Batteries Non-Rechargeable (Primary)

Part Number	Description / PDF	Quantity
CR1620 (EACH) BatteryGuy	3V 68MAH LITHIUM COIN BATTERY	800
373 RENATA BatteryGuy	1.55V 29MAH SILVER OXIDE BATTERY	780
396 RENATA BatteryGuy	1.55V 32MAH SILVER OXIDE BATTERY	780
CR2477N (EACH) BatteryGuy	3V 950MAH LITHIUM COIN BATTERY	590
357 RENATA BatteryGuy	1.55V SILVER OXIDE BATTERY	532
389 RENATA BatteryGuy	1.55V 85MAH SILVER OXIDE BATTERY	490
366 RENATA BatteryGuy	1.55V 47MAH SILVER OXIDE BATTERY	900
CR-P2 BatteryGuy	6V 1400MAH LITHIUM CRP2 BATTERY	0
393 RENATA BatteryGuy	1.55V 80MAH SILVER OXIDE BATTERY	440
370 RENATA BatteryGuy	1.55V 40MAH SILVER OXIDE BATTERY	500
CR2025 (EACH) BatteryGuy	3V 165MAH LITHIUM BATTERY	790
394 RENATA BatteryGuy	1.55V 84MAH SILVER OXIDE BATTERY	980
CR-1/3N BatteryGuy	3V 170MAH LITHIUM BATTERY	790
CR2032 (EACH) BatteryGuy	3V 225MAH LITHIUM COIN BATTERY	980
379 RENATA BatteryGuy	1.55V 16MAH SILVER OXIDE BATTERY	180
CR2450N (EACH) BatteryGuy	3V 550MAH LITHIUM COIN BATTERY	420
386 RENATA BatteryGuy	1.55V 45MAH SILVER OXIDE BATTERY	470
CR2016 (EACH) BatteryGuy	3V 90MAH LITHIUM COIN BATTERY	2000
CR123A MARSELL BatteryGuy	3V 1500MAH CR123A LITHIUM	900
377 RENATA BatteryGuy	1.55V 28MAH SILVER OXIDE BATTERY	850

Batteries Non-Rechargeable (Primary)

1. Overview

Non-rechargeable batteries, also known as primary batteries, are electrochemical cells designed for single-use applications. They convert chemical energy into electrical energy through irreversible reactions. These batteries are critical in applications requiring reliable long-term power without recharging infrastructure, playing vital roles in consumer electronics, medical devices, and industrial systems.

2. Main Types & Functional Classification

Type	Functional Characteristics	Application Examples
Alkaline	High energy density, long shelf life (5-10 years), moderate cost	Remote controls, flashlights, toys
Zinc-Carbon	Lower energy density, short shelf life (2-3 years), low cost	Low-drain devices like radios
Lithium (Li-MnO )	High voltage (3V), excellent energy density, 10-15 years shelf life	Digital cameras, IoT devices, medical equipment
Silver Oxide	Stable voltage output, compact size, 3-5 years shelf life	Watches, calculators, hearing aids
Magnesium	High energy-to-weight ratio, military-grade reliability	Missile systems, emergency equipment

3. Structure & Composition

Typical primary battery construction includes: - Cathode: Manganese dioxide (alkaline) or carbon zinc (zinc-carbon) - Anode: Zinc (alkaline) or lithium metal (lithium batteries) - Electrolyte: Potassium hydroxide (alkaline) or organic solvents (lithium) - Separator: Porous membrane preventing short circuits - Container: Steel or nickel-plated steel casing

4. Key Technical Specifications

Parameter	Typical Values	Importance
Nominal Voltage	1.5V (alkaline), 3V (lithium)	Determines device compatibility
Capacity	1500-3000 mAh (AA)	Runtime prediction
Energy Density	150-250 Wh/kg	Size/weight optimization
Self-Discharge Rate	2-10% per year	Storage longevity
Operating Temperature	-20 C to 60 C	Environmental reliability
Leakage Resistance	5-10 years	Device safety

5. Application Fields

Consumer Electronics: Smart meters, wireless sensors
Medical Devices: Pacemakers, glucose monitors
Industrial Equipment: Smoke detectors, remote sensors
Military/Aerospace: Munitions, satellite systems
Emergency Systems: Backup power supplies

6. Leading Manufacturers & Products

Manufacturer	Key Products	Specialization
Duracell	Ultimate Lithium, Quantum	Military-specification batteries
Energizer	Lithium L91, MAX	Consumer electronics focus
Panasonic	CR123A, Alkaline LR6	Industrial applications
Maxell	Lithium CR2032	Miniature battery solutions
Renata (Switzerland)	Silver Oxide cells	Medical device batteries

7. Selection Recommendations

Match voltage requirements with device specifications
Evaluate expected runtime vs. physical size constraints
Consider operating temperature range (-30 C to 85 C extremes)
Assess leakage risk for critical applications
Compare cost per mAh for high-volume deployments
Verify compliance with IEC 60086 standards

Industry Trends Analysis

Key development directions include: - Energy Density Improvement: Graphene-enhanced cathodes targeting 400 Wh/kg - Eco-friendly Materials: Mercury-free zinc-air batteries for hearing aids - Printed Batteries: Flexible primary cells for IoT sensors - Nano-structured Electrodes: 20% capacity increase in AA format - Standardization: Global adoption of IEC 60086-4 safety protocols - Smart Packaging: Integrated fuel gauges in battery casings