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In the world of art, paintings serve as beautiful expressions of creativity and imagination. However, beyond the artist's skill and vision lies a hidden ingredient that plays a crucial role in preserving and protecting these masterpieces - silicon dioxide. Silicon dioxide, commonly known as silica, is a compound that offers several important functions in the realm of paintings. Let's delve into its main functions and understand why it is a vital component. First and foremost, silicon dioxide acts as a filler in paint formulations. Paints consist of pigments, binders, solvents, and additives. Pigments provide color, binders hold the paint together, solvents control the consistency and drying properties, while additives enhance specific properties. Silicon dioxide, in the form of fine particles, is added to the paint as a filler to improve its viscosity, thereby achieving better coverage and uniformity on the canvas. By filling in gaps and creating a smooth surface, silicon dioxide enhances the appearance and quality of the paint layer. Another key function of silicon dioxide in paintings is its ability to act as a matting agent. Matting agents are used to control the gloss level of the paint. Depending on the desired effect, artists may choose to create a glossy, semi-gloss, satin, or matte finish. Silicon dioxide is particularly effective in achieving a matte finish by scattering light and reducing the surface reflection of the paint layer. This feature is especially valuable in art conservation, as it helps to reduce glare and ensure the viewer's focus remains solely on the artwork itself. Furthermore, silicon dioxide plays a vital role in the long-term durability and protection of paintings. It acts as a reinforcing agent, enhancing the mechanical properties of the paint film. Silicon dioxide particles form a network within the paint layer, increasing its resistance to cracking, flaking, and fading over time. This reinforcement ensures that the artwork remains intact and retains its original beauty for years to come. Additionally, silicon dioxide provides a barrier against environmental factors such as moisture, dust, and UV radiation, safeguarding the painting from potential damage and ensuring its longevity. In conclusion, silicon dioxide plays a multifaceted role in the field of paintings. Its functions as a filler, matting agent, and reinforcing agent contribute to the quality, appearance, and durability of the artwork. By improving viscosity, controlling gloss levels, and enhancing mechanical properties, silicon dioxide helps preserve the integrity of paintings and protects them from various environmental factors. The inclusion of this compound in paint formulations underscores its significance in the art world, ensuring that masterpieces endure the test of time. Inkjet Receptive Coating, Anticorrosion Pigments, Matting Agent

Silicon dioxide, commonly known as silica, is a versatile compound widely used in various industries. One of its applications is as a silica matting agent in the field of paintings. Silica matting agents are additives that can be incorporated into paint formulations to adjust the gloss level of the final finish. By incorporating silica matting agents, painters can achieve the desired level of sheen in their paintings, from high gloss to matte, providing versatility and aesthetic control in the artistic process.   Silica matting agents work by scattering light that hits the painted surface, causing a reduction in gloss and creating a matte finish. This effect is achieved through the particle size and structure of the silica particles used in the matting agent. The fine particles of silica are carefully engineered to provide the desired level of matting effect without compromising the overall quality of the paint film. Painters can experiment with different concentrations of silica matting agents to achieve the desired finish in their artworks, making it a valuable tool for artists seeking to control the visual texture and appearance of their paintings.   In conclusion, the use of silica matting agents as additives in paintings offers artists a powerful tool to manipulate the gloss level and finish of their artworks. By incorporating silica matting agents into their paint formulations, artists can achieve a wide range of aesthetic effects, from high gloss to matte finishes, adding depth and visual interest to their creations. The versatility and control provided by silica matting agents make them a valuable addition to the artist's toolkit, allowing for endless creative possibilities in the world of painting. Inkjet Receptive Coating, Anticorrosion Pigments, Matting Agent

In the realm of artistic innovation, a new breakthrough has emerged in the form of utilizing silica matting agents, specifically silicon dioxide, as additives in paintings. Silica matting agents, commonly known as silica gels, have long been employed in various industries for their ability to create a matte finish on surfaces. However, recent studies have shown that these agents can also be harnessed in the realm of art, specifically in paintings, to enhance aesthetic appeal and longevity.   Silicon dioxide, the primary component of silica matting agents, offers unique properties that make it an ideal additive for paintings. When incorporated into paint formulations, silicon dioxide can enhance the durability and scratch-resistance of the finished artwork. Additionally, the use of silica matting agents can create a subtle matte finish on paintings, adding depth and texture to the visual composition. This innovative application of silica matting agents opens up new possibilities for artists seeking to experiment with different textures and finishes in their work.   Artists and art enthusiasts alike are now discovering the potential of silica matting agents in enhancing the quality and visual impact of paintings. By incorporating silicon dioxide-based additives into their artistic creations, painters can achieve a range of effects, from creating a velvety smooth finish to adding a gritty texture to their works. As the art world continues to explore new materials and techniques, the use of silica matting agents in paintings represents a new role. Inkjet Receptive Coating, Anticorrosion Pigments, Matting Agent

