CH-10Nm³/h PEM Electrolyzer | Industrial Hydrogen Generator

PEM Water Electrolyzer System 10Nm³/h

PEM Electrolyzer CH-10Nm³/h

The CH-10Nm³/h PEM Water Electrolyzer System enables industrial-scale hydrogen generation with 99.999% purity, ideal for semiconductor manufacturing, renewable energy storage, and green fuel production. Featuring rapid response, 4.4 kWh/Nm³ efficiency, and 3.5 MPa output pressure, this scalable solution supports decarbonization goals while reducing operational costs. Designed for seamless integration with solar, wind, and microgrid systems.

The CH-10Nm³/h PEM Water Electrolyzer exemplifies advanced, scalable hydrogen production technology. It delivers high-purity hydrogen with excellent efficiency, pressure capability, and flexibility for integration into modern, sustainable energy systems. Its robust design and operational advantages make it a preferred choice for industries aiming to decarbonize and adopt green hydrogen solutions.

Pem Hydrogen Generator System 10Nm³/h

Parameter	Unit	Value
CH-10Nm³/h PEM Hydrogen Production System
Gas production	Nm³/h	15
Hydrogen production	Nm³/h	10
Operating temperature	℃	5-70
Hydrogen purity	%	99.999
Dew point	℃	-74
Water quality demand	/	ASTM D1193 Type I deionized water (>10MΩ·CM)
Maximum stress	Mpa	3.5
Supply voltage	V	380
Water consumption	L/h	10
Size	mm	3000×1400×2100
Direct current consumption	kW·h/Nm³H₂	4.4
Load regulation range	%	5-120
Application area	/	Photovoltaic off-grid hydrogen production, wind hydrogen production, cogeneration, semiconductor, multi-energy complementary micro-network and other industrial hydrogen fields

Core Components of an PEM Electrolyzer

1. Membrane Electrode Assembly (MEA)

The MEA is the heart of PEM electrolyzer stack design. It includes:

Catalyst-coated membrane: Usually platinum-based
Gas diffusion layers (GDLs): Promote gas flow and distribute water evenly
Ionomer: Facilitates proton conductivity

2. Bipolar Plates and Flow Fields

Bipolar plates manage the flow of gases and fluids. Made from coated metals or graphite composites, they:

Channel water and gases efficiently
Conduct electrical current
Provide mechanical support

3. Current Collectors and Gaskets

These ensure secure electrical connections and gas-tight seals, enabling safe and reliable operation.

4. Advanced Materials for Industrial Systems

Newer PEM systems utilize:

Corrosion-resistant alloys
Enhanced polymer membranes
Heat-resistant composites

These improve durability and performance in high-demand industrial settings.

The PEM Electrolyzer Working Principle (Step-by-Step)

1. Water Decomposition at the Anode

Reaction: 2H₂O → O₂ + 4H⁺ + 4e⁻ Water is fed into the anode chamber, where an applied voltage splits it into oxygen gas, protons (H⁺), and electrons.

2. Proton Transport Through the PEM

The PEM membrane selectively allows only protons to pass through to the cathode side, while blocking electrons and gases.

3. Hydrogen Generation at the Cathode

Reaction: 4H⁺ + 4e⁻ → 2H₂ Electrons from the external circuit and protons recombine at the cathode to form high-purity hydrogen gas.

4. Gas Separation and Purification

Integrated gas management systems ensure:

Efficient O₂ and H₂ separation
Removal of water vapor
Delivery of fuel-cell-grade hydrogen

Key Performance Advantages for Industrial Applications

1. Higher Efficiency (75–85%)

HPEM systems outperform many alternatives with low power consumption per Nm³ of H₂.

2. Rapid Load Response

Ideal for fluctuating inputs from solar PV or wind farms, with dynamic ramping and shutoff.

3. Modular and Compact

Space-saving design enables stackable units for scalable deployment—from 100 Nm³/h to multi-MW plants.

4. Minimal Maintenance

No corrosive alkaline liquids and fewer mechanical parts lead to lower OPEX and longer system uptime.

Technical Specifications Buyers Should Evaluate

1. Current Density

Measured in A/cm². Higher densities indicate greater output per cell but may impact lifespan.

2. Hydrogen Production Capacity

Common ranges:

Small: 1–10 Nm³/h
Medium: 50–100 Nm³/h
Large: >500 Nm³/h

3. Stack Lifetime and Degradation

Modern PEM stacks last 60,000–80,000 hours, depending on operating conditions.

4. Balance of Plant (BoP) Requirements

BoP includes:

Power electronics
Water purification units
Thermal management
Gas dryers and sensors

Industrial Application Case Studies

1. Renewable Hydrogen Megaprojects

Countries like Germany and Australia are scaling up PEM electrolyzer plants >100 MW to feed green hydrogen pipelines.

2. Industrial Energy Storage

PEM systems buffer excess renewable energy in steel plants and chemical factories by converting it to storable hydrogen.

3. Hydrogen for Transportation

HPEM electrolyzers produce clean H₂ for:

Fuel-cell buses
Trucks
Rail and marine fleets

Frequently Asked Questions (FAQs)

Q1: What’s the lifespan of a PEM electrolyzer stack?

Modern stacks typically last 60,000–80,000 hours, depending on usage and conditions.

Q2: Is PEM electrolysis suitable for off-grid renewable systems?

Yes. Their fast startup and flexible load response make them ideal for pairing with solar and wind sources.

Q3: How pure is the hydrogen produced?

PEM electrolyzers can deliver >99.99% purity, suitable for fuel cells and industrial uses.

Q4: Are PEM systems safe to operate?

Absolutely. Built-in sensors, automated shutoff, and leak detection ensure safe and reliable performance.

