The present invention discloses a kelp harvester. The kelp harvester includes a ship body and a U-shaped tripping piece, where two working chain racks are symmetrically arranged on both sides of the ship body; each working chain rack is provided with a chain and a chain driving device used to drive the chain to operate; multiple rope clamping devices are fixedly arranged on each chain; the rope clamping devices can clamp main ropes, so that when the chains operate, the rope clamping devices can drive the ship body to move along with the operation of the chains; the U-shaped tripping piece is rotatablely connected to the ship body through a hinge; and the ship body is further fixedly provided with a limiting baffle, and the limiting baffle limits the U-shaped tripping piece to stopping rotation when the U-shaped tripping piece is in a vertical state.

The present invention discloses a kelp harvester. The kelp harvester includes a ship body and a U-shaped tripping piece, where two working chain racks are symmetrically arranged on both sides of the ship body; each working chain rack is provided with a chain and a chain driving device used to drive the chain to operate; multiple rope clamping devices are fixedly arranged on each chain; the rope clamping devices can clamp main ropes, so that when the chains operate, the rope clamping devices can drive the ship body to move along with the operation of the chains; the U-shaped tripping piece is rotatablely connected to the ship body through a hinge; and the ship body is further fixedly provided with a limiting baffle, and the limiting baffle limits the U-shaped tripping piece to stopping rotation when the U-shaped tripping piece is in a vertical state.

The present invention provides a new energy-driven in-situ plankton collecting device, comprising a solar photovoltaic cell and wind power generation system, a buoyancy support system, a power supply and control system, a plankton suction and collection system, and an anchoring system. The device has the center of gravity on the lower part and vertically floats in water like a tumbler. The plankton suction and collection system is composed of a suction axial-flow pump and a collecting cod end. The bag-shaped plankton collecting cod end has the mesh aperture of less than 0.8 time the average body length of the target plankton, and can be used on both sides. The devices provided by the present invention can be used simultaneously and arranged in an array for collection and utilization of plankton as well as governance and remediation of water area environment, and thus have a favorable application prospect.

The present disclosure relates, according to some embodiments, to a method of continuously supplying a harvested biomass comprising a floating aquatic plant species to a processing facility. The method includes cultivating a microcrop (e.g., a floating aquatic plant species) in a bioreactor system, harvesting the microcrop to generate the harvested biomass, and conveying the harvested biomass to a first position of a harvest canal to form a conveyed biomass. A harvest canal may include a trough configured to contain the conveyed biomass in a volume of a medium and a propulsion mechanism configured to impart a motion on the first medium such that the harvested biomass may be transported from the first position to the second position within the harvest canal. The harvest canal may be positioned adjacent to an outer perimeter of bioreactor system and form an infinity loop. The method may further include activating the propulsion mechanism to impart motion on the first medium and propel the harvested biomass from the first position to the second position, and transferring at least a portion of the propelled biomass from the second position of the harvest canal to a processing facility.

The present disclosure relates, according to some embodiments, to a method of continuously supplying a harvested biomass comprising a floating aquatic plant species to a processing facility. The method includes cultivating a microcrop (e.g., a floating aquatic plant species) in a bioreactor system, harvesting the microcrop to generate the harvested biomass, and conveying the harvested biomass to a first position of a harvest canal to form a conveyed biomass. A harvest canal may include a trough configured to contain the conveyed biomass in a volume of a medium and a propulsion mechanism configured to impart a motion on the first medium such that the harvested biomass may be transported from the first position to the second position within the harvest canal. The harvest canal may be positioned adjacent to an outer perimeter of bioreactor system and form an infinity loop. The method may further include activating the propulsion mechanism to impart motion on the first medium and propel the harvested biomass from the first position to the second position, and transferring at least a portion of the propelled biomass from the second position of the harvest canal to a processing facility.

A seaweed farming system may include a harvesting unit. The harvesting unit may include a harvest disintegrator. The harvest disintegrator may be configured to receive a plantation substrate having mature seaweed thereon after severing a vegetative portion of seaweed. The harvesting unit may further be configured to disintegrate the mature seaweed to separate the mature seaweed from the plantation substrate, the plantation substrate remaining intact during separation of the mature seaweed.

A seaweed farming system may include a harvesting unit. The harvesting unit may include a harvest disintegrator. The harvest disintegrator may be configured to receive a plantation substrate having mature seaweed thereon after severing a vegetative portion of seaweed. The harvesting unit may further be configured to disintegrate the mature seaweed to separate the mature seaweed from the plantation substrate, the plantation substrate remaining intact during separation of the mature seaweed.

A seaweed farming system (100) for farming of seaweed in a water body is described herein. In an embodiment, the seaweed farming system (100) includes a seaweed farm operating assembly (102) which further includes a harvesting unit (106) to separate vegetative portion of seaweed from mature seaweed. The mature seaweed can grow on a plantation substrate (110). The seaweed farm operating assembly (102) also includes a seeding unit (108) to receive the vegetative portion of the seaweed from the harvesting unit (106) and to sow the vegetative portion of the seaweed in a fresh plantation substrate.

A seaweed farming system (100) for farming of seaweed in a water body is described herein. In an embodiment, the seaweed farming system (100) includes a seaweed farm operating assembly (102) which further includes a harvesting unit (106) to separate vegetative portion of seaweed from mature seaweed. The mature seaweed can grow on a plantation substrate (110). The seaweed farm operating assembly (102) also includes a seeding unit (108) to receive the vegetative portion of the seaweed from the harvesting unit (106) and to sow the vegetative portion of the seaweed in a fresh plantation substrate.

A seaweed farming system may include a harvesting unit. The harvesting unit may include a harvest disintegrator. The harvest disintegrator may be configured to receive a plantation substrate having mature seaweed thereon after severing a vegetative portion of seaweed. The harvesting unit may further be configured to disintegrate the mature seaweed to separate the mature seaweed from the plantation substrate, the plantation substrate remaining intact during separation of the mature seaweed.