[China Aluminum Network] Welding methods that can connect high silica and alumina include: fusion welding, brazing, and solid phase welding. The performance of fusion-welded joints is poor, and generally high-energy density welding with rapid thermal cycling and low heat input, including electron beam welding and laser welding, is helpful to reduce the defects caused by fusion welding. Therefore, the research conducted in this area in recent years many. The brazing method is a metal welding method in which the metal is melted after the base metal is melted, and the space is filled with the molten metal after dissolution and diffusion. Solid-state welding technology refers to the welding method that applies static or dynamic pressure to the surface of the weldment after heating, with or without heating, and solidifies the two materials when the base material does not melt. Friction welding, diffusion welding, explosion welding, ultrasonic welding and so on are all examples. High pressure silicon aluminum alloy available pressure welding methods are: friction welding, vacuum diffusion welding and so on. Laser welding studies have shown that high-silicon-aluminum materials need to be connected using low-power fusion welding methods. Due to the high content of Si in the alloy, needle-like eutectic silicon and thick plate-like polygons are formed in the metal structure of the weld. The primary silicon, severely fractured the matrix; the metal in the near-seam region is prone to overheating and grain growth, resulting in a significant decrease in the mechanical properties of the weld and loss of use value. Laser welding has the advantages of large power density, large ratio of depth to width of weld, small heat affected zone, small workpiece shrinkage and deformation, and fast welding speed. This welding method is suitable for high-silicon-aluminum welding. Zhang Weihua et al. studied the microstructure and properties of ZL109 silicon aluminum alloy CO2 laser welded joints and obtained dense and fine grained joints. The heat input of the welding has a significant effect on the mechanical properties of joints, and the heat input increases, and the joint resistance increases. Tensile strength and elongation after breaking both increased first and then decreased. When the heat input was 44 J/mm, the tensile strength and elongation after breaking reached a large value, which were 121.2 MPa and 4.3%, respectively. Electron beam welding Electron beam welding uses high-speed electrons generated by a high electric field to form a stream of electrons after focusing, hitting the welded part of the metal to be welded, transforming its power into heat, and welding the welded metal. The electron beam has high energy density, strong penetration ability, large depth-to-width ratio of the weld, fast welding speed, and low input energy, so the heat affected zone is small and welding distortion is small. Therefore, the electron beam welding quality is good, and the mechanical properties of the weld seam are high. Shi Lei et al. performed vacuum electron beam welding on piston crowns and forged piston skirts of AlSi12CuMgNi aluminum alloy extrusion castings, and studied the microstructure and mechanical properties of welded joints under optimized process conditions. The results show that the joints are well-formed, there is no obvious heat affected zone, and the weld seam is narrow; the weld zone is mainly composed of fine α-Al phase, α+Si eutectic, primary crystal silicon and Mg2Si and other strengthening phases; the center of the weld is formed. It is a fine equiaxed crystal and a dendrite; the fused zone mainly consists of columnar crystals. The joint strength is not lower than that of the squeeze casting parent metal. The hardness of the weld is higher than that of the parent metal. A large number of torn and dissociated surfaces are distributed on the tensile fracture surface of the welded joint, showing brittle fracture. Different from brazing and welding methods, conventional brazing is the use of (or automatically generated in the process) brazing material with a lower melting temperature than the base metal. The operating temperature is lower than the solidus of the base metal and higher than the liquidus of the brazing material. A welding technique. During brazing, the workpiece is usually heated by the entire body or evenly around the brazing seam. Therefore, the relative deformation of the workpiece and the residual stress of the welded joint are much smaller than those of the welding. In today's manufacturing industry, high-silicon-aluminum materials are generally used in high-precision devices in aerospace machinery manufacturing. For these devices brazed welding, the impact on the workpiece is also small. Since the high-silicon aluminum alloy contains a hard silicon phase, the solder has poor wetting properties to the series of materials, and it is difficult to achieve an effective connection by an ordinary soldering method. Hou Ling et al. are conducting high-silicon-aluminum brazing tests. The Ni-Cu-P, Au and Cu layers were pre-plated on the 65Si35Al alloy substrate first, and then the Ni-Cu-P, Au and Cu layers were separately plated, which effectively improved its soldering performance. Using Sn-Pb, Sn-Ag-Cu, Sn-In, and Sn-Bi solders to perform soldering analysis on 65Si35Al alloy samples with different coatings in the furnace, including the use of metallurgical microscopy and spectroscopy. The analytical (EDS) function of scanning electron microscopy and other testing methods were used to examine the microstructure, morphology and phase composition of the welded joints. The influence of brazing process parameters on the quality of the brazed joints of the 65Si35Al alloy was analyzed. The causes of macro defects and micro defects in joints and the differences in the wetting properties of brazing materials for different coatings. Friction welding Friction welding is the use of the heat generated by the end faces of the workpieces moving against each other and friction, so that the ends reach the thermoplastic state, and then quickly forged to complete the welding method. This welding method has not been studied for a long time. It was a process proposed in 1991, but it has also been rapidly developed. N. ARODRIRIGUEZ et al. studied the friction welding of A319 and A413 aluminum-silicon cast alloys. The experimental results show that the distance between the particles in the weld zone decreases and the corresponding hardness increases. Ji Yajuan et al. studied the hardness, microstructure and mechanical properties of friction stir welding joints of ZL114A aluminum alloy under different parameters. Experimental results: The microstructure of the welding center area is a fine equiaxed crystal. The silicon particles were refined in the welding process and evenly covered the entire weld zone. The grain of the weld was small, uniform and dense, and no defects such as blowhole cracks were observed. Diffusion welding diffusion welding is the use of localized plastic deformation between the materials in contact with each other at high temperatures, the close adhesion between the surfaces and the interdiffusion between the surfaces to generate metal bonds, thereby obtaining a certain form of integral joints. Interdiffusion between atoms is the basis for achieving diffusion connections. Diffusion welding requires the use of relatively large pressures, requires high precision in the mating surface, makes it difficult to uniformly pressurize complex components, and even requires expensive and complicated fixtures. Therefore, diffusion welding Requirements more high-end. Diffusion welding can be divided into dissimilar material diffusion welding, diffusion welding of the same kind of material, adding intermediate layer diffusion welding, superplastic forming diffusion welding, isostatic pressure diffusion welding, transitional liquid phase diffusion welding (TLP), among which transitional liquid phase diffusion welding. (TLP) combines the advantages of brazing and solid-phase diffusion welding to form a new joining method. The principle is to place the intermediate layer alloy matching the matrix material on the connecting surface. Domestic and foreign scholars have begun to deepen the method. Research. Research on TLPs in China is still in its infancy. It is mainly aimed at welding processes for some dissimilar hard-to-weld metals. Compared with domestic research, the research direction of foreign countries is broader. It involves not only the research of the process, but also the simulation of TLP welding, and focuses on the key factors of the TLP process. At present, the research on TLP at home and abroad mainly includes the following aspects: Engineer Wang Xuegang of Shandong Electric Power Research Institute adopts self-developed Fe-Ni-Si-B amorphous metal foil tape as intermediate layer material and TLP process in open gas. In the protected environment, the steel pipe used in the welding power station can obtain continuous and uniform weld microstructure and better mechanical properties than manual fusion welding. The process parameters include intermediate layer material, heating temperature, holding time, pressure, and requirements for welding end surfaces. Liu Liming and Niu Jitai et al. used vacuum diffusion welding to weld aluminum matrix composite SiCw/606Al. Through series of experiments, the results showed that when the material is used for diffusion welding, the welding temperature is the main process parameter that affects the strength of the joint. When the welding temperature is between the matrix In the liquid-solid two-phase temperature range of the aluminum alloy, a liquid matrix metal appears on the bonding surface, and a higher joint strength can be obtained. Many researchers at home and abroad are engaged in diffusion welding research, but there are not many researches on diffusion welding of silicon aluminum alloys. The research prospects and exploration space in this area are relatively long-term. High-silicon aluminum alloys play an important role in aerospace, aviation, automotive, and space technology. Research on high-silicon aluminum alloys is becoming more and more in-depth. In the development and application of high-silicon aluminum alloys, related welding methods, It is also a big trend to invest more in welding technology. The application of these fields to the high-silicon-aluminum welding joints requires very high performance, coupled with the high silicon-aluminum material containing silicon, which is easy to oxidize, which has high requirements for high-silicon-aluminum welding technology and welding methods. Welding and soldered joints can not meet the welding requirements of the weldment in some applications, and use more advanced welding methods - diffusion welding is the trend of silicon aluminum alloy welding research. Inkjet Receptive Coating, Anticorrosion Pigments, Matting Agent

