Abstract: There is provided a charging apparatus comprising a charging circuit for charging a battery cell of a battery pack; a computing unit which is supplied with information on detected voltage of the battery cell and information on a quantity of accumulated charging current from the battery pack and information on power consumption of an electronic equipment using the battery pack; and a display unit for indicating the result of computation of the computing unit; and being arranged such that the computing unit calculates a present charged capacity of the battery cell being charged and an usable duration of the electronic equipment using the battery pack by the present charged capacity and indicates them on the display unit.

Abstract: A modification to existing mono-block battery design for positively indicating the operating condition of the battery. The voltage of two groups of internal series connected cells are measured and compared. An indicator of one color indicates the battery is operating normally, an indicator of a contrasting color indicates the battery is defective.

Abstract: An apparatus for charging a battery includes a first electrical connection adapted to connect to a positive terminal of the battery and a second electrical connector adapted to connect to a negative terminal of the battery. An electrical charging source couples to the first and second electrical connectors to charge the battery. Voltage measurement circuitry couples to the first and second electrical connectors and responsively provides a voltage output related to voltage across the battery. Current measurement circuitry also couples to the first and second electrical connectors and responsively provides a current output related to electrical current through the battery. State of charge measurement circuitry responsively provides a state of charge output as a function of the voltage output and the current output.

Abstract: A controller for a hybrid electric system such as a hybrid electric vehicle includes a load, a battery, and a controllable source of auxiliary electricity. The state of charge (SOC) of the battery is estimated, and an error signal is generated which represents the difference between a desired and actual SOC. The SOC error signal is processed by at least integration, to produce a source signal representing the desired auxiliary source current. A second error signal is generated between the actual current. from the auxiliary source and the desired current from the auxiliary source. The second error signal is processed, at least by integration, to produce a control signal for controlling the auxiliary signal source.

Abstract: A smart battery that self-monitors and maintains information about itself that includes its state of charge, its need for maintenance, and for conditions that indicate that it has reached the end of its useful life and should be discarded. The information maintained by the battery is then either displayed on an on-board display or is communicated to another device on a communication bus. The state of charge quantifies the smart battery's ability to reliably deliver charge to a host device and is dynamically adjusted over the lifetime of the smart battery. The state of charge may not exceed a full charge capacity value maintained by the smart battery and initially set to an estimated value. This full charge capacity value is dynamically adjusted throughout the life of the smart battery using information accumulated and maintained by the smart battery that indicates the smart battery's actual performance during use and by using messages received from a battery maintenance and testing system.

Abstract: A mobile electronic device can operate in multiple modes, each at a respective current load. Monitoring a battery in such a mobile device includes acquiring a sensed battery voltage during a particular operating mode and converting the sensed battery voltage to a scaled voltage for a known battery discharge curve having a well-defined turn-off voltage. The known battery discharge curve is preferably one for a full current load. The scaled voltage is then compared with the well-defined turn-off voltage to determine the amount of energy remaining in the battery. Operating times for other operating modes can also be calculated and displayed for the user's information.

Abstract: An on-line battery management and monitoring system and method for monitoring a plurality of battery cells identifies and computes individual cell and battery bank operating parameters. The system comprises a central monitoring station to which a plurality of controllers is connected, each controller having a plurality of battery cells which it monitors.

Abstract: A method for determining state of charge (SOC) of an electrochemical device using fuzzy logic (i.e., an intelligent system) is presented. State of charge of an electrochemical device is determined by an internal characteristic or parameter (or external operating and environmental conditions) with an intelligent system. The electrochemical device comprises such devices as primary ("throwaway") batteries, rechargeable batteries, fuel cells, a hybrid battery containing a fuel cell electrode and electrochemical supercapacitors. The intelligent system is trained in the relationship between the characteristic of the electrochemical device and the SOC of the electrochemical device.

Abstract: The apparatus for metering the state of charge of a battery has a battery current sensor providing a voltage signal dependent on a current flowing into or out of the battery, an integrator for integrating the voltage signal, a window detector circuit providing an output signal each time an output of the integrator reaches an upper or lower threshold voltage level, a digital processing device utilizing the output signals of the window detector circuit to construct a digital battery charge state model, and a switch arrangement for reversing connection of the battery current sensor to the integrator periodically so as to cancel effect of any voltage offset in the output of the integrator.

