A foldable aquaponics, and greenhouse container system and method, includes an insulated shipping container having foldable insulated roof panel disposed thereover; a foldable glazing on a sun facing side at an angle to maximize winter sunlight attached to the roof panel; a foldable floor panel attached to the container with a foldable vent panel attached thereto connecting to the glazing; foldable side panels attached to sides of the container, glazing and roof panel; a plant growing under the glazing; a mushroom growing area within the container having an integrated water wall thermal mass and disposed between the plant and mushroom growing areas; a fish tank within the container; and a natural air ventilation system within the container under the roof panel to provide CO2 and O2 gas exchange between the mushroom growing area and the plant growing area.

A distribution valve positioned in a supply pipe, the distribution valve including a body between a first end and a second end, the first end is substantially flat in which an inlet orifice is positioned, the inlet orifice has a circular shape and includes an axis of revolution positioned according to a parallel of the longitudinal axis of the distribution valve, the second end is substantially flat and comprises a spherical cap on which at least two outlet orifices are positioned, each outlet orifice has a circular shape, the distribution valve includes a mobile plug contained in the distribution valve body, the mobile plug includes a rigid duct that passes through it and is adapted for selectively making the inlet orifice communicate with one of the outlet orifices.

A distribution valve positioned in a supply pipe, the distribution valve including a body between a first end and a second end, the first end is substantially flat in which an inlet orifice is positioned, the inlet orifice has a circular shape and includes an axis of revolution positioned according to a parallel of the longitudinal axis of the distribution valve, the second end is substantially flat and comprises a spherical cap on which at least two outlet orifices are positioned, each outlet orifice has a circular shape, the distribution valve includes a mobile plug contained in the distribution valve body, the mobile plug includes a rigid duct that passes through it and is adapted for selectively making the inlet orifice communicate with one of the outlet orifices.

A pen system is for farming aquatic organisms. The pen system has an outer surrounding rigid structure and an internal, closed enclosure. The outer surrounding rigid structure forms an upper portion and a lower portion. The pen system further has: an internal surrounding connecting element, the closed enclosure being attached to the connecting element; and a heave-compensation system having a plurality of fluid-filled cylinders, each fluid-filled cylinder being hingedly attached, in a first end portion, to the connecting element, and being hingedly attached, in a second end portion, to the inside of the rigid structure.

A pen system is for farming aquatic organisms. The pen system has an outer surrounding rigid structure and an internal, closed enclosure. The outer surrounding rigid structure forms an upper portion and a lower portion. The pen system further has: an internal surrounding connecting element, the closed enclosure being attached to the connecting element; and a heave-compensation system having a plurality of fluid-filled cylinders, each fluid-filled cylinder being hingedly attached, in a first end portion, to the connecting element, and being hingedly attached, in a second end portion, to the inside of the rigid structure.

The subject invention provides microbe-based products, as well as their use, for enhancing aquaculture. In particular, the subject invention provides materials and methods for producing healthy and high quality farmed fish by applying yeast and/or bio surfactant-based compositions to a fish farm. In one embodiment, the subject invention improves the environment in which the fish are farmed. In another embodiment, the subject invention provides a highly nutritious fish feed, as well as methods of feeding fish at low cost.

The subject invention provides microbe-based products, as well as their use, for enhancing aquaculture. In particular, the subject invention provides materials and methods for producing healthy and high quality farmed fish by applying yeast and/or bio surfactant-based compositions to a fish farm. In one embodiment, the subject invention improves the environment in which the fish are farmed. In another embodiment, the subject invention provides a highly nutritious fish feed, as well as methods of feeding fish at low cost.

A fish feed dispersing apparatus includes a helical dispersing tube attached to a fish pen with a mounting assembly. The helical dispersing tube has an inlet end that receives fish feed from a source, and includes a number of spaced apertures that disperse the received fish feed. A mounting assembly supports the dispersing tube, and includes two spaced-apart attachment members connected by a plurality of elongate members, and a plurality of hanger subassemblies. Each hanger subassembly has a first end attached to one of the elongate members and a second end that includes a clamp configured to engage the helical dispersing tube. The hangar assemblies are adjustable, and support the helical dispersing tube during use.

A fish feed dispersing apparatus includes a helical dispersing tube attached to a fish pen with a mounting assembly. The helical dispersing tube has an inlet end that receives fish feed from a source, and includes a number of spaced apertures that disperse the received fish feed. A mounting assembly supports the dispersing tube, and includes two spaced-apart attachment members connected by a plurality of elongate members, and a plurality of hanger subassemblies. Each hanger subassembly has a first end attached to one of the elongate members and a second end that includes a clamp configured to engage the helical dispersing tube. The hangar assemblies are adjustable, and support the helical dispersing tube during use.

A pond filter unit and a method for operating a pond filter unit is provided. A control unit controls the operation of the pond filter unit, including the cleaning cycle of the filter. The pond filter unit further includes one or more plugs for connecting one or more auxiliary devices, such as a separate pump, one or more additional pond filter units, illumination means/lamps, air pumps, and/or feed automats. The control unit of the pond filter further controls the one or more auxiliary devices connected to the plugs, such as pumps, air pumps, automatic feeding devices based on input settings for each of the one or more auxiliary devices. The control unit further controls the cleaning cycle for cleaning of the filter in the vessel.