Abstract: Systems and methods for an atmospheric carbon dioxide removal system are disclosed herein. The system may include a carbon capture vessel including a container, one or more sorbent subcontainer, a sorbent material, and a heating element. The container may include a first outer sidewall and a first hollow interior. Each sorbent subcontainer may be disposed within the first hollow interior and may include a second outer sidewall defining a second hollow interior. The sorbent material may be disposed within the second hollow interior of each sorbent subcontainer. The heating element may be disposed within the container and around one or more sidewalls of a sorbent subcontainer. The heating element may be arranged to heat the sorbent material within the second hollow interior.

Abstract: Systems and methods for an atmospheric carbon dioxide removal system are disclosed herein. The system may include a carbon capture vessel including a container, one or more sorbent subcontainer, a sorbent material, and a heating element. The container may include a first outer sidewall and a first hollow interior. Each sorbent subcontainer may be disposed within the first hollow interior and may include a second outer sidewall defining a second hollow interior. The sorbent material may be disposed within the second hollow interior of each sorbent subcontainer. The heating element may be disposed within the container and around one or more sidewalls of a sorbent subcontainer. The heating element may be arranged to heat the sorbent material within the second hollow interior.

Abstract: A support structure for a rotary regenerative machine or rotary absorption machine (RAM), the support structure including an upper stator and a lower stator axially spaced apart from one another by a first segment of at least two pedestals, the first segment of each pedestal extending between the upper stator and the lower stator, and an upper rotor bearing housing mount disposed above a lower surface of the upper stator, the rotor bearing housing mount is attached to the upper stator by at least one radially extending bearing support structure, wherein a radially inner end of at least one of the radially extending bearing support structure is attached to the bearing housing mount and a radially outer end of the at least one radially extending bearing support structure is proximate a top portion of the first segment of each of the pedestals.

Abstract: Systems and methods for an atmospheric carbon dioxide removal system that includes a plurality of carbon capture containers, a plurality of fans, an air diverter, and a velocity stack. Each of the carbon capture containers has an outwardly facing side and an inwardly facing side with the inwardly facing side facing an enclosed space. The fans are disposed adjacent to the carbon capture containers. The fans are arranged to move air through the carbon capture containers in a first direction from the outwardly facing side into the enclosed space. The air diverter is disposed within the enclosed space and receives the air flowing in the first direction and redirects the air to flow in a second direction that is angled upwardly from the first direction. The velocity stack is disposed on top of the enclosed space and is configured to accelerate the flow of the air in the second direction.

Abstract: Systems and methods for an atmospheric carbon dioxide removal system that includes a plurality of carbon capture containers, a plurality of fans, an air diverter, and a velocity stack. Each of the carbon capture containers has an outwardly facing side and an inwardly facing side with the inwardly facing side facing an enclosed space. The fans are disposed adjacent to the carbon capture containers. The fans are arranged to move air through the carbon capture containers in a first direction from the outwardly facing side into the enclosed space. The air diverter is disposed within the enclosed space and receives the air flowing in the first direction and redirects the air to flow in a second direction that is angled upwardly from the first direction. The velocity stack is disposed on top of the enclosed space and is configured to accelerate the flow of the air in the second direction.

Abstract: A rim assembly for a non-pneumatic tire has at least two rim components including: a first rim component having a first rim flange and a first lip, and a second rim component having a second rim flange and a second lip. The rim assembly further includes a plurality of lateral rim component support structures configured to extend through a plurality of openings of a tire support structure. The rim assembly also includes a first plurality of fasteners securing the plurality of lateral rim component support structures to the first rim flange, and a second plurality of fasteners securing the plurality of lateral rim component support structures to the second rim flange.

Abstract: A support structure for a rotary regenerative machine or rotary absorption machine (RAM), the support structure including an upper stator and a lower stator axially spaced apart from one another by a first segment of at least two pedestals, the first segment of each pedestal extending between the upper stator and the lower stator, and an upper rotor bearing housing mount disposed above a lower surface of the upper stator, the rotor bearing housing mount is attached to the upper stator by at least one radially extending bearing support structure, wherein a radially inner end of at least one of the radially extending bearing support structure is attached to the bearing housing mount and a radially outer end of the at least one radially extending bearing support structure is proximate a top portion of the first segment of each of the pedestals.

Abstract: A shrimp processing method and system, the system comprising a plurality of clamps, wherein each clamp is configured to hold a shrimp proximate a tail of the shrimp, a plurality of processing stations comprising at least one data collection station capable of collecting data regarding a shrimp held in a clamp and at least one functional station capable of changing the shrimp held in a clamp, a conveying system connecting the plurality of processing stations, the conveying system configured to move the plurality of clamps between the processing stations, and a controller operably connected to the conveying system and the processing stations, the controller configured to operate the conveying system and to selectively activate each processing station.

Abstract: Systems and methods for an atmospheric carbon dioxide removal system that includes a plurality of carbon capture containers, a plurality of fans, an air diverter, and a velocity stack. Each of the carbon capture containers has an outwardly facing side and an inwardly facing side with the inwardly facing side facing an enclosed space. The fans are disposed adjacent to the carbon capture containers. The fans are arranged to move air through the carbon capture containers in a first direction from the outwardly facing side into the enclosed space. The air diverter is disposed within the enclosed space and receives the air flowing in the first direction and redirects the air to flow in a second direction that is angled upwardly from the first direction. The velocity stack is disposed on top of the enclosed space and is configured to accelerate the flow of the air in the second direction.

