BatterySimulatorBLAST/nmc111_gr_Kokam75Ah_2017.py

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2023-04-08 06:05:55 +09:00
# Paul Gasper, NREL
import numpy as np
from functions.extract_stressors import extract_stressors
from functions.state_functions import update_power_state, update_sigmoid_state
# EXPERIMENTAL AGING DATA SUMMARY:
# Aging test matrix varied primarly temperature, with small DOD variation.
# Calendar and cycle aging were performed between 0 and 55 Celsius. C-rates always at 1C,
# except for charging at 0 Celsius, which was conducted at C/3. Depth-of-discharge was 80%
# for nearly all tests (3.4 V - 4.1 V), with one 100% DOD test (3 V - 4.2 V).
# Reported relative capacity was measured at C/5 rate at the aging temperatures. Reported
# relative DC resistance was measured by HPPC using a 10s, 1C DC pulse, averaged between
# charge and discharge, calculated using a simple ohmic fit of the voltage response.
# MODEL SENSITIVITY
# The model predicts degradation rate versus time as a function of temperature and average
# state-of-charge and degradation rate versus equivalent full cycles (charge-throughput) as
# a function of temperature and depth-of-discharge. Sensitivity to cycling degradation rate
# at low temperature is inferred from physical insight due to limited data.
# MODEL LIMITATIONS
# There is NO C-RATE DEPENDENCE for degradation in this model. THIS IS NOT PHYSICALLY REALISTIC
# AND IS BASED ON LIMITED DATA.
class Nmc111_Gr_Kokam75Ah_Battery:
# Model predicting the degradation of a Kokam 75 Ah NMC-Gr pouch cell.
# https://ieeexplore.ieee.org/iel7/7951530/7962914/07963578.pdf
# It is uncertain if the exact NMC composition is 1-1-1, but it this is definitely not a high nickel (>80%) cell.
# Degradation rate is a function of the aging stressors, i.e., ambient temperature and use.
# The state of the battery is updated throughout the lifetime of the cell.
# Performance metrics are capacity and DC resistance. These metrics change as a function of the
# cell's current degradation state, as well as the ambient temperature. The model predicts time and
# cycling dependent degradation, using Loss of Lithium Inventory (LLI) and Loss of Active
# Material (LAM) degradation modes that interact competitively (cell performance is limited by
# one or the other.)
# Parameters to modify to change fade rates:
# Calendar capacity loss rate: q1_0
# Cycling capacity loss rate (LLI): q3_0
# Cycling capacity loss rate (LAM): q5_0, will also effect resistance growth onset due to LAM.
# Calendar resistance growth rate (LLI), relative to capacity loss rate: r1
# Cycling resistance growth rate (LLI), relative to capacity loss rate: r3
def __init__(self):
# States: Internal states of the battery model
self.states = {
'qLoss_LLI_t': np.array([0]), # relative Li inventory change, time dependent (SEI)
'qLoss_LLI_EFC': np.array([0]), # relative Li inventory change, charge-throughput dependent (SEI)
'qLoss_LAM': np.array([1e-8]), # relative active material change, charge-throughput dependent (electrode damage)
'rGain_LLI_t': np.array([0]), # relative SEI growth, time dependent (SEI)
'rGain_LLI_EFC': np.array([0]), # relative SEI growth, charge-throughput dependent (SEI)
}
# Outputs: Battery properties derived from state values
self.outputs = {
'q': np.array([1]), # relative capacity
'q_LLI': np.array([1]), # relative lithium inventory
'q_LLI_t': np.array([1]), # relative lithium inventory, time dependent loss
'q_LLI_EFC': np.array([1]), # relative lithium inventory, charge-throughput dependent loss
'q_LAM': np.array([1.01]), # relative active material, charge-throughput dependent loss
'r': np.array([1]), # relative resistance
'r_LLI': np.array([1]), # relative SEI resistance
'r_LLI_t': np.array([1]), # relative SEI resistance, time dependent growth
'r_LLI_EFC': np.array([1]), # relative SEI resistance, charge-throughput dependent growth
'r_LAM': np.array([1]), # relative electrode resistance, q_LAM dependent growth
}
# Stressors: History of stressors on the battery
self.stressors = {
'delta_t_days': np.array([np.nan]),
't_days': np.array([0]),
'delta_efc': np.array([np.nan]),
'efc': np.array([0]),
'TdegK': np.array([np.nan]),
'soc': np.array([np.nan]),
'Ua': np.array([np.nan]),
'dod': np.array([np.nan]),
}
# Rates: History of stressor-dependent degradation rates
self.rates = {
'q1': np.array([np.nan]),
'q3': np.array([np.nan]),
'q5': np.array([np.nan]),
}
# Nominal capacity
@property
def _cap(self):
return 75
# Define life model parameters
@property
def _params_life(self):
return {
'q1_0' : 2.66e7, # CHANGE to modify calendar degradation rate (larger = faster degradation)
'q1_1' : -17.8,
'q1_2' : -5.21,
'q2' : 0.357,
'q3_0' : 3.80e3, # CHANGE to modify cycling degradation rate (LLI) (larger = faster degradation)
'q3_1' : -18.4,
'q3_2' : 1.04,
'q4' : 0.778,
'q5_0' : 1e4, # CHANGE to modify cycling degradation rate (LAM) (accelerating fade onset) (larger = faster degradation)
'q5_1' : 153,
'p_LAM' : 10,
'r1' : 0.0570, # CHANGE to modify change of resistance relative to change of capacity (calendar degradation)
'r2' : 1.25,
'r3' : 4.87, # CHANGE to modify change of resistance relative to change of capacity (cycling degradation)
'r4' : 0.712,
'r5' : -0.08,
'r6' : 1.09,
}
# Battery model
def update_battery_state(self, t_secs, soc, T_celsius):
