Battery Charger Systems. Test Procedure, Call for Data, & Proposed Standards. April 8, 2008 Prepared for: Patrick Eilert Ed Elliott Gary Fernstrom

Battery Charger Systems Test Procedure, Call for Data, & Proposed Standards April 8, 2008 Prepared for: Patrick Eilert Ed Elliott Gary Fernstrom Prepared by: Paul Bendt, Ph.D, Ecos Consulting TM

April 8, 2008 Battery Charger Systems Test Procedure, Call for Data, & Proposed Standards

Agenda Background and History Test Procedure Call for Data Tentatively Proposed Standards

Background and History

What is a Battery Charger System? Battery Charger System (BCS) Battery chargers coupled with their batteries are together referred to as battery charger systems. This term covers all rechargeable batteries or devices incorporating a rechargeable battery and the chargers used with them.

Battery Charger Product Categories (1) Home Electronics Audio Toys Video Two-Way Radios (2) Cell Phones Cell Phones Cell Phone Accessories (3) Cordless Phones (4) Information Appliances Laptop Other Data Devices Business Equipment (5) Emergency Backup Battery Systems Lighting Power Security (6) Personal Care Oral Care Hair Trimmers Shavers (7) Tools Electric House wares Outdoor Appliances Power Tools (8) Universal Battery Chargers Marine RV/General Use AA/AAA/9V (9) Transportation Forklift Personal Electric Vehicle Golf Carts/Electric Carts Electric Cars (10) Lighting Lanterns Flashlights

Sales Trends of Fastest Growing/Declining Product Categories Compound Annual Growth Rate (Unit Sales) 140% Compound Annual Growth Rate (%) 120% 100% 80% 60% 40% 20% 0% -20% -40% Portable CD Players MP3 players Cordless Phones Cell Phones PDAs Blue Tooth Headsets Laptops

CA Stock Estimates Universal Battery Charger 2,653,098 Tools 2% 5,920,810 5% Transportation 1,500,203 1% Lighting 1,139,136 1% Personal Care 8,262,169 7% Emergency Backup Battery Systems 9,539,774 8% Information Appliances 15,961,613 13% Cordless Phones 24,980,040 20% Home Electronics 30,968,549 23% Cell Phones 25,486,933 20% Over 126 million products in California Over 9 products per California household

Prior History Test Procedure Development Procedure in development for four years, representing input from dozens of stakeholders, including EPA ENERGY STAR and DOE Updated Version 1.1 as of March 5, 2008 covers batteries that do not have a rated charge capacity Available at www.efficientproducts.org/ bchargers/ along with comment and response document for final revisions

Extensive Data Gathering and Prior Research Ecos and EPRI tested and measured over 60 products from the different product categories using the recently approved BCS test procedure Total dataset, including legacy research from Ecos, EPRI, and Cadmus Group includes over 250 battery charger measurements Dataset includes 24-hour Charge-Maintenance-Discharge Efficiency, Maintenance Mode Power, and No Battery Mode Power

Recommended BCS Standards Timeline Preliminary Draft Test Procedure (PG&E) 1 st BCS stakeholder workshop (PG&E) 2 nd BCS stakeholder workshop (CEC PIER) Draft 2 BCS test procedure complete (CEC PIER) 3rd BCS stakeholder workshop (CEC PIER) Issue Rulemaking on BCS (CEC) Tier 1 Standards effective (Jan 1) (CEC) CEC PIER PG&E NRDC Energy Star DOE Tier 2 Standards effective (Jan 1) (CEC) 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 Initial BCS research (NRDC) Draft 1 BCS Test Procedure Complete (CEC PIER) ENERGY STAR BCS specification take effect DOE BCS test procedure published Final BCS Test Procedure Completed (PG&E) DOE BCS ANOPR hearing date: March, 2010 DOE BCS proposed rule January, 2011 Working Draft Test Procedure released (PG&E)

Test Procedure

Snapshot of Current Dataset 24-Hour Charge-Maintenance Efficiency (%) 70 60 50 40 30 20 10 24-Hour Charge-Maintenance Efficiency vs. Measured Battery Energy Capacity Lead Acid NiMH Li-Ion NiCd 0 0 10 20 30 40 50 60 Measured Battery Energy Capacity (Wh)

Updates to Test Procedure Batteries without a rated charge capacity About 30% of products tested Determine an appropriate discharge current Three-phase and over 2kW Determine if scope can be extended Requesting data and comments Significant savings potential in this category also

Power Factor for Battery Chargers Voltage Waveforms 180 160 140 120 100 80 60 40 20 0 0 5 10 15 20 25 30 Ti me ( mi ll i se c onds) Rectified AC Filter Capacitor Input Voltage and Current 200 150 100 50 0 0 5 10 15 20 25 30-50 -100-150 Volt age Current -200 Time (milliseconds)

Power Factor for Battery Chargers Voltage Waveforms 180 160 140 120 100 80 60 40 20 0 0 5 10 15 20 25 30 Time ( milliseconds) Rectified AC Filter Capacitor Input Voltage and Current 200 150 100 50 0 0 5 10 15 20 25 30-50 -100-150 Volt age Current -200 Time (milliseconds)

Power Factor for Battery Chargers Voltage Waveforms 200 150 100 50 0 0 5 10 15 20 25 30-50 -100-150 -200 Ti me ( mil l i se c onds) Voltage (or Currrent) Power

Recommended Action Adopt the Battery Charger Test Procedure Provides proven and reliable techniques for measuring energy consumption in all operating modes Call for data from all interested parties, to be submitted by May 16, 2008 Seeking data on all categories of products to ensure a representative sample Particularly interested in test data on large chargers, including 3-phase and over 2 kw Also interested in test data on any products with special requirements Proposed language for data request is included in proposal submitted to CEC by PG&E, Energy Solutions and Ecos.

