Porous titanium sheets are versatile materials used as gas diffusion layers (GDLs) in various industries. With their unique properties, these sheets enable efficient gas transfer, making them crucial components in fuel cells, electrolyzers, and other electrochemical applications. Porous titanium sheets are typically produced through a process called powder metallurgy. It involves compacting titanium powder into a desired shape and sintering it at high temperatures. The sintering process creates interconnected pores, resulting in the desired porosity. Specifications: Filtration precision: 0.2umâ??100microns Porosity: 30%â??45% Temperature resistance: 300 â??(wet) Thicknessï¼?0.5mm-50mm Width: Max. 1500mm Length: Max. 6000mm Feature Efficient Gas Distribution: The interconnected pore structure of porous titanium sheets allows for uniform gas distribution across the surface area, ensuring efficient gas diffusion and transport. Enhanced Catalyst Utilization: The high surface area of porous titanium sheets allows for the deposition of catalyst materials, promoting efficient electrochemical reactions and maximizing catalyst utilization. Low-Pressure Drop: The design of porous titanium sheets ensures minimal pressure drop across the gas diffusion layer, optimizing overall system performance. Surface Area: Porous titanium sheets offer a high surface area, enhancing the gas diffusion process and providing better electrochemical performance. Electrical Conductivity: These sheets exhibit good electrical conductivity, ensuring efficient current distribution within the electrochemical systems. Water Management: Porous titanium sheets assist in managing water within the gas diffusion layer, preventing flooding and aiding in effective electrochemical reactions. Application: Fuel Cells: Porous titanium sheets serve as essential components in proton exchange membrane fuel cells (PEMFC) and solid oxide fuel cells (SOFC). They enable effective gas distribution, and water management, and provide electrical conductivity. Electrolyzers: Porous titanium sheets are used in electrolyzers for hydrogen production. They facilitate efficient gas diffusion and enable water management, resulting in improved electrolysis performance. Batteries: Porous titanium sheets find application in various types of batteries, including lithium-air batteries and redox flow batteries. They enhance gas diffusion, and electrolyte distribution, and provide structural support for the electrode materials. Chemical and Petrochemical Industry: Porous titanium sheets play a vital role in catalytic reactors, gas separation units, and other chemical processes. They provide a high surface area for catalyst deposition and facilitate efficient gas transport.
Porous titanium sheets are versatile materials used as gas diffusion layers (GDLs) in various industries. With their unique properties, these sheets enable efficient gas transfer, making them crucial components in fuel cells, electrolyzers, and other electrochemical applications. Specifications: Filtration precision: 0.2umâ??100microns Porosity: 30%â??45% Temperature resistance: 300 â??(wet) Thicknessï¼?0.5mm-50mm Width: Max. 1500mm Length: Max. 6000mm Feature Efficient Gas Distribution: The interconnected pore structure of porous titanium sheets allows for uniform gas distribution across the surface area, ensuring efficient gas diffusion and transport. Enhanced Catalyst Utilization: The high surface area of porous titanium sheets allows for the deposition of catalyst materials, promoting efficient electrochemical reactions and maximizing catalyst utilization. Low-Pressure Drop: The design of porous titanium sheets ensures minimal pressure drop across the gas diffusion layer, optimizing overall system performance. Surface Area: Porous titanium sheets offer a high surface area, enhancing the gas diffusion process and providing better electrochemical performance. Electrical Conductivity: These sheets exhibit good electrical conductivity, ensuring efficient current distribution within the electrochemical systems. Water Management: Porous titanium sheets assist in managing water within the gas diffusion layer, preventing flooding and aiding in effective electrochemical reactions. Application: Fuel Cells: Porous titanium sheets serve as essential components in proton exchange membrane fuel cells (PEMFC) and solid oxide fuel cells (SOFC). They enable effective gas distribution, and water management, and provide electrical conductivity. Electrolyzers: Porous titanium sheets are used in electrolyzers for hydrogen production. They facilitate efficient gas diffusion and enable water management, resulting in improved electrolysis performance. Batteries: Porous titanium sheets find application in various types of batteries, including lithium-air batteries and redox flow batteries. They enhance gas diffusion, and electrolyte distribution, and provide structural support for the electrode materials. Chemical and Petrochemical Industry: Porous titanium sheets play a vital role in catalytic reactors, gas separation units, and other chemical processes. They provide a high surface area for catalyst deposition and facilitate efficient gas transport.
