Presentation is loading. Please wait.

Presentation is loading. Please wait.

Design Process Analysis & Evaluation Part II Example Design: Solar Candle by Prof. Bitar.

Published byEustace Martin Modified over 9 years ago

Similar presentations

Presentation on theme: "Design Process Analysis & Evaluation Part II Example Design: Solar Candle by Prof. Bitar."— Presentation transcript:

1 Design Process Analysis & Evaluation Part II Example Design: Solar Candle by Prof. Bitar

2 Existing Window Candle Block Diagram Solar Cell Charge Controller Rechargeable Battery 1.2V NiCd DC-DC Boost Converter LED 3.2V 20mA Flickering Control Mode Selection Photo Sensor

3 Diodes/Zetex - ZXLD383ET5CT

4 Typical Application Circuit Note Control Pin!

5 DC-DC Converter Efficiency

6 Modified System Block Diagram Solar Panel Charge Controller Rechargeable Battery 1.2V NiCd 700 mAhrs Zetex LED Driver 85% Eff. LED 20mA 3.2V(min) Switching Control Mode Selection Photo Sensor Timer

7 Changing Focus to Charging How much energy is removed from the battery during a typical evening? LED requires 20mA x 3.2V x 6hrs = 384 mW hrs (power x time = energy)LED requires 20mA x 3.2V x 6hrs = 384 mW hrs (power x time = energy) Converter is only 85% efficient, so energy taken from battery is 384 mW hrs / 0.85 ≈ 452 mW hrsConverter is only 85% efficient, so energy taken from battery is 384 mW hrs / 0.85 ≈ 452 mW hrs How much charge? Dividing by the battery voltage gives the charge removed: 452 mW hrs / 1.2V ≈ 377 mA hrsDividing by the battery voltage gives the charge removed: 452 mW hrs / 1.2V ≈ 377 mA hrs

8 The Prior Art Dissected

9 On to the Solar Panel Requirements After taking the Home Depot Landscape Light apart, I made the following measurements (in direct sun): I SC = 50mA, V OC = 4.3V

10 Solar Panel V-I Characteristic

11 Solar Panel Considerations How much charge is restored if the panel is connected directly to the battery? What assumptions should we make? How about 10 Hours of Daylight10 Hours of Daylight 50% Incident Light50% Incident Light This gives 50mA x 10hrs x 50% = 250mA hrs Is this enough? We need 377 mA hrs. No. 

12 Charge Options? Use two solar panels in parallel to boost the current (although we seem to be throwing away the excess voltage?) Modify the existing panel for higher current (at the expense of voltage).

13 Modified Solar Panel Configuration

14 Modified Characteristic I SC = 100 mA, V OC = 2.15 V (V OC still greater than V BAT )

15 A Possible Solution Now we have: 100mA x 10 hrs x 50% = 500 mA hrs. Is this enough? We need 377mA hrs. Yes! Is this enough? We need 377mA hrs. Yes!

16 Solar Panel Update to System Block Diagram Solar Panel I SC = 100mA V OC = 2.15V I AVE = 50mA Δt = 10hrs Q = 500mAHrs Charge Controller Rechargeable Battery 1.2V NiCd Zetex LED Driver LED 20mA 3.2V(min) Switching Control Mode Selection Photo Sensor Timer

17 And now the Charge Controller… Solar Panel I SC = 100mA V OC = 2.15V I AVE = 50mA Δt = 10hrs Q = 500mAHrs Charge Controller Rechargeable Battery 1.2V NiCd Zetex LED Driver LED 20mA 3.2V(min) Switching Control Mode Selection Photo Sensor Timer

18 NiCd Charge Control Methods (Panasonic)

19 Which Charge Method to Choose? Semi-Constant Current Charge Most Typical Charge System Most Typical Charge System Simple and Economical Simple and Economical Typical Charge Time = 15 Hrs Typical Charge Time = 15 Hrs Typical Charge Current = 0.1 It Typical Charge Current = 0.1 It (0.1*700 mA Hrs = 70mA) Time Controlled Charge More reliable than Semi-Constant Current More reliable than Semi-Constant Current Slightly more complicated. Requires timer. Slightly more complicated. Requires timer. Typical Charge Time = 6-8 Hrs Typical Charge Time = 6-8 Hrs Typical Charge Current = 0.2 It (140mA) Typical Charge Current = 0.2 It (140mA)

20 Semi-Constant Current Charge Seems Viable With our low average current of 50mA, and charge time of 10 hrs, the Semi- Constant Current Charge method seems viable. Also, if we are concerned about over charge, we can extend the on-time beyond 6 hrs. This method is more economical and may not require a timer for this application.