# Update the battery states, based both on the degradation state as well as the battery performance
# at the ambient temperature, T_celsius
# Inputs:
# t_secs (ndarry): vector of the time in seconds since beginning of life for the soc_timeseries data points
# soc (ndarry): vector of the state-of-charge of the battery at each t_sec
# T_celsius (ndarray): the temperature of the battery during this time period, in Celsius units.
# Check some input types:
if not isinstance(t_secs, np.ndarray):
raise TypeError('Input "t_secs" must be a numpy.ndarray')
if not isinstance(soc, np.ndarray):
raise TypeError('Input "soc" must be a numpy.ndarray')
if not isinstance(T_celsius, np.ndarray):
raise TypeError('Input "T_celsius" must be a numpy.ndarray')
if not (len(t_secs) == len(soc) and len(t_secs) == len(T_celsius)):
raise ValueError('All input timeseries must be the same length')
self.__update_states(t_secs, soc, T_celsius)
self.__update_outputs()
def __update_states(self, t_secs, soc, T_celsius):
# Update the battery states, based both on the degradation state as well as the battery performance
# at the ambient temperature, T_celsius
# Inputs:
# t_secs (ndarry): vector of the time in seconds since beginning of life for the soc_timeseries data points
# soc (ndarry): vector of the state-of-charge of the battery at each t_sec
# T_celsius (ndarray): the temperature of the battery during this time period, in Celsius units.
# Extract stressors
delta_t_secs = t_secs[-1] - t_secs[0]
delta_t_days, delta_efc, TdegK, soc, Ua, dod, Crate, cycles = extract_stressors(t_secs, soc, T_celsius)
TdegC = TdegK - 273.15
TdegKN = TdegK / (273.15 + 35) # normalized temperature
UaN = Ua / 0.123 # normalized anode-to-reference potential
# Grab parameters
p = self._params_life
# Calculate degradation rates
q1 = p['q1_0'] * np.exp(p['q1_1'] * (1 / TdegKN)) * np.exp(p['q1_2'] * (UaN / TdegKN))
q3 = p['q3_0'] * np.exp(p['q3_1'] * (1/TdegKN)) * np.exp(p['q3_2'] * np.exp(dod**2))
q5 = p['q5_0'] + p['q5_1'] * (TdegC - 55) * dod
# Calculate time based average of each rate
q1 = np.trapz(q1, x=t_secs) / delta_t_secs
q3 = np.trapz(q3, x=t_secs) / delta_t_secs
q5 = np.trapz(q5, x=t_secs) / delta_t_secs
# Calculate incremental state changes
states = self.states
# Capacity
dq_LLI_t = update_power_state(states['qLoss_LLI_t'][-1], delta_t_days, 2*q1, p['q2'])
dq_LLI_EFC = update_power_state(states['qLoss_LLI_EFC'][-1], delta_efc, q3, p['q4'])
dq_LAM = update_sigmoid_state(states['qLoss_LAM'][-1], delta_efc, 1, 1/q5, p['p_LAM'])
# Resistance
dr_LLI_t = update_power_state(states['rGain_LLI_t'][-1], delta_t_days, p['r1']*q1, p['r2'])
dr_LLI_EFC = update_power_state(states['rGain_LLI_EFC'][-1], delta_efc, p['r3']*q3, p['r4'])
# Accumulate and store states
dx = np.array([dq_LLI_t, dq_LLI_EFC, dq_LAM, dr_LLI_t, dr_LLI_EFC])
for k, v in zip(states.keys(), dx):
x = self.states[k][-1] + v
self.states[k] = np.append(self.states[k], x)
# Store stressors
t_days = self.stressors['t_days'][-1] + delta_t_days
efc = self.stressors['efc'][-1] + delta_efc
stressors = np.array([delta_t_days, t_days, delta_efc, efc, np.mean(TdegK), np.mean(soc), np.mean(Ua), dod])
for k, v in zip(self.stressors.keys(), stressors):
self.stressors[k] = np.append(self.stressors[k], v)
# Store rates
rates = np.array([q1, q3, q5])
for k, v in zip(self.rates.keys(), rates):
self.rates[k] = np.append(self.rates[k], v)
def __update_outputs(self):
# Calculate outputs, based on current battery state
states = self.states
p = self._params_life
# Capacity
q_LLI = 1 - states['qLoss_LLI_t'][-1] - states['qLoss_LLI_EFC'][-1]
q_LLI_t = 1 - states['qLoss_LLI_t'][-1]
q_LLI_EFC = 1 - states['qLoss_LLI_EFC'][-1]
q_LAM = 1.01 - states['qLoss_LAM'][-1]
q = np.min(np.array([q_LLI, q_LAM]))
# Resistance
r_LLI = 1 + states['rGain_LLI_t'][-1] + states['rGain_LLI_EFC'][-1]
r_LLI_t = 1 + states['rGain_LLI_t'][-1]
r_LLI_EFC = 1 + states['rGain_LLI_EFC'][-1]
r_LAM = p['r5'] + p['r6'] * (1 / q_LAM)
r = np.max(np.array([r_LLI, r_LAM]))
# Assemble output
out = np.array([q, q_LLI, q_LLI_t, q_LLI_EFC, q_LAM, r, r_LLI, r_LLI_t, r_LLI_EFC, r_LAM])
# Store results
for k, v in zip(list(self.outputs.keys()), out):
self.outputs[k] = np.append(self.outputs[k], v)