Abstract: A voltage control apparatus checks a battery voltage when an automotive generator gradually increases its output to be within a predetermined range after temporarily stopping the generator. Then, the battery voltage is picked up to calculate the charge rate. Further, a first charge rate and a first residual capacity of the battery is memorized when the engine is stopped. Periodically, a pseudo-open circuit voltage is checked when a charge/discharge current fits within a predetermined small range while the engine is not running, and a second charge rate calculated based on the checked pseudo-open circuit voltage. A second residual capacity is calculated using the first charge rate, the first residual capacity and the second charge rate.

Abstract: A method for determining a state of charge (SOC) characteristic variable for a storage battery including determining a first SOC value and a second SOC value. The method further including determining changes in the first and second SOC values. These changes in the first and second SOC values are measured between a first operating time and a second operating time. The method also including determining a characteristic variable relating to the state of charge as a function of the change in the first and second SOC values.

Abstract: A method for testing a precursor of a secondary cell with high reliability and high efficiency to judge the precursor to be acceptable or defective. The current flowing when a test voltage is applied between a pair of electrodes is measured before an electrolyte is placed between the electrodes. If a current the current value of which exceeds a predetermined reference current value (13) is detected during the time from the start of application of a voltage to a normal secondary cell precursor until the current becomes constant, the precursor is determined to be defective.

Abstract: A measuring apparatus with storage that measures and analyzes both stray currents from subway rails or power lines and the pipe-to-soil voltage of a buried metallic structure simultaneously is disclosed. The data measuring apparatus with storage for measuring stray currents from subway rails or power lines and the pipe-to-soil voltage of a buried metallic structure in accordance with the present invention comprises measuring means, which is a portable module that allows easy installation at one or multiple measurement points of the buried metallic structure, for measuring stray currents from the subway rails or power lines and the pipe-to-soil voltage of a buried metallic structure simultaneously and for storing and transmitting the measurement data and analytic computing means for receiving the measurement data transmitted from the measuring means and for databasing and graphically displaying the received measurement data for time-synchronous data analysis.

Abstract: A computer provided with an intelligent battery 52 for charging/discharging, the intelligent battery 52 supplying power to a main system unit, wherein the intelligent battery 52 includes: a voltage measuring circuit 70 for measuring a battery voltage of the intelligent battery 52; a current measuring circuit 63 for measuring a charging/discharging current of the intelligent battery 52; a temperature measuring circuit 90 for measuring a temperature of the intelligent battery 52; and a CPU 62 for periodically reading the battery voltage measured by the voltage measuring circuit 70, the charging/discharging current measured by the current measuring circuit 63, and the temperature measured by the temperature measuring circuit 90 so as to manage a capacity deterioration of the battery due to a storage deterioration and a cycle deterioration, and wherein the main system unit includes an embedded controller 41 for receiving information about the capacity deterioration from the CPU 62 of the battery.

Abstract: An active tester for vehicle circuit evaluation includes a signal source for generating a dynamic signal, such as an AC current, for injecting to a circuit under test. The tester includes a data storage device for storing at least one test parameter and a data processor for processing data. In operation, the data processor controls to apply the dynamic signal to the separated points of the circuit via the first set of terminals. The response of the circuit under test to the applied dynamic signal is measured. The data processor determines a dynamic parameter of the circuit under test as a function of the dynamic signal and the response. The data process then generates a test result related to the characteristics of the circuit as a function of the at least one test parameter and the determined dynamic parameter. The test result is compared with specification values to determine whether the circuit under test works normally.

Abstract: The invention provides a system and battery including a state-of-charge indicator (SOCI) to monitor and display the amount of charge within the battery. The SOCI is capable of operating in a hibernate mode, an active mode, and/or a sleep mode. The battery may be manufactured, shipped and/or stored with the SOCI operating in a power-saving hibernate mode. The SOCI may exit the hibernate mode and begin operating in active mode if a physical key connected to the battery is removed. In addition, the SOCI may operate in a sleep mode while the battery is not being used to conserve power. Furthermore, the invention provides a method of making a battery including a SOCI to monitor and display the state of charge of the battery.