Titanium plates with flow fields are essential components used in electrolyzers for various industrial applications. These plates, made from corrosion-resistant titanium materials, are designed with intricate flow field patterns to optimize the electrochemical process of water electrolysis. Electrolyzers equipped with titanium plates and flow fields play a crucial role in industries such as hydrogen production, water treatment, and chemical processing. Specifications: Material: Titanium (Grade 2 or Grade 5) Plate Thickness: 0.5-30 mm Flow Field Pattern: Serpentine, Interdigitated, or Customizable Dimensions: 90*90mm Customizable Features Enhanced Mass Transfer: The flow field pattern on titanium plates promotes efficient mass transfer of gases and electrolytes, ensuring uniform distribution and maximizing the electrochemical reaction efficiency. Improved Current Distribution: The optimized flow field design helps achieve uniform current distribution across the electrode surface, minimizing localized effects and improving electrolyzer performance. Extended Lifespan: Titanium's corrosion resistance and durability contribute to the longevity of electrolyzers, reducing maintenance costs and downtime. Customizable Designs: Titanium plates with flow fields can be customized to meet specific electrolyzer requirements, allowing for optimized gas and electrolyte flow patterns tailored to the application. Applications Hydrogen Generation: Electrolyzers equipped with titanium plates and flow fields are extensively used in industries involved in hydrogen production, enabling the production of clean and sustainable hydrogen gas for fuel cell applications, energy storage, and industrial processes. Chlor-Alkali Industry: Titanium plates find applications in the chlor-alkali industry, where electrolysis is employed to produce chlorine, caustic soda (sodium hydroxide), and hydrogen. The plates' resistance to highly corrosive electrolytes and durability make them suitable for this demanding application. Desalination: Titanium plates with flow fields are utilized in electrochemical desalination processes, where they play a vital role in the removal of salt and other impurities from seawater, making it suitable for drinking water or industrial use. Electrosynthesis: Titanium plates are used in electrosynthesis applications, where electrochemical reactions are employed to synthesize various chemicals and pharmaceutical intermediates. The flow field design on the plates helps facilitate efficient mass transfer and uniform current distribution, enabling controlled and precise electrochemical reactions.
Titanium plates with flow fields are essential components used in electrolyzers for various industrial applications. These plates, made from corrosion-resistant titanium materials, are designed with intricate flow field patterns to optimize the electrochemical process of water electrolysis. Electrolyzers equipped with titanium plates and flow fields play a crucial role in industries such as hydrogen production, water treatment, and chemical processing. Electrolysis is a process that involves the decomposition of water into hydrogen and oxygen gases through the application of an electric current. Titanium plates with flow fields are specifically designed to enhance the efficiency and performance of this electrochemical reaction. The flow field pattern on the titanium plate ensures a uniform distribution of gases and electrolytes, maximizing mass transfer and minimizing concentration gradients. This results in improved electrolysis efficiency, higher production rates, and enhanced product quality. The flow field pattern on the titanium plates can vary depending on the specific electrolyzer design and application requirements. Common flow field patterns include serpentine, interdigitated, or customizable designs tailored to optimize mass transfer and current distribution. The flow fields induce controlled turbulence, reduce diffusion path length, and prevent the accumulation of gas bubbles, further enhancing the overall efficiency of the electrolysis process. Specifications: Material: Titanium (Grade 2 or Grade 5) Plate Thickness: 0.5-30 mm Flow Field Pattern: Serpentine, Interdigitated, or Customizable Dimensions: 90*90mm Customizable Features Enhanced Mass Transfer: The flow field pattern on titanium plates promotes efficient mass transfer of gases and electrolytes, ensuring uniform distribution and maximizing the electrochemical reaction efficiency. Improved Current Distribution: The optimized flow field design helps achieve uniform current distribution across the electrode surface, minimizing localized effects and improving electrolyzer performance. Extended Lifespan: Titanium's corrosion resistance and durability contribute to the longevity of electrolyzers, reducing maintenance costs and downtime. Customizable Designs: Titanium plates with flow fields can be customized to meet specific electrolyzer requirements, allowing for optimized gas and electrolyte flow patterns tailored to the application.
