A method of modulating the impact of electromagnetic irradiance on the thermal energy budget of a predominantly enclosed space includes providing at least an inner shell of the predominantly enclosed space, and placing a plurality of functional elements in an exterior position relative to an outside facing side of the inner shell. The outside facing surfaces of the functional elements have higher reflectivity in the visible (VIS) and near infrared (NIR) wavelength range relative to the (MIR) wavelength range. The inside facing surfaces of the functional elements have higher reflectivity in the NIR and mid-infrared (MIR) wavelength range relative to the (VIS) wavelength range. A thickness of the functional elements is equal to or smaller than a thickness of the inner shell.

To reduce the overall environmental impact of a residence or commercial facility, a system is provided for integrating energy usage. In such a system, there is a system for capturing solar energy; a system for fermenting biomass and concentrating the fermentate, generating carbon dioxide and ethanol; a system for storing excess energy for subsequent release; and a system for growing biomass. In integrating the systems, the captured solar energy is used as heat and electrical power. Excess energy beyond an instantaneous energy requirement is stored in the system for storing excess energy. Ethanol produced is used as a fuel. Carbon dioxide that is produced is provided to the system for growing biomass. Instantaneous energy deficiencies are reduced by releasing stored excess energy.

A method of modulating the impact of electromagnetic irradiance on the thermal energy budget of a predominantly enclosed space, in some instances buildings, includes providing at least an inner shell and placing a plurality of functional elements in an exterior position relative to an outside facing side thereof. The outside facing surfaces of the functional elements have higher reflectivity in the visible (VIS) and near infrared (NIR) wavelength range relative to the mid-infrared (MIR) wavelength range. The inside facing surfaces of the functional elements have higher reflectivity in the NIR and MIR wavelength range relative to the VIS wavelength range. The functional elements are least in one degree of freedom spatially adjustable. A thermal carrier medium may be present to increase thermal capacity and to permit transfer of thermal energy. A control system adjusts the spatial position of some of said functional elements and/or the distribution of the thermal carrier medium such that the thermal energy budget of the predominately enclosed space is influenced according to at least one desired target value.

A method of modulating the impact of electromagnetic irradiance on the thermal energy budget of a predominantly enclosed space, in some instances buildings, includes providing at least an inner shell and placing a plurality of functional elements in an exterior position relative to an outside facing side thereof. The outside facing surfaces of the functional elements have higher reflectivity in the visible (VIS) and near infrared (NIR) wavelength range relative to the mid-infrared (MIR) wavelength range. The inside facing surfaces of the functional elements have higher reflectivity in the NIR and MIR wavelength range relative to the VIS wavelength range. The functional elements are least in one degree of freedom spatially adjustable. A thermal carrier medium may be present to increase thermal capacity and to permit transfer of thermal energy. A control system adjusts the spatial position of some of said functional elements and/or the distribution of the thermal carrier medium such that the thermal energy budget of the predominately enclosed space is influenced according to at least one desired target value.

To reduce the overall environmental impact of a residence or commercial facility, a system is provided for integrating energy usage. In such a system, there is a system for capturing solar energy; a system for fermenting biomass and concentrating the fermentate, generating carbon dioxide and ethanol; a system for storing excess energy for subsequent release; and a system for growing biomass. In integrating the systems, the captured solar energy is used as heat and electrical power. Excess energy beyond an instantaneous energy requirement is stored in the system for storing excess energy. Ethanol produced is used as a fuel. Carbon dioxide that is produced is provided to the system for growing biomass. Instantaneous energy deficiencies are reduced by releasing stored excess energy.

To reduce the overall environmental impact of a residence or commercial facility, a system is provided for integrating energy usage. In such a system, there is a system for capturing solar energy; a system for fermenting biomass and concentrating the fermentate, generating carbon dioxide and ethanol; a system for storing excess energy for subsequent release; and a system for growing biomass. In integrating the systems, the captured solar energy is used as heat and electrical power. Excess energy beyond an instantaneous energy requirement is stored in the system for storing excess energy. Ethanol produced is used as a fuel. Carbon dioxide that is produced is provided to the system for growing biomass. Instantaneous energy deficiencies are reduced by releasing stored excess energy.