Abstract: A method and apparatus for simulating a battery tester with a fixed resistance load, such as a widely used Japanese load tester that rates the strength of Japanese batteries that are categorized under the Japanese Industrial Standard (JIS), are provided. This invention simulates such a device without invoking large current loads, yields familiar results, utilizes an existing database and provides more conclusive testing. The method includes measuring an open circuit voltage (OCV), temperature and a dynamic parameter of the battery. A load voltage of the battery is estimated as a function of the measured battery dynamic parameter, the OCV, the load resistance value of the load tester and the battery temperature. A bounceback voltage (BBV) of the battery is then predicted. The BBV, the load voltage and the battery temperature are utilized to rate the strength of the battery.

Abstract: A time varying electrical excitation(s) is applied to a system containing biologic and/or non-biologic elements, whereupon the time-varying electrochemical or electrical response is detected and analyzed. For biologic specimens, the presence, activity, concentration or relative quantity, and certain inherent characteristics of certain target substances (hereinafter referred to as “target analytes”) within, or comprising, the specimen of interest may be determined by measuring either the current response induced by a voltage-mode excitation, or the voltage response induced by a current-mode excitation. Labeling or marker techniques may be employed, whereby electrochemically active auxiliary molecules are attached to the substance to be analyzed, in order to facilitate or enhance the electrochemical or electrical response.

Abstract: A voltage indicator circuit for indicating a charge state of a power supply, such as a battery pack, is disclosed. The voltage indicator circuit includes a voltage divider circuit that connects to a plurality of series connected light sources, such as light emitting diodes. Upon activation of the voltage divider circuit, one or more of the light sources may illuminate to provide a visual indication of the current charge state of the power supply. More particularly, the number of light sources illuminated varies according to the charge state of the battery pack.

Abstract: An electronic battery tester connectable to a battery through any one of multiple cables. The tester includes an input that can couple to any one of the multiple cables. Also included is a memory that contains multiple calibration values, each calibration value corresponds to a different one of the multiple cables. Test circuitry, which is coupled to the input and to the memory, detects which one of the multiple cables is coupled to the input, and tests the battery as a function of one of the multiple calibration values that corresponds to the detected one of the multiple cables.

Abstract: A method and apparatus for detecting a resistive fault in an electrical conductor is presented. The apparatus of the invention includes an oscillating signal generator that applies an oscillating signal to the electrical conductor under test. The apparatus includes a measuring device for measuring the potential between the electrical conductor under test and a reference node. Such measurements are obtained both when the apparatus is disconnected from the electrical conductor under test and when the apparatus is connected to the electrical conductor under test. A difference in the measurements indicates that the connectivity of the electrical conductor is intact, whereas no difference indicates that a resistive fault exists somewhere in the electrical conductor. For greater accuracy, the longitudinal balance of the disconnected apparatus and connected apparatus measurements are calculated to determine connectivity.

Abstract: A discharge current and terminal voltage of the battery are periodically measured while a rush current flows into a predetermined constant load of the loads. The rush current first monotonically increases from zero to a peak value and subsequently monotonically decreases from the peak value to a steady value. A first approximate expression of a current-voltage characteristic for the increasing discharge current and a second approximate expression of a current-voltage characteristic for the decreasing discharge current are computed. An intermediate value of two values of the terminal voltage change per unit current change at points corresponding to the peak values of the first and second approximate expressions excluding a voltage drop caused by a concentration polarization component is computed when the first and second approximate expressions include the voltage drop. The intermediate value computed is measured as the pure resistance of the battery.

Abstract: A method and an apparatus for utilizing a periodic disconnection of a cathodic protection circuit, the voltage fluctuations caused on a cathodically protected structure by periodic disconnection of the protection circuit being detected in an apparatus and used for remote-controlled disconnection of a decoupling capacitor. Detection of periodically occurring negative-going voltage edges on a cathodically protected structure. The voltage supply of an apparatus through a capacitor or an electric circuit by means of a current transformer and a voltage outlet via a breaker.

