An electrical connector includes a main body portion, connection portions, a first temperature sensing element and a second temperature sensing element. The connection portions allow the main body portion to be electrically connected to a charged element provided in a flow channel. The main body portion includes a first side and a second side which are parallel to a flow direction of fluid. The first temperature sensing element and the second temperature sensing element are provided at mutually opposite positions on the first side and the second side in an electrically insulated manner. A fluid state test device having the electrical connector and a fluid heat exchange system are further provided. Thus, the original flow field where the electrical connector of the electrode of the electric heater is located may not change, and destruction to the flow field is avoided.

Systems and methods are involved for an enhanced heating system includes (I) an enclosure, (II) a burner, (III) an electrically-powered fan, (IV) a wall partition, and (V) a thermoelectric generator to generate electrical power for the electrically-powered fan. In addition, other aspects are described in the claims, drawings, and text forming a part of the present disclosure.

A power plant for generating electrical energy comprises at least a heat storage device (100) for storing electrical energy in heat energy, comprising: an electrical heater (10) for converting electrical energy in heat energy; a heat storage body (30, 31) for receiving and storing heat energy of the electrical heater (10); a heat exchanger (50) for receiving heat energy from the heat storage body (30, 31). The power plant further comprises a turbine (120) and a generator (123). A heat storage fluid circuit (130) connects to the heat exchanger (50) or the heat exchangers (50) and a working fluid circuit (140) connects to the turbine (120). A fluid circuit heat exchanger (131) transfers heat from the heat storage fluid to a working fluid in the working fluid circuit (140).

An electrical connector includes a main body portion, connection portions, a first temperature sensing element and a second temperature sensing element. The connection portions allow the main body portion to be electrically connected to a charged element provided in a flow channel. The main body portion includes a first side and a second side which are parallel to a flow direction of fluid. The first temperature sensing element and the second temperature sensing element are provided at mutually opposite positions on the first side and the second side in an electrically insulated manner. A fluid state test device having the electrical connector and a fluid heat exchange system are further provided. Thus, the original flow field where the electrical connector of the electrode of the electric heater is located may not change, and destruction to the flow field is avoided.

A power plant for generating electrical energy comprises at least a heat storage device (100) for storing electrical energy in heat energy, comprising: an electrical heater (10) for converting electrical energy in heat energy; a heat storage body (30, 31) for receiving and storing heat energy of the electrical heater (10); a heat exchanger (50) for receiving heat energy from the heat storage body (30, 31). The power plant further comprises a turbine (120) and a generator (123). A heat storage fluid circuit (130) connects to the heat exchanger (50) or the heat exchangers (50) and a working fluid circuit (140) connects to the turbine (120). A fluid circuit heat exchanger (131) transfers heat from the heat storage fluid to a working fluid in the working fluid circuit (140).

An installation for producing electricity and heat, comprising a gas turbine unit, a photovoltaic unit and a solar thermal unit, and being configured for switching between: a first operation mode, in which the gas turbine unit produces said electricity and said heat, a second operation mode, in which the gas turbine unit produces only part of said electricity and the photovoltaic unit produces a rest of said electricity, and in which the solar thermal unit either produces a rest of said heat or provides heat to the gas turbine unit, and a third operation mode, in which said electricity and said heat are produced by the photovoltaic unit, the solar thermal unit, and optionally one or several steam turbines of the gas turbine unit.

A self-contained portable heating system to heat a stored liquid in a storage tank to a desired temperature is provided. The system can comprise operatively connected components such as a generator to power a burner that can transfer energy from a combustion product, from for example, a fuel supplied by an attached fuel tank, to a heat transfer fluid through the use of a boiler. The heat transfer fluid can transfer heat from the boiler to a heat exchanger which can then transfer heat to the stored liquid in the tank. The tank can also comprise a circulating pump that can circulate the heat transfer fluid and an expansion tank that can receive the heat transfer fluid when it expands as a result of being heated. In some embodiments, the heating components can be supplied separately from storage tank so that they can be retrofit onto an existing tank.

A co-generation system for heating an application includes an energy storage system that dissipates heat upon operation thereof. The co-generation system also includes a first heat exchanger in thermal contact with the energy storage system. A coolant flowing through the first heat exchanger extracts the heat generated by the energy storage system. The co-generation system further includes a second heat exchanger in thermal contact with the application. The second heat exchanger receives the coolant from the first heat exchanger. The coolant flowing through the second heat exchanger exchanges heat with air in the application to at least partially heat the application. The co-generation system includes a first controller communicably coupled with the energy storage system. The first controller is configured to receive a heating requirement of the application and control one or more operating conditions of the energy storage system in order to meet the heating requirement of the application.