Titanium sheet Surface: As-rolled, sandblasting, machined or polished. Free from contamination, oil, scratches and other defects. Applications: Medical, aerospace, military, petrochemical industry, metallurgy, electroplating, vacuuming metal usage, marine building industry etc. Minimum Order: Comply with customer's demand. (If the quantity is less than our MOQ, we may recommend you the similar dimension in stock. ) Packaging: Ply wooden cases or In accordance with customers requirement.
Titanium sheet Surface: As-rolled, sandblasting, machined or polished. Free from contamination, oil, scratches and other defects. Applications: Medical, aerospace, military, petrochemical industry, metallurgy, electroplating, vacuuming metal usage, marine building industry etc. Minimum Order: Comply with customer's demand. (If the quantity is less than our MOQ, we may recommend you the similar dimension in stock. ) Packaging: Ply wooden cases or In accordance with customers requirement.
Titanium Plates for Osteosynthesis: Precision, Quality, Innovation Titanium plates play a vital role in osteosynthesis, stabilizing fractures and facilitating bone healing. At HB ORTHO, we specialize in crafting premium titanium implants that meet the high standards of modern orthopedic surgery. Using advanced technology and superior materials, we deliver reliable, high-performance solutions for healthcare providers worldwide. Key Features of HB ORTHO Titanium Plates Premium Titanium Material Biocompatibility: Made from medical-grade titanium, our plates are safe for the human body, minimizing the risk of allergic reactions or implant rejection. Corrosion Resistance: Titaniumâ??s resistance to corrosion ensures long-lasting durability, even in challenging environments. Lightweight Strength: Combining exceptional strength with minimal weight, titanium reduces stress on bones while maintaining stability. Innovative Design Precision Engineering: Advanced machining techniques deliver plates with accurate fit and optimal stability. Versatile Options: Our product line includes locking plates, reconstruction plates, and specialized designs for cranial, spinal, and trauma surgeries. Low-Profile Designs: These minimize soft tissue irritation, enhancing patient comfort. Custom Solutions Patient-Specific Plates: Tailored to match unique anatomical needs, our customized plates provide personalized solutions for complex cases. Collaborative Design: Parameters such as length, shape, and hole placement can be adjusted based on surgical requirements. Why Choose HB ORTHO? ISO 13485 Certification Our production adheres to strict international quality standards, ensuring the reliability and safety of every implant. Affordable Excellence We offer competitively priced solutions, enabling healthcare providers to deliver outstanding care without exceeding budgets. Benefits of HB ORTHO Titanium Plates Enhanced Healing and Stability Titanium integrates naturally with bone, accelerating recovery. Precision-engineered plates reduce micro-movements, lowering complication risks. Improved Surgeon Experience Pre-contoured plates streamline implantation, saving surgical time. Compatibility with various screws ensures versatility in procedures. Better Patient Outcomes Durable designs minimize implant failure risks. Low-profile plates provide greater comfort post-surgery. Comprehensive Support From initial consultation to delivery, we provide expert guidance to ensure seamless integration of our products into medical practices. Sustainability Titanium is both biocompatible and environmentally sustainable, supporting eco-friendly healthcare.
clad wear plate are composite steel plates that consist of two or more layers of different metals bonded together to enhance their properties. The bonding process is either roll-bonding or explosion-bonding. The resulting material has exceptional strength, corrosion resistance, and wear resistance characteristics compared to individual metals. Clad plates are widely used in various industries due to their unique properties, including Oil and Gas, chemical, and nuclear sectors, aerospace, marine engineering, and others. Processing clad plates is an advanced method that allows for tailor-made solutions to various industrial needs, increasing equipment performance and longevity. Advantages Of Using Clad Plate Corrosion resistance: Clad plates offer superior resistance to corrosion, allowing for prolonged equipment life and more efficient operations. Strength: The bonding process used in making clad plates leads to superior strength compared to other materials, making them ideal for use in heavy-duty applications. Customizability: Clad plates can be customized to suit various industrial applications, making them a versatile solution for industrial needs. Reduced costs: The excellent strength-to-weight ratio of clad plates is cost-effective compared to other high-strength materials.
