Lab 06: AEV System Analysis 2 (Performance Analysis) Advanced Energy Vehicle (AEV)

Slides:

Advertisements

Similar presentations

Multiplying Polynomials

Advertisements

Advanced Energy Vehicle

Lab 02: AEV Arduino Programming Basics Advanced Energy Vehicle (AEV)

Lab 09: Performance Test 1 Advanced Energy Vehicle.

Lab 07: System Analysis 3 (Wind Tunnel Testing) Advanced Energy Vehicle.

Lab 06: AEV System Analysis 2 Advanced Energy Vehicle (AEV)

Lab 01: AEV Project Introduction Advanced Energy Vehicle (AEV)

Lab 04: AEV External Sensors Advanced Energy Vehicle (AEV)

Parallel Circuit electricity has more than one path to follow total amps are equal to the sum of the individual amps total watts are equal to the sum of.

Electric Circuits Chapter 20.3.

 Rate at which energy is consumed or produced  Changed into other forms of energy  Measured in WATTS (W)

Lab 08: AEV Design Analysis Tool Advanced Energy Vehicle (AEV)

First-Year Engineering Program Performance Test 1: Design Concept Comparisons Objective and Goals Lab Procedure Analysis Test Readiness Review.

Lab 06: AEV System Analysis 2 Advanced Energy Vehicle (AEV)

DECIMAL ARITHMETIC. Equivalent Additions You may be asked to do the following sum without a calculator How ? As we shall see throughout this.

First-Year Engineering Program Advanced Energy Vehicle System Analysis 2 Reference:  AEV Lab Manual  System Analysis 2 Grading Guidelines.

Lab 04: AEV External Sensors Advanced Energy Vehicle (AEV)

First-Year Engineering Program Advanced Energy Vehicle Arduino Programming Basics Reference:  AEV Lab Manual  Arduino Programming Basics Grading Guidelines.

Lab 02: Arduino Programming Basics Advanced Energy Vehicle (AEV)

First-Year Engineering Program Performance Test 2: Operational Objectives Objective and Goals Analysis Test Readiness Review.

Lab 03: AEV Arduino Programming Basics Advanced Energy Vehicle (AEV)

ELECTRICAL UNITS Match up correctly: CURRENT (C) Joules Ω

Lab 01: Creative Design Thinking* Advanced Energy Vehicle (AEV) *Directly from the EEIC Multidisciplinary Capstone Program.

Chapter 6 Ohm’s Law, Work, Energy and Power. 16 V.

Lab 05: AEV System Analysis 1 Advanced Energy Vehicle (AEV)

Paying for Electricity How much does it cost to watch T.V. for 2 hours?

Measuring Electrical Energy.  Energy: the ability to do work.  Electrical Energy: energy transferred to an electrical load by moving electric charges.

First-Year Engineering Program Performance Test 3: Energy Optimization Objective and Goals Lab Procedure Analysis Test Readiness Review.

ELECTRICAL COMPONENTS and CIRCUITS Instrumental Analysis II CTEC 1345.

ELECTRIC CURRENT 2 Ohm’s law shows the relationship between current, potential, and voltage. We need a few more rules to make predictions about current.

Measuring Electrical Energy Energy: -the ability to do work Electrical Energy: - energy transferred to an electrical load by moving electric charges.

Lab 07: AEV Design Analysis Tool Advanced Energy Vehicle (AEV)

5.10 Energy and Power  Energy (E) the ability to do work Measured in Joules (J)  Power (P) the amount of work that can be accomplished in a certain amount.

First-Year Engineering Program Advanced Energy Vehicle System Analysis 3 Reference:  AEV Lab Manual  System Analysis 3 Grading Guidelines.

Lab 07: System Analysis 3 (Wind Tunnel Testing) Advanced Energy Vehicle.

Previous Lecture 4 The Relationship of Current, Voltage, and Resistance Calculating Current Calculating Voltage Calculating Resistance.

