- •FOREWORD
- •OVERVIEW
- •TABLE OF CONTENTS
- •LIST OF FIGURES
- •LIST OF TABLES
- •INTRODUCTION
- •DEFINITIONS
- •BATTERY COMPONENTS AND OPERATION
- •Cells vs. Batteries
- •Primary and Secondary Cells and Batteries
- •Battery Components
- •Cell and Battery Voltage
- •Capacity and Battery Ratings
- •Series and Parallel Connections
- •LEAD-ACID BATTERY TYPES
- •Flooded Lead-Acid Batteries
- •Sealed Lead-Acid Batteries
- •OPERATION AND CONSTRUCTION
- •Lead-Acid Battery Active Materials
- •Electrochemistry of the Lead-Acid Cell
- •Negative and Positive Plate Construction Methods
- •Antimony/Calcium/Selenium/Tin Alloying
- •Specific Gravity
- •Effects of Discharge Rate and Temperature on Capacity and Life
- •APPLICATIONS
- •Starting, Lighting, and Ignition
- •Industrial
- •Traction
- •Stationary
- •Portable
- •SIZING AND SELECTION
- •MAINTENANCE
- •General
- •Matching the Charger to Battery Requirements
- •Avoiding Overdischarge
- •Maintaining Electrolyte Levels
- •Cleaning
- •Avoiding High Temperatures
- •Supplying an Equalizing Charge
- •Safety Precautions
- •Testing
- •STORAGE, TRANSPORTATION, AND DISPOSAL
- •Storage
- •Transportation
- •Disposal
- •BIBLIOGRAPHY
- •CONCLUDING MATERIAL
Lead-Acid Storage Batteries |
DOE-HDBK-1084-95 |
SIZING AND SELECTION |
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SIZING AND SELECTION
Sizing and selection of lead-acid batteries should be performed according to ANSI/IEEE Std 485, IEEE Recommended Practice for Sizing Large Lead Storage Batteries for Generating
Stations and Substations. As described earlier, the duty cycle is the most important criterion in battery sizing and selection. ANSI/IEEE Std 485 contains directions as well as a sample exercise for determining the duty cycle. A simple duty cycle diagram is shown in Figure 15.
Each of the loads (designated by L1-6) requires a certain amperage for a specified time and duration. In the example duty cycle, a randomly occurring load (L7 ) is assumed to occur in the 120th minute. The placement of randomly occurring loads in the duty cycle is also covered in ANSI/IEEE Std 485.
320 |
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280 |
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L5 |
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L7 |
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240 |
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200 |
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L2 |
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180 |
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L4 |
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120 |
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80 |
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L3 |
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L6 |
L |
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7 |
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40 |
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L1 |
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1 |
30 |
60 |
90 |
120 |
150 |
179 |
180 |
1 |
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Minutes |
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Min |
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Figure 15. Diagram of a duty cycle.
Rev. 0 |
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Batteries |
SIZING AND SELECTION |
DOE-HDBK-1084-95 |
Lead-Acid Storage Batteries |
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Other selection factors recommended by ANSI/IEEE Std 485 are the following:
1.Physical characteristics, such as size and weight of the cells, container material, vent caps, intercell connectors, and terminals
2.Planned life of the installation and expected life of the cell design
3.Frequency and depth of discharge
4.Ambient temperature
5.Maintenance requirements for the various cell designs
6.Seismic characteristics of the cell design.
Additional requirements for nuclear facility service are contained in ANSI/IEEE Std 535,
IEEE Standard for Qualification of Class 1E Lead Storage Batteries for Nuclear Power Generating Substations.
Batteries |
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