Skip to content

A battery pack simulation tool that uses the PyBaMM framework

License

Notifications You must be signed in to change notification settings

RuiheLi/liionpack

 
 

Repository files navigation

logo

liionpack Documentation Status codecov Open In Colab DOI

Overview of liionpack

liionpack takes a 1D PyBaMM model and makes it into a pack. You can either specify the configuration e.g. 16 cells in parallel and 2 in series (16p2s) or load a netlist.

Installation

Follow the steps given below to install liionpack. The package must be installed to run the included examples. It is recommended to create a virtual environment for the installation, see the documentation.

To install liionpack using pip, run the following command:

pip install liionpack

Conda

The following terminal commands are for setting up a conda development environment for liionpack. This requires the Anaconda or Miniconda Python distribution. This environment installs liionpack in editable mode which is useful for development of the liionpack source code. General users should install liionpack with pip.

# Create a conda environment named lipack
cd liionpack
conda env create --file environment.yml

# Activate the environment
conda activate lipack

# Exit the environment
conda deactivate

# Delete the environment
conda env remove --name lipack

LaTeX

In order to use the draw_circuit functionality a version of Latex must be installed on your machine. We use an underlying Python package Lcapy for making the drawing and direct you to its installation instructions here for operating system specifics.

Example Usage

The following code block illustrates how to use liionpack to perform a simulation:

import liionpack as lp
import numpy as np
import pybamm

# Generate the netlist
netlist = lp.setup_circuit(Np=16, Ns=2, Rb=1e-4, Rc=1e-2, Ri=5e-2, V=3.2, I=80.0)

output_variables = [
    'X-averaged total heating [W.m-3]',
    'Volume-averaged cell temperature [K]',
    'X-averaged negative particle surface concentration [mol.m-3]',
    'X-averaged positive particle surface concentration [mol.m-3]',
]

# Heat transfer coefficients
htc = np.ones(32) * 10

# Cycling experiment, using PyBaMM
experiment = pybamm.Experiment([
    "Charge at 20 A for 30 minutes",
    "Rest for 15 minutes",
    "Discharge at 20 A for 30 minutes",
    "Rest for 30 minutes"],
    period="10 seconds")

# PyBaMM parameters
parameter_values = pybamm.ParameterValues("Chen2020")

# Solve pack
output = lp.solve(netlist=netlist,
                  parameter_values=parameter_values,
                  experiment=experiment,
                  output_variables=output_variables,
                  htc=htc)

Documentation

There is a full API documentation, hosted on Read The Docs that can be found here.

Contributing to liionpack

If you'd like to help us develop liionpack by adding new methods, writing documentation, or fixing embarrassing bugs, please have a look at these guidelines first.

Get in touch

For any questions, comments, suggestions or bug reports, please see the contact page.

Acknowledgments

PyBaMM-team acknowledges the funding and support of the Faraday Institution's multi-scale modelling project and Innovate UK.

The development work carried out by members at Oak Ridge National Laboratory was partially sponsored by the Office of Electricity under the United States Department of Energy (DOE).

License

liionpack is fully open source. For more information about its license, see LICENSE.

About

A battery pack simulation tool that uses the PyBaMM framework

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages

  • Python 97.2%
  • TeX 2.8%