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Seawater Desalination Heat Exchanger Titanium System Equipment Corrosion Resistant Heat Resistant
| Place of Origin: | China |
| Brand Name: | BaseTi |
| Certification: | ISO9001:2015 |
| Model Number: | THR-001 |
| Minimum Order Quantity: | NO MOQ LIMITATION. |
| Price: | CONTACT US |
| Packaging Details: | External: wooden box packaging; Inside: an inner packing with protective foam; |
| Delivery Time: | 60~90days |
| Payment Terms: | L/C, D/A, D/P, T/T, Western Union, MoneyGram |
| Supply Ability: | According to Drawings |
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Detail Information |
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| Place of Origin | China | Brand Name | BaseTi |
|---|---|---|---|
| Certification | ISO9001:2015 | Model Number | THR-001 |
| Grade: | Typically Made From Commercial Pure Titanium Grades Such As Grade 1, Grade 2, Or Grade 7, And Sometimes From Titanium Alloys Like Grade 5 (Ti-6Al-4V) For Enhanced Mechanical Properties. | Production Standards: | ASTM B338 (seamless And Welded Titanium Tubes For Heat Exchangers), ASTM B265 (titanium And Titanium Alloy Strip, Sheet, And Plate), ASME Boiler And Pressure Vessel Code Section VIII. |
| Tolerance: | Customized | Rolling Process: | Manufactured Using Advanced Rolling Techniques To Achieve Desired Shape And Properties. |
| Surface Process: | Surface Treatments Include Polishing, Pickling, Anodizing, And Other Coatings As Needed. | Size: | Thickness (0.01mm-0.5mm), Width (50mm-300mm) |
| Minimum Order Quantity: | 1 | Delivery Time: | 60-90 DAYS |
| High Light: | Seawater Desalination pool heat exchanger titanium,pool heat exchanger titanium Corrosion Resistant,heat exchanger titanium Heat Resistant |
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Product Description
Seawater Desalination Titanium Heat Exchanger System Equipment Customized Size Corrosion-Resistant Heat-Resistant
*If you have any requirements for customized industrial titanium heat exchanger, we would be delighted to further discuss the technical specifications with you and provide a quotation.
*Our production capacity is efficient, and our logistics channels are well-developed. We can deliver products via international express to any corner of the globe within 3 to 7 days.
| Titanium heat exchanger & parameters | |
| Product name | Industrial titanium heat exchanger |
| Application field | Petrochemical industry, Chemical processing, Power generation, Desalination plants, HVAC systems, Food and beverage industry. |
| Available size | based on client requirements. |
| Grade | Grade 1, Grade 2, or Grade 7, and sometimes from titanium alloys like Grade 5 (Ti-6Al-4V) |
| Production stadards | ASTM B338 (seamless and welded titanium tubes for heat exchangers), ASTM B265 (titanium and titanium alloy strip, sheet, and plate), ASME Boiler and Pressure Vessel Code Section VIII. |
| Tolerance | Customizable |
| Rolling process | Manufactured using advanced rolling techniques to achieve desired shape and properties. |
| Surface process | polishing or coatings |
| Delivery time | 10-15days |
| Key words |
Titanium Heat Exchanger Titanium Shell and Tube Heat Exchanger Titanium Plate Heat Exchanger Industrial Titanium Heat Exchanger Titanium Finned Tube Heat Exchanger Titanium Tube Bundle Heat Exchanger Corrosion-Resistant Heat Exchanger High Efficiency Titanium Heat Exchanger Titanium Cooling System Titanium Heat Transfer Equipment |
Application Field: Seawater Desalination
Seawater desalination is a critical process that addresses water scarcity by converting seawater into fresh water. Titanium heat exchangers play a pivotal role in this field due to their exceptional corrosion resistance, efficiency, and durability. As a key component in desalination plants, titanium heat exchangers enable the conversion of seawater into potable water through the process of thermal desalination.
Role and Advantages:
Corrosion Resistance: Seawater is highly corrosive and can cause rapid deterioration of conventional materials. Titanium's superior corrosion resistance ensures the longevity and reliability of heat exchangers in such aggressive environments.
Efficiency: Titanium's high thermal conductivity and heat transfer efficiency result in more efficient heat exchange, reducing energy consumption and operational costs.