The price increase was triggered by the 300 yuan/t increase in the production of titanium dioxide powder in Sichuan Longyan. Nearly 30 domestic producers in the Southwest, East China, Central China, South China, and Northeast China have announced that they will increase their prices. 500 yuan / ton; the current domestic market conditions temporarily stable, monitoring data show that most of the sulfuric acid rutile and anatase titanium dioxide mainstream offer in 10600-11200 yuan / ton and 8500-9500 yuan / ton, the southwest price range In the range of 10,600-11,000 yuan/ton, the market area in Shandong is 11,000-12,000 yuan/ton, and the price range in central China is 10800-11000 yuan/ton; After you read it, you think that it has gone too fast? In fact, in the long term, the price of titanium dioxide is still at a low level. The data shows that the price of titanium dioxide in all regions fell by 15% year-on-year; on the other hand, the overall cost of titanium dioxide production is generally around 10,000 yuan/ton, plus environmental protection investment, sales costs, and funds. Although the cost of different companies in different regions, different resource allocation, but the sales price of sulfuric acid rutile titanium dioxide market in accordance with the current environmental level, resource allocation and other factors calculated 13000-15000 yuan / ton is more reasonable, titanium dioxide enterprises to achieve profitability. The rise also belongs to the normal price rebound. However, the continuation of this increase is more worth considering. At present, the market is stable and the inventory pressure is not high, but the downstream manufacturers have no intention of selling goods, and the transaction volume is not large. The industry just needs to support the price, the company's price increases are constantly being implemented, the recent low-end transaction prices have gradually decreased, and the market supply and demand tend to be dynamically balanced. Some producers in the southwestern and central regions of China, due to the operating rate and other issues, are in tight supply on the spot market. Some manufacturers have already forecasted the expected increase in April. In the short-term, there is a bubble in this price increase. The price still needs time to digest. Inkjeteceptive Coating, Anticorrosion Pigments, Matting Agent Inkjet Receptive Coating, Anticorrosion Pigments, Matting Agent

[China Aluminum Network] 1. This product makes full use of renewable resources, energy conservation and environmental protection. 2, no burning, no hollowing, no seams, initial condensation fast, direct bonding with the grass-roots level, forming an integrated insulation system, a solid structure. This greatly improves the insulation performance. 3, strong bonding ability, no cracking, cold, thermal bridge deformation coefficient is small, in the insulation system structure, do not have to brush the interface agent on the base wall and the use of cracking glass fiber mesh cloth. The thickness of the insulation layer is within 120mm and can be continuously formed on the same day. The construction procedures have been reduced, the speed of construction has been accelerated, and labor and time have been saved, thereby reducing costs and achieving good economic results. 4. The product has added near-nano-scale fiber imported from abroad. There are hundreds of millions of criss-crossing fibers per cubic meter of material, which improves the thermal insulation performance, crack resistance, compressive strength, adaptability, and fatigue resistance of the product. Ability, shock resistance, resistance to cold and hot bridges, and durability. 5, excellent thermal insulation performance, thermal conductivity of the detection value of 0.046-0.048W / (m? K), SQ aluminum new insulation material is in the country on the premise of building energy conservation standards continue to improve (total energy saving 65 For development and production, the thickness of the insulation layer in most areas of China is only between 30mm and 100mm to meet the insulation requirements of the building wall. 6. Accurate ratio: The packaging adopts silica-alumina gel material and polyphenyl granule aggregate separately packaged, and the ratio of 1:1 bags ensures that the product ratio is accurate. The polyphenylene granule aggregate is specially processed and eliminated during stirring. Disadvantages of easy flying in the process. Ink [China Aluminum Network] 1. This product makes full use of renewable resources, energy conservation and environmental protection. 2, no burning, no hollowing, no seams, initial condensation fast, direct bonding with the grass-roots level, forming an integrated insulation system, a solid structure. This greatly improves the insulation performance. 3, strong bonding ability, no cracking, cold, thermal bridge deformation coefficient is small, in the insulation system structure, do not have to brush the interface agent on the base wall and the use of cracking glass fiber mesh cloth. The thickness of the insulation layer is within 120mm and can be continuously formed on the same day. The construction procedures have been reduced, the speed of construction has been accelerated, and labor and time have been saved, thereby reducing costs and achieving good economic results. 4. The product has added near-nano-scale fiber imported from abroad. There are hundreds of millions of criss-crossing fibers per cubic meter of material, which improves the thermal insulation performance, crack resistance, compressive strength, adaptability, and fatigue resistance of the product. Ability, shock resistance, resistance to cold and hot bridges, and durability. 5, excellent thermal insulation performance, thermal conductivity of the detection value of 0.046-0.048W / (m? K), SQ aluminum new insulation material is in the country on the premise of building energy conservation standards continue to improve (total energy saving 65 For development and production, the thickness of the insulation layer in most areas of China is only between 30mm and 100mm to meet the insulation requirements of the building wall. 6. Accurate ratio: The packaging adopts silica-alumina gel material and polyphenyl granule aggregate separately packaged, and the ratio of 1:1 bags ensures that the product ratio is accurate. The polyphenylene granule aggregate is specially processed and eliminated during stirring. Disadvantages of easy flying in the process. Inkjet Receptive Coating, Anticorrosion Pigments, Matting Agent jet Receptive Coating, Anticorrosion Pigments, Matting Agent