A 10 micron ultra-long microporous metal titanium plate is a material made from sintered titanium powder, possessing high gas diffusion and electrical conductivity. The manufacturing process involves blending titanium powder, shaping it, and then subjecting it to high-temperature sintering to form a sturdy titanium plate with a specific porous structure. Parameters Filtration precision: 10um (0.5 um, 1 um, 3 um, 5 um, 10 um, 20 um, 30 um, 50 um) Porosity: 30%â??40% Pressure: � 0.2Mpa/cm2 Temperature resistance: 300 â??(wet) Maximum Operating pressure: 0.2Mpa/cm2 Size: 200*1000*1.5mm Features 1.High gas diffusion performance: The porous sintered titanium plate features a uniform pore structure, enabling efficient gas diffusion. This characteristic makes it suitable as a gas diffusion layer in polymer electrolyte membrane fuel cells (PEMFC), facilitating the effective transport of fuel and oxygen. 2.Excellent high-temperature resistance: Due to titanium's high melting point and excellent corrosion resistance, the porous sintered titanium plate exhibits remarkable stability and durability in high-temperature and corrosive environments. This property makes it an ideal material for filters, capable of effectively removing impurities in harsh conditions. 3.Coating capability: The porous sintered titanium plate can be coated with precious metals such as platinum (Pt) through electrochemical methods, enhancing its catalytic performance at the anode. This feature presents potential for its application as an anode material in fuel cells, improving fuel cell performance and efficiency. Applications Polymer electrolyte membrane fuel cells (PEMFC) Filters for high-temperature and corrosive environments Anode material in fuel cells
Titanium pipes for exhaust and downpipe applications are highly sought after due to their excellent properties, including high strength, lightweight design, corrosion resistance, and heat endurance. Specifications: Material: Gr1 Purity: >99.6% Outer Diameter (OD): 8mm Wall Thickness: 1.2mm Leg Length: 400mm (Customizable) Bend Angle: 90�° Surface Finish: Polished Features Superior Strength and Durability: Titanium pipes exhibit a remarkable strength-to-weight ratio, making them incredibly strong and durable. This property allows them to withstand high-pressure conditions, extreme temperatures, and mechanical stresses associated with exhaust systems, ensuring long-lasting performance. Lightweight Design: Titanium is renowned for its exceptional lightweight nature, which contributes to reduced overall weight in vehicles and aircraft. The lighter weight of titanium pipes for exhaust and downpipe applications not only improves fuel efficiency but also enhances the handling and performance of vehicles. Corrosion Resistance: Titanium is highly resistant to corrosion, making it an ideal choice for exhaust and downpipe systems exposed to harsh environments, such as corrosive gases, high temperatures, and moisture. This corrosion resistance ensures the longevity and reliability of the pipes, even in challenging conditions. Improved Engine Performance: Titanium pipes offer excellent exhaust gas flow characteristics, reducing backpressure and improving engine performance. The enhanced flow efficiency contributes to increased horsepower, torque, and overall engine responsiveness, providing a thrilling driving experience. Aesthetic Appeal: In addition to their exceptional performance, titanium pipes often feature a polished or brushed surface finish, adding an aesthetic appeal to the exhaust and downpipe systems. The sleek and sophisticated appearance of titanium pipes enhances the overall visual appeal of vehicles and aircraft. Applications: Automotive Industry Downpipes Motorsports Performance Upgrades Aerospace Industry Jet Engines Energy Sector Power Generation Marine Industry Marine Exhaust Systems
Titanium micro porous flow channel plates are widely used materials made from titanium powder using sintering processes. They consist of numerous tiny pores that provide channels and distribution paths for fluid or gas transfer. Titanium porous flow plates find extensive applications in various industrial sectors such as chemical engineering, oil and gas industry, aerospace, and more. Parameters Material:pure titanium Brand:TOPTITECH Technical:sintering Size:60*60*1mm Chamfer:as drawing Pore size:30 microns Features Enhanced mass transfer and heat transfer Tailorable pore structure Thermal conductivity Versatile applications Applications Chemical Engineering: Used in chemical reactors, adsorption separation, catalyst carriers, etc., to provide uniform mass transfer and reaction effects. Oil and Gas Industry: Used in oil well production, gas separation, corrosion protection, etc., to meet complex process requirements and environmental conditions. Aerospace: Used in aerospace engines, fuel cells, spacecraft thermal control, etc., to provide efficient fluid and thermal management. Biomedical: Used in artificial organs, tissue engineering, drug delivery, etc., to achieve precise substance transport and biological reactions. Renewable Energy: Titanium porous flow plates can be used in fuel cells, solar cells, etc., to provide efficient gas and electron transfer.