Abstract: An electronic circuit and a method for accurately measuring intermittent current pulses supplied by a storage battery to energize a load. In the preferred embodiment, an analog integrator accumulates current pulses in response to a voltage drop across a sense resistor that is connected in series between the storage battery and the load. The voltage drop is proportional to the flow of current from the battery through the load. The output of the integrator is filtered with a low pass filter to block high frequency noise, and the output of the filter is coupled to an analog to digital (A/D) converter that transforms the filtered analog signal into a corresponding digital signal. The output of the A/D converter is supplied to a port of a processor. The processor provides a signal to actuate a reset switch coupled across the integrator. When closed at the end of each integration time period, this switch zeroes the output of the analog integrator.

Abstract: A method (200) for charging a nickel cadmium, nickel-metal hydride or lithium-ion battery cell using an ultra-fast vehicular charging system includes determining (201, 203, 205) manufacturer identity, ultra-fast battery charging capability and battery capacity from the battery system to provide (207) battery type information. A direct current (DC) input voltage in a predetermined input supply voltage range is converted (211) to a an output supply current in a predetermined output voltage range. The predetermined output supply voltage is supplied (217) to the battery cell for recharging while a number of battery parameters are monitored (219) such as the battery cell voltage, charging current and temperature of the battery cell to generate monitoring information.

Abstract: An apparatus and method for initiating an intelligent battery discharge in an electrical system thereby allowing battery diagnostic testing to be performed more efficiently and more accurately. Specifically, the discharge is initiated by reducing the voltage being supplied to the electrical system by a main power supply such that the battery power supply begins supplying the system voltage. The output of the main power supply is only reduced to a predetermined non-zero level, such that the battery power supply will begin discharging while the main power supply continues to maintain a floor voltage. This floor voltage ensures that the system voltage will not fall below the floor voltage even if the battery power supply fails completely. Once the battery power supply begins discharging, the system voltage is monitored to determine whether the battery power supply is capable of supplying sufficient electrical power to maintain the system voltage above the floor voltage.

Abstract: A capacity calibration apparatus for the battery of a portable computer system is provided. The computer system includes a main board circuit, a processor unit, a display unit, a power-supply board circuit, a battery and a parallel port interface. The capacity calibration apparatus includes a standard parallel port interface and a control circuit. The standard parallel port interface is connected to the parallel port interface of the computer system. Via the parallel port interface, the computer system outputs at least one control signal to the capacity calibration apparatus. The capacity calibration apparatus selectively outputs the alternating current supply to the power-supply board circuit in order to proceed a charge/discharge procedure of a predetermined type such that the capacity value of the battery is initialized.

Abstract: Known is an induction charging apparatus for charging battery means in an electronic device when inductively coupled to the charging apparatus, the charging apparatus comprising a first casing having a charging receptacle for receiving the electronic device and an alternating current power source coupled to a primary coil provided in the first casing, and the electronic device comprising a second casing provided with a secondary coil electronically coupled to the battery means, whereby the primary and the secondary coil are magnetically coupled for inductively conveying energy from the primary coil to the secondary coil when the electronic device is put in the receptacle.

Abstract: This method to determine remaining capacity of a rechargeable battery calculates remaining battery capacity by subtracting discharge capacity, computed by integrating battery discharge current, from charge capacity. Voltage of the discharging rechargeable battery is measured, and when battery voltage reaches a first voltage and a lower second voltage, the computed remaining battery capacity is corrected according to a previously established first remaining battery capacity and second remaining battery capacity corresponding to those voltages. The difference between calculated remaining battery capacity or discharge capacity at the first and second voltages is compared to the difference between the previously established first and second remaining battery capacity values, and the first voltage is modified to make those two differences equal.

Abstract: A method and apparatus for determining the instantaneous state-of-charge of a battery in which change in composition with discharge manifests itself as a change in optical absorption. In a lead-acid battery, the sensor comprises a fiber optic system with an absorption cell or, alternatively, an optical fiber woven into an absorbed-glass-mat battery. In a lithium-ion battery, the sensor comprises fiber optics for introducing light into the anode to monitor absorption when lithium ions are introduced.