[China Aluminum Network] 1. This product makes full use of renewable resources, energy conservation and environmental protection. 2, no burning, no hollowing, no seams, initial condensation fast, direct bonding with the grass-roots level, forming an integrated insulation system, a solid structure. This greatly improves the insulation performance. 3, strong bonding ability, no cracking, cold, thermal bridge deformation coefficient is small, in the insulation system structure, do not have to brush the interface agent on the base wall and the use of cracking glass fiber mesh cloth. The thickness of the insulation layer is within 120mm and can be continuously formed on the same day. The construction procedures have been reduced, the speed of construction has been accelerated, and labor and time have been saved, thereby reducing costs and achieving good economic results. 4. The product has added near-nano-scale fiber imported from abroad. There are hundreds of millions of criss-crossing fibers per cubic meter of material, which improves the thermal insulation performance, crack resistance, compressive strength, adaptability, and fatigue resistance of the product. Ability, shock resistance, resistance to cold and hot bridges, and durability. 5, excellent thermal insulation performance, thermal conductivity of the detection value of 0.046-0.048W / (m? K), SQ aluminum new insulation material is in the country on the premise of building energy conservation standards continue to improve (total energy saving 65 For development and production, the thickness of the insulation layer in most areas of China is only between 30mm and 100mm to meet the insulation requirements of the building wall. 6. Accurate ratio: The packaging adopts silica-alumina gel material and polyphenyl granule aggregate separately packaged, and the ratio of 1:1 bags ensures that the product ratio is accurate. The polyphenylene granule aggregate is specially processed and eliminated during stirring. Disadvantages of easy flying in the process. Inkjet Receptive Coating, Anticorrosion Pigments, Matting Agent

Only to oxygen, silicon is the most abundant element in Earth's crust. It is found in rocks, sand, clays and soils, combined with either oxygen as silicon dioxide, or with oxygen and other elements as silicates. Silicon's compounds are also found in water, in the atmosphere, in many plants, and even in certain animals. Silicon is the fourteenth element of the periodic table and is a Group IVA element, along with carbon germanium, tin and lead. Pure silicon is a dark gray solid with the same crystalline structure as diamond. Its chemical and physical properties are similar to this material. Silicon has a melting point of 2570° F (1410° C), a boiling point of 4271° F (2355° C), and a density of 2.33 g/cm3. When silicon is heated it reacts with the halogens (fluorine, chlorine, bromine, and iodine) to form halides. It reacts with certain metals to form silicides and when heated in an electric furnace with carbon, a wear resistant ceramic called silicon carbide is produced. Hydrofluoric acid is the only acid that affects silicon. At higher temperatures, silicon is attacked by water vapor or by oxygen to form a surface layer of silicon dioxide. When silicon is purified and doped with such elements as boron, phosphorus and arsenic, it is used as a semiconductor in various applications. For maximum purity, a chemical process is used that reduces silicon tetrachloride or trichlorosilane to silicon. Single crystals are grown by slowly drawing seed crystals from molten silicon. Silicon of lower purity is used in metallurgy as a reducing agent and as an alloying element in steel, brass, alumiinum, and bronze. When small amounts of silicon are added to aluminum, aluminum becomes easier to cast and also has improved strength, hardness, and other properties. In its oxide or silicate form, silicon is used to make concrete, bricks, glass, ceramics, and soap. Silicon metal is also the base material for making silicones used in such products as synthetic oils, caulks and sealers, and anti-foaming agents. In 1999, world production was around 640,000 metric tons (excluding China), with Brazil, France, Norway and the United States major producers. This is a continued decline compared to the last several years (653,000 tons in 1998 and 664,000 in 1997). Though data is not available, China is believed to be the largest producer, followed by the United States. One estimate puts China's production capacity as high as 400,000 metric tons per year, with over 400 producers. Exports from this country have increased in recent years. Consumption of silicon metal in the United States was roughly 262,000 metric tons, at a cost of 57 cents per pound. The annual growth rate during 1980-1995 was about 3.5% for silicon demand by the aluminum industry and about 8% by the chemical industry. Demand by the chemical industry (mainly silicones) was affected by the Asian economic crisis of the late 1990s. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