Platinized Titanium Anode Platinized titanium anode consist of titanium anodes coated with platinum or platinum metal oxide. These anodes act as inert and non-consumable electrodes, making them very durable. In addition, they remain insoluble in the electrolyte even under the conditions present in the electrolysis process. Platinum Plated Titanium Anode Platinum plated titanium anode consist of titanium anodes coated with platinum or platinum metal oxide. These Platinum plated titanium anode act as inert and non-consumable electrodes, making them very durable. In addition, they remain insoluble in the electrolyte even under the conditions present in the electrolysis process. Platinum is an ideal anode material due to its excellent electrical conductivity and low consumption rate. However, in view of its status as a precious metal, a cost-effective method of electroplating a thin layer of platinum on a highly corrosion-resistant substrate is usually employed. Titanium, known for its ability to form insulating oxide films under anodic conditions, is a commonly used anode substrate.
MMO Coated Titanium Anodes Mixed metal oxide coatings on titanium substrates are widely used as anodes in various electrochemical processes, such as chlorination, oxygen production, electrolytic deposition of metals and cathodic protection in the chlor-alkali industry. The application of materials with high conductivity and long-term stability in electrochemical environments is considered to be one of the main goals of electrochemical cell engineering. Metal oxides such as RuO2 and IrO2, which have high electrical conductivity and electrochemical activity, have received much attention as electrocatalysts in the electrochemical industry. In order to further improve the stability of these oxides, other oxides such as TiO2, Ta2O5 and ZrO2 have been added to these active oxides. Anodic chloride and oxygen precipitation are the most important reactions in the application of these materials. Oxygen precipitation is the most important reaction in electrochemical processes such as water electrolysis, electrolytic deposition of metals and cathodic protection. In addition, this reaction is unavoidable in many anodic processes. RuO2-based coatings (e.g. pure RuO2 and RuO2-TiO2) are very stable to the chloride precipitation reaction. However, they are unstable to anodic oxygen precipitation and are subject to severe corrosion in acidic media. IrO2 is more stable for the oxygen precipitation reaction, but its oxygen precipitation electrocatalytic activity is lower. Therefore, due to the favourable properties of the two oxides, a mixture of IrO2 and RuO2 could be a suitable electrocatalyst for the oxygen revolution. Mixing two or more different oxides can affect the electrocatalytic performance of the oxides by changing the microstructure, surface composition and morphology of the electrocatalyst components. In addition, the surface composition, morphology and microstructure of mixed oxide coatings are not homogeneous and may be affected by preparation factors and active oxide content. Ruthenium mixed oxide coated titanium anodes are generally used in environments such as hydrochloric acid, electrolytic seawater and electrolytic brine environments. Fields of application Electrolytic production of non-ferrous metals, electrolysis of chlorinated salts, electrolysis of salt/seawater, metal foil manufacturing, electrochemical treatment of metal foil surfaces, disinfection, electrolytic extraction and recovery of non-ferrous metals, organic electrolysis, cathodic protection, electrodialysis, production of acidic and alkaline ionised water, treatment of industrial wastewater.
Grades: Grade2,Grade3,Grade4,Grade5,Grade6,Grade11,Grade12,B-1,TB5,Ti-6.5Al-1Mo-1V-2Zr(-0.15Si),Ti-70,Ti-75,customized Specifications Range(mm): Thickness x Width x Length 4.0~101.6x400-1600 6000 >0.6~
Material: Ta0 Ta1 Ta2 Ta7 Ta9 etc. Thickness: 0.25mm, 0.3mm, 0.4mm, 0.6mm, 0.8mm, 1.0mm etc. Porosity: 50-60%,55%, 65%, 60-70%, 75% 70-80% Size: 100x100mm, 200x200mm, 300x300mm, 400x400mm, 500x500mm, 600x600mm etc. Applicationï¼? The field of hydrogen production by electrolysis of water; PEM electrolyzer diffusion layer; Hydrogen fuel; Hydrogen suction machine, hydrogen-rich water dispenser, hydrogen-rich cup;
Titanium Titanium is a common material used in a wide variety of products such as watches, drills, laptops and bicycles. Pure titanium is silvery-white in color and has a brilliant luster. It has a melting point of 1,660�°C, a density of 4.5 g/cc and a vapor pressure of 10 -4 Torr at 1,453�°C. Titanium is a strong material that is easy to work with when heated. Its strong, lightweight properties and excellent corrosion resistance make it ideal for ocean liner hulls, aircraft engines and designer jewelry. Titanium is biocompatible and can be used in surgical instruments and implants. Titanium is typically evaporated in a vacuum for wear and decorative, semiconductor and optical coatings. Titanium Sputtering Targets Titanium sputtering targets are a versatile material with 20 variants. They are commonly used as sputtering targets in thin film deposition processes. Titanium's high strength, light weight, corrosion resistance and biocompatibility allow it to be used for surface coatings in applications ranging from semiconductors to medical implants. Improve wear resistance, reduce friction coefficient and prevent adhesion. It is a kind of coating on CNC tools. The single-layer titanium nitride coating is golden yellow, Vickers hardness is about 2300hv, and the maximum service temperature is 500 â??. It is a kind of high cost-effective coating widely used in CNC tools. It can also form composite coating with other elements such as aluminum and carbon, such as AlTiN
