Abstract: Disclosed is an aperture assembly for use with a subsurface ejection vessel that includes an electromagnet, a first dynamic aperture (309C), a second dynamic aperture, a hollow shaft injection drill bit (1711), a third dynamic aperture (807C), collar perforations (607B), and closed window apertures (907A, 907B, and 907C). The electromagnet actuates a closing of the first dynamic aperture (309C). The electromagnet actuates an opening of the second dynamic aperture. The third dynamic aperture (807C) dynamically opens when triggered by a first pre-determined depth achievement counting by the encoder (1605B) of the lead screw (1713) or distance traveled by a platform (505A) triggered by the limit switch (1707) that are communicated to the AI robot (1407C), the computer (1411C), and the PLC (1405C).

Abstract: Disclosed is a device for dispensing a plurality of constituent materials by one or more of weight, volume, flow, time interval, and depths through one or more actuated dispenser openings connected to one or more of a plurality of chambers and a plurality of vessels. The device includes a gate (411B); an actuator a physical gate (405B); one or more load cells (605A, 605B. and 713); an artificial intelligence (AI) robot (807C); a lens (905); a computer (811C); a programmable logic controller (PLC) (805C); an encoder (1005B); a limit switch (1209B); and a sensor. The gate (411B), the actuator a physical gate (405B); and the load cell (713) enable a sequential dispensing of one or more constituents at targeted depths via the AI robot (807C), the lens (905), the computer (811C), the PLC (805C); the encoder (1005B), the limit switch (1209B), and/the sensor.

Abstract: Disclosed is a hollow shaft injection drilling array (FIG. 4A) to enable sequential dispensing of a plurality of constituents at targeted depths. The hollow shaft injection drilling array (FIG. 4A) includes an artificial intelligence (AI) robot (1507C); a lens (1405); a computer (1511C); a programmable logic controller (PLC) (1505C); one or more encoders (1605B); one or more limit switches (1809B); a sensor; a plurality of hollow shaft drill bits (503); a plurality of guide rail(s) (917); a plurality of matching platforms comprising elastomers (903, and 909), and granite (905); and a plurality of lead screws (913). The elastomers (903, and 909), granite (905), and the lead screws (913) enable sequential dispensing of the constituents within a plurality of different targeted depths controlled via the AI robot (1507C), the lens (1405), the computer (1511C), the PLC (1505C), the encoder (1605B), the limit switch (1809B), and the sensor.

Abstract: Disclosed is a sub-surface injection system for subsurface blending and horizon creation. The sub-surface injection system includes wings (105B, 519A, 511C, 513C, 519C), partially actuated mixing wings (205B, 309A, 411C, 419C, 511A, 519A, 511B, 513B, and 521B), an electromagnet, AI robot (1107C), lens (1205), computer (1111C), a PLC (1105C), encoder (1305B), limit switch (1409B), and a GPS (1113C). The wings (105B) are actuated by the electromagnet. The wings (105B) include blades (911B, 913B, and 915B), the partially actuated mixing wings (513B) during descension and/or ascension, and industrial diamonds or blades to cut through sub-surface impediments. The wings (105B, 519A, 511C, 513C, 519C) are controlled by the AI robot (1107C), the lens (1205), the computer (1111C), the PLC (1105C), the encoder (1305B), the limit switch (1409B), and the sensor.

Abstract: Disclosed is 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) that 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.

Abstract: Disclosed is an apparatus for injecting a plurality of constituents by confining the constituents in one or more tubes. The apparatus includes an outer tube (1015D); a global positioning satellite (GPS) (1113C); a programmable logic controller (PLC) (1105C); an Artificial intelligence (AI) robot (1107C, and 1205); a computer (1111C); an encoder (1305B); a plurality of limit switches (1405, 1407, and 1409), and a spacer tube (1015D). The outer tube (1015D) includes a plurality of stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D). The stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) are stackable either in cylinder segments or polygonal shapes. Constituents confined therein or the stackable tubes (1003D, 1005D, 1007D, 1009D, 1011D, and 1013D) themselves may be ejected through apertures for injection purposes. Some constituent contents may be ejected vertically or laterally-through perforations in the tube wall sub-surface to enable constituent amendment or sequestration.

Abstract: Disclosed is an apparatus (100) for sub-surface injection of constituents of a slurry, wet mixture, and or gas in a phase of entrainment for controlled flow. The apparatus (100) includes a rotary union (113), a drilling assembly (403), hollow shaft injection drilling arrays (1003A), limit switches (1705, 1707, 1709), and encoders (1605B). The rotary union (113) facilitates the filling of the constituent in hollow shaft drilling bits (129) during a drilling process or before the drilling process via an opening and closing of a plurality of valves (111, 215, 505B, 805B, and 1107B). The constituents are capable of being injected through the rotary union, wherein the rotary union (113) is in concert with the valve (111) to dispense predefined quantities of constituents at a specific depth in a sequence of dispersal. The drilling assembly (403) is directed by a GPS (1413C) to control an X plane and Y-plane injection coordinates.

Abstract: Disclosed is a plunger mixer device (307B, 309B, 311B, and 313B) deployable within a hollow shaft injection drill bit system (305B). The plunger mixer device (307B, 309B, 311B, and 313B) includes a motor (313B), a piston (507D), and a plunger motor assembly (403C, 405C, 407C, 409C, 411C, 413C, and 415C). The motor (313B) is connected to a feeder auger tip. The piston (507D) is configured to be driven by the motor (313B). The piston (507D) is connected to a feeder auger (103C, 105A, 109B, and 205A). The plunger motor assembly (403C, 405C, 407C, 409C, 411C, 413C, and 415C) includes a stacked series of panels (503D, 505D, and 507D), and a plurality of motor shafts (311D). The stacked series of panels (503D, 505D, and 507D) has a plurality of ribbed panels (307D) with a rib locking feature. One of the stacked series of the panel (507C) is actuated by the motor (313B). The ribbed panels (303C) lock between each other when the ribbed panels (305D, 307B, 307D, and 309B) are spun into a fully formed deployment.

Abstract: A device and method for playing a card game where four game cards are selected. To win, a fifth, outcome card must have either a higher or lower value than any same suited game card.

Abstract: A method of processing toll-free calls in a wireless telephoning communication system by extracting and manipulating call data records.

Abstract: A device and method for playing a card game where four game cards are selected for each of a plurality of game hands. To win, a fifth, outcome card must have either a higher or lower value than any same suited game card for each hand.