Porous titanium sheets are highly desirable for use as the porous transport layer (PTL) in polymer electrolyte membrane (PEM) water electrolyzers. However, the passivation of titanium leads to an increase in surface contact resistance, thereby negatively affecting the performance of the electrolyzer. To address this issue and ensure long-term operation, a common approach is to apply platinum or gold coatings on titanium-based PTLs. The platinum-coated porous titanium electrode sheets are highly effective electrode materials in acidic environments. These products find applications in organic electrolysis, such as cysteine, Cr3+, Cr6+, CN, and toxic substance electrolysis. They can also serve as auxiliary electrodes in the electroplating industry, including as auxiliary anodes for chromium, electrolytic copper, and electrolytic zinc, as well as in electrolytic cobalt and nickel processes. Parameters Material: Sintered Porous Titanium Sheet Coating: Platinum (Pt) Thickness of platinum: 1 microns Porosity: Customizable, commonly between 30% and 40% Pore Size: 10 microns Size: 46*46* 2mm Features Enhanced Conductivity: The platinum coating on sintered porous titanium sheets provides excellent electrical conductivity, facilitating efficient electron transfer during electrochemical reactions. Durability and Corrosion Resistance: Titanium's inherent corrosion resistance, combined with the protective platinum coating, ensures prolonged electrode lifespan, even in aggressive chemical environments. High Surface Area: The porous structure of the titanium sheets offers a large surface area, enabling more active sites for electrochemical reactions and enhancing cell efficiency. Customizable Pore Size: The pore size of sintered porous titanium sheets can be tailored to specific applications, allowing for optimized mass transport and improved electrolyte flow.
Porous titanium sheets are highly desirable for use as the porous transport layer (PTL) in polymer electrolyte membrane (PEM) water electrolyzers. However, the passivation of titanium leads to an increase in surface contact resistance, thereby negatively affecting the performance of the electrolyzer. To address this issue and ensure long-term operation, a common approach is to apply platinum or gold coatings on titanium-based PTLs. Parameters Material: Sintered Porous Titanium Sheet Coating: Platinum (Pt) The thickness of platinum: 1 micron Porosity: Customizable, commonly between 30% and 40% Pore Size: 10 microns Size: 46*46* 2mm Features Enhanced Conductivity: The platinum coating on sintered porous titanium sheets provides excellent electrical conductivity, facilitating efficient electron transfer during electrochemical reactions. Durability and Corrosion Resistance: Titanium's inherent corrosion resistance, combined with the protective platinum coating, ensures prolonged electrode lifespan, even in aggressive chemical environments. High Surface Area: The porous structure of the titanium sheets offers a large surface area, enabling more active sites for electrochemical reactions and enhancing cell efficiency. Customizable Pore Size: The pore size of sintered porous titanium sheets can be tailored to specific applications, allowing for optimized mass transport and improved electrolyte flow. Applications Chlor-Alkali Industry Water Treatment Fuel Cells Electrosynthesis
