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New Energy Equipment----Successfully collaborated with the American New Energy Group to develop the first DC hydrogen cracking furnace project

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New Energy Equipment----Successfully collaborated with the American New Energy Group to develop the first DC hydrogen cracking furnace project

Name: New Energy EquipmentSuccessfully collaborated with the American New Energy Group to develop the first DC hydrogen cracking furnace project
Brand: Shaanxi Chengda
Price: 1 USD

Cheap New Energy Equipment----Successfully collaborated with the American New Energy Group to develop the first DC hydrogen cracking furnace project for sale

Brand Name : Shaanxi Chengda

Model Number : Negotiate based on equipment processing capacity

Certification : ISO9001

Place of Origin : China

MOQ : 1set

Price : price is negotiable

Payment Terms : L/C,D/A,T/T,Western Union,MoneyGram

Supply Ability : Complete production supply chain, supply on time, and meet quality standards

Delivery Time : 2 months

Packaging Details : Discuss according to the specific requirements of Party A

Production : 1400m³/d

Gas use : New clean energy

Gas characteristics : Synthetic fuel (Burning mixture)

Alternate use : Sewage (waste water) treatment

Warranty : 1year

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DC Hydrogen Cracking Furnace

Overview

DC hydrogen cracking furnace is a specialized thermal processing equipment integrating direct current (DC) heating technology and hydrogen atmosphere cracking , mainly used for high-purity material purification, waste resource recycling, and advanced material preparation. It utilizes DC arc/plasma heating to generate ultra-high temperature environments (1800–3000℃) and relies on hydrogen's strong reducing property and cracking effect to decompose organic/inorganic impurities, reduce metal oxides, or crack complex compounds into high-purity target products. The equipment is widely applied in fields such as rare metal extraction, semiconductor material purification, battery material recycling, and high-temperature alloy processing.

Core Working Principle

DC Heating System: The furnace generates stable DC arc or plasma through graphite electrodes (cathode + anode) , realizing rapid heating of materials via direct thermal radiation and electromagnetic induction. Compared with AC heating, DC heating has stronger arc stability, uniform temperature field distribution, and lower energy consumption, which can avoid material oxidation caused by unstable arcs.
Hydrogen Atmosphere Cracking Mechanism:
- Reduction Reaction: Hydrogen (H₂) acts as a reducing agent to react with metal oxides in materials (e.g., MOₓ + xH₂ → M + xH₂O) , reducing high-valence metals to elemental form and improving product purity.
- Cracking Reaction: Under ultra-high temperature and hydrogen atmosphere, organic impurities (e.g., oils, resins) or complex compounds (e.g., metal carbides, nitrides) are cracked into small-molecule gases (CH₄, NH₃, H₂O) , which are discharged with the tail gas to achieve impurity removal.
- Purification Effect: Hydrogen can also eliminate gas impurities (O₂, N₂, CO) in materials by forming H₂O, NH₃, and CH₄, further improving the purity of target products (up to 99.99% or higher) .

Key Technical Parameters

Parameter Category	Key Indicators	Typical Range	Application Notes
Heating Performance	Rated Power	50–500 kW	Matched with furnace volume and material heating demand
	Maximum Temperature	1800–3000℃	Adjustable according to process; precise control via infrared/thermocouple
	Heating Rate	10–50℃/min	Rapid heating for small-batch production; slow heating for high-purity purification
Hydrogen System	Hydrogen Purity	≥99.99% (high-purity H₂)	Impurity-free hydrogen avoids secondary pollution of materials
	Atmosphere Pressure	0.1–0.5 MPa (positive pressure)	Positive pressure prevents air leakage; pressure adjustable via pressure relief valve
	Hydrogen Flow Rate	5–50 L/min	Matched with material quantity and cracking reaction rate
Vacuum Performance	Ultimate Vacuum Degree	1×10⁻³–5×10⁻² Pa	Pre-vacuum to remove air before hydrogen injection; reduces oxidation risk
	Vacuum Pumping Speed	10–100 m³/h	Ensures rapid vacuuming and stable vacuum environment
Structural Parameters	Furnace Chamber Volume	0.01–0.5 m³	Suitable for small-to-medium batch production (0.1–50 kg/batch)
	Electrode Type	Graphite electrode (replaceable)	High-temperature resistance, low impurity content; matching electrode diameter with power
	Lining Material	Zirconia, alumina, or graphite	Corrosion resistance, high-temperature stability; avoids material contamination
Cooling System	Cooling Method	Water cooling (circulating)	Cools furnace shell, electrodes, and vacuum chamber
	Water Pressure/Flow Rate	0.3–0.6 MPa / 10–50 L/min	Prevents equipment overheating; equipped with water shortage alarm
Safety System	Safety Interlocks	Vacuum leak detection, hydrogen concentration monitoring, over-temperature alarm, emergency shutdown	Ensures safe operation of hydrogen atmosphere and high-temperature environment
	Explosion-Proof Device	Explosion-proof valve, hydrogen discharge pipeline	Prevents hydrogen explosion risk; meets industrial safety standards