Titanium Plate and Titanium Sheet We offer titanium plate, titanium sheet, titanium alloy plate, titanium alloy sheet, custom titanium plate and custom titanium sheet. TITANIUM PLATE /SHEET .01" to 3" x up to 110" Wide x to 275" Long [Wider Widths, Custom and Special Shapes (Circles, Rectangles, Squares and Others) available on request.] Plate/Sheet can be Sheared, Saw Cut or Water-Jet Cut to Standard sizes or any Custom size (dependent upon Customer preference and size considerations) 1) Type: hot and cold rolled 2) Grades: most alloys and unalloyed CP grades, Gr1, Gr2, Gr3, Gr5, Gr9 3) Thickness: 0.3 - 60mm 4) Width:
Platinized titanium felt is a specialist material frequently utilized as a flow field or diffuser material in electrolyzer stacks and single cells, particularly on the oxygen (anode) side. This material is made by depositing a thin layer of platinum onto flattened titanium fibers that have been compressed and annealed to create a smooth, flat surface suitable for use in electrolyzers. Platinum coating thickness: 0.5 micron or customized Substrate: titanium fiber felt Felt thickness: 0.2-5.0mm Porosity: 60%-80% Fiber diameter: 10~100 microns Features High electrocatalytic activity: Platinum is known for its high electrocatalytic activity, particularly for the oxygen reduction reaction. When deposited on a titanium felt substrate, platinum forms a highly porous material with a large surface area, providing ample space for electrochemical reactions to occur. High durability: Platinized titanium felt is highly resistant to corrosion and can withstand harsh operating conditions, making it ideal for use in a variety of industrial and scientific applications. Applications Platinized titanium felt is used as an anode material in the production of chlorine and caustic soda in the The platinum coating on the titanium substrate prevents the formation of a passivating oxide layer on the anode surface, ensuring high electrochemical performance and durability. Electrowinning: Platinized titanium felt is used as an electrode material in the electrowinning of metals such as copper, zinc, and lead. The platinum coating on the titanium substrate provides excellent electrical conductivity and corrosion resistance, making it an ideal electrode material. Electrosynthesis: Platinized titanium felt is used as a catalyst support in electrosynthesis reactions, such as the production of organic compounds and fine chemicals. The platinum coating on the titanium substrate enhances the catalytic activity of the supported catalyst, leading to higher yields and selectivity. Electrolytic capacitors: Platinized titanium felt is used as an electrode material in high-performance electrolytic capacitors. The platinum coating on the titanium substrate provides excellent electrical conductivity and corrosion resistance, ensuring high performance and long-term reliability. Water treatment: Platinized titanium felt is used as an electrode material in electrochemical water treatment systems, such as electrocoagulation and electrooxidation. The platinum coating on the titanium substrate enhances the electrochemical performance of the electrode, leading to effective water treatment and disinfection.
Customized titanium fiber felt for fuel cell is a high-performance material made through a process of sintering titanium fibers. The result is a porous and lightweight material that is exceptionally strong and corrosion-resistant. The material is commonly used in industries such as aerospace, chemical processing, and medical equipment manufacturing. Parameters Material: Ti Porousity: 50%-80% Size: 1000 2000mm Thickness: 0.2mm-1.0mm(0.2mm 0.4mm 0.8mm 1.0mm) Filtration rate: 10um 20um 30um and so on Features: Sintered titanium fiber felt is a unique material that possesses several features that make it ideal for various industrial applications. Firstly, the material has a high strength-to-weight ratio, making it an attractive choice for applications where weight is a critical factor. Additionally, sintered titanium fiber felt is highly resistant to corrosion, even in harsh environments, making it an excellent choice for chemical processing applications. The material is also highly durable and can withstand high temperatures, making it a suitable choice for aerospace applications. Application Sintered titanium felt has a wide range of applications in the field of proton exchange membrane and gas diffusion layer (GDL). Here are some of the applications of sintered titanium felt in these fields: fuel cells: Sintered titanium felt is used as a gas diffusion layer in fuel cells. It is an excellent material for this application because it is highly porous and has good electrical conductivity. The high porosity of the sintered titanium felt allows for uniform gas distribution and efficient mass transport, which is critical for the performance of fuel cells. Electrolyzers: Sintered titanium felt is also used as an electrode substrate in water electrolysis systems. The high surface area of the sintered titanium felt provides a large active surface for the electrode reactions to occur, which enhances the efficiency of the electrolysis process. Gas purification: Sintered titanium felt is used as a gas purification medium in gas separation and purification systems. Its high porosity and good thermal conductivity make it an ideal material for this application because it can effectively remove impurities from gases and maintain a stable temperature during the purification process. Catalysis: Sintered titanium felt is also used as a catalytic support material in various chemical and industrial processes. Its high surface area and porosity make it an excellent substrate for supporting catalysts, which can enhance the efficiency and selectivity of chemical reactions.