Break

Tentatively Proposed Standards

Standards Concepts Three components: Active, Maintenance and No Battery Active mode considers battery energy: Eff E E batt Ebatt a+ b E Can also be considered as an energy budget: E24 a + b E batt Staged Standards Near Term, removes least efficient chargers Later standard for improved efficiency = 24 batt

Standards Concepts Efficiency vs. Energy Capacity 24-Hour Efficiency (%) 80 70 60 50 40 30 20 10 0 Tier B Tier A 0 10 20 30 40 50 60 Measured Battery Energy (Wh)

Standards Concepts Maintenance Power vs. Energy Capacity No Battery Power vs. Energy Capacity Maintenance Power (w) 10 9 8 7 6 5 4 3 2 Tier A Tier B Maintenance Power (w) 10 9 8 7 6 5 4 3 2 Tier A Tier B 1 1 0 0 10 20 30 40 50 60 0 0 10 20 30 40 50 60 Measured Battery Energy (Wh) Measured Battery Energy (Wh)

CA ENERGY USE AND SAVINGS POTENTIAL 4500 4000 CA Battery Charger Energy Use and Savings Potential 5% savings Overall Energy Use Energy Delivered from Batteries CA Annual Energy Use (GWh/year 3500 3000 2500 2000 1500 1000 3000 2800 39% savings 1450 58% savings 680 69% savings 250 500 1000 1000 1000 1000 1000 0 Current Efficient Pow er Supplies Tier A Tier B Practical Limit Potential to reduce BCS energy use by 39% (1.55 TWh/year) even with early, less stringent standards

CA ENERGY USE AND SAVINGS POTENTIAL 1400 1200 Large 1-Phase Battery Chargers Overall Energy Use Energy Delivered from Batteries CA Annual Energy Use (GWh/year 1000 800 600 400 14% savings 22% savings 27% savings 500 330 240 175 700 700 700 700 200 0 Current Not Aplicable Efficient Pow er Supplies Tier A Tier B Practical Limit Large chargers (golf carts, forklifts, and electric vehicles) have significant potential for savings.

CA Energy Use and Savings Potential 3200 2800 Consumer and Auto/Marine Battery Chargers 7% savings Overall Energy Use Energy Delivered from Batteries CA Annual Energy Use (GWh/year 2400 2000 1600 1200 800 2500 2300 49% savings 1120 74% savings 87% savings 400 440 75 0 300 300 300 300 300 Current Efficient Pow er Supplies Tier A Tier B Practical Limit Small chargers for consumer products have low efficiencies and present an opportunity for large energy savings.

CA Battery Charger Annual Energy Use and Savings by Mode No Battery Mode Energy Use 231 GWh (6%) Maintenance Mode Energy Savings, 799, 21% No Battery Mode Energy Savings, 211, ~6% Active Mode Energy Use 1,919 GWh (49%) Maintenance Mode Energy Use 1,848 GWh (45%) Active Mode Energy Savings, 568, 15%

Efficient Design Strategies 1. Don t continue to charge batteries are already fully charged 2. Reduce standby power when not actively charging the battery 3. Use an efficient power conversion process, including an efficient power supply 4. Use power factor correction These recommendations can be achieved through multiple design paths

Economic Analysis Product Examples Power Tools Product A NiCd battery 11.8% 24-hr Efficiency Maintenance Mode: 2.8W No Battery Mode: 0.6W Purchase Price: $23.99 Product B Li-Ion battery 23.7% 24-hr Efficiency Maintenance Mode: 0.5W No Battery Mode: 0.42 Purchase Price: $34.97 Product C Li-Ion Battery 42.6% 24-hr Efficiency Maintenance Mode: 0.28W No Battery Mode: 0.2W Purchase Price: $95.99 Difference in Technology: Charging Circuitry Incremental Cost: Minimal

Economic Analysis Product Examples Universal Chargers Product A Product B NiMH batteries NiMH batteries 13.1% 24-hr Efficiency 27.5% 24-hr Efficiency Maintenance Mode: 2.74W Maintenance Mode: 0.7W No Battery Mode: 2.4W No Battery Mode: 0.2W Purchase Price: $25.00 Purchase Price: $20.49 Difference in Technology: Charging Technology Incremental Cost: Minimal to none

Economic Analysis Product Examples Cordless Phones Product A (Base Unit Only) Product B NiMH batteries Li-Poly Battery 3.64% 24-hr Efficiency 5.80% 24-hr Efficiency Maintenance Mode: 1.82W Maintenance Mode: 1.07W No Battery Mode: 1.47W No Battery Mode: 1.00W Purchase Price: $54.99 Purchase Price: $65.99 Difference in Technology: Battery Chemistry, Charging Circuitry Incremental Cost: Minimal

Economic Analysis Product Examples Two-Way Radios Product A Product B NiMH batteries Li-Ion Battery 10%-20% 24-hr Efficiency 20%-24% 24-hr Efficiency Maintenance Mode: 2.43W Maintenance Mode: 1.3W No Battery Mode: 1.15W No Battery Mode:.74W Purchase Price: $69.95 Purchase Price: $79.95 Difference in Technology: Battery Chemistry, Charging Technology Incremental Cost: Minimal

Products with Unique Requirements Some types of products may need energy allowances, but should not be excluded from standards.