Abstract: An architecture for organising information in a battery monitoring system, the architecture having a hierarchy of levels including a first level containing information relating to battery variables; a second level containing information relating to analysis of real-time or trend behaviour of the battery variables, and a third level containing user information relating to user and/or maintenance parameters, the user information being derived from the first and/or second level information. A method of estimating the condition of one or more cells, the method including periodically measuring the capacity of the cells, wherein the type of measurement and/or the period between measurements is dependent upon the state of health of the cell or cells and/or the result of a previous test.

Abstract: A battery capacity detection device and the method for the same are disclosed. The charge time for the capacitor in an RC circuit and a lookup table are employed to determine the charge capacity of the battery. The disclosed device uses a microprocessor with a programmable pin to form a discharge loop that controls the RC circuit. Therefore, the microprocessor can measure the current charge capacity of the battery after each time the capacitor discharges by measuring the time needed for the capacitor to get fully charged.

Abstract: A method of measuring impedance is based on carrier function Laplace transform. The measurement includes detecting a response signal from a device under test, to which signal an excitation such as a pulse, interrupt or constant load is applied. Resulting data is fitted to a carrier function, selected so as to be capable of providing a good fit and for which an analytical Laplace transform is known, in order to obtain parameters of such function providing best fit. Obtained parameters are further substituted into the analytical expression of Laplace transform of carrier function which is used to calculate a frequency dependent impedance function in the Laplace domain. The resulting impedance function is used for calculating the impedance spectrum in a frequency domain and for calculating the measurement error of the frequency domain impedance spectrum using the standard deviations of the parameters, obtained during fitting of time-domain data.

Abstract: Methods and apparatus employ the use of arrays of two or more electronically discrete electrodes to facilitate high-throughput preparation and testing of materials with two or more elements. High rates of deposition, synthesis and/or analysis of materials are achieved with the use of arrays of electrodes whereby desired materials are developed. The high rate synthesis and/or analysis of an array of materials uses deposition control techniques in conjunction with the electrode array to develop a meaningful array of materials and to analyze the materials for desired characteristics to develop one or more materials with desired characteristics. The use of an array of electrodes enables high throughput development of materials having scientific and economic advantages.

Abstract: An acid concentration continuous measuring apparatus is equipped with the combination of a body having a flow path through which pickling solution contained in a pickling tank is made to continuously pass in a single direction, a density sensor, a temperature sensor, and a conductivity sensor which are installed on the body and substantially continuously measure the pickling solution flowing along the flow path, and a calculating apparatus which calculates the acid concentration of the pickling solution based on the measured results. Feedback control of the hydrochloric acid concentration in a final pickling tank of a plurality of pickling tanks forming a continuous pickling line is performed using the acid concentration continuous measuring apparatus.

Abstract: A device for controlling the operation of a vehicle battery exhibits two current paths for connecting the battery to the vehicle electrical system. Here, the first current path allows current to flow in both directions and the second current path only allows a charging current to flow from the vehicle electrical system to the battery. In addition, the first current path contains a switch which is only closed when the voltage at the generator connection is less than a predetermined value. Apart from this, a measuring device which measures a change in the state of charge of the battery, a storage device which stores the instantaneous state of charge of the battery, and a checking device which checks a predetermined electrical criterion for the maximum attainable state of charge of the battery, are provided.

Abstract: A battery capacity detection device and the method for the same are disclosed. The charge time for the capacitor in an RC circuit and a lookup table are employed to determine the charge capacity of the battery. The disclosed device uses a microprocessor with a programmable pin to form a discharge loop that controls the RC circuit. Therefore, the microprocessor can measure the current charge capacity of the battery after each time the capacitor discharges by measuring the time needed for the capacitor to get fully charged.

Abstract: The invention relates to a method for compensating for the measuring error in detecting current in an energy storing means (1), in which the detecting current is effected via a first current converter (9) and a second current converter (10) for higher currents, and the converter values (14), (15) of the two current converters (9), (10) are converted in an electronic evaluation unit (13) into measured values (17). The measured values for the battery current IBatt. (6) are measured with both current converters (9), (10) upon reaching a threshold (24), and from this the offset (27) of one current converter (10) is determined and corrected by the measured values (30).