Since the beginning of 2016, the market price of titanium dioxide has continued to rise, coupled with the pulling of foreign trade, driving the continuous rise in the price of titanium dioxide. From January to May, the cumulative export of titanium dioxide nationwide was 28,4623.7 tons, an increase of 5,665,800 tons, an increase of 24.85%. In May 2016, the country`s export of titanium dioxide was 7,1231.6 tons, which was the highest in the history of monthly export volume, which was an increase of 2,3957.5 tons, an increase of 50.68% year-on-year; an increase of 1,5564.2 tons, an increase of 27.96%; the first three exports. The countries are India, the United States, and South Korea. The export volume of titanium dioxide in May accounted for about 30% of the national titanium dioxide production for the month, which played a key role in the improvement of the recent industry boom. However, in terms of the average unit price of imported titanium dioxide in May, the import price of US$2,298.84/ton was 1.54 times the export price of US$1541.1/ton. From January to May, the cumulative amount of titanium dioxide imported nationwide was 69211.4 tons, a year-on-year decrease of 1,1811.2 tons, a decrease of 14.58%. In May, the national import volume of titanium dioxide was 1,5904.6 tons, a year-on-year decrease of 3470.0 tons, a reduction of 17.91%, an increase of 2797.7 tons, an increase of 21.34%; the top three countries or regions of import were Taiwan, Australia, and the United States. Titanium dioxide prices pick up return to rational Since the 1-2 quarter of 2012, the titanium dioxide industry has gradually shown a sluggish market. The market demand has shrunk and the price has dropped. Although the short-term [rebounds" and [crunch" in the middle, it is not enough to change the general trend of the downward trend. There is a big difference from the hot scenes in 2010-2011. Thanks to the gradual recovery of the global economy and the country's policy of encouraging exports, a good balance of production and sales in the entire industry emerged from 2013 to 2014: In 2013, exports exceeded 400,000 tons for the first time, reaching 403,000 tons, accounting for the current year. The national output of 18.7%; 2014 exports increased by 37% over the previous year, reaching 552,000 tons, accounting for 22.7% of the country's total production. However, by 2015, especially in the second half of the year, due to the slowdown of global economic growth and weak domestic market demand, titanium dioxide prices have been [diving" all the way, hitting historical lows. Most of the titanium dioxide manufacturers except some large companies The Department chose to restrict production and stop production to reduce losses. The export volume of titanium dioxide also decreased: In 2015, the export volume was 53,8394.4 tons, a year-on-year decrease of 1,4084.8 tons, a decrease of 2.5%. In 2016, under the pressure of global and Chinese economic downturn, the price of titanium dioxide began to bottom out. Different from previous years, the current titanium dioxide inventory is lower than the conventional level, and even some products are "hard to find"; exports have also repeatedly hit a record high, although the domestic market demand is not yet strong, but the rigid demand and titanium dioxide production and inventory Can match. From the beginning of July to the beginning of July, domestic titanium dioxide companies experienced an [eight-pronged rise", which laid the trend for a reasonable market price in the first half of the year. The overall titanium dioxide industry in China is in a rising channel. The price of titanium dioxide in 2016 is expected to become reasonable. Based on. According to statistics, the current domestic market is about 13,000 yuan/ton. The increase in the price of titanium dioxide was mainly due to the shrinkage of production capacity of domestic and foreign titanium dioxide enterprises and the improvement of supply and demand patterns. Real estate new construction area and car sales data show that demand continues to pick up this year. At the same time, the supply side was also affected by multiple factors, overseas production capacity was shut down, domestic environmental protection high standards eliminated backward production capacity, and industry integration increased. In addition, the prices of titanium concentrates in the upstream raw materials continued to be strong, and recent Panxi mines stopped production due to environmental pressure, tighter mineral resources and larger price increases, which also supported the downstream price of titanium dioxide. Industry promotes supply-side reform and accelerates merger integration With the advancement of supply-side reforms in China's titanium dioxide industry and the acceleration of industry mergers and acquisitions, the industry supply and demand pattern in the future is expected to further improve. Chlorination titanium dioxide progress As we all know, the chlorination process has many advantages over the sulfuric acid process and is the mainstream process for the development of the titanium dioxide industry in the world. The development of chlorinated titanium dioxide in China can be said to be difficult and costly. Fortunately, although the process is difficult, although the price is heavy, China's chlorination titanium dioxide has been a breakthrough, product quality has significantly improved. In terms of prices, although the current market is still increasing prices, Longyi has accumulated an increase of 3,500 yuan/ton this year, but the actual domestic demand is still not high, and entered the traditional off-season in July and August, Europe and the United States also began holiday peak, foreign exports Or decrease, the expectation of market price increase is getting smaller and smaller, or it will stop "up eight consecutive rise". In the second half of the year, manufacturers are more likely to be war-torn each other, and they will be priced based on actual conditions such as their own inventory. The prices may fall back, but the falling-back space will remain within reasonable prices, appearing to be lower than most manufacturers as last year. The chances of the cost price situation are already small. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

The so-called silicon pump, in fact, refers to aluminum zinc silicon pump. Aluminum zinc silicon pump, refers to the pump impeller, shell, gland and other major components are all corrosion resistant alloy steel - aluminum-zinc-silicon alloy. Al-Zn-Si pump can effectively control the zinc liquid in the pump flow rate, temperature drop, thermal expansion coefficient of the material and other indicators to meet the special requirements of repeated use for a long time, therefore, aluminum zinc-silicon pump by hot galvanized units Welcome and favor. The application of aluminum alloy pump can greatly improve the production efficiency, but also liberate the workers from the heavy manual labor, greatly reducing the labor intensity of the workers, and also avoiding the high temperature and liquid zinc splashing on people's injury, Thus greatly improving the economic benefits of hot-dip galvanizing manufacturers. Aluminum zinc silicon pump is also a feature of the long axis of transmission (usually more than 2 meters), the drive motor away from heat, to ensure that the motor can work for a long time. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