In PEM fuel cells, 0.5microns sintered porous Ti plate for PEM is commonly used as electrode materials for anodes and cathodes. It has high electrical conductivity and good chemical stability, and is suitable for the occurrence of electrode reactions. 0.5microns sintered porous Ti plate acts as both anode and cathode electrodes in PEM fuel cells. It provides the supporting structure of the catalyst layer and provides a conductive path for the oxidation reaction of hydrogen and the reduction reaction of oxygen, thereby realizing the electrochemical reaction of fuel and oxygen and generating electricity. Parameters Material: pure titanium powder Technical: sintering and coating Size:as drawing Porosity:30-40% Pore size:0.5microns Advantages High electrical conductivity: The sintered porous titanium plate has good electrical conductivity and can effectively conduct electrons. This is crucial for the electrode reaction to proceed, ensuring smooth transport of electrons between the anode and cathode. High surface area: The porous structure of the sintered porous titanium plate provides a large amount of surface area, increasing the contact area with the catalyst reaction. This increases the reaction rate and enhances the efficiency of the electrochemical reaction between fuel and oxygen. Good chemical stability: Sintered porous titanium plate has good chemical stability and can resist corrosion under acidic environment and high temperature conditions. This makes it work stably for a long time in PEM fuel cells. Suitable for catalyst immobilization: The surface of sintered porous titanium plate can accommodate and immobilize catalysts, such as platinum or its alloys. This provides good catalytic activity and maintains catalyst stability and dispersibility. Strong adaptability: The sintered porous titanium plate can be customized in shape and size according to needs, so as to adapt to fuel cell stack designs of different sizes and forms. It can also be used in combination with other materials to achieve better electrode performance. There are several commonly used materials that can be used in combination with sintered porous titanium plates to enhance electrode performance, the following are some of these common combinations: Platinum Catalyst Carbon materials Oxide Conductive polymers Transition metal nitrides
Titanium bipolar electrolyser plate in electrolysis is a special electrode for electrolysis, usually made of pure titanium. In electrochemical processes, electrodes are usually divided into anodes and cathodes, each responsible for the flow of electrons and the flow of ions. A bipolar plate is an electrode that has both anodic and cathodic properties. In electrolysis, titanium bipolar electrolyser plates are usually used in the fields of electroplating, electrolytic preparation and water treatment. They can withstand high voltage and high current density, but also have good corrosion resistance, which allows them to be used in harsh environments such as strong acid, strong alkali, high temperature and high pressure. Parameters Material: Gr1 titanium Size: Customized according to the drawing Application: Fuel cell Features 1.Good electrical conductivity: Titanium bipolar plates have excellent electrical conductivity and can withstand high voltage and high current density, thus effectively promoting electrochemical reactions. 2.Good corrosion resistance: Titanium bipolar plates have good corrosion resistance and can be used in harsh environments such as strong acid, strong alkali, high temperature and high pressure, and are not easily corroded and worn. 3.Good mechanical properties: Titanium bipolar plates have high strength and rigidity, can withstand large forces and pressures, and are not easily deformed and broken. 4.Lightweight: Titanium bipolar plates have a lower density and are a lightweight material that can reduce the weight of the entire electrolytic cell and improve overall efficiency. Methods of coatings for Ti bipolar plates A number of methods are used to deposit coatings onto metallic bipolar plates. Processes include physical vapor deposition techniques such as electron beam evaporation, sputtering and glow discharge decomposition, chemical vapor deposition techniques, and liquid phase chemical techniques such as electroplating and electroless deposition, chemical anodizing/oxidation coatings and painting.
