra high pressure liquid pump, and at least a first liquid jet soil implementation head and a second liquid jet soil implementation head fluidly connected to the ultra high pressure liquid pump via the set of ultra high-pressure lines. The first and second implementation heads are configured to condition soil for seed deposition by generating a plurality of trenches.