Lab 04: AEV External Sensors Advanced Energy Vehicle (AEV)

First-Year Engineering Program Advanced Energy Vehicle External Sensors Reference:  AEV Lab Manual  External Sensors Grading Guidelines.

Chapter 6 Ohm’s Law, Work, Energy and Power. 16 V.

© Oxford University Press 2011 IP The National Grid: Power transmitted The National Grid: Power transmitted.

Welcome to Engineering 1182 or Lab Attendance  Expected to attend all labs  Missing a lab meeting time A valid documented excuse required  Allowed.

Electrical Power is rate at which energy flows

First-Year Engineering Program Advanced Energy Vehicle System Analysis 1 Reference:  AEV Lab Manual  System Analysis 1 Grading Guidelines.

Preliminary Design Review (PDR) Advanced Energy Vehicle.

Lab 01: AEV Project Introduction Advanced Energy Vehicle (AEV)

First-Year Engineering Program Advanced Energy Vehicle Design Analysis Tool Reference:  AEV Lab Manual  Design Analysis Tool Grading Guidelines.

Energy and Power. Energy The ability to do work. Measured in Joules.

First-Year Engineering Program Preliminary Design Review (PDR) Definition PDR Objectives PDR Material Project Management Review.

Lab 05: System Analysis 1 (Wind Tunnel Testing) Advanced Energy Vehicle.

Lab 07: System Analysis 3 (Wind Tunnel Testing) Advanced Energy Vehicle.

Lab 05: AEV System Analysis 1 Advanced Energy Vehicle (AEV)

Current and Power Calculations Practice Math once again!!!

Electrical Systems Series Circuits Parallel Circuits Electrical Power.

Advanced Energy Vehicle (AEV)

Electricity, Sound and Light

Electric Power Energy Cost

Measuring Electrical Energy

Advanced Energy Vehicle

Section 3.3 Measuring Energy Input and Output 1

Circuits & Voltage.

Section 3.3 Measuring Energy Input and Output 1

Advanced Energy Vehicle

More electricity stuff

Ohm’s Law This formula shows the relationship between current, voltage and resistance. Voltage (Volts) Current (Amps) Resistance (Ohms, )

Section 3.3 Measuring Energy Input and Output 1

What is work Chapter 4 section 1.

Energy and Power.

Electric Power.

Advanced Energy Vehicle

Advanced Energy Vehicle

Presentation transcript:

Lab 06: AEV System Analysis 2 (Performance Analysis) Advanced Energy Vehicle (AEV)

AEV Project Objective (Problem Definition) INITIAL CONCEPTS (Brainstorming) EXPERIMENTAL RESEARCH ANALYZE DESIGN DECISION RESEARCH COMPARE FINAL DESIGN Present AEV Design PT 1 PT 2 PT 3 PT 4 (System Analysis)(Programming)

AEV Data Conversion  Convert the EEProm into physical parameters of: Time (seconds) Current (amps) Voltage (volts)  Analyze the data by calculating: Power (watts) Incremental Energy (joules) Total Energy (joules)

Time, Current, Voltage, & Power  Time:  Current:  Voltage:  Power:  Distance t = time (seconds) t E = EEProm time (milliseconds) I = current (amps) I E = EEProm equivalent current V R = Arduino reference voltage V = Voltage (volts) V E = EEProm equivalent voltage P in = Power in (watts) V = Voltage (volts) I = Current (amps)

Energy  Remember that Energy is the area under the power versus time curve.  A rectangle approximation of the power and time will be used to calculate the incremental and total energy.  There are 3 approximation methods:

Energy  The midpoint method will be used to calculate the energy.  The midpoint method uses the averaged power of 2 neighboring points and multiplied by the time increment:  Sum up the incremental energy for the total value used throughout the operation

Things to Remember  Executive Summary for Lab 06  Update Project Portfolio  Study for Lab Proficiency Quiz (LPQ)  Extra Credit Video (Due: Lab 07 (Part 1))  Continue to work on PDR (Due: Lab 09B)