Titanium bipolar electrolyser plate in electrolysis is a special electrode for electrolysis, usually made of pure titanium. In electrochemical processes, electrodes are usually divided into anodes and cathodes, each responsible for the flow of electrons and the flow of ions. A bipolar plate is an electrode that has both anodic and cathodic properties. Parameters Material: Gr1 titanium Size: Customized according to the drawing Application: Fuel cell Features 1.Good electrical conductivity: Titanium bipolar plates have excellent electrical conductivity and can withstand high voltage and high current density, thus effectively promoting electrochemical reactions. 2.Good corrosion resistance: Titanium bipolar plates have good corrosion resistance and can be used in harsh environments such as strong acid, strong alkali, high temperature and high pressure, and are not easily corroded and worn. 3.Good mechanical properties: Titanium bipolar plates have high strength and rigidity, can withstand large forces and pressures, and are not easily deformed and broken. 4.Lightweight: Titanium bipolar plates have a lower density and are a lightweight material that can reduce the weight of the entire electrolytic cell and improve overall efficiency. Methods of coatings for Ti bipolar plates A number of methods are used to deposit coatings onto metallic bipolar plates. Processes include physical vapor deposition techniques such as electron beam evaporation, sputtering and glow discharge decomposition, chemical vapor deposition techniques, and liquid phase chemical techniques such as electroplating and electroless deposition, chemical anodizing/oxidation coatings and painting. Processing Titanium bipolar plates can be manufactured by CNC machining, hydraulic forming and stamping, and photochemical etching.
2mm GR1 Seamless Titanium Capillary Tube for Medical is a small, thin-walled tube made of titanium metal. It is mainly used in applications requiring high corrosion resistance, high strength and light weight. Parameter: Material: Pure titanium Grade: GR1 Outer diameter:2mm Wall thickness: 0.4mm Length: Max. 6000mm Surface treatment: polished Certificates: ISO9001:2015 Features 1.Capillary effect: Due to the very small diameter of the titanium capillary, the liquid will exhibit a capillary effect in it. This means that liquids can exhibit special flow behaviors in pipes, such as self-priming, condensation, and lifting. The capillary effect makes titanium capillaries very useful in specific applications, such as microfluidics, liquid chromatography and analytical chemistry. 2.Corrosion Resistance: Titanium is a metal with excellent corrosion resistance. Titanium capillaries are resistant to a variety of corrosive media, including acids, bases, salt water, and oxides. This makes titanium capillaries versatile for applications involving corrosive environments or chemicals. 3.Strength and Lightweight: Despite titanium's excellent strength, its relatively low density makes titanium capillary a lightweight tubing choice. This enables it to reduce overall weight in applications that require strength and rigidity, such as structures and equipment in the aerospace sector. 4.Biocompatibility: Titanium is a biocompatible material that is well tolerated by human tissues and organisms. This makes titanium capillaries widely used in medical devices and biomedical fields, such as artificial joints, implantable devices and biosensors. Applications 1.Orthopedic implants 2.Dental applications 3.Cardiac stents 4.Neural Implants 5.Medical devices and tools
Platinum-coated porous titanium plates are essential components used in electrolyzers for diverse industrial applications such as hydrogen production, water treatment, and energy storage. These plates play a critical role in facilitating efficient and reliable electrochemical reactions. Specifications: Material: porous Titanium plate Coating: Platinum (usually 0.2-5 microns thick) Porosity: 30%-40% Thickness: 0.6-20 mm Dimensions: Customizable based on specific electrolyzer requirements Surface Area: Varies based on design and application, usually 50-100 cm�² Why is platinum used as a coating material? Platinum is highly resistant to corrosion and possesses excellent catalytic properties, making it ideal for enhancing electrochemical reactions. It ensures long-term stability and efficiency of the electrode, resulting in improved performance and durability of the electrolyzer. What are the advantages of using porous titanium plates? The porous structure of titanium plates increases the available surface area for reactions, allowing for greater contact with the electrolyte. This enhances mass transfer and promotes efficient gas diffusion, leading to faster reaction rates and improved overall electrolyzer performance. Can the dimensions of the plates be customized? Yes, the dimensions of platinum-coated porous titanium plates can be tailored to suit specific electrolyzer designs and requirements. Customization allows for compatibility with different system sizes and configurations.
