Protected: EV Powertrain Architecture and Energy Storage System Part 2 : Battery Pack Design and Selection

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Battery Pack Design and Selection : Unit 1 – Basic Terminologies of Cell Model

1
Lecture 1.1.0 : Introduction to Cells – History of Battery
00:14:44 hr
2
Lecture 1.1.1 : Types of energy storage system
00:22:16 hr
3
Lecture 1.1.2 : Why Li-Ion Cells
00:10:23 hr
4
Lecture 1.1.3 : Lithium Cells Working
00:09:13 hr
5
Lecture 1.1.4 : Battery Terminologies
00:20:41 hr
6
Lecture 1.1.5 : Lithium Chemistry
00:32:07 hr
7
Lecture 1.1.6 : Cell Types – Form Factors
00:16:32 hr
8
Lecture 1.1.7 : Lithium Cell Materials
00:16:21 hr
9
Lecture 1.1.8 : Lithium Cell Failures
00:11:43 hr
10
Lecture 1.2.0 : Equivalent Cell Model – Open Circuit Voltage
00:39:05 hr
11
Lecture 1.2.1 : Linear Polarization
00:52:02 hr
12
Lecture 1.2.2 : Finding RC Values
00:10:39 hr
13
Lecture 1.2.3 : Hysteresis Voltage
00:28:32 hr
14
Lecture 1.2.4 : Enhanced Self Correcting Model
00:11:12 hr
15
Lecture 1.2.5 : Cell Testing and Coulombic Efficiency
00:43:36 hr
16
Lecture 1.2.6 : Temperature and OCV
00:34:27 hr
17
Lecture 1.2.7 : Dynamic Testing
00:33:35 hr
18
Lecture 1.2.8 : Model Simulation
00:41:13 hr
19
Unit 1 : Expert Lecture – Live (Basic Terminologies of Cell Model)
20
Unit 1 : Assignment (Basic Terminologies of Cell Model)

Battery Pack Design and Selection : Unit 2 – Battery Model

1
Lecture 2.1.0 : Physics Based Model – Intro (Emperical vs Physics Model and Micro Scale Eqn – Basics)
00:09:02 hr
2
Lecture 2.1.1 : Charge Continuity (Point form of Ohms Law
00:41:02 hr
3
Lecture 2.1.2 : Mass Continuity Eqn (Ficks Law, Continuity Eqn, 1D Linear Diffusion)
00:48:31 hr
4
Lecture 2.1.3 : Thermal Energy and Potential (Thermodynamic Potential
00:20:27 hr
5
Lecture 2.1.4 : Thermodynamics Law and Gibbs Free Energy
00:38:34 hr
6
Lecture 2.1.5 : Electro Chemical Potential (Partial Molar Qnty, Electrochemical Potential
00:26:01 hr
7
Lecture 2.1.6 : Absolute Activity (Debye Huckle Theory
00:18:06 hr
8
Lecture 2.1.7 : Binary Electrolyte Behavior(Stoichiometric Coefficient, Electroneutrality in Electrolyte
00:19:42 hr
9
Lecture 2.1.8 : Electrolyte Mass Continuation Eqn Pt1 (Maxwell Stefan Relation
00:48:42 hr
10
Lecture 2.1.9 : Electrolyte Mass Continuation Eqn Pt1 (Ion Fluxes
00:35:39 hr
11
Lecture 2.1.10 : Boundary Conditions (Transfer Equations, Cell Level Quantities
00:28:32 hr
12
Lecture 2.1.11 : Cell Operating Condition and Life (Cell Charging and Discharging, Cell C-Rating)
01:12:00 hr
13
Lecture 2.1.12 : Improving Cell Life (Factors Effecting Cel Life, Cell Degradation Causes
01:12:00 hr
14
Lecture 2.1.13 : Battery Calculaition Basics
00:39:47 hr
15
Lecture 2.1.14 :Energy Consumption Pt01
00:44:50 hr
16
Lecture 2.1.15 :Energy Consumption Pt02
00:32:27 hr
17
Lecture 2.2.1 : Reduced Order Model for Cell Dynamics – Approach for Reduced Order Model
18
Lecture 2.2.2 : Finding Internal Resistance
19
Lecture 2.2.3 : Finding Impedance
20
Lecture 2.2.4 : Negative Electrode Transfer fnc.
21
Lecture 2.2.5 : Positive Electrode Transfer fnc.
22
Lecture 2.2.6 : 1D model for Ce(x,t)
23
Lecture 2.2.7 : Solution to homogenous PDE
24
Lecture 2.2.8 : One Dimensional Model
25
Lecture 2.2.9 : Summary of Transfer fnc
26
Lecture 2.2.10 : Cell Voltage
27
Lecture 2.2.11 : Full Cell Model
28
Lecture 2.2.12 : Model Blending
29
Unit 2 : Expert Lecture – Live (Battery Model)
30
Unit 2 : Assignment (Battery Model)

Battery Pack Design and Selection : Unit 3 – Battery Pack Design

1
Lecture 3.1.0 : Battery Size Calculation – Energy Consumption Calculation
2
Lecture 3.1.2 : Calculating Battery Pack Size
3
Lecture 3.2.0 : Battery Pack Capacity and Voltage – Cell Load Characteristics
4
Lecture 3.2.1 : Battery Pack Capacity and Voltage
5
Lecture 3.3.0 : Cell to Cell Bonding – Nickel Strip Selection
6
Lecture 3.3.1 : Bus Bar Bonding
7
Lecture 3.3.2 : Tab Bonding
8
Lecture 3.3.3 : Cell to Cell Gap
9
Lecture 3.3.4 : Spot Welding vs Laser Welding
10
Lecture 3.4.0 : Battery Safety – Performance Design and Safety Layer
11
Lecture 3.4.1 : Safety Layer Design
12
Lecture 3.5.0 : Battery Modelling – Cell Assembly Model
13
Lecture 3.5.1 : Battery Case Design Principles
14
Lecture 3.5.2 : Battery Case Design – Model
15
Lecture 3.5.3 : Battery Pack – Component Packaging
16
Unit 3 : Expert Lecture – Live (Battery Pack Design)
17
Unit 3 : Assignment (Battery Pack Design)

Battery Pack Design and Selection : Unit 4 – Battery Testing and Safety

1
Lecture 4.1.0 : Functional Safety – Functional Safety for Battery Pack
2
Lecture 4.2.0 : Performance Testing – Ah/ pack testing
3
Lecture 4.2.1 : C-Rating performance
4
Lecture 4.2.2 : Self – discharge testing
5
Lecture 4.2.3 : Range/ Discharge Test
6
Lecture 4.3.0 : Safety Testing – Short circuit testing
7
Lecture 4.3.1 : Overcharge cut-off
8
Lecture 4.3.2 : Deep Discharge test
9
Lecture 4.3.3 : Under voltage Cut-off
10
Lecture 4.4.0 : Battery Mechanical Test – Impact Test and Drop Test – Simulation
11
Lecture 4.4.1 : Vibration Test
12
Unit 4 : Expert Lecture – Live (Battery Testing and Safety)
13
Unit 4 : Assignment (Battery Testing and Safety)

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