Abstract: A hybrid electric vehicle comprises an electric motor, a battery pack for the electric motor, a generator driven by an engine to provide electric power used for charging the battery pack, and a battery management for the battery pack. The battery management determines a current value of battery temperature (BT) of the battery pack and a current value of state of charge (SOC) within the battery pack. What are stored are a first set of varying SOC values and a second set of varying SOC values against varying BT values. The first set of varying SOC values are minimum SOC values required for the battery pack to produce a constant electric power output at varying BT values. The second set of varying SOC values are each indicative of an allowable upper limit to the quantity of electric charge that will accumulate in the battery pack due to operation of charging the battery pack with a constant electric power input at a corresponding BT value.

Abstract: According to the invention, the discharge depth representing the ratio of discharged capacity relative to the rated discharge capacity of a battery is divided into a plurality of ranges with each range allocated with the number of charges at which a refresh discharge should be carried out. The discharge depth is obtained as a sum of discharged capacity between one charge and the next. At the time of charging, summing up the count of the number of charges in the corresponding range according to the discharge depth is repeated until the number of charges in any of the ranges reaches the number at which the refresh discharge should be carried out. Then the refresh discharge is carried out either automatically or manually.

Abstract: An electrolyte level monitor used in combination with a battery having multiple cells. The monitor includes a circuit having an indicator which operates when the electrolyte level is at or above the minimum acceptable electrolyte level. The circuit is connected across cells of the battery to provide a potential to operate the monitor.

Abstract: A self-correcting and adjustable apparatus and method of predicting remaining capacity (Q) and reserve time (t) of a discharging battery to a selected end voltage determined by an arrangement considering the open circuit voltage (E.sub.oc), battery voltage (V) battery temperature (T) and battery internal resistance (R.sub.int). The apparatus and method of the present invention utilize a calculation process which first compares calculated and measured capacity discharged between two times (Q.sub.dis.calc. -Q.sub.dis.act.). If this difference exceeds a certain predetermined tolerance or limit of error, the calculation process is adjusted or tuned and the comparison is repeated until the difference between the actual capacity and the calculated capacity are within a predetermined tolerance. The calculation process is tuned by adjusting the value attributed to the battery's internal resistance (R.sub.int).

Abstract: The present invention measures the energy consumption of battery-powered telephone devices to prevent the inadvertent deep discharge of a vehicle's battery by prolonged use of said devices when the vehicle is unattended. In a preferred embodiment, current to the devices is incrementally measured or estimated from a measurement of other relevant parameters. The incremental measurements of current are accumulated to produce a total current consumption indicative of the total energy consumption. At each update after an incremental measurement, the accumulated total is compared to a pre-established or adaptively determined. When the total energy consumption meets or exceeds the threshold, the power to the battery-powered telephone device is interrupted in order to conserve a sufficient amount of power to start the vehicle and to operate other peripheral systems.

Abstract: A portable hair dryer (12) comprising a tubular housing (14) having an air inlet end (16) and an air outlet nozzle end (18). A foldable hollow pistol-type handle (20) is pivotally connected at pivot pin (22) to the tubular housing (14) adjacent the air inlet end (16). The handle (20) can pivot from an inoperative position parallel to the tubular housing (14) to an operative position perpendicular to the tubular housing (14). An electrically actuated air pump assembly (24) is in the tubular housing (14) to draw air in through the air inlet end (16) and out through the air outlet nozzle end (18). An electrical resistance heating element (26) is disposed within the tubular housing (14) between the air pump assembly (24) and the air outlet nozzle end (18), to heat the air passing through the tubular housing (14). A circuit (28) electrically connects the air pump assembly (24) and the heating element (26) with a source of electrical power through the handle (20).

Abstract: A battery monitoring routine is executed at a short period such as one minute as an initial value when a key switch is turned on to drive an electric vehicle (so that the battery is discharged). On the other hand, when the key switch is turned off to stop or park the electric vehicle so that the battery is released open from discharge, the battery monitoring routine is executed at a short period such as one minute to measure the battery data finely within a specified time such as 30 minutes, but at a long period such as one hour to measure the battery data coarsely after the specified time such as 30 minutes to save monitoring power. The battery deterioration can be monitored by measuring the restoration status of the battery after released open from discharge, for recharging or replacement of the battery.

Abstract: Apparatus indicates a charge on a battery that has a predetermined operating range. The apparatus includes a thermochromatic material for displaying the charge level of the battery, and a resistive heating device, which is in thermal contact with the thermochromatic material, for generating heat for activating the thermochromatic material. A controlling device which is connected to the resistive heating device is also included for controlling the heat generated by the heating device so that the thermochromatic material has sufficient resolution to indicate the charge on the battery over a substantial portion of the thermochromatic material.