Platinum-coated porous titanium plates are essential components used in electrolyzers for diverse industrial applications such as hydrogen production, water treatment, and energy storage. These plates play a critical role in facilitating efficient and reliable electrochemical reactions. Specifications: Material: porous Titanium plate Coating: Platinum (usually 0.2-5 microns thick) Porosity: 30%-40% Thickness: 0.6-20 mm Dimensions: Customizable based on specific electrolyzer requirements Surface Area: Varies based on design and application, usually 50-100 cm�² Features: Catalytic Efficiency: The platinum coating on the porous titanium plates provides exceptional catalytic activity, enabling rapid and efficient electrochemical reactions. This results in improved performance and higher reaction rates, contributing to the overall efficiency of the electrolyzer. Corrosion Resistance: Titanium is inherently resistant to corrosion, and the platinum coating further enhances this property, ensuring the longevity and stability of the plates even in harsh operating conditions. This resistance to corrosion guarantees the durability and reliability of the electrolyzer system. Enhanced Mass Transfer: The controlled porosity of the titanium plates facilitates effective gas diffusion and reactant accessibility. This feature enhances mass transfer, allowing for faster reaction kinetics and improved overall electrolyzer performance. Customizable Dimensions: Platinum-coated porous titanium plates can be customized to meet specific electrolyzer design requirements. The dimensions can be tailored to fit different system sizes and configurations, ensuring compatibility and versatility in various applications. Application: Hydrogen Production Water Treatment Energy Storage
Product Introduction Ultra-thin 0.6mm titanium porous transfer layer for hydrogen has a wide range of applications in hydrogen industry. In the hydrogen industry, these plates are used for hydrogen purification and separation, and they are an important component in many hydrogen-based technologies. Ultra-thin 0.6mm titanium porous transfer layer for hydrogen has good electrical conductivity, gas permeability, liquid permeability and chemical stability. In electrochemical systems such as fuel cells, the application of porous titanium plates can improve the energy conversion efficiency and stability of electrochemical systems, thereby promoting the development and application of electrochemical systems. Parameters Material: Gr1 titanium powder Purity: 99.6% Thickness:0.6mm Size: customized Application: PTL GDL in PEM electrolyzer Porosity: 35% Pore size: 20um Features High conductivity: Titanium is a good conductive material, and the porous titanium plate has excellent conductivity and can effectively transport electrons. High gas permeability: The porous titanium plate can control the parameters such as pore size and porosity to make it have high gas permeability, so that it can effectively transmit gases such as hydrogen and oxygen. Good liquid permeability: The pore structure of the porous titanium plate can control the transmission of liquid, so that it has high liquid permeability. High chemical stability: Titanium has good chemical stability and can operate stably for a long time in acidic or alkaline environments. Applications Hydrogen energy industry Gas filtration Oil and liquid filters Muffler Fuel Industry Catalyst filtration Package and Shipment 1. Sintered Filters are usually packed in cartons, wrapped in soft film, and fixed in a box filled with industrial foam cotton, and the outer baler is packed with plastic bags with no damage during transportation. 2. Wooden box export packaging can also be customized. The foam cotton can be filled and fixed, the external box is sealed, the bottom is specified, the whole packaging is processed, and the goods can be delivered to the customer's designated place without damage.