Abstract: Liquid conductivity and temperature are measured in respective sensitivity fields that are collocated—i. e., in volumes that nearly match by mathematical, geometrical, or functional criteria. Collocation is as distinct from mere adjacency or proximity; and is with respect to measurement volumes, not measuring hardware. Preferably pressure too is measured with sensitivity very generally collocated to the conductivity and temperature sensitivity. Preferably, respective temporal/spatial bandwidths of the two (or three) sensors are matched. Preferably the pressure sensor is a MEMS transducer, the conductivity sensor is a four-terminal device, the thermometer is a thermistor encapsulated in a silkscreened glass wall, and circuits (1) compensate for time lag between conductivity and temperature measurement, (2) remove artifacts due to detritus in or near either sensor, and (3) derive secondary parameters of the liquid.

Abstract: The present invention relates to an offshore installation including an oil/gas flowline umbilical installed between a platform—or a shore installation—and a sea bed based template and including an insulated electrical cable conductor connected in series with the steel oil/gas pipe to a power supply. The main features of the invention is that the far end interconnection between the cable conductor (or parallel cable conductors) and the pipe is grounded to seawater to provide a single point grounded system, such that all the current flows in the selected cable conductors, and the system has zero volts at the far end whereby no current is transmitted though the sea. The power supply is insulated from ground and the current is fed from the power supply through the pipe, and returns through the cable, whereby a voltage level of zero Volts is obtained at the far end where the system is grounded, and all the current is forced through the cable(s) and the pipe/flowline.

Abstract: A power source device comprises a cell unit 12 comprising a plurality of cells 12a. Connected between a positive side terminal and a negative side terminal of the cell unit 12 is a first current line 34 having two voltage dividing resistors 30, 32 interposed therebetween, and is a second current line 22 having two protection resistors 14, 16 and two detection resistors 18, 20 interposed therebetween. An intermediate point 24 of the second line 22 is grounded to a grounding 26 via an insulation resistor 28. The voltage difference between a voltage (V1, V2) detected by the detection resistors 18, 20 and a reference voltage (Vc) obtained from a point of connection 35 between the voltage dividing resistors is input to two Op-Amps 36, 38 serving as the input voltage (V1IN, V2IN). Based on the output voltage (V1OUT, V2OUT) obtained from the Op-Amps 36, 38, leakage occurrence is detected.

Abstract: Apparatus for determining the distribution of the electric polarization of a vessel in water, comprises an array of electric potential sensors (22) which are located in the water beneath the vessel and each generates a signal corresponding to the amplitude of the electric potential at the sensor as effected by the vessel, a signal processor unit (48) and cables (42) connecting each sensor (22) to the signal processor unit (48) to deliver each respective signal to the signal processor unit, the signal processor unit (48) serving to determine the potential difference between respective pairs of sensors (22) from the respective signals they generate, and the signal processor unit (48) processing multiple such potential difference determinations to deduce the distribution of electric polarization in the vessel which would cause said electric potential at each of the electric potential sensors (22).

Abstract: Disclosed herein is a battery inspection system. The battery inspection system includes a battery feeding conveyor for feeding batteries to be inspected. One or more transfer robots are positioned near the rear end of the battery feeding conveyor for transferring batteries fed through the battery feeding conveyor to inspection and discharge positions. An X-ray generator is positioned under the transfer robots for applying X-rays to batteries transferred by the transfer robots. A satisfactory battery discharging conveyor is positioned near the transfer robots for discharging satisfactory battery moved by the transfer robots and having been inspected. A defective battery discharging robot is positioned near the front end of the satisfactory battery discharging conveyor for removing defective batteries from batteries moving along the satisfactory battery discharging conveyor and having been inspected.

Abstract: An apparatus configured to couple to a battery contact is provided. The apparatus includes an electrical connector for connection to a battery contact and an environment sensor integrated with the electrical connector, the environment sensor senses changes in a battery environment during battery charging or testing. In addition, a method of coupling an electrical circuit to a battery contact is provided.

