Titanium anode for treating sodium bromide wastewater

Substrate: ASTM Grade 1 Titanium
Coating: Ru-Ir mixed metal oxide
Current Density: 200–3000 A/m²
Temperature Range: 5°C to 60°C
Acid Concentration: 0.5–15 wt%
Acid Recovery Rate: ≥85%
Design Life: ≥8 years
Application: Acid water electrodialysis treatment systems

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Product Description

What Is Titanium Anode for Treating Sodium Bromide Wastewater and How to Choose the Right One for Your Industry?

A Titanium Anode for Treating Sodium Bromide Wastewater is a high-performance electrochemical electrode designed for the treatment, purification, and recycling of bromide-containing industrial wastewater. Sodium bromide wastewater is commonly generated in pharmaceutical production, oil and gas drilling fluids, flame retardant manufacturing, photographic chemicals, dye production, and specialty chemical industries. These waste streams often contain bromide ions, organic contaminants, suspended solids, and dissolved salts that require effective treatment before discharge or reuse.

The Titanium Anode for Treating Sodium Bromide Wastewater is manufactured using a Grade 1 or Grade 2 titanium substrate coated with ruthenium-iridium mixed metal oxides (Ru+Ir MMO). This advanced coating exhibits excellent electrocatalytic activity, superior corrosion resistance, low chlorine evolution potential, and long operational life in highly corrosive bromide-containing environments.

During electrochemical treatment, the electrode generates powerful oxidizing species that efficiently decompose organic pollutants, reduce COD levels, remove color, and improve water quality. Compared with conventional graphite and lead-based electrodes, MMO-coated titanium anodes provide higher current efficiency, lower energy consumption, and significantly longer service life.

When selecting a suitable electrode, industries should consider bromide concentration, wastewater composition, operating temperature, current density, reactor design, and desired treatment efficiency. Proper electrode selection ensures stable operation, reduced maintenance, and maximum wastewater treatment performance.

Features of Titanium Anode for Treating Sodium Bromide Wastewater

Superior Corrosion Resistance、Ultra-Long Service Life、High Electrocatalytic Activity & Efficiency、Eco-Friendly、Low Maintenance

Superior Resistance to Corrosion Damage

The titanium anode boasts outstanding anti-corrosion performance to withstand harsh acidic, alkaline and saline electrolyte environments for stable long-term operation.

Ultra-Long and Reliable Service Life

With stable coated active layers and robust titanium substrate, this anode achieves remarkably extended service cycles far exceeding conventional metal anode alternatives.

High Electrocatalytic Activity & Efficiency

Its specialized noble metal coating delivers excellent electrocatalytic performance, lowering cell voltage and improving overall electrolysis energy utilization efficiency.

Environmentally Friendly and Energy Saving

No harmful heavy metal dissolution occurs during electrolytic reactions, avoiding secondary pollution and complying with global environmental production standards.

Low Maintenance with Reduced Costs

Structurally stable with minimal electrode degradation in regular service, requiring few downtime checks and negligible spare part replacement costs.

Full Customization Solutions to Meet Your Specific Needs!

Customization Available (Size, Material, Coating, Shape, Lifespan & Installation)

Titanium anode for treating sodium bromide wastewater can be fully customized according to industrial requirements:

HY Ti-Ni Import & Export provides comprehensive customization services for Titanium Anodes for Treating Sodium Bromide Wastewater.

Available Custom Options

Titanium mesh, plate, rod, tube, ribbon designs
Grade 1 and Grade 2 titanium substrates
Customized Ru+Ir coating formulations
Coating loading from 6–20 g/m²
Single-side or double-side coating
Custom dimensions and thicknesses
High-current-density electrode configurations
Enhanced bromide-resistant coating systems
Custom electrical connections and busbars
Modular electrode assemblies
Large-scale wastewater treatment electrode arrays
Long-life coating optimization
High-temperature operation designs
OEM logo and packaging support
Custom mounting structures and frames

Why Choose Titanium Anode from HY Ti-Ni Import & Export?

At Hengyi Ti-Ni Import Export, we specialize in titanium-based electrochemical materials with strong engineering capability in anode system design.

HY Ti-Ni Import & Export is a professional supplier of Titanium Anodes for Treating Sodium Bromide Wastewater. Located in Baoji, China, we benefit from advanced titanium manufacturing resources, mature MMO coating technology, and a complete industrial supply chain.

Every electrode is produced under strict quality control procedures, including substrate preparation, coating application, thermal decomposition sintering, and final electrochemical performance testing.

Our advantages include:

Advanced Ru+Ir MMO coating technology
Excellent bromide corrosion resistance
High current efficiency
Stable electrochemical performance
Long service life
Competitive factory pricing
Flexible OEM and ODM solutions
Fast worldwide delivery
Professional engineering assistance
Comprehensive inspection reports

We are committed to providing reliable and cost-effective electrochemical wastewater treatment solutions for global customers.

Titanium Anode Purchase Guide: A Comprehensive Guide

Selecting the right Titanium Anode for Treating Sodium Bromide Wastewater is essential for ensuring stable electrochemical performance, efficient pollutant removal, and long-term cost control. Since sodium bromide wastewater contains bromide ions, organic compounds, and dissolved salts, the electrode must provide strong oxidation ability and excellent corrosion resistance.

First, analyze the wastewater characteristics, including bromide concentration, COD level, pH value, conductivity, and temperature. These parameters directly affect the required coating formulation and current density range.

Second, choose the appropriate electrode structure based on your reactor design. Titanium mesh anodes are suitable for high surface-area applications and efficient oxidation processes. Plate anodes are ideal for large-scale industrial systems, while rod and tubular anodes are better for compact or customized equipment configurations.