Abstract: Shrimp processing apparatus to peel shrimp along with methods for peeling shrimp are described herein. The shrimp processing apparatus may be provided in systems including one or more processing stations configured to peel individual shrimp, where peeling may involve removal of shell segments on the dorsal surfaces of the shrimp abdomen and/or removal of pleopods/swimmerets on the ventral surfaces of the shrimp abdomen and, optionally, separation of shell segments. The processing systems and methods may, in one or more embodiments, include apparatus for and methods of measuring the shrimp.

Abstract: A telemetry system is disclosed for use in a wellbore extending from the surface. The telemetry system includes fiber optic cable locatable in the wellbore, the fiber optic cable including at least one optical fiber. The telemetry system also includes a telemetry device operable to transmit an optical telemetry signal over the fiber optic cable. An optical detector operably connected to the optical fiber and includes a single-photon detector operable to receive the optical telemetry signal transmitted over the optical fiber.

Abstract: This invention relates to novel whitening agents for cellulosic substrates. The whitening agents are comprised of at least two components: at least one chromophore component and at least one polymeric component. Suitable chromophore components generally fluoresce blue, red, violet, or purple color when exposed to ultraviolet light, or they may absorb light to reflect these same shades. The whitening agents are further characterized by having a dispersion component value of the Hansen Solubility Parameter of less than or equal to about 17 MPa0.5. This invention also relates to laundry care compositions including but not limited to liquid and/or powder laundry detergent formulations and rinse added fabric softening (RAFS) compositions that comprise such whitening agents.

Abstract: Injection systems and methods of using the same are described herein. Each injection system may include one, two, or more needles, with each needle being configured to move needle between an injection position and a retracted position to deliver an inoculant. The injection needles may rotate about a carriage axis that extends through the injection axis along which each needle moves when moving between their injection and retracted positions. The injection needles in systems that include two or more injection needles may be advanced from the retracted position to the injection position at the same or different times.

Abstract: A rim assembly for a non-pneumatic tire has at least two rim components including: a first rim component having a first rim flange and a first lip, and a second rim component having a second rim flange and a second lip. The rim assembly further includes a plurality of lateral rim component support structures configured to extend through a plurality of openings of a tire support structure. The rim assembly also includes a first plurality of fasteners securing the plurality of lateral rim component support structures to the first rim flange, and a second plurality of fasteners securing the plurality of lateral rim component support structures to the second rim flange.

Abstract: A rim assembly for a non-pneumatic tire has at least two rim components including: a first rim component having a first rim flange and a first lip, and a second rim component having a second rim flange and a second lip. The rim assembly further includes a plurality of lateral rim component support structures configured to extend through a plurality of openings of a tire support structure. The rim assembly also includes a first plurality of fasteners securing the plurality of lateral rim component support structures to the first rim flange, and a second plurality of fasteners securing the plurality of lateral rim component support structures to the second rim flange.

Abstract: Injection systems and methods of using the same are described herein. Each injection system may include one, two, or more needles, with each needle being configured to move needle between an injection position and a retracted position to deliver an inoculant. The injection needles may rotate about a carriage axis that extends through the injection axis along which each needle moves when moving between their injection and retracted positions. The injection needles in systems that include two or more injection needles may be advanced from the retracted position to the injection position at the same or different times.

Abstract: A telemetry system is disclosed for use in a wellbore extending from the surface. The telemetry system includes fiber optic cable locatable in the wellbore, the fiber optic cable including at least one optical fiber. The telemetry system also includes a telemetry device operable to transmit an optical telemetry signal over the fiber optic cable. An optical detector operably connected to the optical fiber and includes a single-photon detector operable to receive the optical telemetry signal transmitted over the optical fiber.

Abstract: The invention includes embodiments of a system and method for managing a sales campaign. The system and methods disclosed herein are particularly useful in the context of an entity in the business of direct marketing and sales.

Abstract: A shrimp processing method and system, the system comprising a plurality of clamps, wherein each clamp is configured to hold a shrimp proximate a tail of the shrimp, a plurality of processing stations comprising at least one data collection station capable of collecting data regarding a shrimp held in a clamp and at least one functional station capable of changing the shrimp held in a clamp, a conveying system connecting the plurality of processing stations, the conveying system configured to move the plurality of clamps between the processing stations, and a controller operably connected to the conveying system and the processing stations, the controller configured to operate the conveying system and to selectively activate each processing station.

Abstract: Shrimp processing apparatus to peel shrimp along with methods for peeling shrimp are described herein. The shrimp processing apparatus may be provided in systems including one or more processing stations configured to peel individual shrimp, where peeling may involve removal of shell segments on the dorsal surfaces of the shrimp abdomen and/or removal of pleopods/swimmerets on the ventral surfaces of the shrimp abdomen and, optionally, separation of shell segments. The processing systems and methods may, in one or more embodiments, include apparatus for and methods of measuring the shrimp.