The invention relates to a system for extracting thermal energy, a method for operating such a system and a thermal module for such a system. More particularly, the system is for extracting thermal energy from sunlight or other thermic energy sources.

A regulating method for a heating and/or cooling system uses at least one load circuit (6), through which a fluid as a heat transfer medium flows and switches the at least one load circuit (6) on and off in dependence on a room temperature in a room to be thermally regulated by the at least one load circuit (6). A feed temperature (T.sub.mix) of the fluid fed to the at least one load circuit (6) is set in dependence on the relative switch-on duration (D) of the at least one load circuit (6). A manifold device is also provided for a heating and/or cooling system with a control device for carrying out such a regulating method.

The invention concerns a system for energy and environmental optimisation of a facility comprising at least one combustion apparatus (1) with a burner (3). The system comprises an electrolyser (2) and an injection system (4) connected to at least one fuel (3a) and/or oxidant (3b) inlet of the burner (3). The injection system is capable of injecting, at such an inlet, gases from the electrolyser (2) and/or a mixture of these gases and a combustible fluid and/or an oxidising fluid. The electrolyser (2) and/or the injection system (2) are controlled on the basis of at least one piece of information originating from the combustion apparatus (1) and/or sensors (6x) of the installation. The electrolyser can comprise a heat exchanger (2a) for cooling the device and/or preheating the water (EP) that is intended to then be heated (EC) by the combustion apparatus (1).

Provided is a heating and hot water supply device. The heating and hot water supply device includes: a combustion part; a heat exchanger; a circulation passage; a circulation part; a bypass passage; a distribution means for distributing the heating medium to the circulation passage and the bypass passage; a hot water supply heat exchanger; a water supply passage; and a hot water supply passage (21). The distribution ratio of the distribution means is adjustable so as to correspond to a heating operation, a hot water supply operation, and the simultaneous heating and hot water supply operation. The heating and hot water supply device includes an operation part, which heats the heating medium to one or more heating terminal setting temperatures and circulates the heating medium, and switches a setting of the one or more heating terminal setting temperatures to be increased by a prescribed temperature during the simultaneous heating and hot water supply operation.

A radiant heating system includes a housing and a plurality of heating elements. The housing includes a top cover configured to cover and seal an upper surface of the housing and a coolant directing enclosure positioned on an upper interior surface of the top cover. The top cover includes a plurality of openings, an inlet configured to allow a coolant to enter into the housing and an outlet configured to allow the coolant to exit the housing. The plurality of heating elements are configured to be inserted into the plurality of openings of the top cover such that the plurality of heating elements project into the housing and contact a coolant. A diameter of the inlet is greater than a diameter of the outlet.

A radiant heating system includes a housing and a plurality of heating elements. The housing includes a top cover configured to cover and seal an upper surface of the housing and a coolant directing enclosure positioned on an upper interior surface of the top cover. The top cover includes a plurality of openings, an inlet configured to allow a coolant to enter into the housing and an outlet configured to allow the coolant to exit the housing. The plurality of heating elements are configured to be inserted into the plurality of openings of the top cover such that the plurality of heating elements project into the housing and contact a coolant. A diameter of the inlet is greater than a diameter of the outlet.

An integrated solar thermal system for a building roof is provided. The system utilizes a plurality of fin pipes to collect solar energy as heat, and to transfer this heat to a working fluid conveyed in a parallel flow through the fin pipes. The heated working fluid is then used for productive energy conversion.

An solar energy harvester and method for controlling the solar energy harvester, in which an insolation collector is formed of one or more elements each having two opposite major sides, a first side and a second side, and being configured to collect energy from insolation incident on any of the first and second sides. A cradle enables installation of the insolation collector on a roof with the first side generally towards the sun independently of the form of the roof. One or more heliostats reflect insolation to the second side of the insolation collector. A controller controls the one or more heliostats to maintain reflected insolation incident on the collector and to decrease the reflected insolation incident on the collector when necessary to inhibit the insolation collector receiving insolation exceeding given threshold through its first and second sides.

A system includes a first subsystem configured to produce a resource by consuming electricity, a second subsystem configured to produce the resource by consuming a fuel, and a controller. The controller is configured to determine an allocation of a predicted demand for the resource over a future time period between the first subsystem and the second subsystem based on a first carbon emissions rate associated with off-site production of the electricity and a second carbon emissions rate associated with on-site consumption of the fuel. The controller is also configured to control the first subsystem and the second subsystem to produce the resource in accordance with the allocation during the future time period.

A system includes a first subsystem configured to produce a resource by consuming electricity, a second subsystem configured to produce the resource by consuming a fuel, and a controller. The controller is configured to determine an allocation of a predicted demand for the resource over a future time period between the first subsystem and the second subsystem based on a first carbon emissions rate associated with off-site production of the electricity and a second carbon emissions rate associated with on-site consumption of the fuel. The controller is also configured to control the first subsystem and the second subsystem to produce the resource in accordance with the allocation during the future time period.