Recently, China has independently developed a 4-inch high-purity semi-insulating silicon carbide substrate products available. It is reported that the silicon carbide project developed by Shandong Tianyue made. China Electronics Materials Industry Association experts believe that the results of the leading domestic and has reached the international advanced level. Earlier, a Beijing enterprise and the Chinese Academy of Sciences, successfully developed from 2 inches to 6 inches of silicon carbide substrate, completed our SiC process from scratch. Nowadays, the second enterprise in our country has also realized mass production of silicon carbide materials, which indicates that the development of silicon carbide materials in our country is gradually becoming mature. Observer network that informed, Shandong Tianyue is a silicon carbide manufacturing enterprises and Shandong University Materials Research Center. Materials Science and Technology has always been one of the shortcomings restricting the development of China's military industry. In January 2015, Observer Network reported that Beijing Tianke Heda Bluestar Semiconductor Co., Ltd. and CAS successfully developed a 6-inch silicon carbide substrate and formed a With an annual output of 70,000 silicon carbide wafer production lines, the company was once the only silicon carbide semiconductor materials manufacturing enterprises in China. However, the shortcomings of materials science and technology not only reflected in the technology, but also reflected in the production. Although compared to the lower the technical gap, but the observer network learned that Shandong Tianyue new production line will reach an annual output of 40-50 million 4-inch silicon carbide substrate extent, such a huge scale may mean that our country The cost of silicon carbide products is reduced, leaping in output. As we all know, most of the current semiconductor materials are monocrystalline silicon. For a long time, China's monocrystalline silicon mainly relies on imports. Compared with single crystal silicon, the production and application of silicon carbide material has been very difficult. The world's most developed silicon carbide devices are the United States, Germany, Switzerland, Japan and other countries, but until now the industrial application of silicon carbide is mainly as an abrasive (Emery) to use. ABB Switzerland has once successfully developed a silicon carbide diode, but in 2002, due to process difficulties, the future is unknown, ABB terminated the silicon carbide project, showing the difficulty of research and development. The important strategic value of semiconductor silicon carbide substrate and chip, making it always the United States Department of Commerce's embargo list, which also makes it difficult for our country to obtain the corresponding products from abroad. China's second enterprise on the 4-inch high-purity semi-insulating silicon carbide substrate product development success, indicating that China's silicon carbide wafer products in the process and production have been able to get rid of dependence on foreign countries, to the autonomous mass production and widespread application. The physical properties of silicon carbide and silicon are very different. Monocrystalline silicon carbide has many superior physical properties than monocrystalline silicon, such as about 10 times the electric field strength, about 3 times higher thermal conductivity, about 3 times the width of the forbidden band, about twice the saturation drift velocity. In addition, although silicon carbide devices are much more difficult to process than single crystal silicon in specific applications, once the process is solved, the manufacturing process of the silicon carbide devices is short, the volume and weight are small, the anti-oxidation life is long, and the output power is high Will make it an ideal 21st century semiconductor material that is far superior to single crystal silicon. And silicon carbide materials on the energy consumption is very low, according to the annual output of 400,000 silicon carbide wafer substrate plan, only used in the lighting field, the annual energy consumption is equivalent to saving 26 million tons of standard coal, is a The ideal energy-saving materials. Comparison of properties of single crystal silicon carbide (SIC) and single crystal silicon (SI) materials Thus, with the rapid development of wireless communication technology, the demand for high power density and fast response speed of hardware systems is becoming more and more urgent. Silicon-based materials-based transistors have unparalleled monocrystalline silicon and gallium arsenide devices in the microwave radio frequency field Advantages for aerospace, microwave communications, electronic warfare, large-capacity information processing applications. Phased array radars for the U.S. military's fourth-generation fighter jets, electronic jammers and Aegis destroyers have begun to refurbish their SiC-based microwave devices. With the enhancement of the production capacity of silicon carbide wafers in China, both domestic fighters and warships will be able to replace the "clairvoyance" with better performance and narrow the gap with the United States in quality and quantity. In addition to military applications, silicon carbide materials are also in urgent need of civilian semiconductors and power. According to the introduction of Shandong Tianyue official website, this is a private enterprise established in November 2010 to develop and produce semiconductor chips and substrate materials. It is an industrialized base, a high-tech enterprise of Shandong University, a brand building of Shandong Province Demonstration business. In the past, the production of silicon carbide wafers could only meet the needs of military products. The annual output of 400,000 pieces of silicon carbide chips means that silicon carbide wafers are no longer "special" products for military radar electronic equipment and their use may be extended to generate electricity , Power transmission, railway, lighting and other civilian areas, to play a greater role in the development of the national economy. Domestic silicon carbide materials help domestic radar Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