Abstract: The present invention supports power management modes which includes (1) a maximum power performance mode, (2) a battery-optimized mode, and (3) a performance/optimization cycling mode for performing the maximum performance mode and the battery-optimized mode alternately within a prescribed period of time. The cycling mode allows flexibility in power management and faster charging of the battery.

Abstract: A method for measuring fitness for use of a storage battery subject to electric loading including determining a load profile (current profile I(t) or power profile P(t)) as a function of time t, for the storage battery, recording an actual voltage response U(t) of the storage battery to the load profile or calculating a voltage response U(t) of the storage battery to the load profile, and determining a fitness for use value SOH for the storage battery based on the difference between a lowest (highest) voltage value Umin (Umax) during application of the load profile to the storage battery, and based on a voltage limiting value U1, wherein U1 is a voltage value which may not be undershot (overshot) by the voltage U(t) at any time t during which the load profile is applied to the storage battery.

Abstract: A method for determining performance of a storage battery including evaluating a time profile of voltage drop in the storage battery by application of a heavy current load, determining a voltage A from voltage response U(t) of the storage battery after switching on the heavy current load, determining a state value A1 from the voltage value A, battery temperature TBAT and state of charge SOC, comparing state value A1 with a preset value A1x which depends at least on associated battery temperature (TBAT) and associated state of charge (SOC) of the storage battery, wherein the present value A1x is calculated from comparison values A1T which are determined from the state values A1 for previous heavy current loads applied to the storage battery, and determining performance of the storage battery from the difference between the present value A1x and the state value A1.

Abstract: A cathode-anode apparatus is constructed whereby the wafer under test, connected to a conducting wire, forms the cathode terminal and a copper plate, also connected to a conducting wire, forms the anode terminal. The wafer under test and the copper plate are immersed in a CuSO4—H2O solution. A positive dc voltage is applied to the copper plate; the dc current ionizes the CuSO4 solution and forms Cu2+ ions. These Cu2+ ions will diffuse to the wafer surface. Most of the Cu2+ ions will accumulate in and around defective contacts or vias in the semiconductor surface making these defective contacts or vias readily identifiable.

Abstract: A pH analyzer is operated to measure pH of a solution by applying a reference electrode current, IREF, to a reference electrode of a pH sensor and an ion-specific electrode current, IGLASS, to an ion-specific electrode of the pH sensor. The currents to the reference electrode and ion-specific electrode are multiplexed to avoid cross-talk. Multiplexing the currents provides a more accurate measurement of electrode impedance for diagnostic purpose. A current spike is optionally added to the reference electrode current to discharge any charge in the solution due to the reference electrode current.

Abstract: A system and method for monitoring and reporting on the condition of a vehicle battery which measures battery voltage and current drain during engine start, and computes the battery dynamic internal resistance (IR) and dynamic polarization resistance (PR) from these quantities. Also, the quiescent voltage (QV) of the battery, which is that measured while the vehicle electrical system has a current drain of from 0 to a predetermined amount, is measured and the battery state-of-charge (SoC) is computed from the QV. From these quantities, calculations are made of quantities such as rate of change of dynamic IR and PR to analyze battery condition, rate of change of QV and SoC to predict the time during which the battery can still start the engine, and minimum ambient temperature at which the battery will be able to start the engine, and of other conditions.

Abstract: A sensor array for detecting the distribution of fluids having different electrical characteristics, comprising a multilayer structure including a first layer which defines an array of spaced apart sensor electrodes, a second layer separated from the first layer by dielectric material and defining a conductive screen, and a third layer separated from the second layer by dielectric material and defining a series of spaced apart elongate connections, each sensor being connected to a respective connection by a respective conductive path extending through an opening in the conductive screen defined by the second layer.

Abstract: In a process for operating an electric device (1), especially an electric motor drive, an electric consumer (6) is fed from an a.c. network in that the input alternating voltage that is rectified and the intermediate circuit voltage so obtained is applied to the half bridges of a bridge circuit. Each of the half bridges has two bridge arms (7a, 7b) in which in any given case at least one semiconductor switch (8a, 8b) is arranged, to which control signals are applied through an actuation circuit (9a, 9b) fed from an auxiliary supply voltage source (16). Each of the bridge arms is connected to one of the poles (4) of the intermediate circuit voltage (5), and a test shutdown of the auxiliary supply voltage is applied to the actuation circuit (9a, 9b) of this semiconductor switch (8a, 8b) during a non-actuation phase of the semiconductor switch (8a, 8b) arranged in the relevant bridge arm.