Abstract: A charging apparatus for charging a secondary battery, arranged in such a manner that the terminal voltage of the battery being charged is measured and then correlated with remaining charging time and usable time of the battery being charged. The remaining charging time and usable time of the battery being charged is stored in memory and then outputted for display to the operator.

Abstract: A charging apparatus for charging a secondary battery arranged in such a manner that the interterminal voltage of the battery, which is being charged, is measured so that the charging status of the battery is detected in accordance with the measured interterminal voltage of the battery which is being charged and the charging/discharging characteristics with respect to the interterminal voltage of the battery. As a result, the charging status of the battery can accurately be detected.

Abstract: A battery capacity indicating device includes a plurality of switching parts connected in parallel to a battery, each of which outputs a controlling signal corresponding to a predetermined voltage range when a voltage across the battery terminals falls within the predetermined voltage range, with at least one of the predetermined voltage ranges having finite upper and lower limits; a controlling part for receiving the output controlling signal among other controlling signals and generating from the received controlling signals a displaying signal corresponding to a display range into which the voltage falls; and a displaying part for generating a display indication representative of the display range. A battery capacity indicating method is provided wherein the displaying signals corresponding to the controlling signals are output when they are applied.

Abstract: A complete energy management system for lead-acid batteries. The system is designed for deep discharge batteries in traction vehicle type applications such as electric wheelchairs, electric vehicles, golf carts, or industrial equipment, where more efficient use of lead-acid batteries during both the charging and discharging cycle is needed. This system utilizes current measurements, open circuit voltage measurements during the recovery from charging or discharging, and an adaptation calculation to account for variations in physical battery characteristics, battery treatment, battery environment, and battery aging.

Abstract: The invention is directed to a method of conditioning accumulators in an apparatus operating in the line and the accumulator modes, in which an accumulator discharge/charge cycle is effected at cyclic intervals in which the accumulator is at least nearly completely discharged, wherein a count is made of the number of times the apparatus is used, wherein upon attainment of a predetermined frequency of use a cycle is started when the apparatus is connected to the line, in which cycle the accumulator is first completely discharged through a load and subsequently recharged, and wherein following this discharge/charge cycle a fresh count is made of the number of times the apparatus is used.

Abstract: Apparatus with rechargeable battery (B), a load (MR) and a power supply (PS) for charging the battery (B). When the load (MR) receives current from the battery (B) the charge consumed by the load (MR) is measured by means of a series resistor (RS) and a voltage-to-frequency converter (VFC). A microcontroller (MC) computes the average charge consumed per session of usage and computes the number of remaining sessions of usage from the actual charge in the battery (B) and the average charge per session and shows this number on a display (D).

Abstract: A method and apparatus for indicating a low battery condition and for dynamically controlling the load on a battery in order to optimize battery usage. A dynamic load controller for a battery includes detection circuitry for measuring at least one condition related to battery capacity, and power control circuitry for adjusting a power load on the battery based upon the condition. The dynamic load controller may be employed to control the power load on a battery that powers an electrotherapy device, such as a defibrillator. The battery condition may include the slope of a capacity curve, which may be the product of the battery voltage and the power delivered from the battery as a function of the delivered power. Based upon this condition, the power control circuitry adjusts the power load to optimize power delivery from the battery.

Abstract: The present invention provides an estimate of the amount of time left on the battery by monitoring not only the voltage available from the battery, but also the amount of current flowing from the battery. It has been found that periodic sampling of the battery voltage and current drain enables accurate battery monitoring. The sampling technique alternates between sampling battery voltage and sampling current drain. An electric circuit is provided which enables the cost-effective sampling to occur. A method is then applied to the sampling signals by a microprocessor which determines the amount of time left under battery power. In a preferred embodiment, a graphic representation is provided of the amount of battery time left.

Abstract: A power source check apparatus of a camera capable of using one of different type of batteries or battery packs detects the type of the power source used, and checks residual capacity of the power source by measuring the terminal voltage of the power source while applying suitable dummy load current in accordance with the detected type of the power source. The type of the power source is detected on the basis of any one of open circuit terminal voltage, appearance, or data code provided therein.