Recently, China has independently developed a 4-inch high-purity semi-insulating silicon carbide substrate products available. It is reported that the silicon carbide project developed by Shandong Tianyue made. China Electronics Materials Industry Association experts believe that the results of the leading domestic and has reached the international advanced level. Earlier, a Beijing enterprise and the Chinese Academy of Sciences, successfully developed from 2 inches to 6 inches of silicon carbide substrate, completed our SiC process from scratch. Nowadays, the second enterprise in our country has also realized mass production of silicon carbide materials, which indicates that the development of silicon carbide materials in our country is gradually becoming mature. Observer network that informed, Shandong Tianyue is a silicon carbide manufacturing enterprises and Shandong University Materials Research Center. Materials Science and Technology has always been one of the shortcomings restricting the development of China's military industry. In January 2015, Observer Network reported that Beijing Tianke Heda Bluestar Semiconductor Co., Ltd. and CAS successfully developed a 6-inch silicon carbide substrate and formed a With an annual output of 70,000 silicon carbide wafer production lines, the company was once the only silicon carbide semiconductor materials manufacturing enterprises in China. However, the shortcomings of materials science and technology not only reflected in the technology, but also reflected in the production. Although compared to the lower the technical gap, but the observer network learned that Shandong Tianyue new production line will reach an annual output of 40-50 million 4-inch silicon carbide substrate extent, such a huge scale may mean that our country The cost of silicon carbide products is reduced, leaping in output. As we all know, most of the current semiconductor materials are monocrystalline silicon. For a long time, China's monocrystalline silicon mainly relies on imports. Compared with single crystal silicon, the production and application of silicon carbide material has been very difficult. The world's most developed silicon carbide devices are the United States, Germany, Switzerland, Japan and other countries, but until now the industrial application of silicon carbide is mainly as an abrasive (Emery) to use. ABB Switzerland has once successfully developed a silicon carbide diode, but in 2002, due to process difficulties, the future is unknown, ABB terminated the silicon carbide project, showing the difficulty of research and development. The important strategic value of semiconductor silicon carbide substrate and chip, making it always the United States Department of Commerce's embargo list, which also makes it difficult for our country to obtain the corresponding products from abroad. China's second enterprise on the 4-inch high-purity semi-insulating silicon carbide substrate product development success, indicating that China's silicon carbide wafer products in the process and production have been able to get rid of dependence on foreign countries, to the autonomous mass production and widespread application. The physical properties of silicon carbide and silicon are very different. Monocrystalline silicon carbide has many superior physical properties than monocrystalline silicon, such as about 10 times the electric field strength, about 3 times higher thermal conductivity, about 3 times the width of the forbidden band, about twice the saturation drift velocity. In addition, although silicon carbide devices are much more difficult to process than single crystal silicon in specific applications, once the process is solved, the manufacturing process of the silicon carbide devices is short, the volume and weight are small, the anti-oxidation life is long, and the output power is high Will make it an ideal 21st century semiconductor material that is far superior to single crystal silicon. And silicon carbide materials on the energy consumption is very low, according to the annual output of 400,000 silicon carbide wafer substrate plan, only used in the lighting field, the annual energy consumption is equivalent to saving 26 million tons of standard coal, is a The ideal energy-saving materials. Comparison of properties of single crystal silicon carbide (SIC) and single crystal silicon (SI) materials Thus, with the rapid development of wireless communication technology, the demand for high power density and fast response speed of hardware systems is becoming more and more urgent. Silicon-based materials-based transistors have unparalleled monocrystalline silicon and gallium arsenide devices in the microwave radio frequency field Advantages for aerospace, microwave communications, electronic warfare, large-capacity information processing applications. Phased array radars for the U.S. military's fourth-generation fighter jets, electronic jammers and Aegis destroyers have begun to refurbish their SiC-based microwave devices. With the enhancement of the production capacity of silicon carbide wafers in China, both domestic fighters and warships will be able to replace the "clairvoyance" with better performance and narrow the gap with the United States in quality and quantity. In addition to military applications, silicon carbide materials are also in urgent need of civilian semiconductors and power. According to the introduction of Shandong Tianyue official website, this is a private enterprise established in November 2010 to develop and produce semiconductor chips and substrate materials. It is an industrialized base, a high-tech enterprise of Shandong University, a brand building of Shandong Province Demonstration business. In the past, the production of silicon carbide wafers could only meet the needs of military products. The annual output of 400,000 pieces of silicon carbide chips means that silicon carbide wafers are no longer "special" products for military radar electronic equipment and their use may be extended to generate electricity , Power transmission, railway, lighting and other civilian areas, to play a greater role in the development of the national economy. Domestic silicon carbide materials help domestic radar Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

CHINACOAT - An Annual Exhibition for The Industry November 15 - 17, 2023 | Shanghai New International Expo Centre (SNIEC) November 1 – December 31, 2023 | Online Show (www.chinacoatonline.net) CHINACOAT2023 will open its gates to global visitors once again since our last show being held there in 2019. The show to be held on November 15-17 at the Shanghai New International Expo Centre (SNIEC) covers 7.5 exhibition halls (Halls E2, E3, E4, E5, E6, E7, E8 and E9), with a total gross exhibition area of more than 70,000 square meters. Over 900 exhibitors from 30 Countries and Regions are going to display their new products, services and solutions. It will be a Global Event not to be missed by any players in our industry. Register to visit now! CHINACOAT continues to offer an Online Show (www.chinacoatonline.net) this year, providing Exhibitors with extra exposure and connecting with the visitors worldwide to extend the promotional mix. This year, we have appointed Shanghai PCI&KM, the Coatings Industry technical media service platform, as our Official Video Production Provider. They will visit Exhibitors` Booths onsite at the exhibition hall to shoot videos for you, to introduce your products in interview format, in order to show global visitors real-time footages to increase engagement. The edited videos will be uploaded to our various official channels as well as Shanghai PCI&KM`s official channels, with total of over 123,000 followers, as early as the next day. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