Abstract: Liquid conductivity and temperature are measured in respective sensitivity fields that are collocated—i. e., in volumes that nearly match by mathematical, geometrical, or functional criteria. Collocation is as distinct from mere adjacency or proximity; and is with respect to measurement volumes, not measuring hardware. Preferably pressure too is measured with sensitivity very generally collocated to the conductivity and temperature sensitivity. Preferably, respective temporal/spatial bandwidths of the two (or three) sensors are matched. Preferably the pressure sensor is a MEMS transducer, the conductivity sensor is a four-terminal device, the thermometer is a thermistor encapsulated in a silkscreened glass wall, and circuits (1) compensate for time lag between conductivity and temperature measurement, (2) remove artifacts due to detritus in or near either sensor, and (3) derive secondary parameters of the liquid.

Abstract: An acid concentration continuous measuring apparatus is equipped with the combination of a body having a flow path through which pickling solution contained in a pickling tank is made to continuously pass in a single direction, a density sensor, a temperature sensor, and a conductivity sensor which are installed on the body and substantially continuously measure the pickling solution flowing along the flow path, and a calculating apparatus which calculates the acid concentration of the pickling solution based on the measured results. Feedback control of the hydrochloric acid concentration in a final pickling tank of a plurality of pickling tanks forming a continuous pickling line is performed using the acid concentration continuous measuring apparatus.

Abstract: Present invention relates to a process for determining the electrical conductivity of fluids by means of conductively operable conductivity measuring cells using analysis and processing measurement technology, wherein the conductivity of the fluid is determined from a measured resistance value and the geometric measuring cell constants (k); in order to reduce error in the determination of the electrical conductivity, this is determined in the following manner: by using a measurement converter, the impedance of the measuring cell immersed in the fluid is determined for at least two frequency values of an alternating voltage, the frequency-independent parameters (n, Q) and the desired resistance (Rf1) are determined based on the determined impedance values and based on an equivalent circuit diagram comprised of a parallel connection of a capacitor (Ccell) representing the measuring cell capacitance, an ohmic resistance (Rf1) representing the desired resistance of the fluid inside the conductivity measuring ce

Abstract: Apparatus for, and a method of, simultaneously measuring the concentration of a selected ion species in a solution and the pH of the solution, uses an ion selective electrode, a reference electrode and an ISFET immersed in the solution. The ion concentration is determined in a first circuit from the potential difference between the ion selective electrode and the reference electrode, and the pH is determined in a second circuit from the current flowing between the ISFET and the reference electrode. The reference electrode is connected into the second circuit via a high resistance so as to isolate the two circuits from each other. The earth potential of the solution is connected to provide the earth potential of the first circuit, and is connected to the second circuit via a high capacitance so as to provide a virtual earth thereforee. Each circuit is supplied from a separate power source, and the circuit outputs are supplied via respective isolation amplifiers to a multi-channel meter.

Abstract: A voltage measuring circuit for measuring a voltage level of an unknown voltage source, including a capacitor configured for storing a charge from the unknown voltage source, a switch such as a transistor, configured to discharge the capacitor after the capacitor has reached a known threshold voltage, a microprocessor which controls the switch and measures the amount of time required to charge the capacitor to the threshold voltage, allowing the voltage level to be measured without disconnecting the capacitor from the circuit.

Abstract: A detection device which measures the electrolytic conductivity of a fluid in a small tube or a capillary, including first and second electrodes which are both located outside the tube or capillary and placed along the path of the liquid in a longitudinal direction of the tube or capillary and separated from each other by a distance along the tube or capillary. The first and second electrodes are adapted to be connected to an AC power source and coupled to a processing device.