Product Introduction Sintered titanium plate is a kind of titanium product, which is widely used in various industries such as chemical industry, medical treatment and food processing due to its excellent corrosion resistance and high strength. The porous titanium plate produced using the sintering process is to press the titanium powder into the desired shape and then sinter at high temperature. Titanium powder particles link together during sintering to form a solid structure with interconnecting pores of specified size and shape. The sintered titanium plates produced have a high strength-to-weight ratio and are resistant to high temperatures and harsh chemical conditions. Sintered titanium plates can be tailored to suit customer needs, such as pore size, pore dispersion, and thickness. To meet a wide range of applications, we can also manufacture porous titanium plates with complex geometries such as cylindrical, conical, and flat shapes. To ensure product quality, we conduct strict tests on porous titanium plates, including pore size distribution analysis, compressive strength test and corrosion resistance test. Product parameters Filtration grade: 0.2-100um Thickness: above 1mm Shape: square, round, shaped Size: 300 800mm can be customized Pressure: 0.2Mpa Features 1. High strength and toughness: During the sintering process, the titanium powder particles are closely combined with each other, so that the sintered titanium plate has high strength and toughness, and can withstand certain impact and pressure. 2. Excellent corrosion resistance: Titanium itself has good corrosion resistance, and a uniform microporous structure can be formed through sintering, which further improves the corrosion resistance of titanium plates. 3. Can be made into complex shapes: through the sintering process, titanium sheets of various complex shapes and pore diameters can be made to meet the needs of different industries and applications. 4. Adjustable pore size and porosity: By adjusting the sintering process parameters, the pore size and porosity of the titanium sheet can be controlled to obtain the performance required for different applications such as filtration, separation, and adsorption. How to purchase porous sintered titanium plate A. Materials to be delivered; B. Corrosion problems; C. Special operating conditions involving pressure, temperature, etc.; D. Pollutants encountered; E. Required shape, dimensions and tolerances; F. Required flow and pressure allowed by the filter unit.
Dia 40mm titanium fiber felt is made by a special laying process and a special ultra-high temperature vacuum sintering process. Compared with titanium powder sintered plate, Ti fiber felt has an excellent three-dimensional network, porous structure, high porosity, large surface area, uniform pore size distribution, special pressure, and corrosion resistance, and can be rolled and processed. Titanium fiber felts are widely used in military, aerospace, civil, medical care, and other industries abroad. Titanium fiber felts are primarily used in electrolyzer stacks as the flow field or diffuser material, particularly on the oxygen (anode) side. Features: has an excellent three-dimensional network porous structure; high porosity, several times larger surface area; uniform pore size distribution, strong corrosion resistance, good water permeability; high porosity, and heat dissipation; good performance, high current density, low voltage, stable performance, long life, and so on. Parameters Color: Light grey Dimension: Customized as request Thickness:0.2mm-2mm Often made thickness (0.25,0.4,0.6,0.8mm) Porosity:30-50%
Product Introduction Pure Titanium Electrode Porous Fiber Felts, also known as ti felts or ti fiber felts, are commonly used in electrolyzer stacks as the diffusion layer or flow field material on the oxygen (anode) side. Unlike carbon-based gas diffusion layers that cannot be used at the oxygen evolution electrode due to immediate oxidation, titanium fiber felt is an ideal diffusion medium that provides electrical contact between the anode catalyst layer and bipolar plate or current collector component. Its unique properties, including high porosity and uniform pore size distribution, enable efficient gas transport and water management within the cell, enhancing the overall efficiency of the electrolysis process. Overall, the use of titanium fiber felt in electrolyzer stacks improves their durability, reliability, and efficiency in hydrogen production. Parameter Material: pure titanium fiber Max Size: 1000x1000mm Other Size: 200x200mm, 205x205mm, 300x300mm, 305x305mm or customized Porosity: 60%-80% Thickness: 0.25-2mm Features 1. Uniform pore size distribution: Titanium fiber felt´s consistent pore size distribution ensures efficient filtration and separation processes, providing reliable filtration performance. 2. Strong corrosion resistance: Titanium fiber felt´s exceptional corrosion resistance makes it suitable for harsh environments and ensures reliable performance in applications requiring durability and longevity. 3. Good water permeability: Titanium fiber felt´s good water permeability makes it useful for water filtration and wastewater treatment applications, providing clean and safe water for various applications. 4. High porosity: Titanium fiber felt´s high porosity enables high gas and liquid flow rates, allowing for efficient heat transfer and suitable for thermal management applications. 5. Good heat dissipation: Titanium fiber felts excellent heat dissipation properties make it ideal for high-temperature environments, ensuring stable performance and long-term durability.
