A computer-controlled greenhouse system constructed in accordance with the invention above provides climate management and precision cultivation capability. It is equipped with solar energy filtering devices to precisely manage visible sunlight intake based on plants stages and adjust solar heat intake according to climate management needs; it uses geothermal energy for heating and cooling; it reclaims water from moisture released by plants with vapor condensing devices.

The invention relates to a modular building structure (10) comprising: a framework (12) including a plurality of rods (14) and connectors (16) to interconnect the plurality of rods (14) together, the framework (12) comprising empty spaces bordered by corresponding rods (14) of said plurality of rods; a plurality of panels (20), wherein one panel (20) is mounted inside each empty space and connected to the framework (12) in order to create an interior (40), an air chamber layer (44) inside which air may circulate, said air chamber layer (44) forming at least a portion of an outer surface of said interior (40), at least one upper valve system (46a) mounted in the upper portion of the structure (10), and at least one lower valve system (46b) mounted in the lower portion of the structure (10). The at least one upper and lower valve systems (46a, 46b) are selectively operable to regulate the thermal conditions inside the interior (40) as a function of the meteorological conditions outside the modular building structure (10) and a desired temperature inside the interior (40). The invention also relates to a method for operating the at least one upper and lower valve systems (46a, 46b) of the modular building structure (10).

The attic hot air recirculation system is mechanical system. The attic hot air recirculation system is configured for use with an HVAC system of a building. The attic hot air recirculation system is energy saving technology. The attic hot air recirculation system captures solar energy from the roof of the building. The attic hot air recirculation system monitors the temperature of the captured solar energy and the temperature of a chamber in the building. The attic hot air recirculation system uses the heat generated from the captured solar energy to heat a chamber in the room. When the temperature difference between the temperature of the captured solar energy and the temperature of a chamber in the building makes it thermodynamically favorable to do so, the attic hot air recirculation system transfers heat from the roof into the chamber.

The attic hot air recirculation system is mechanical system. The attic hot air recirculation system is configured for use with an HVAC system of a building. The attic hot air recirculation system is energy saving technology. The attic hot air recirculation system captures solar energy from the roof of the building. The attic hot air recirculation system monitors the temperature of the captured solar energy and the temperature of a chamber in the building. The attic hot air recirculation system uses the heat generated from the captured solar energy to heat a chamber in the room. When the temperature difference between the temperature of the captured solar energy and the temperature of a chamber in the building makes it thermodynamically favorable to do so, the attic hot air recirculation system transfers heat from the roof into the chamber.

A heat collector device is provided. The heat collector includes an exterior surface exposed to an environment, and an interior surface. Side walls separate the exterior and interior surfaces. A heat insulation interposes the exterior and interior surfaces. Each hot air duct includes a first portion interfacing with the external surface and a second portion interfacing with the heat insulation. Each cold air duct is encompassed by the heat insulation. A first chamber formed by a first side wall provides fluidic communication between the air ducts at a first end portion of each respective duct. A second chamber formed by a second side wall provides fluidic communication between the air ducts at a second end portion of each respective duct. A heat exchange mechanism disposed in the second chamber removes heat from a first fluidic medium of the air ducts, the first chamber, and the second chamber.

A heat collector device is provided. The heat collector includes an exterior surface exposed to an environment, and an interior surface. Side walls separate the exterior and interior surfaces. A heat insulation interposes the exterior and interior surfaces. Each hot air duct includes a first portion interfacing with the external surface and a second portion interfacing with the heat insulation. Each cold air duct is encompassed by the heat insulation. A first chamber formed by a first side wall provides fluidic communication between the air ducts at a first end portion of each respective duct. A second chamber formed by a second side wall provides fluidic communication between the air ducts at a second end portion of each respective duct. A heat exchange mechanism disposed in the second chamber removes heat from a first fluidic medium of the air ducts, the first chamber, and the second chamber.

A solar collector comprising a wide-angle, nonimaging asymmetric optical reflector comprising a reflective film, an absorber assembly positioned within the optical reflector having a transparent tube evacuated to a vacuum or partial vacuum and at least two pipes with fluid flowing through the pipes, the pipes arranged in a flow-through configuration, wherein the solar acceptance angle of the collector is about 40 degrees, allowing for passive (stationary) solar tracking, and where the solar energy collected is transferred to the fluid in the form of heat. The fluid exiting the solar collector is in the range of 100° C. to 250° C., and the thermal energy of the fluid may be used to generate high-quality steam for solar industrial process heat applications.

A solar collector comprising a wide-angle, nonimaging asymmetric optical reflector comprising a reflective film, an absorber assembly positioned within the optical reflector having a transparent tube evacuated to a vacuum or partial vacuum and at least two pipes with fluid flowing through the pipes, the pipes arranged in a flow-through configuration, wherein the solar acceptance angle of the collector is about 40 degrees, allowing for passive (stationary) solar tracking, and where the solar energy collected is transferred to the fluid in the form of heat. The fluid exiting the solar collector is in the range of 100° C. to 250° C., and the thermal energy of the fluid may be used to generate high-quality steam for solar industrial process heat applications.

A solar thermal control system includes a membrane configured to receive solar energy, wherein the membrane is configured to form a cavity between the membrane and an outer surface of a structure by coupling to the outer surface, and wherein the solar energy is configured to heat air within the cavity. The control system also includes a thermal collection unit configured to connect to the cavity and receive and direct air from the cavity, and a ducting system coupled to the thermal collection unit and configured to direct air from the thermal collection unit to at least one of the interior of the structure and a vent.

A solar thermal control system includes a membrane configured to receive solar energy, wherein the membrane is configured to form a cavity between the membrane and an outer surface of a structure by coupling to the outer surface, and wherein the solar energy is configured to heat air within the cavity. The control system also includes a thermal collection unit configured to connect to the cavity and receive and direct air from the cavity, and a ducting system coupled to the thermal collection unit and configured to direct air from the thermal collection unit to at least one of the interior of the structure and a vent.