Q5: What influences the cost of an HPEM system?

Major factors include:

Stack size and material
Pressure output
Required BoP components
Operating environment

Hele Titanium Hydrogen Company Profile

Expertise:
Hele Titanium Hydrogen is a leading PEM electrolyzer manufacturer in China, boasting over a decade of specialized experience in designing and producing advanced PEM electrolyzers tailored to meet the unique demands of diverse industries.

Service Scope:
The company offers end-to-end services, from design to large-scale production, ensuring clients receive high-quality, high-performance PEM electrolyzers that support their transition to sustainable energy solutions.

Customization Services:
Hele Titanium Hydrogen provides bespoke solutions, enabling adjustments to electrolyzer stack dimensions and capacity, optimization of operational parameters, selection of appropriate electrode materials and components, configuration of efficient cell structures, and additional system customization options to align with specific client requirements.

PEM Electrolyzer Product Overview

Capacity Range:
The company offers PEM electrolyzers in various capacities, including 0.01-1Nm³/h, 1-10Nm³/h, 10-50Nm³/h, 50-200Nm³/h, as well as compact models (2000-7000ml/min and 300-2000ml/min), catering to applications spanning small-scale laboratories to large industrial operations.

Applications:
These electrolyzers are widely deployed across sectors such as fuel cells, multi-energy hybrid microgrids, power plants, semiconductor manufacturing, hydrogen refueling stations, polysilicon production, chemical industries, optoelectronics, energy storage facilities, power absorption systems, and renewable hydrogen production.

PEM Electrolyzer Operating Principle & Advantages

Operating Principle:
PEM electrolyzers generate hydrogen and oxygen through water electrolysis. At the anode, an oxidation reaction produces oxygen, protons, and electrons; protons migrate via the proton exchange membrane to the cathode, where they combine with electrons to form hydrogen gas.

Advantages:
PEM electrolyzers excel in producing ultra-pure hydrogen, operating with high efficiency, and offering rapid response times. They are ideally suited for integration with renewable energy sources (e.g., wind, solar), advancing global decarbonization efforts and enabling the transition to a low-carbon future.

Key Considerations for Selecting PEM Electrolyzers

Hydrogen Production Requirements:
Define required hydrogen volume, purity, and pressure to select the appropriate electrolyzer model.
Input Power Specifications:
Evaluate current and voltage requirements to ensure alignment with production scale and application needs.
System Design & Configuration:
Assess critical components (e.g., proton exchange membrane, gas diffusion layer, catalyst layer) to guarantee system efficiency and durability.
Manufacturer Reputation:
Partner with reputable manufacturers delivering reliable, high-quality electrolyzers and comprehensive after-sales support.
Customization Options:
Inquire about tailor-made solutions to address specific operational demands.

Hele Titanium Hydrogen’s Commitment & Strengths

One-Stop Solutions:
Beyond premium PEM electrolyzers, Hele Titanium Hydrogen provides detailed product proposals, seamless logistics, and expert installation assistance.

Strategic Partnerships:
Collaborating with Hele Titanium Hydrogen means gaining a partner dedicated to the success of your hydrogen generation project, offering end-to-end support from design and planning to delivery and installation.

Client-Centric Solutions:
The company delivers customized hydrogen generation solutions for wholesalers, brand owners, manufacturers, suppliers, laboratories, and individual users, accommodating diverse scales and requirements.

CH-10Nm³/h PEM Water Electrolyzer System

High-Efficiency Hydrogen Generation for Industrial Applications

Elevate your hydrogen production with the CH-10Nm³/h PEM Water Electrolyzer—engineered for reliability, efficiency, and seamless integration into modern industrial operations. As a leading solution in the field of green hydrogen technology, this system is designed to meet the rigorous demands of B2B clients across energy, manufacturing, and technology sectors.

Key Features & Advantages

High-Purity Hydrogen Output:
Delivers up to 10 Nm³/h of hydrogen at 99.999% purity, meeting the strictest industry standards for electronics, chemical processing, and renewable energy storage.
Advanced PEM Technology:
Utilizes state-of-the-art Proton Exchange Membrane (PEM) technology for rapid response, high efficiency (4.4 kWh/Nm³ H₂), and safe, reliable operation.
Robust Industrial Design:
Built for continuous operation with a compact footprint (3000×1400×2100 mm) and maximum pressure up to 3.5 MPa, supporting both centralized and distributed hydrogen supply.
Flexible Integration:
Optimized for renewable energy sources—seamlessly connects with photovoltaic, wind, and cogeneration systems, making it ideal for off-grid and multi-energy microgrid applications.
Low Operating Costs:
Efficient water consumption (10 L/h) and low maintenance requirements reduce total cost of ownership for industrial clients.

Why Choose the CH-10Nm³/h PEM Electrolyzer?

Brand Reliability:
Trusted by leading companies in hydrogen production, semiconductor manufacturing, and energy storage.
Scalable & Customizable:
Modular design allows for easy scaling to meet growing hydrogen demands—future-proofing your investment.
Compliance & Safety:
Meets international standards for water quality (ASTM D1193 Type I) and safety, ensuring uninterrupted, high-purity hydrogen supply.

Target Applications

Green hydrogen production for refueling stations
Renewable energy storage and grid balancing
Electronics and semiconductor manufacturing
Chemical and industrial gas supply

Optimize Your Hydrogen Supply Chain

The CH-10Nm³/h PEM Water Electrolyzer empowers your business to achieve sustainability targets, reduce carbon footprint, and secure a competitive edge in the evolving hydrogen economy. Contact us today to discover how our advanced PEM electrolyzer solutions can transform your industrial hydrogen operations.

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