Abstract: A detection device which measures the electrolytic conductivity of a fluid in a small tube or a capillary, including first and second electrodes which are both located outside the tube or capillary and placed along the path of the liquid in a longitudinal direction of the tube or capillary and separated from each other by a distance along the tube or capillary. The first and second electrodes are adapted to be connected to an AC power source and coupled to a processing device.

Abstract: An apparatus and method for measuring an electrochemical impedance at high speed. The method for measuring the electrochemical impedance of an electrolyte at high speed includes applying a direct current (DC) voltage having the reaction potential of the electrolyte to the electrolyte via a counter electrode and, after a delay, applying a signal voltage, including a DC voltage added to a differentiated or integrated Dirac-delta function voltage, to the electrolyte; computing a digital data value related only to the differentiated or integrated Dirac-delta function voltage, obtained by converting signal current flowing in a working electrode via the electrolyte into a voltage, integrating or differentiating the voltage, and Fourier transforming the result of the integration or differentiation; and obtaining changes in magnitude and phase as a function of frequency based on the Fourier transform, to compute the impedance.

Abstract: An electrochemical field probe for measuring solute concentrations of elements dissolved in a liquid, such as a molten metal bath, generally including a base having a first end, a second end, an external surface, and extending about a longitudinal axis, a reference electrode positioned between the first and second ends of the base, and a glassy electrolyte positioned adjacent the reference electrode, wherein the reference electrode is a Mo substrate coated with a electrode reference material selected from a group including NiAl, graphite, Cr, a compound of Mo and Mo3Si, a compound of Cr and Cr2O3, a compound of Ti and TiN, a compound of Ti and TiS, and a compound of Th and ThP and the glassy electrolyte is selected from a group including a compound of 38% CaO, 42% SiO2, and 20% Al2O3, soda glass, pyrex powder, and a pre-fused mixture of cryolite (Na3AlF6) admixed with approximately 5% to 10% CaF2 (fluorspar) and approximately 4% to 7% Al2O3.

Abstract: A circuit for a NOx concentration sensor includes two connected measurement cells disposed in a solid-state electrolyte, a first circuit configuration that, by tapping off a first Nernst voltage (first reference variable), establishes in the cell an oxygen concentration that differs from that in a measured gas, a second circuit configuration that, by tapping off a second Nernst voltage (second reference variable), establishes in the cell an oxygen concentration that differs from that in the first cell, a third circuit configuration that, by tapping off a third Nernst voltage (third reference variable), drives a pump current of oxygen ions that originate from NOx, out of the second cell, a conditioning circuit, and a digital controller.

Abstract: The pump currents in an NOx measurement sensor are generated by voltage-controlled current sources. Instead of the respective pump current, a setting voltage received by the voltage-controlled current sources occurs as the feedback variable in a respective control loop, so that a current measurement can be dispensed with.

Abstract: A method of measuring quantities that indicates the state of an electrochemical device having an electrode and an ionic conductor, such as material properties or a residual capacity, without disassembling the device. The quantities are measured by comparing (a) a series of theoretical data of an electrical characteristic of the device obtained by combining at least one of an electron transportation model of the electrode, an ion transportation model of the electrode, an ion conduction model of the ionic conductor and a model of an electrochemical reaction taking place in an interface between the electrode and the ionic conductor, with a potential model of the electrode, with (b) a series of measured data of the electrical characteristic of the electrochemical device.

Abstract: A buoyant water conditioner has a housing with an upper surface and an apertured chamber for receiving a chlorination agent. Three separate measurement systems are carried by the housing: a water temperature system, a pH level system, and a chlorine concentration system. Each system has a sensor for measuring the respective water parameter, a display for displaying the measured value, and a processor for converting the sensor signals to display driving signals. Each system is powered by a solar cell battery or a chemical battery.

Abstract: A battery cell inspection method in which the difference in the measured value in case of normal battery cell insertion and that incase of mistaken battery cell insertion is large to facilitate decision as to whether or not mistaken insertion occurred to enable stable result of decision to be achieved, and in which, if the area of the electrode plate and/or the number of the electrode plates making up a sole battery cell is small, decision as to mistaken insertion can be given easily to assure correct results of decision.