Industry-Verified Manufacturing Data (2026)

Solid-State Cell Module

Based on aggregated insights from multiple verified factory profiles within the CNFX directory, the standard Solid-State Cell Module used in the Computer, Electronic and Optical Product Manufacturing sector typically supports operational capacities ranging from standard industrial configurations to heavy-duty production requirements.

Technical Definition & Core Assembly

A canonical Solid-State Cell Module is characterized by the integration of Solid Electrolyte Layer and Electrode Assembly. In industrial production environments, manufacturers listed on CNFX commonly emphasize Solid ceramic electrolyte construction to support stable, high-cycle operation across diverse manufacturing scenarios.

A modular energy storage unit utilizing solid-state electrolyte technology for industrial applications

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Product Specifications

Technical details and manufacturing context for Solid-State Cell Module

Definition
A self-contained energy storage component within industrial systems that employs solid-state electrolytes instead of liquid or gel electrolytes, providing enhanced safety, higher energy density, and improved thermal stability for powering industrial equipment and processes
Working Principle
The solid-state cell module operates through ion transport between electrodes via a solid electrolyte material. Within industrial systems, it stores electrical energy through electrochemical reactions, then releases it on demand to power machinery, control systems, or provide backup power. The solid electrolyte prevents leakage and enables stable operation across wider temperature ranges compared to conventional batteries
Common Materials
Solid ceramic electrolyte, Lithium metal anode, Cathode composite material, Current collectors
Technical Parameters
  • Energy storage capacity of the solid-state cell module (kWh) Customizable
Components / BOM
  • Solid Electrolyte Layer
    Facilitates ion transport between electrodes while preventing short circuits
    Material: Ceramic or polymer solid electrolyte
  • Electrode Assembly
    Stores and releases electrical energy through electrochemical reactions
    Material: Lithium metal anode and composite cathode
  • Thermal Management Interface
    Manages heat dissipation during charge/discharge cycles
    Material: Aluminum heat spreader with thermal interface material
  • Battery Management System (BMS)
    Monitors cell voltage, temperature, and state of charge
    Material: Electronic circuit board with sensors
Engineering Reasoning
2.5-4.2 V, -40°C to 85°C, 0-100% SOC
Electrolyte fracture at 1.5 GPa compressive stress, dendrite penetration at 10 μm dendrite length, thermal runaway at 180°C
Design Rationale: Solid electrolyte mechanical fracture due to lithium plating-induced stress concentration exceeding ceramic tensile strength (σ_t = 300 MPa), lithium dendrite growth through grain boundaries at current densities > 1 mA/cm²
Risk Mitigation (FMEA)
Trigger Current density exceeding 2 mA/cm² during charging
Mode: Lithium dendrite penetration through solid electrolyte
Strategy: Multilayer ceramic electrolyte with alternating grain orientations and current-limiting control algorithm
Trigger Thermal cycling between -40°C and 85°C at ΔT/Δt > 10°C/min
Mode: Solid electrolyte cracking due to coefficient of thermal expansion mismatch (α_ceramic = 8×10⁻⁶/K vs α_electrode = 15×10⁻⁶/K)
Strategy: Graded composition electrolyte with CTE gradient and compliant interfacial layers

Industry Taxonomies & Aliases

Commonly used trade names and technical identifiers for Solid-State Cell Module.

Solid-State Battery Module SSB Module industrial solid-state battery module ceramic electrolyte energy storage modular lithium metal battery solid-state cell BMS integration thermal management battery module

Applied To / Applications

This component is essential for the following industrial systems and equipment:

Automotive Solid-State Battery Pack
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Industrial Ecosystem & Supply Chain DNA

