Fast Screening Method for Used Batteries Using Constant-Current Impulse Ratio (CCIR) Calibration

We claim: 1 . A method for screening a battery for reuse or disposal comprising: (a) charging the battery with a constant current until a battery voltage reaches a voltage threshold; (b) multiplying a value of the constant current by a Constant-Current (CC) time period during which the constant current is applied to the battery to reach the voltage threshold to generate a constant-current charge value that is stored in a computer memory; (c) after the voltage threshold is reached, charging the battery with a constant voltage until a variable current applied to the battery voltage reaches a current threshold; (d) integrating a value of the variable current over a Constant-Voltage (CV) time period that the constant voltage and variable current are applied to the battery to reach the current threshold to generate a constant-voltage charge value that is stored in the computer memory; (e) generating a Constant-Current Impulse Ratio (CCIR) by dividing the constant-current charge value by a sum of the constant-current charge value and the constant-voltage charge value; inputting the CCIR to a calibration function processor that outputs a modeled State of Health (SOH) value that corresponds to the CCIR input to the calibration function processor; and using the modeled SOH value to classify the battery for reuse when the modeled SOH value is above a SOH threshold, and to classify the battery for disposal when the modeled SOH value is below the SOH threshold. 2 . The method of claim 1 wherein step (a) further comprises: discharging the battery to a starting voltage before applying the constant current, wherein the battery is charged from the starting voltage to the voltage threshold during the CC time period. 3 . The method of claim 2 further comprising: pre-screening the battery by measuring an initial voltage of the battery before discharging the battery to the starting voltage, and discarding the battery when the initial voltage of the battery is less than a minimum pre-screened voltage. 4 . The method of claim 2 wherein the constant current is 20% of a maximum battery current. 5 . The method of claim 2 further comprising: sorting the battery into one of multiple bins in response to the modeled SOH value, wherein each of the multiple bins receives batteries having a different range of modeled SOH values. 6 . The method of claim 2 further comprising: generating a CCIR-SOH model that programs the calibration function processor to generate the modeled SOH values from input CCIR values by: (f) performing steps (a) to (e) on a new battery and storing the CCIR as a model-input CCIR value; (g) discharging the new battery with the constant current during a capacity-measuring time period that ends when the new battery reaches a second voltage threshold; (h) multiplying the value of the constant current by the capacity-measuring time period to generate a present capacity charge value that is stored in the computer memory; (i) generating a model-input SOH value by dividing the present capacity charge value by an initial capacity charge value, wherein the initial capacity charge value is the present capacity charge value before the new battery is aged by step (j); (j) aging the new battery by repeatedly charging and discharging the new battery over N charge/discharge cycles, wherein N is a whole number of at least 10; repeating steps (f) to (i) after the new battery is aged; using the model-input CCIR values and the model-input SOH values to generate parameters that describe the CCIR-SOH model that programs the calibration function processor to generate the modeled SOH values from input CCIR values. 7 . The method of claim 6 wherein using the model-input CCIR values and the model-input SOH values to generate parameters that describe the CCIR-SOH model further comprises: (m) inputting the model-input CCIR values to input of a neural network; using the neural network to process the model-input CCIR values to generate a calculated SOH value; comparing the calculated SOH value to the model-input SOH value using a loss function to generate a loss value; using the loss value to adjust weights to nodes within the neural network and repeating from step (m) until a modeling endpoint is reached; storing the weights in a computer memory connected to the neural network; when the modeling endpoint is reached, using final values of the weights with the neural network to generate the modeled SOH value from the CCIR input to implement the calibration function processor that generates the modeled SOH values from input CCIR values. 8 . The method of claim 7 wherein the neural network comprises a first layer of nodes that perform wavelet functions, and a second layer of nodes that perform product functions, and a third layer of nodes that perform summing functions. 9 . The method of claim 7 further comprising: (k) comparing the model-input SOH value to an endpoint SOH value; when the model-input SOH value is greater than the endpoint SOH value, continuing from step (j) to continue aging the new battery; when the model-input SOH value is greater than the endpoint SOH value, jump to step (m) to generate the CCIR-SOH model. 10 . A battery screening method comprising: initially discharging a battery using an initial constant current until a lower voltage target is reached; cooling the battery after initial discharge for a period of rest time; charging the battery using a constant current until an upper voltage target is reached and recording a Constant-Current charge, Q CC , of charge transferred to the battery by the constant current; switching to a Constant-Voltage (CV) charging process when the upper voltage target is reached, and recording a Constant-Voltage charge, Q CV , of charged transferred to the battery during the CV charging process; calculating a Constant-Current Impulse Ratio (CCIR) as a ratio of one of the group consisting of Q CC and Q CV , to a sum of Q CC and Q CV ; inputting the CCIR to a calibration function generator that returns a modeled State of Health (SOH) value that corresponds to a value of the CCIR inputted; using the modeled SOH value to determine when the battery is to be discarded and when the battery is to be reused, whereby the battery is screened based on the modeled SOH value that is a function of the CCIR measured. 11 . The battery screening method of claim 10 further comprising: during the Constant-Voltage (CV) charging process, allowing a charging current to vary while maintaining a constant voltage applied to the battery. 12 . The battery screening method of claim 11 further comprising: terminating the CV charging process when a lower current target is reached for the charging current. 13 . The battery screening method of claim 12 further comprising: generating calibration datapoints by aging and measuring a plurality of new batteries, each new battery being processed by a calibration data-collection process that comprises: (a) initially discharging the new battery using an initial constant current until the lower voltage target is reached; cooling the new battery after initial discharge for a period of rest time; charging the new battery using the constant current until the upper voltage target is reached and recording a Constant-Current charge, Q CC , of charge transferred to the new battery by the constant current; switching to the Constant-Voltage (CV) charging process when the upper voltage target is reached, and recording a Constant-Voltage charge, Q CV , of charged transferred to the new battery during the CV charging process; calculating a datapoint C