The invention relates to a system (1) comprising: a heating device (11) comprising at least one heating means (110) supplied by an AC power grid (2); a control module (12) for controlling said heating device (11),
the system being characterized in that the heating means (110) is supplied via a switching converter (120) rectifying the alternating current of the grid (2) into direct current, the switching converter (120) being controlled by the control module (12) in accordance at least with descriptive data of a state of said power grid (2), so as to adjust the power of the heating means (110).

A system and method to determine building thermal performance parameters through empirical testing is described. The parameters can be formulaically applied to determine fuel consumption and indoor temperatures. To generalize the approach, the term used to represent furnace rating is replaced with HVAC system rating. As total heat change is based on the building's thermal mass, heat change is relabeled as thermal mass gain (or loss). This change creates a heat balance equation that is composed of heat gain (loss) from six sources, three of which contribute to heat gain only. No modifications are required for apply the empirical tests to summer since an attic's thermal conductivity cancels out and the attic's effective window area is directly combined with the existing effective window area. Since these tests are empirically based, the tests already account for the additional heat gain associated with the elevated attic temperature and other surface temperatures.

Example embodiments disclosed herein relate to network device heating based on power classification and temperature. The network device may be configured to receive power via a network connector. The received power can be associated with a power classification. Temperature associated with the network device can be determined. Heat can be produced based on the power classification and the determined temperature.

A system for solar assisted water heating provides hot water to a user at a lower cost, higher energy efficiency, and with a quicker response time than conventional systems, reducing energy losses, and improving user comfort. The basic architecture includes four main components: a solar collector, a heat exchanger, an in-line heater, and a control system. A transient heat profile of a first temperature in a primary loop is measured while a first flow generator G1 is active for the primary loop. Solar assisted heating of water in a secondary loop is provided based on: a flow of water in the secondary loop; a current first temperature; and the transient heat profile of the first temperature by activating: the first flow generator in the primary loop and an in-line water heater in the secondary loop.

A control mechanism for controlling an air conditioning system includes an optical sensor and an energy controller. The air conditioning system includes a solar power module, an outdoor unit, a fan, and a storage device containing a first liquid. The optical sensor detects sunlight received by the solar power module. The energy controller controls the outdoor unit based on luminance and temperature of the sunlight, an operation state of the fan, an operation state of the outdoor unit, a temperature of the first liquid, a flow speed of a second liquid in a conduit between the storage device and the fan, and temperatures of the second liquid at different portions of the conduit.

The remote control of networks of heat-pump systems, in particular where thermal stores are used, for the purpose of demand side management. A heat generating system comprising a heat pump, electrical immersion elements, thermal stores, pumps, heat exchangers, a solar collector, a software driven control system, a 5 means of remote control and a local control network linking local systems. This provides the means to be able to remotely control the timing and quantity of energy drawn from the grid in order to provide instantaneously controllable electrical demand for the purposes of grid balancing whilst maintaining a continuous supply of heat to the building or process for which it is built.

A control mechanism for controlling an air conditioning system includes an optical sensor and an energy controller. The air conditioning system includes a solar power module, an outdoor unit, a fan, and a storage device containing a first liquid. The optical sensor detects sunlight received by the solar power module. The energy controller controls the outdoor unit based on luminance and temperature of the sunlight, an operation state of the fan, an operation state of the outdoor unit, a temperature of the first liquid, a flow speed of a second liquid in a conduit between the storage device and the fan, and temperatures of the second liquid at different portions of the conduit.

A controller for controlling energy consumption in a home includes a constraints engine to define variables for multiple appliances in the home corresponding to various home modes and persona of an occupant of the home. A modeling engine models multiple paths of energy utilization of the multiple appliances to place the home into a desired state from a current context. An optimal scheduler receives the multiple paths of energy utilization and generates a schedule as a function of the multiple paths and a selected persona to place the home in a desired state.

A fluid distribution system for optimizing consumption of energy is provided comprising: a thermal controller configured to be connected to an external fluid tank containing external fluid having an external fluid temperature adapted to be heated by solar energy, and to an internal fluid tank containing an internal fluid having an internal fluid temperature and a heater adapted to be heated by a non-renewable energy, the thermal controller being configured to be connected to thermostats located at the internal and external tanks for determining the internal fluid temperature and the external fluid temperature; a valve in fluid communication with the internal and external tanks; a fluid controller connected to the thermal controller and to the valve, the fluid controller being configured to operate the valve based on the internal and external fluid temperatures in such a manner to optimize consumption of the non-renewable energy for heating the internal fluid.

In accordance with one aspect of the present invention there is provided a method for controlling an operation of an electronic cigarette. The method can include determining a total amount of vaporization energy required to vaporize an amount of liquid stored in a reservoir of an electronic cigarette. The method can include determining a total amount of atomizer power that is delivered to an atomizer associated with the electronic cigarette over a period of time. The method can include determining an amount of liquid remaining in the reservoir of the electronic cigarette, based on a comparison between the total amount of vaporization energy and the total amount of atomizer power delivered to the atomizer over the period of time.