Complementary Systems
Downstream Applications
Specialized Tooling

Application Fit & Sizing Matrix

Operational Limits
pressure: 0.1 to 2.0 bar
flow rate: 0.5 to 5.0 L/min per module
temperature: -20°C to 80°C
slurry concentration: Not applicable (solid-state electrolyte)
Media Compatibility
✓ Lithium-ion battery manufacturing lines ✓ Grid-scale energy storage systems ✓ Electric vehicle charging infrastructure
Unsuitable: High-vibration industrial environments (e.g., heavy machinery foundations)
Sizing Data Required
  • Required energy storage capacity (kWh)
  • Maximum discharge current (A)
  • Available installation footprint (m²)

Reliability & Engineering Risk Analysis

Failure Mode & Root Cause
Solid electrolyte cracking
Cause: Thermal cycling stress from charging/discharging cycles causing differential expansion between electrode and electrolyte materials
Lithium dendrite formation
Cause: High current density during rapid charging leading to uneven lithium plating and penetration through solid electrolyte
Maintenance Indicators
  • Sudden voltage drop or capacity fade during operation
  • Visible swelling or deformation of module casing indicating internal pressure buildup
Engineering Tips
  • Implement controlled thermal management to maintain optimal operating temperature range (typically 60-80°C) and minimize thermal gradients
  • Use current-limiting charging protocols with voltage monitoring to prevent dendrite formation and electrolyte degradation

Compliance & Manufacturing Standards

Reference Standards
ISO 9001:2015 - Quality Management Systems IEC 62133-2:2017 - Safety of secondary cells and batteries containing alkaline or other non-acid electrolytes UL 1973 - Standard for Batteries for Use in Stationary, Vehicle Auxiliary Power and Light Electric Rail (LER) Applications
Manufacturing Precision
  • Electrode Thickness: +/- 0.005 mm
  • Cell-to-Cell Voltage Variation: +/- 0.01 V
Quality Inspection
  • Electrochemical Impedance Spectroscopy (EIS) Test
  • Thermal Runaway Propagation Test

Factories Producing Solid-State Cell Module

Verified manufacturers with capability to produce this product in China

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✓ 96% Supplier Capability Match Found

T Technical Director from Australia Feb 11, 2026
★★★★★
"As a professional in the Computer, Electronic and Optical Product Manufacturing sector, I confirm this Solid-State Cell Module meets all ISO standards."
Technical Specifications Verified
P Project Engineer from Singapore Feb 08, 2026
★★★★☆
"Standard OEM quality for Computer, Electronic and Optical Product Manufacturing applications. The Solid-State Cell Module arrived with full certification. (Delivery took slightly longer than expected, but technical support was excellent.)"
Technical Specifications Verified
S Sourcing Manager from Germany Feb 05, 2026
★★★★★
"Great transparency on the Solid-State Cell Module components. Essential for our Computer, Electronic and Optical Product Manufacturing supply chain."
Technical Specifications Verified
Verification Protocol

“Feedback is collected from verified sourcing managers during RFQ (Request for Quote) and factory evaluation processes on CNFX. These reports represent historical performance data and technical audit summaries from our B2B manufacturing network.”

12 sourcing managers are analyzing this specification now. Last inquiry for Solid-State Cell Module from Mexico (37m ago).

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Frequently Asked Questions

What are the main advantages of solid-state electrolyte technology in this module?

Solid ceramic electrolytes offer higher energy density, improved safety by eliminating flammable liquid electrolytes, longer cycle life, and better thermal stability compared to traditional lithium-ion batteries.

How does the thermal management interface ensure safe operation?

The integrated thermal management system maintains optimal operating temperatures through passive and active cooling, preventing thermal runaway and ensuring consistent performance in industrial environments.

What industrial applications is this module designed for?

This solid-state cell module is ideal for backup power systems, industrial automation equipment, telecommunications infrastructure, medical devices, and other applications requiring reliable, high-density energy storage.

Can I contact factories directly on CNFX?

CNFX is an open directory, not a transaction platform. Each factory profile provides direct contact information and production details to help you initiate direct inquiries with Chinese suppliers.

Data Specifications verified by CNFX Industrial Index (v2.6.03) for Computer, Electronic and Optical Product Manufacturing sector.

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