The advanced cool roof can make up the entire roof of a building or vehicle, or be integrated into a portion of said roofs. This invention utilizes and reduces the amount of solar radiation that enters a building or vehicle via the roof. This system consists of a water holding tank or plurality of tanks, thermal collectors, fire sprinkler heads and various glazing options. Said thermal collectors are contained between the rafters or trusses, and takes advantage of thermal syphoning to store energy in said tank or plurality of tanks. Additionally, this roof system can function as a fire suppression apparatus and a skylight apparatus that allows natural light into the structure, and may be integrated with LED lighting to illuminate said glazing and interior space. The exterior upper covering may consist of a glazing material like tempered glass coupled with additional roofing elements or standard upper covering assemblies.

A digital fluid heating system may include a solar collection system configured for focusing sunlight on a focal axis, an elongated flow element arranged and configured for transporting fluid along the solar collection system at the focal axis, and a flow-control assembly comprising a digitally controlled valve configured to control the flow of the fluid in the elongated flow element such that pathogens present in the fluid are substantially inactivated before the fluid exits the fluid heating system and at a maximized flow rate under the given energy providing conditions. The system may also include one or more digital controls and communication systems for remote and/or automatic control.

A building integrated modular thermal system is disclosed. A modular thermal unit comprises a plurality of metal battens having a longitudinal channel mounted horizontally onto a plurality of wooden battens, a thermal tubing containing liquid mounted on the longitudinal channels, a plurality of solar electric roof tiles mounted on the plurality of metal battens and connected in series to form a string, an inverter connected to each of the strings, an energy storage tank is connected between the thermal tubing, and a pump. The plurality of solar electric roof tiles generates DC electricity from solar energy and the inverter converts the DC electricity to AC electricity to feed to a utility grid. The plurality of metal battens collects the solar energy and converts into thermal energy through running the liquid which is extracted to the heat exchanger resulting in producing domestic hot water. The modular thermal unit and the thermal control system provide an easy installation with a removable modular structure.

Disclosed is a solar water-heating-and-cooling system (20) that included a collector array panel (32, 36) having thermosyphon coaxial heating/cooling tubes (52). The disclosed system (20) avoids damaging the collector array panel (32, 36) by filling the tubes (52): 1. only when environmental conditions ensure that damage won't occur,and/or 2. using a filling method that ensures that damage won't occur. Thermosyphon coaxial heating/cooling tubes (52) disclosed herein may be open both at their upper and lower ends. Tubes (52) that are open at their, lower end enables capturing radiative cooling of liquid present within the tubes (52). A cold water storage tank (46) and cold radiator array (48) included in the water-heating-and-cooling system (20) permits preserving and using the radiative 'cooling. Also disclosed are coaxial tubes (104, 106) that enable simpler and easier installation of the system (20), and also provide a less architecturally intrusive system (20).

A heat exchanger system, comprising: a storage tank; and heat exchanger apparatus comprising: a heat exchanger; and a plenum structure defining a hollow body comprising a first end that is coupled to the heat exchanger, and a second end remote from the first end; a mounting arrangement to mount the heat exchanger apparatus within the tank in an orientation wherein the heat exchanger is disposed in substantially a horizontal condition, whereas the plenum structure is disposed in substantially a vertical condition.

The present invention provides a method, an apparatus and chemical products for treating petroleum equipment wherein a fluid is flowing, preferably of the hydrocarbon type, and wherein treating is performed by establishing a closed or semi-closed flow circulation loop, during the normal production operations of the equipment. The treatment can refer to the cleaning of equipment, to yield improvement as compared to normal run conditions and/or to a reduction of coke formation and/or to coke removal on catalysts.

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 characterised 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 thermoregulation apparatus for a solar thermal energy capture system comprising a piping infrastructure in fluid communication with a fluid storage tank and one or more solar thermal energy collectors. The thermoregulation apparatus comprises: (i) a thermostatically actuated valve interposed the piping infrastructure downstream from the one or more solar energy collectors and upstream from the fluid storage tank, and (ii) piping for interconnecting the thermostatically actuated valve with the piping infrastructure, and the fluid storage tank. The thermostatically actuated valve can be configured for diverting the flow of working fluid away from the fluid storage tank when the temperature of the working fluid is below a selected set point for actuating the valve, and for diverting the flow of working fluid to the fluid storage tank when the temperature of the working fluid is about or greater than the selected set point.

A fluid-based system for use in heating and/or cooling. In particular, the system may have a fluid heating device, which may be a solar fluid heating device, configured to heat a fluid. Heat from the heated fluid may be transferred to one or more cooling subsystems or heating subsystems. A cooling subsystem may be an absorption cooling subsystem, for example, wherein heat may cause phase change of a refrigerant. A heating subsystem may include a storage tank through which heated fluid may be circulated to heat the storage tank. A system of the present disclosure may include multiple cooling and/or heating subsystems for cooling and or heating a variety of different environments, objects, or materials.

A hot water heating system of a dwelling includes a storage tank and a hot water pipe that collects water from a relative upper portion of the storage tank. This water is fed towards a hot water distribution network of the dwelling. The hot water heating system includes in addition a cross-connection pipe that is activated during an emergency mode of the system to direct water from a relative lower portion of the storage tank to be supplied to occupants of the dwelling via the hot water distribution network of the dwelling.