Disclosed are methods and functional elements for enhanced thermal management of predominantly enclosed spaces. In particular, the invention enables the construction of buildings with reduced power requirements for heating and/or air-conditioning systems since under certain conditions less energy for heating or cooling is required to maintain, within certain boundaries, desirable temperatures inside such buildings, habitats, or other enclosed spaces.

In some instances the invention is in part based on dynamically changing functional elements with variable properties, or effective properties, in terms of their electromagnetic radiative behavior and/or their thermal energy storage properties, or the spatial distribution of the stored thermal energy, which permits the application of methods and algorithms to control the overall thermal behavior of the entire structure in such a way that desired levels of inside temperature can be reached with reduced consumption of external energy (typically electricity, gas, oil, or coal).

In some instances no conventional heating of cooling is required at all, whereas in other instances the expenditure of external energy for conventional heating or cooling is reduced. In some instances the invention enables the reduction of the time to reach desired temperatures inside such buildings, habitats, or other predominantly enclosed spaces.

In some instances the obtained sensor data may be used to detect the occurrence or imminently predicted occurrence of a catastrophic event, including but not limited to fire or flooding, internal or external to the predominantly enclosed space.

In some embodiments this information may support any single or any combination of locally or remotely alerting humans, alerting rescue units, activating countermeasures, uploading at least partially said sensor data to off-site computers, determining the cause(s) of said catastrophic event, determining liability, determining insure payments, determining insurance premiums.

Disclosed are methods and functional elements for enhanced thermal management of predominantly enclosed spaces. In particular, the invention enables the construction of buildings with reduced power requirements for heating and/or air-conditioning systems since under certain conditions less energy for heating or cooling is required to maintain, within certain boundaries, desirable temperatures inside such buildings, habitats, or other enclosed spaces.

In some instances the invention is in part based on dynamically changing functional elements with variable properties, or effective properties, in terms of their electromagnetic radiative behavior and/or their thermal energy storage properties, or the spatial distribution of the stored thermal energy, which permits the application of methods and algorithms to control the overall thermal behavior of the entire structure in such a way that desired levels of inside temperature can be reached with reduced consumption of external energy (typically electricity, gas, oil, or coal).

In some instances no conventional heating of cooling is required at all, whereas in other instances the expenditure of external energy for conventional heating or cooling is reduced. In some instances the invention enables the reduction of the time to reach desired temperatures inside such buildings, habitats, or other predominantly enclosed spaces.

In some instances the obtained sensor data may be used to detect the occurrence or imminently predicted occurrence of a catastrophic event, including but not limited to fire or flooding, internal or external to the predominantly enclosed space.

In some embodiments this information may support any single or any combination of locally or remotely alerting humans, alerting rescue units, activating countermeasures, uploading at least partially said sensor data to off-site computers, determining the cause(s) of said catastrophic event, determining liability, determining insure payments, determining insurance premiums.

A transformable house comprises a stationary part and a movable part placed inside the stationary part and configured to move out of the stationary part along a first direction of the movable part by a first distance. The movable part includes a first sub section having a first width equal to the first distance and a second sub section having a second width that is the rest of a width of the movable part, the second sub section including a water tank. The first width and the second width are determined to meet the following equation: W1D1=W2D2, wherein W1, W2, D1, and D2 are the weight of the first sub section, the weight of the second sub section, the first width, and the second width, respectively.

The present disclosure provides a thermomechanical actuator and a cleaning system implementing the thermomechanical actuator. The thermomechanical actuator includes a solar heat collector (SHC) housing shape memory alloy springs connected between a piston movably disposed therein and one end of the SHC. A cable extending from the piston through an opposite end of the SHC is connected to a bias load that develops returning force on the springs. In presence of solar radiation, the springs contract and cause linear movement of the piston in a direction of contraction and, in absence of the solar radiation, the springs expand and cause linear movement of the piston in direction of expansion. Useful power and work is extracted in form of the cleaning system from such linear movement of the piston.