An energy storage system may include an internal battery. Further, the energy storage system may include a motor electrically coupled to the internal battery. Further, the energy storage system may include an alternator rotatably coupled with the motor. Further, the energy storage system may include a primary battery electrically coupled to the alternator. Further, the energy storage system may include a voltage sensor configured for sensing a voltage level of the primary battery. Further, the energy storage system may include a switching device electrically coupled to each of the internal battery and the motor; and, may be configured for controlling electrical connectivity between the internal battery and the motor based on the voltage level of the primary battery. Further, the energy storage system may include an electrical interconnect electrically coupled to one or more of the internal battery, the alternator and the primary battery.

Systems and methods for battery testing including a holder system. The holder system is designed to couple one or more transducers to a battery under test, wherein the one or more transducers are configured for electrochemical-acoustic signal interrogation (EASI) of the battery. The holder system includes at least one arm to house at least one transducer to be coupled to the battery, and a pressure applying device to apply pressure to the at least one transducer, and to control pressure between the at least one transducer and the battery. The holder system is also configured to determine the pressure between the at least one transducer and the battery and adjust the pressure applied to the at least one transducer based on the determined pressure.

A method for producing silver nanowires, containing reduction-precipitating silver in the form of wire in an alcohol solvent having dissolved therein a silver compound, the deposition being performed in the alcohol solvent having dissolved therein a chloride, a bromide, an alkali metal hydroxide, an aluminum salt, and an organic protective agent, the molar ratio Al/OH of the total Al amount of the aluminum salt dissolved in the solvent and the total hydroxide ion amount of the alkali metal hydroxide dissolved therein being from 0.01 to 0.40, the molar ratio OH/Ag of the total hydroxide ion amount of the alkali metal hydroxide dissolved in the solvent and the total Ag amount of the silver compound dissolved therein being from 0.005 to 0.50.

The invention is directed towards a battery. The battery includes a cathode, an anode, a separator between the cathode and the anode, and an electrolyte. The cathode includes a conductive additive and an electrochemically active cathode material. The electrochemically active cathode material includes a beta-delithiated layered nickel oxide. The beta-delithiated layered nickel oxide has a chemical formula. The chemical formula is Li.sub.xA.sub.yNi.sub.1+azM.sub.zO.sub.2.Math.nH.sub.2O where x is from about 0.02 to about 0.20; y is from about 0.03 to about 0.20; a is from about 0 to about 0.2; z is from about 0 to about 0.2; and n is from about 0 to about 1. Within the chemical formula, A is an alkali metal. The alkali metal includes potassium, rubidium, cesium, and any combination thereof. Within the chemical formula, M comprises an alkaline earth metal, a transition metal, a non-transition metal, and any combination thereof. The anode includes an electrochemically active anode material. The electrochemically active anode material includes zinc, zinc alloy, and any combination thereof.

A method of testing a battery includes causing a battery in a test environment to produce a fire having a flame that extends out from the battery, and capturing a digital image of a scene that includes at least a portion of a test environment and the flame, the digital image being formed using visible light. The method includes uploading the digital image to a computer configured to produce a quiver plot and identify points on the quiver plot that define a polygon that is an approximate outline of the flame. The computer is configured to determine dimensions of the polygon, and translate the dimensions from the quiver plot to the digital image, and from the digital image to dimensions of the flame in the scene. And the computer is configured to generate a displayable report that includes at least the dimensions of the flame.

An apparatus and method for testing a battery pack are provided. Measurement circuitry is configured to measure parameters of batteries within the battery pack. The measurement circuitry responsively provides an output indicative of a condition of a battery in the battery pack. The output is based upon a measured parameter of the battery pack and a correction factor.

A test cell station (50) for at least one electrochemical test cell (10), comprising a housing (57), at least one receptacle (51) for the contacting insertion of at least one electrochemical test cell (10) and electrical connection means (54) for the electrical connection of a test cell (10) that has been inserted into the receptacle (51), characterized in that a thermally insulated temperature chamber (20) with a controllable cooling/heating device (27) for adjusting a temperature in the temperature chamber (20) is integrated into the test cell station (50), wherein the receptacle (51) is arranged in the test cell station (50) in such a way that the corresponding receptacle space for the electrochemical test cell (10) is arranged within the temperature chamber (20).

The invention is directed towards an electrochemically active cathode material. The electrochemically active cathode includes beta-delithiated layered nickel oxide and an electrochemically active cathode material selected from the group consisting of manganese oxide, manganese dioxide, electrolytic manganese dioxide (EMD), chemical manganese dioxide (CMD), high power electrolytic manganese dioxide (HP EMD), lambda manganese dioxide, gamma manganese dioxide, beta manganese dioxide, and mixtures thereof. The beta-delithiated layered nickel oxide has an X-ray diffraction pattern. The X-ray diffraction pattern of the beta-delithiated layered nickel oxide includes a first peak from about 14.9 2 to about 16.0 2; a second peak from about 21.3 2 to about 22.7 2; a third peak from about 37.1 2 to about 37.4 2; a fourth peak from about 43.2 2 to about 44.0 2; a fifth peak from about 59.6 2 to about 60.6 2; and a sixth peak from about 65.4 2 to about 65.9 2.

A method of testing a battery includes causing a battery in a test environment to produce a fire having a flame that extends out from the battery, and capturing a digital image of a scene that includes at least a portion of a test environment and the flame, the digital image being formed using visible light. The method includes uploading the digital image to a computer configured to produce a quiver plot and identify points on the quiver plot that define a polygon that is an approximate outline of the flame. The computer is configured to determine dimensions of the polygon, and translate the dimensions from the quiver plot to the digital image, and from the digital image to dimensions of the flame in the scene. And the computer is configured to generate a displayable report that includes at least the dimensions of the flame.

In a method for estimating a voltage of a battery a given electrochemical battery model is provided, wherein one parameter of the electrochemical battery model is an open circuit potential. The open circuit potential is linearized. The voltage of the battery is estimated by means of the electrochemical battery model with the linearized open circuit potential.