The present invention relates to a cell culture scaffold, and provides a cell culture scaffold which has a hydrogel structure comprising alginate and cellulose extracted by means of algae decellularization and which enable the stable growth of cells even at low cost while having a simple preparation.

Floating ponds for the cultivation of algae are disclosed. The floating ponds consist of a buoyant framework, a liner, a culture, and a mooring system. Submersible floating ponds are disclosed with a buoyant framework built from tubes that may be filled or partially filled with, for example, air, or water, or the surrounding water, or the culture, and thereby the present invention provides a framework in which the buoyancy may be modulated. Use of submerging lines and spools are disclosed to control the orientation and depth of the floating pond during submersion.

Floating ponds for the cultivation of algae are disclosed. The floating ponds consist of a buoyant framework, a liner, a culture, and a mooring system. Submersible floating ponds are disclosed with a buoyant framework built from tubes that may be filled or partially filled with, for example, air, or water, or the surrounding water, or the culture, and thereby the present invention provides a framework in which the buoyancy may be modulated. Use of submerging lines and spools are disclosed to control the orientation and depth of the floating pond during submersion.

Provided herein are methods for the production of high density cultures of algae as well as nutritional supplements from such cultures and the use of such cultures to produce therapeutic proteins.

Provided herein are methods for the production of high density cultures of algae as well as nutritional supplements from such cultures and the use of such cultures to produce therapeutic proteins.

A system for growing algae includes a pivot arm pivotally coupled to a pivot connection positioned in a pond containing water and algae, and a mixing device coupled to the pivot arm and extending into the pond to mix the water and the algae as the pivot arm rotates.

Provided is a sunlight lighting system used in a greenhouse or a plant factory. The sunlight lighting system converts sunlight into light with a stable illumination direction and a controllable illumination intensity by means of a combination of a controller, a light condenser, a main driving mechanism and an illuminator, so that the sunlight lighting system meets lighting requirements of high-density stereoscopic cultivation frames. A supporting greenhouse is further comprised, where a facade or a top is provided with a light through hole. A main optical axis of the sunlight lighting system passes through the light through hole. A supporting lighting method is further comprised, which can obtain a better lighting effect with fewer steps.

Provided is a sunlight lighting system used in a greenhouse or a plant factory. The sunlight lighting system converts sunlight into light with a stable illumination direction and a controllable illumination intensity by means of a combination of a controller, a light condenser, a main driving mechanism and an illuminator, so that the sunlight lighting system meets lighting requirements of high-density stereoscopic cultivation frames. A supporting greenhouse is further comprised, where a facade or a top is provided with a light through hole. A main optical axis of the sunlight lighting system passes through the light through hole. A supporting lighting method is further comprised, which can obtain a better lighting effect with fewer steps.

The present invention includes an apparatus configured for aquaculture, and more specifically for kelp growth and kelp farming. The apparatus includes a vertical central mast connected to horizontal buoyancy bars that are also connected to six vertical vertex struts surrounding the central mast. Buoyancy bars further connect adjacent vertex struts, such that the top profile of the apparatus is a hexagon. The apparatus is able to be connected to and share elements of other similar apparatuses, allowing for ease of aggregation of the apparatuses for scalable farming. The central mast is optionally configured to integrate a wind turbine, which is optionally able to power water pumps in the six vertex struts, which serve to transport water upward around the apparatus for more efficient carbon sequestration by the apparatus.

The present invention includes an apparatus configured for aquaculture, and more specifically for kelp growth and kelp farming. The apparatus includes a vertical central mast connected to horizontal buoyancy bars that are also connected to six vertical vertex struts surrounding the central mast. Buoyancy bars further connect adjacent vertex struts, such that the top profile of the apparatus is a hexagon. The apparatus is able to be connected to and share elements of other similar apparatuses, allowing for ease of aggregation of the apparatuses for scalable farming. The central mast is optionally configured to integrate a wind turbine, which is optionally able to power water pumps in the six vertex struts, which serve to transport water upward around the apparatus for more efficient carbon sequestration by the apparatus.