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Advanced Energy Storage Nano-Carbon AGM Battery

C&D’s Advanced Energy Storage (AES) battery line meets the demanding standards of applications that may face extreme temperature, shock, or vibration. Enhanced features such as a rugged case, Deep Cycle Series (DCS) Technology, and Advanced Nano-Carbon® technology make the AES an ideal choice for renewable energy applications, Battery Energy Storage Systems (BESS), or any application that calls for repetitive cycling.

Battery Quick Facts

  • Battery type: VRLA Nano-Carbon AGM (VRLA)
  • Capacity: 100 - 204 Amp-Hours
  • Design Life: 3,000 Cycles @ 50% DoD
  • Operating Environments: Indoor, Outdoor Controlled, Outdoor Uncontrolled
  • Certifications & Compliances: Complies with UN 2794., UL1989 Compliant
  • Industries: Telecom, Renewable Energy

Features & Benefits

  • Field-proven DCS high density active material for extended cycle life
  • C&D Nano-Carbon® enhanced active material to maximize cycle performance and Partial state of charge (PSoC) operation
  • PSoC operation allows installation into nearly all cycling applications
  • Improved charging efficiency reduces grid corrosion for longer battery life
  • 12V Monobloc design aids installation and handling
  • Removable carrying handles allow installation without specialized lifting equipment
  • Rugged polypropylene case and cover for resistance to shock and vibration
  • AGM construction means no liquid electrolyte, eliminates watering and spills
  • UL recognized flame-arresting one-way pressure-relief vent for safety and long life
  • Over 98% recyclable
  • Not restricted for surface transport; classified as non-hazardous material as related to DOT-CFR Title 49 parts 171-189.
# AGM# VRLA

Attachments & Resources

AES-Datasheet.pdf

.PDF • 0.4 KB

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Related Knowledges

Mapping the Capacity–Conductance Boundary in VRLA Lead-Acid Batteries

This article distills a technical study into a practical, plain-English guide on how **electrolyte conductance** and **deliverable capacity** relate inside **VRLA (valve-regulated lead-acid)** batteries. By modeling the **electrolyte** (acid + water) and the **plates** (active materials) separately—and then combining their constraints—we obtain **upper and lower bounds** that define where a battery’s **normalized conductance** \(G_d/G_n\) and **normalized capacity** \(Ah_d/Ah_n\) can realistically sit. The result helps field engineers interpret conductance readings, separate **undercharge/sulfation** from **electrolyte dry-out**, and decide when capacity testing or replacement is justified.

#AGM #VRLA
Mr. Kasiean Sukemoke

Mr. Kasiean Sukemoke

Founder & MD

August 29, 2025 at 01:18 AM 5 min
Battery Health Testing with Impedance & Conductance: A Clear, Practical Guide

Impedance and conductance tests provide a fast, non-destructive way to assess battery health—especially for lead-acid and VRLA cells—without doing a full discharge test. This article explains what these tests measure, why baseline values matter more than one-off readings, and how to build a simple trending program that reliably flags aging cells before they fail.

#VRLA #PM
Mr. Kasiean Sukemoke

Mr. Kasiean Sukemoke

Founder & MD

August 29, 2025 at 01:13 AM 4 min
Choosing and Using VRLA Batteries (AGM vs. Gel): A Practical Guide

Valve Regulated Lead-Acid (VRLA) batteries are widely used in critical power systems because they’re sealed, low-maintenance, and safe when operated correctly. This guide explains how VRLA batteries work, compares Absorbent Glass Mat (AGM) and Gel technologies, and gives clear, field-ready advice for selecting the right type and operating it for long life.

#VRLA #AGM #UPS
Mr. Kasiean Sukemoke

Mr. Kasiean Sukemoke

Founder & MD

August 27, 2025 at 06:45 PM 3 min
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