Steam Activated Carbon ir and water filters: Steam activated carbon's ability to trap contaminants in its many small openings makes it a popular choice for water and air filters. Deodorizer: Steam activated carbon can be used to remove unpleasant odors from refrigerators, closets, and shoes. Food and pharmaceutical processing: Steam activated carbon can be used to decolorize, refine, and purify sugars and alcohols. Chemical processing: Steam activated carbon can be used to purify and separate gases, recover solvents, and deodorize exhaust gases. Solvent recovery: Steam activated carbon can be used for solvent recovery. Methane and hydrogen storage: Steam activated carbon can be used to store methane and hydrogen. Decaffeination: Steam activated carbon can be used for decaffeination. Gold purification: Steam activated carbon can be used for gold purification. Metal extraction: Steam activated carbon can be used for metal extraction
- K01: Vinyl Acetate Synthesis Catalytic Support Activated Carbon - K02: Chlorothalonil Synthesis Catalyst Activated Carbon - K03: MSG Crystallization Granular Activated Carbon - K04: Alcohol Dedicated Activated Carbon - K05: Gold Extraction Granular Activated Carbon - K06: Water Purification Granular Activated Carbon - K07: Gasoline Deodorization Activated Carbon - K08: Solvent Recovery Activated Carbon
Carbon Fiber Braided Sleeve for Prosthetic The Braided Carbon Fiber Sleeve will perfectly conform to the shape of products with changing geometries, such as prosthetic limbs and field hockey sticks, to improve overall performance, minimize weight, and maximize the ultimate tensile strength of carbon. Braided Carbon Fiber Sleeve The Braided Carbon Fiber Sleeve will perfectly conform to the shape of products with changing geometries, such as prosthetic limbs and field hockey sticks, to improve overall performance, minimize weight, and maximize the ultimate tensile strength of carbon. FEATURES Twill weave for excellent compliance, strength and aesthetics 45° angle twill weave direction Easily wetted by resin Resistant to fatigue and durable
Silicon carbide is composed of carbon and silicon elements. It has many excellent properties, making it widely used in various fields. With outstanding high temperature resistance, it can withstand temperatures above 1600�°C. Silicon carbide can be used as a refining agent in the steelmaking process. It provides high-temperature reduction, helping to remove impurities and oxides from the steel, improving its quality and purity. Due to its unique properties, silicon carbide finds wide application in areas such as abrasive tools, high-temperature equipment, steelmaking, chemical industry, optical components, and solar energy. Additionally, silicon carbide is also used in the production of ceramic products, thermal barrier coatings, and catalysts.
Coal based activated carbon originates from coal that has undergone a steam activation process Coal based carbon has mainly mesopores and macropores and is very popular in gas phase purification portable water purification wastewater purification and aquariumpond water purification applications.
Coconut shell activated carbon is derived from coconut shells. It has a very high hardness and is more abrasion resistant than any other type.
Carbon fiber unidirectional fabric is a type of reinforcement material used in composite manufacturing. Unlike traditional woven fabrics, which consist of fibers running in two directions (warp and weft), unidirectional carbon fiber fabric has all its fibers aligned in a single direction. This alignment provides specific advantages in terms of strength, stiffness, and weight distribution.
Desicca Chemical's Carbon Chemically Activated Powder is a highly effective adsorbent with a wide range of applications. It is produced from high-quality raw materials and is activated using a proprietary process to create a product with a high surface area and pore volume. This makes it ideal for use in a variety of applications, including gas and liquid purification, air and water treatment, and food and beverage processing.
Carbon Black Ex Factory MUMBAI Price list Grade INR price per Kg USD price /82.5 FP330J / Beads/Granules 1180 FP330C / Beads type 1020 FP330C / Powder type 1010 P330 / Beads / Granules 867
good quantity 700 tons and good quality from jordan
Various models can be customized 1.Ferromanganese is an essential deoxidizer and desulfurizer in steelmaking industry. 2.Good need in smelting, steel deoxidation desulphurization processing, and ferromanganese is a cheap deoxidizer, 3.such as ferromanganese we can achieve the purpose of the desulfurization very well, effectively reduce the content of harmful elements in steel, improve the quality of steel.