Sintered Titanium Frit well suited for use in Electrolyzers. These frits have a smooth, porous surface (80 micron filter rating) that gives good support for membranes. A much finer surface than our Expanded Titanium Mesh, this product is recommended to be placed against the membrane when designing higher pressure electrolyzers ( 20 psi). Custom sizes are available upon request. Titanium Foam Frit Specifications: Raw Material: Titanium Filter Rating: 80 Micron Thickness: 1.5 mm Working Temperature: 300 C Membrane Filtration Corrosion resistance Why not use a Carbon based Gas Diffusion Layer in an Electrolyzer Carbon based GDL materials will be consumed and converted into CO2 gas in the presence of the Oxygen ions and Voltage found on the Anode (Oxygen) side of the electrolyzer. This secondary reaction of oxidizing the Carbon in the GDL will give temporarily lower electrolysis voltage, but this is a short lived phenomenon. The carbon GDL is quickly consumed, resulting in poor compression in the stack, and thus high resistance and lower performance. You can still used carbon cloth or carbon paper material on the Hydrogen side (cathode) since there is oxygen on that side that will oxidize the GDL material.
Pure titanium processing parts have high titanium content, good plasticity, easy processing and forming, and good stamping and welding performance. It is resistant to corrosion in the atmosphere, ocean, and other conditions. Pure titanium processing parts are mainly used in aircraft skeletons, ship pipes, valves, pumps, heat exchangers, distillation towers, coolers, ion pumps, and compressor valves. In the industry, Ta1 is generally required for high formability, Ta3 is used for wear resistance and high strength, and Ta2 is the most widely used in general. Product parameters Product Name: Titanium Processing Parts Material grade: TA1 TA2 TC4 TA9 TA10 TA15 TC11 Executive standard: GB/T, GJB, AWS, ASTM, AMS, JIS Process state: Annealed state (M) hot working state (R) cold working state (Y) (annealing, ultrasonic flaw detection) Surface treatment: Sandblasting surface bright surface Product use: Aerospace equipment, petrochemical, shipbuilding, automobiles, watch accessories, etc. Features High-quality material selection Professional processing Fine workmanship Special customization The characteristics of titanium 1. It has a low density, a high strength, and a high specific strength. Titanium has a density of 4.51g/cm3, which is 57% that of steel, less than twice that of aluminum, and three times stronger. Titanium alloy has the highest specific strength of any regularly used industrial alloy. Titanium alloy has a specific strength that is 3.5 times that of stainless steel, 1.3 times that of aluminum alloy, and 1.7 times that of magnesium alloy. As a result, it is a necessary structural material in the aerospace sector. 2. Excellent corrosion resistance Titanium's passivity is dependent on the presence of an oxide film; its corrosion resistance in oxidizing media is far superior to that in reducing medium, and fast rate corrosion can occur in reducing medium. Titanium is not rusted in some corrosive environments. 3. Excellent heat resistance Aluminum typically loses its initial high mechanical qualities at 150 C, stainless steel at 310 C, and titanium alloys retain good mechanical properties at around 500 C. When the airplane achieves 2.7 times the speed of sound, the surface temperature of the aircraft mechanism hits 230 C, and the aluminum alloy and magnesium alloy can no longer be used, while the titanium alloy can. Titanium has a high heat resistance, making it ideal for turbine disks, aeroengine compressor blades, and aircraft rear fuselage skins.
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