Ultra-thin 0.6mm titanium porous transfer layer for hydrogen has a wide range of applications in hydrogen industry. In the hydrogen industry, these plates are used for hydrogen purification and separation, and they are an important component in many hydrogen-based technologies. Ultra-thin 0.6mm titanium porous transfer layer for hydrogen has good electrical conductivity, gas permeability, liquid permeability and chemical stability. In electrochemical systems such as fuel cells, the application of porous titanium plates can improve the energy conversion efficiency and stability of electrochemical systems, thereby promoting the development and application of electrochemical systems. Parameters Material: Gr1 titanium powder Purity: 99.6% Thickness:0.6mm Size: customized Application: PTL GDL in PEM electrolyzer Porosity: 35% Pore size: 20um Features High conductivity: Titanium is a good conductive material, and the porous titanium plate has excellent conductivity and can effectively transport electrons. High gas permeability: The porous titanium plate can control the parameters such as pore size and porosity to make it have high gas permeability, so that it can effectively transmit gases such as hydrogen and oxygen. Good liquid permeability: The pore structure of the porous titanium plate can control the transmission of liquid, so that it has high liquid permeability. High chemical stability: Titanium has good chemical stability and can operate stably for a long time in acidic or alkaline environments. Applications Hydrogen energy industry Gas filtration Oil and liquid filters Muffler Fuel Industry Catalyst filtration
Mixed-metal Coated Titanium Anodes for Trivalent Chromium Plating is a material used as an anode in an electrochemical reaction, and it is usually made of pure titanium or titanium alloy. During the electrochemical reaction, Mixed-metal Coated Titanium Anodes for Trivalent Chromium Plating absorb electrons and are oxidized, forming an oxide coating on its surface, commonly known as titanium anodic oxide (TAO). Titanium anodized layer has many useful properties, such as high hardness, excellent corrosion resistance, wear resistance, etc., which makes it widely used in many applications. Among them, the application of coated titanium anode is particularly prominent. Parameter Substrate material: titanium Grade 1, titanium Grade 2 Dimensions: customer drawing welcomed Shape: Plate/Tube/Rod/Mesh shape MMO coating: Ir-Ta coating Coating thickness: 0.2-12 m Temperature:
Mixed-metal Coated Titanium Anodes for Trivalent Chromium Plating is a material used as an anode in an electrochemical reaction, and it is usually made of pure titanium or a titanium alloy. During the electrochemical reaction, Mixed-metal Coated Titanium Anodes for Trivalent Chromium Plating absorbs electrons and is oxidized, forming an oxide coating on its surface, commonly known as titanium anodic oxide (TAO). Parameter Substrate material: titanium Grade 1, titanium Grade 2 Dimensions: customer drawing welcomed Shape: Plate/Tube/Rod/Mesh shape MMO coating: Ir-Ta coating Coating thickness: 0.2-12m Temperature:
With the rapid advancement of technology, particularly in aerospace and other related industries, the demand for titanium metal has significantly increased. However, this has also resulted in a substantial amount of titanium metal scrap. As a result, the recovery of titanium metal scrap has become crucial in conserving resources and reducing costs. Titanium scrap comes from various sources, such as during the production of sponge titanium. The upper skin, bottom, and sides of sponge titanium may be contaminated by impurities like iron, chlorine, oxygen, and nitrogen. These impurities make the titanium scrap unsuitable for manufacturing and must be recycled. Additionally, titanium ingot casting and processing titanium materials into titanium products also generate titanium scrap. To recycle titanium metal scrap, the following methods can be employed: High-quality uncontaminated titanium scrap can be utilized as an additive for smelting titanium ingots or mixed with sponge titanium to produce titanium blocks. Waste titanium sponges, heads, and scraps can be utilized as alloy additives in the ferrotitanium industry or raw materials for titanium powder, depending on their purity and composition. Waste titanium powder can be utilized as deflagration agents in the pyrotechnic sector, additives in the processing of aluminum, and raw materials for titanium products made using powder metallurgy. Titanium scrap with numerous impurities can be processed into high-titanium iron. What is the process for recycling titanium scrap? The process of recycling titanium scrap typically involves the following steps: Collection and sorting: Titanium scrap is collected from various sources, such as manufacturing facilities, aerospace companies, and medical facilities. The scrap is then sorted based on its composition and quality. Cleaning and preparation: The titanium scrap is cleaned and prepared for processing. This may involve removing any impurities, such as oil or dirt, and cutting the scrap into smaller pieces. Melting: The titanium scrap is melted in a furnace at high temperatures. This process helps to separate titanium from any other metals or materials that may be present. Refining: The melted titanium is refined to remove any remaining impurities and improve its quality. This may involve adding other materials, such as aluminum or vanadium, to improve the properties of the titanium. Forming: The refined titanium is then formed into various shapes and products, such as sheets, bars, or wire. These products can be used in a wide range of applications, including aerospace, medical, and automotive industries.