Hard & Soft In Nature
Coconut Shell Activated Carbon
Coal Based Carbon - Granular
Coal Based Carbon - Powder
Wood Based Activated Carbon
Pallestised Activated Carbon
Activated carbon specifications: iodine 900-990mr/gr, ash content 0,26%, water content 1,39%, pH 9,72, Methylblue absorption 400-420/ mg/gr. from sumatera selatan (indonesia coco shell). Minimal order 5 ton, delivery timelines 1-2 month
Activated carbon (also known as active carbon or activated charcoal), is an artificial carbonaceous (carbon-rich) material. It is typically made from wood, but also can be made using bamboo, coconut husk, peat, woods, coir, lignite, coal, pitch, and other dense carbon sources. There are a variety of similar substances that fall under the general classification of activated carbon such as activated coal and activated coke, but they all share the properties of vast surface area per mass, exceptional microporosity, and a composition of almost exclusively elemental carbon. The pore structure of activated carbon can be seen with an electron microscope and is primarily responsible for its usefulness. Microscopes show a surface honeycombed with holes and crenelated with ridges which join to a similar structure deeper within the carbon. Due to this structure, a pound of activated carbon, for instance, can have as much as 100 acres of surface area packed into it. These small, low-volume pores allow for increased adsorption capacity (the process of chemical surface bonding, not to be confused with absorption) and allow more reactions between the carbon and other media. Activated carbon is therefore highly valued in filtering, deodorization, medical, and chemical applications, as most contaminants easily bind to it and remain trapped in the carbon microstructure via many small distance-dependent atomic attractions (known as London dispersion forces). Because carbon is produced through a relatively inexpensive and simple series of activation processes, it is widely available for applications; however, activated carbon must be constantly changed as it becomes clogged with contaminants, water, and becomes a breeding ground for dangerous microorganisms after a certain contact time. This means activated carbon is constantly produced to meet the demands of its uses and is kept in large supply to ensure no delay exists in the replacement process. How to Make Activated Carbon The production process of activated carbon, or the activation of carbon, exists in two forms. A carbonaceous source such as wood, coal, peat, or any organic carbonaceous material is carbonized, which means the pure carbon is extracted by a heating method known as pyrolysis. Once the material is carbonized, the material needs to be oxidized or treated with oxygen either by exposure to CO2 or steam or by an acid-base chemical treatment. The sections below will briefly detail these processes.
Unidirectional carbon fiber fabric is a type of composite material that consists of carbon fibers arranged in a single direction within a matrix material, typically epoxy resin. The carbon fibers in unidirectional fabric are aligned parallel to each other, which gives the material its name, "unidirectional." Directional Strength: Unidirectional carbon fiber fabric exhibits exceptional strength in the direction of the fibers. This characteristic is particularly advantageous when a component or structure primarily experiences loads along a specific axis. Lightweight: Carbon fibers are renowned for their low density, contributing to the lightweight nature of unidirectional fabric. This attribute is crucial in applications where weight reduction is critical. High Stiffness: Carbon fibers have a high modulus of elasticity, resulting in a stiff material. This stiffness minimizes deflection under load, which is important in applications where structural rigidity is paramount. Tailorability: Unidirectional carbon fiber fabric can be customized to meet specific requirements. Engineers can adjust the fiber orientation, the type of matrix material (commonly epoxy resin), and the number of plies to tailor the mechanical properties for different applications. Corrosion Resistance: Carbon fibers are inherently corrosion-resistant, making unidirectional fabric suitable for use in harsh environments, where protection against environmental factors is essential. Fatigue Resistance: These materials are highly resistant to fatigue, ensuring a long service life even under cyclic loading conditions. Thermal Conductivity: Carbon fibers have relatively low thermal conductivity, which can be advantageous in applications where thermal insulation or minimal heat transfer is required. Balanced Anisotropy: Unidirectional fabric offers anisotropic properties, meaning its mechanical characteristics vary with orientation. Engineers can harness this anisotropy by combining multiple layers or orientations of fabric to achieve balanced mechanical properties in different directions. High Cost: Unidirectional carbon fiber fabric can be expensive due to the cost of carbon fibers and the manufacturing process. However, the high performance and durability of the material can often justify the cost in applications where its unique properties are essential. Structural Strengthening: Unidirectional carbon fiber composites can be used to reinforce and strengthen existing building structures, such as bridges, beams, columns, and slabs. This technique can help extend the service life of older buildings or structures that require additional load-bearing capacity. Seismic Retrofitting: In regions prone to seismic activity, unidirectional carbon fiber composites can be applied to enhance the seismic resistance of buildings by improving their structural integrity. This retrofitting helps reduce the risk of damage during earthquakes.