21 Charge Controller Update Solar Panel I SC = 100mA V OC = 2.15V I AVE = 50mA Δt = 10hrs Q = 500mAHrs Charge Controller Semi-Const. Current Method Rechargeable Battery 1.2V NiCd Zetex LED Driver LED 20mA 3.2V(min) Switching Control Mode Selection Photo Sensor Timer

22 Charge Controller Update Solar Panel I SC = 100mA V OC = 2.15V I AVE = 50mA Δt = 10hrs Q = 500mAHrs Charge Controller Semi-Const. Current Method Rechargeable Battery 1.2V NiCd Zetex LED Driver LED 20mA 3.2V(min) Switching Control Mode Selection Photo Sensor Timer

Download ppt "Design Process Analysis & Evaluation Part II Example Design: Solar Candle by Prof. Bitar."

Similar presentations

Solarwind solutions The Hybrid Home Customer presentation.

Solarwind solutions The Hybrid Home Customer presentation.
Indian Institute of Technology Hyderabad BETTER WAYS OF USING SOLAR ENERGY Byby BOLLAM UMAMAHESWAR REDDY A VENKATA KOWSHIK.

Indian Institute of Technology Hyderabad BETTER WAYS OF USING SOLAR ENERGY Byby BOLLAM UMAMAHESWAR REDDY A VENKATA KOWSHIK.
Solar Powered Battery Charger Christine Placek Philip Gonski Group 4 ECE 445 – Spring 2007.

Solar Powered Battery Charger Christine Placek Philip Gonski Group 4 ECE 445 – Spring 2007.
Introduction Since the beginning of the oil crises, which remarkably influenced power development programs all over the world, massive technological and.

Introduction Since the beginning of the oil crises, which remarkably influenced power development programs all over the world, massive technological and.
ELECTRICAL SYSTEMS 21.3.

ELECTRICAL SYSTEMS 21.3.
TI Confidential – Selective Disclosure BMS Deep Dive 2012 1 Battery Charger Design (1S): Key considerations and system design limitations Miguel Aguirre.

TI Confidential – Selective Disclosure BMS Deep Dive Battery Charger Design (1S): Key considerations and system design limitations Miguel Aguirre.
Introduction to Space Systems and Spacecraft Design Space Systems Design Power Systems Design -I.

Introduction to Space Systems and Spacecraft Design Space Systems Design Power Systems Design -I.
Solar Energy- Photovoltaics (solar cells)

Solar Energy- Photovoltaics (solar cells)
7/9/2007 AIIT Summer Course - D# 1 Wireless Embedded Systems and Networking Foundations of IP-based Ubiquitous Sensor Networks Micro-Power Systems David.

7/9/2007 AIIT Summer Course - D# 1 Wireless Embedded Systems and Networking Foundations of IP-based Ubiquitous Sensor Networks Micro-Power Systems David.
Self-Sustaining Solar Powered Robot Mason Drew Mark Nolan Wesley Varghese.

Self-Sustaining Solar Powered Robot Mason Drew Mark Nolan Wesley Varghese.
Lecture – 7 Basic input and output

Lecture – 7 Basic input and output
Design Process Analysis & Evaluation Part II Example Design: Solar Candle by Prof. Bitar.

Design Process Analysis & Evaluation Part II Example Design: Solar Candle by Prof. Bitar.
Energy Harvesting and Wireless Sensor Networks Adam Skelton.

Energy Harvesting and Wireless Sensor Networks Adam Skelton.
SOLAR CELL PRESENTED BY ANJALI PATRA ANKITA TRIPATHY BRANCH-EEE.

SOLAR CELL PRESENTED BY ANJALI PATRA ANKITA TRIPATHY BRANCH-EEE.
Final Year Project Project Progress Presentation Title: Energy Conversion for low voltage values. Supervisor: Dr.Maeve Duffy.

Final Year Project Project Progress Presentation Title: Energy Conversion for low voltage values. Supervisor: Dr.Maeve Duffy.
Physics Energy Flow and Conservation of resources SOLAR ENERGY.

Physics Energy Flow and Conservation of resources SOLAR ENERGY.
Design Process Analysis & Evaluation Part I Example Design: Solar Candle by Prof. Bitar.

Design Process Analysis & Evaluation Part I Example Design: Solar Candle by Prof. Bitar.
SUPR E-Harv Model Simulations Chuhong Duan ECE Department, University of Virginia 07/31/2012.

SUPR E-Harv Model Simulations Chuhong Duan ECE Department, University of Virginia 07/31/2012.
LunaLight PCB Rev 2.1 Mike Deagen (MATE) IME 458 May 25, 2012 Fully Integrated Solar-Rechargeable LED Lantern and Cell Phone Charger.

LunaLight PCB Rev 2.1 Mike Deagen (MATE) IME 458 May 25, 2012 Fully Integrated Solar-Rechargeable LED Lantern and Cell Phone Charger.
ENERGY EFFICIENT LIGHTING OD BATTERY BACKUP MODULE ML4LEMU - 4= Outdoor/ L=LED/ EMU = Battery Backup /blank= Internal ML4LEMUE - 4= Outdoor/ L= LED/ EMU.

ENERGY EFFICIENT LIGHTING OD BATTERY BACKUP MODULE ML4LEMU - 4= Outdoor/ L=LED/ EMU = Battery Backup /blank= Internal ML4LEMUE - 4= Outdoor/ L= LED/ EMU.

Similar presentations

Ads by Google