Core Advantages

High Purity Output: Hydrogen's strong reducing property and vacuum pre-treatment effectively remove oxides, gases, and organic impurities, enabling target product purity up to 99.99%–99.999% , suitable for high-end material preparation.
Efficient Heating: DC arc/plasma heating realizes rapid temperature rise (10–50℃/min) and ultra-high temperature environment (up to 3000℃) , which can handle high-melting-point materials (e.g., tungsten, molybdenum, titanium) and accelerate cracking reactions.
Environmental Friendliness: The main by-products of hydrogen cracking are H₂O and small-molecule gases, which can be discharged after simple treatment (e.g., water condensation) ; no toxic waste is generated, complying with environmental protection standards.
Stable and Reliable: DC heating ensures uniform temperature field and stable arc; positive pressure hydrogen atmosphere and vacuum interlock prevent air leakage, reducing material oxidation and improving product consistency.

Typical Application Scenarios

Rare Metal Extraction & Purification: Reduction of rare metal oxides (e.g., WO₃, MoO₃, TiO₂) to high-purity elemental metals; purification of rare earth metals to remove impurities such as oxygen and carbon.
Battery Material Recycling: Cracking of lithium-ion battery cathode materials (e.g., LiCoO₂, LiNiMnCoO₂) to recover cobalt, nickel, lithium, and other valuable metals; hydrogen reduction of metal oxides in waste batteries to improve recovery rate.
Semiconductor & High-Tech Material Preparation: Purification of semiconductor materials (e.g., silicon, germanium) to remove trace impurities; preparation of high-purity metal powders (e.g., hydrogen-reduced nickel powder, cobalt powder) for electronic components.
Waste Resource Recycling: Cracking of organic-inorganic composite waste (e.g., metal-plastic composites, electronic waste) to separate metals and organic matter; recycling of valuable metals in industrial waste residues.

Key Technical Challenges & Solutions

Challenge	Solution
Hydrogen Leakage Risk	Equip hydrogen concentration sensors (detection limit ≤1% LEL) , vacuum leak detection system, and explosion-proof valves; use sealed furnace body and high-temperature resistant gaskets.
Electrode Consumption	Select high-purity graphite electrodes; optimize arc stability and current density to reduce electrode ablation; design replaceable electrode structure for easy maintenance.
Material Contamination	Use high-purity lining materials (e.g., zirconia, high-purity graphite) ; pre-treat hydrogen to remove moisture and impurities; avoid direct contact between materials and contaminated components.
Energy Consumption Control	Adopt energy-saving DC power supply; recover waste heat from cooling water; optimize heating curve to avoid unnecessary high-temperature holding.

Selection & Customization Suggestions

Based on Material Properties: For high-melting-point metals (e.g., W, Mo) , select high-power models (≥200 kW) with maximum temperature ≥2500℃ ; for low-melting-point materials or organic cracking, choose medium-power models (50–150 kW) with temperature ≤2000℃ .
According to Production Scale: Small-batch R&D (0.1–1 kg/batch) selects furnace chamber volume ≤0.05 m³ ; medium-batch production (1–50 kg/batch) chooses 0.05–0.5 m³ furnace chamber.
Considering Purity Requirements: For ultra-high purity (≥99.999%) products, select models with high vacuum performance (ultimate vacuum ≤1×10⁻³ Pa) and high-purity hydrogen purification system; for general purity requirements, common vacuum and hydrogen configurations are acceptable.
Matching Safety Standards: Ensure the equipment meets local hydrogen safety standards (e.g., GB 3634 for hydrogen use safety, NFPA 55 for international standards) , and is equipped with complete safety interlocks and explosion-proof devices.

If you need to customize parameters (e.g., furnace chamber volume, maximum temperature, hydrogen flow rate) for specific materials or production processes, please provide detailed requirements (e.g., material type, batch weight, target purity) , and we can provide a tailored technical solution and equipment parameter list.

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