Third, evaluate the Ru+Ir coating performance, including coating loading, adhesion strength, and expected service life. High-quality MMO coatings ensure stable chlorine/bromine evolution reactions and reduce energy consumption.

Additionally, confirm system voltage, current density requirements, and installation space before purchasing. Maintenance frequency and expected operating lifespan should also be considered for cost efficiency.

Finally, always work with a qualified manufacturer offering technical support, testing reports, and customization capabilities. A properly selected titanium anode significantly improves treatment efficiency, extends equipment life, and ensures reliable operation in sodium bromide wastewater treatment systems.

Purchase Guide

1. What is a Titanium anode for treating sodium bromide wastewater?
2. Main Technical Parameters of a Titanium anode for treating sodium bromide wastewater.
3. Specifications of a Titanium anode for treating sodium bromide wastewater.
4. Current Output of Standard Titanium anode for treating sodium bromide wastewater.
5. Applications of a Titanium anode for treating sodium bromide wastewater.
6. How to Purchase the Suitable Titanium anode for treating sodium bromide wastewater?
7. FAQ
8. Our Factory

Products Introduction

What Is Titanium anode for treating sodium bromide wastewater?

A Titanium Anode for Treating Sodium Bromide Wastewater is an insoluble electrochemical electrode used in advanced wastewater treatment systems. It consists of a titanium substrate coated with ruthenium-iridium mixed metal oxides that offer excellent conductivity and corrosion resistance.

During electrolysis, the electrode promotes the formation of active oxidizing species that break down organic contaminants and improve wastewater quality. The system effectively reduces COD, removes color, and enhances overall treatment efficiency. Due to its durability and low maintenance requirements, the titanium anode has become a preferred solution for bromide-containing industrial wastewater treatment applications.

Main Technical Parameters

Parameter	Specification
Product Name	Titanium Anode for Treating Sodium Bromide Wastewater
Coating Type	RuO₂ + IrO₂
Substrate Material	ASTM B265 Gr1 / Gr2 Titanium
Coating Loading	6–20 g/m²
Current Density	500–3000 A/m²
Operating Voltage	1.0–1.8 V
Working Temperature	≤80°C
pH Range	0–14
Bromide Resistance	Excellent
Oxygen Evolution Potential	≤1.45 V
Service Life	3–8 Years
Coating Adhesion	Excellent

Specifications

Type	Standard Size	Thickness
Titanium Mesh Anode	100×100 mm – 1500×3000 mm	1–3 mm
Titanium Plate Anode	100×100 mm – 2000×4000 mm	2–10 mm
Titanium Rod Anode	Ø6–50 mm	Custom
Titanium Tube Anode	Ø10–100 mm	Custom
Titanium Ribbon Anode	6.35×0.635 mm	Custom
Titanium Wire Anode	Ø1–10 mm	Custom

Cerrent output of Standard

Electrode Type	Recommended Current Density	Maximum Current Output
Titanium Mesh Anode	500–1500 A/m²	3000 A/m²
Titanium Plate Anode	1000–2500 A/m²	5000 A/m²
Titanium Rod Anode	500–2000 A/m²	3500 A/m²
Titanium Tube Anode	800–2500 A/m²	4500 A/m²
Titanium Ribbon Anode	200–1000 A/m²	1500 A/m²

Applications of MMO Titanium Anode

Be used in a wide range of industries.

Water Treatment Industry

Electroplating Industry

Chlor-Alkali Industry

Marine Engineering

Hydrogen Energy Industry

Mining and Metal Recovery

How to Purchase the Suitable Titanium Anode

Determine bromide ion concentration.
Analyze wastewater composition.
Confirm COD and pollutant levels.
Select appropriate electrode geometry.
Choose suitable titanium grade.
Verify operating temperature range.
Calculate required current density.
Determine treatment capacity requirements.
Select coating loading level.
Consider desired service life.
Review reactor dimensions.
Verify power supply specifications.
Evaluate maintenance requirements.
Request technical drawings and reports.
Discuss customization options with supplier.

Partnering with an experienced manufacturer ensures the electrode is optimized for your specific wastewater treatment conditions. Customized designs can improve treatment efficiency, reduce energy consumption, and extend equipment lifespan while lowering long-term operating costs.

FAQ

Q1. What coating is used on the electrode?

Ru+Ir mixed metal oxide coating.

Q2. Is the electrode resistant to bromide-containing solutions?

Yes. It is specifically designed for highly corrosive bromide environments.

Q3. What is the typical service life?

Generally 3–8 years depending on operating conditions.

Q4. Can custom sizes be manufactured?

Yes. OEM and ODM customization services are available.

Q5. Is it suitable for continuous industrial operation?

Yes. It is designed for long-term industrial wastewater treatment systems.

Q6. Can it reduce COD and organic pollutants?

Yes. It effectively oxidizes and removes many organic contaminants.

Our Factory

TitaniumAnode for Electrodialysis | High Efficiency | Long Service Life | Eco-Friendly

Production site

State-of-the-art manufacturing for titanium anodes, precision coating and quality control.

Choseing titanium substrate	Substrate Cutting	Sandblasting	Pickling
Laser Cutting Configure Precious Metal	Coating	Sintering	Packaging

Workshop

Precision machining and coating workshop for titanium anodes.

Titanium anode coating workshop	Thermal decomposition sintering furnace workshop	Titanium mesh anode production area	Pickling/surface treatment process
Pickling/surface treatment process	Quality inspection workshop	Worker operation photos	Panoramic view of a clean production line

Quality inspection

Rigorous testing for coating adhesion, electrochemical performance, and durability.

Dimension Inspection	Coating Thickness Testing	Coating Adhesion Testing	Microstructure Analysis
Conductivity Testing	Corrosion Resistance Testing	Bond Strength Testing	Final Inspection & Packaging