Durability: The harsh conditions of seawater desalination require equipment that can withstand continuous exposure to corrosive elements. Titanium's durability and resistance to pitting and crevice corrosion ensure the long-term integrity of heat exchangers.
Solution: Titanium Heat Exchangers
Titanium heat exchangers, designed for seawater desalination, facilitate the heat transfer process essential for evaporation and condensation. They are integral components of multi-effect distillation (MED) and multi-stage flash (MSF) desalination technologies.
Titanium's non-reactive nature in the presence of seawater enables efficient heat transfer without compromising water quality. This ensures the production of clean, potable water free from contamination.
Comparison with Other Materials:
Unlike traditional materials like copper, brass, or stainless steel, titanium exhibits unmatched resistance to corrosion in aggressive saline environments. Other materials are prone to degradation and fouling, leading to increased maintenance and reduced efficiency.
Unique Advantage:
The unique advantage of titanium lies in its ability to maintain peak performance and integrity over an extended lifespan in seawater desalination applications. This longevity translates into reduced downtime, maintenance, and replacement costs, making titanium heat exchangers a cost-effective and sustainable choice.
In summary, BaseTi's titanium heat exchangers offer a cutting-edge solution to the challenges of seawater desalination. Their corrosion resistance, efficiency, and durability make them indispensable components in the production of clean, fresh water from seawater.
Seawater desalination is a critical process to address the growing global water scarcity issue. Titanium heat exchangers play a crucial role in this domain, enabling efficient heat transfer to facilitate the conversion of seawater to potable water. Designing effective titanium heat exchangers for seawater desalination requires careful consideration of several key factors and technical indicators.
1. Corrosion Resistance:
Seawater is highly corrosive due to its high salt content and aggressive nature. Titanium's exceptional corrosion resistance makes it an ideal material for heat exchangers in this application. To avoid corrosion-related failures, it's crucial to select titanium alloys with a high level of resistance to pitting and crevice corrosion.
2. Thermal Efficiency:
Efficient heat transfer is essential for successful desalination. Titanium's high thermal conductivity ensures effective heat exchange, promoting better energy efficiency and reducing operational costs. Designers must optimize the heat exchanger's geometry, surface area, and flow rates to achieve maximum thermal efficiency.
3. Fouling Prevention:
Seawater contains various organic and inorganic impurities that can lead to fouling, reducing heat transfer efficiency. Incorporating specialized designs such as enhanced surface textures and using high-velocity fluid flows can mitigate fouling, ensuring consistent performance.
4. Material Selection:
Choosing the appropriate titanium alloy is crucial. Commercially pure titanium (CP-Ti) and titanium alloys like Ti-6Al-4V are commonly used for their corrosion resistance and mechanical properties. Material selection should align with the heat exchanger's operating conditions and fluid chemistry.
5. Water Velocity and Turbulence:
Maintaining an adequate water velocity within the heat exchanger tubes is essential to prevent scale deposition and fouling. Turbulence promoters, such as baffles and turbulators, can enhance heat transfer by promoting fluid mixing and reducing the formation of stagnant zones.
6. Flow Distribution:
Uniform flow distribution across the heat exchanger's tubes is critical to ensure balanced heat transfer. Proper design of inlet and outlet headers, along with careful consideration of tube layout, helps achieve optimal flow distribution.
7. Maintenance and Accessibility:
Design considerations must also encompass maintenance access. Incorporating features such as removable tube bundles and access doors can simplify maintenance and reduce downtime.
8. Avoiding Galvanic Corrosion:
In the presence of dissimilar metals, galvanic corrosion can occur. Designers should prevent direct contact between titanium and other metals or use appropriate insulation techniques to minimize the risk.
9. Safety and Codes:
Adhering to industry codes and standards ensures the heat exchanger's safe operation. Compliance with standards such as ASME Boiler and Pressure Vessel Code is essential to meet regulatory requirements.
Designing titanium heat exchangers for seawater desalination demands a holistic approach that considers material selection, heat transfer efficiency, corrosion resistance, and maintenance requirements. By addressing these factors, designers can create robust and efficient heat exchangers that contribute to sustainable freshwater production from seawater sources.
al titanium forgings. Our commitment to excellence, coupled with our flexible approach, means that you receive top-notch products designed to elevate your projects. Contact us today to explore the possibilities.
