An electrochemical device, configured for electric power storage, including: a reactor, the wall of the reactor being configured to form a first electrode, the reactor being provided with an electrolyte inlet and an electrolyte outlet, a central electrode arranged in the centre of the reactor, additional electrodes E.sub.x, with x an integer ranging from 1 to n, the additional electrodes E.sub.x being tubular and arranged around the central electrode.

An electrochemical cell having a positive electrode; a negative electrode and an electrolyte, wherein the electrochemical cell contains reversible ions in an amount sufficient to maintain a negative electrode potential verses reference level below a negative electrode damage threshold potential of the cell and a positive electrode potential verses reference level above a positive electrode damage threshold potential of the cell under an applied load at a near zero cell voltage state, such that the cell is capable of recharge from the near zero cell voltage state, and method for its production is disclosed.

Method and system for generating electrical energy from a volume of water.

Method and system for generating electrical energy from a volume of water.

A secondary battery includes a positive electrode, a negative electrode and an electrolyte containing aqueous electrolyte. The negative electrode is provided with a negative electrode current collector having a compound including aluminum, and a negative electrode active material including titanium on a granule surface of the negative electrode current collector. A ratio of an atomic concentration of aluminum atoms to sum of atomic concentrations of aluminum atoms and titanium atoms on a surface of the negative electrode ({Al atomic concentration/(Al atomic concentration+Ti atomic concentration)}×100) is 3 atm % or more and 30 atm % or less.

A multi-use testing device is disclosed that is able to test a user fluid or dissolved tissue samples for a medical condition comprising, e.g.: blood related, heart (FABS enzymes); liver and kidney function; gene mutations; COVID-19; and pregnancy status. The testing device is positioned in a bio-fluid chamber configured to store at least one electrolyte or charging fluid to create a conductive path for electrons emitted by an anode electrode and a cathode electrode to generate electricity to recharge the micro battery. The generated electricity is transferred to power the testing device. The reusable testing device further comprises a computing device configured to control the communication between a user electronic computing device and the testing device. The reusable testing device is dipped into a sample in a container and outputs the encrypted test result for wireless transmission to electronic computing devices.

The present invention relates to a polyimide precursor comprising a repeating unit represented by the following chemical formula (1): ##STR00001##
wherein A is a tetravalent group having at least one aliphatic six membered ring and no aromatic ring in the chemical structure, and B is a divalent group having at least one amide bond and an aromatic ring in the chemical structure; or A is an aliphatic tetravalent group and B is a divalent group having at least one chemical structure represented by the following chemical formula (2) in the chemical structure: ##STR00002##
and X.sub.1 and X.sub.2 are each independently hydrogen, a C.sub.1-6 alkyl group or a C.sub.3-9 alkylsilyl group.

A converter includes a working fluid, a housing, a heat sink, a heat source that is at an elevated temperature relative to the heat sink, a first electrochemical cell disposed within the housing, and a micro/nano porous media disposed within the housing. The first electrochemical cell includes a first membrane electrode assembly across which the working fluid is configured to flow. The first membrane electrode assembly includes a first porous electrode and a second porous electrode and at least one ion conductive membrane sandwiched between the first and second porous electrodes. The first electrochemical cell is arranged between the heat source and the heat sink. The working fluid is contained within the micro/nano porous media. The micro/nano porous media is thermally coupled between the heat source and the heat sink, and creates a pressure differential across the first electrochemical cell by transpiration pumping of the working fluid.

A converter includes a working fluid, a housing, a heat sink, a heat source that is at an elevated temperature relative to the heat sink, a first electrochemical cell disposed within the housing, and a micro/nano porous media disposed within the housing. The first electrochemical cell includes a first membrane electrode assembly across which the working fluid is configured to flow. The first membrane electrode assembly includes a first porous electrode and a second porous electrode and at least one ion conductive membrane sandwiched between the first and second porous electrodes. The first electrochemical cell is arranged between the heat source and the heat sink. The working fluid is contained within the micro/nano porous media. The micro/nano porous media is thermally coupled between the heat source and the heat sink, and creates a pressure differential across the first electrochemical cell by transpiration pumping of the working fluid.

A hydride heat engine produces electricity from a heat source, such as a solar heater. A plurality of metal hydride reservoirs are heated by the heating device and a working fluid comprises hydrogen is incrementally move from one metal hydride reservoir to a success metal hydride reservoir. The working fluid is passed, at a high pressure, from the last of the plurality of metal hydride reservoirs to an electro-chemical-expander. The electro-chemical-expander has an anode, a cathode, and an ionomer therebetween. The hydrogen is passed from the anode at high pressure to the cathode at lower pressure and electricity is generated. The solar heater may be a solar water heater and the hot water may heat the metal hydride reservoirs to move the hydrogen. The working fluid may move in a closed loop.