Artur Palasz, Ph.D., Spektrochem, discusses the proper use of raw materials in formulations and how to avoid errors when scaling a formulation from lab to production scale, while ensuring maximum efficiency of time and energy Today`s reality of latex paint formulations requires the supply to the R&D department (a paint manufacturer both in a large and a small company producing various latex paints) of technical materials showing the advantage of raw materials offered by a given supplier over the competition, as well as education of R&D employees in the use of specific raw materials in formulations through the so-called application studies, constituting case studies showing how a given raw material works in guideline formulations. Providing such tools is not only a competitive advantage of raw material suppliers, but also the ease of using the raw material in tests in specific projects, thanks to e.g. comparisons of effectiveness in various PVC ranges, performance with competitive additives, etc. The consequence of this is the appropriate transfer to full-scale production, which must be relatively easy and made with all paint parameters set at the R&D stage. Translating a laboratory scale to a production scale is usually not extremely difficult, however, in this article we will focus on those raw material yields that, properly selected at the R&D stage, will later allow for the effective use of their full-scale potential and the production of high-quality latex paints. Starting formulations and application studies Everyone in the paint industry knows that starting point formulations are standard support for launching raw materials on the market. However, today they are required to do a bit more than just be a list of ingredients from which the paint should be made. Today, market expectations and the competitiveness of raw material suppliers mean that, together with starting point formulations, application studies should also be provided showing how the raw material works in a given formulation and how the process of its adaptation to the formulation to be developed by the paint manufacturer should be conducted. READ MORE: Flash rust inhibitors in waterborne paints for architectural and wood applications Paint companies adapt to tightening environmental legislation Application studies are a kind of guide which, for the formulator, is to be a signpost on how to use a given raw material so that its efficiency is maximally used, and how to later translate it into full-scale production. In this article, I will focus on two raw materials that are very much related to the transfer from lab to full scale and, contrary to the first glance, extremely related to each other, namely dispersants and defoamers. Dispersing agents In the starting point formulations, the quantities of raw materials are already defined. If we assume that they have been determined by laboratory tests, then how much is due to something. In the case of dispersants, this amount should result, firstly, from mill-base viscosity reduction, and secondly, from the effect of a specific dose selected by effective mill-base viscosity reduction on some other parameters, e.g. scrub resistance. Yes, a dispersant additive can (and usually does) affect the scrub resistance results. It can also affect the colour acceptance, storage stability or water sensitivity of the coating, however, in my article, let`s focus on scrub resistance as a key performance property. In the starting point formulations, the defined dose of dispersant will be difficult to interpret without application studies showing how the dispersant performed at other doses. Such ladder studies provide an enormous amount of data and show not only the amount used to build a standard formulation, but where that dose was taken from. Below are examples of such application studies with their short characteristics for dispersing agent. The tested dispersant was characterised by laboratory tests in a slurry formulation, which was then used to prepare latex paints. The first characteristic of the dispersant was its effectiveness, defined as mill-base viscosity, i.e. the ability to lower the mill-base viscosity during grinding in the cowles dissolver. The slurry was composed of calcium carbonate and titanium dioxide (solid content 80% by weight) and the viscosity was tested after grinding with dispersant dosing in doses of 0.25%, 0.50%, 0.75%, 1.0% and 1.25% by weight calculated on active substances per solid content in the slurry. In general, we recommend expressing the amount of dispersant in this way, calculating in terms of active substances (active solids) and total pigments and fillers in the formulation. Of course, later in the final formulation, the amount is expressed in the dose of dispersant as supplied for the entire formulation, but it should be remembered that its amount is related to the above. Figure 1. Summary of results of mill-base viscosity tests and the effect on paint viscosity and scrubbability depending on the dose of dispersant The results of the viscosity measurements (ASTM D2196 method A by Brookfield viscometer, measurement directly from the metal Griffin beaker in which the slurry was prepared, immediately after its preparation) are shown in Figure 1. Each slurry was then combined with the acrylic polymer dispersion and other ingredients to form a PVC 37% acrylic paint formulation. For the prepared paints, after their stabilisation, viscosity measurements were also made as above, and their values are also shown in Figure 1. Finally, each of the prepared paints were applied to scrub panels and, after 7 days of conditioning at 23°C and 50% RH, were subjected to scrubbability tests according to ASTM D2486. Test results are also shown in Figure 1. The discussed example of the application study provides the formulator with knowledge on the effectiveness of mill-base viscosity reduction, of course, together with the formulation in which it was used, as well as how the dispersant content affects the change in paint viscosity, which is the result of its impact on the thickeners and binder used in starting point formulations. The presented graph shows that the effectiveness of mill-base viscosity reduction increases practically linearly with the reduction of the dispersant dosing, which in turn is the opposite to the viscosity of the paint with its participation. In terms of scrubbability results, it can be seen that the sample with 0.5% of dispersant actives has the best result, which also correlates with the optimal viscosity of both slurry and paint. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

The acrylic paints market is growing at an average pace and is anticipated to record a CAGR of 4.5 % from 2022 to 2032. One of the primary differentiating competitive tactics is the development of high-performance acrylic paint bonding for manufacturers to emerge as winners in the market. Advances in technology-driven end-use applications of acrylic paints are significant factors driving market expansion. The expansion of infrastructure also plays a pivotal role in fuelling the growth of the acrylic paints market, as factors such as water resistance and superior finish boost its popularity. Acrylic paint has been treated as a type of medium that is suitable for kindergarten classrooms only over the past few decades. However, with the advancement of pigmentation, consistency and finishes, many artists - David Hockey, Helen Frankenthaler, Mark Rothko - prefer acrylic paints as an ideal choice for acrylic art. What boosts the adoption of acrylic paints? The high reliance of artists on acrylic paints to get consistency and finishes in their portraits is one of the major revenue channels for the market. Stemming from the popularity of water-based acrylic binders in house paints and artisanal professionals, the global acrylic paint market will continue to make material progress over the decade ahead. Known for their durability, flexibility and affordability, the acrylic paints market has established itself as a sizeable market over the years. Tech-driven advancements in acrylic paints are key factors fuelling the market growth. An increasing number of compatible media is expanding the application scope of acrylic paints. Significant players are leveraging market intelligence, such as consumer trends and region-wise analysis to devise research and development efforts. The rise in infrastructure development is a major factor of growth for the acrylic paints market. Factors such as water resistance, superior finish and consistent drying time are propelling their adoption in construction projects. Consumer demand for high-performance exterior paint sun-reflective and water-resistant – and improved finish quality is making acrylic paints the preferred choice for exterior surfaces. Acrylic paints do not deteriorate under excessive sunlight and offer enhanced adhesion and thermoplastic properties. Hence, real estate companies are selecting acrylic paints to differentiate themselves in the competitive real estate market. As a result, construction contractors will continue to buy more acrylic paint products thereby expanding the acrylic paints market. How is the acrylic paints market classified? Acrylic paint set out to be a medium for elementary use has gained a wide range of applications and preferences in recent times with diversified products. Acrylic paint has been treated as a type of medium that is suitable for kindergarten classrooms only over the past few decades. However, with the advancement of pigmentation, consistency and finishes, many artists – David Hockey, Helen Frankenthaler, Mark Rothko – prefer acrylic paints as an ideal choice for acrylic art. This changing preference has boosted the prominence of acrylic paints among artists over the years. In addition, the excellent properties of acrylic paint are broadening their adoption among artists, globally. Acrylic paints are low-maintenance mediums that do not require custom supplies such as conventional oil paints. They offer the benefits of enhanced consistency and texture. The versatile nature of acrylic paints is making them an ideal medium that allows artists to do acrylic painting on canvas. Artists are the key consumers of acrylic paints. Companies focused on stationery products are increasing their investments in acrylic paint, further creating lucrative prospects for manufacturers. Hence, the increasing adoption of acrylic paint as a professional medium of painting will continue to drive market growth in the coming years. PET Silica MAnticorrosion Pigments, Inkjet Receptive Coating, Matting Agentatting Agent,Anti Corrosive Pigment

The anti-corrosive pigment industry is a sector that produces and supplies pigments that can be used to protect metal surfaces from corrosion. These pigments are typically added to coatings, paints, and other protective coatings to enhance their corrosion resistance properties. The main function of anti-corrosive pigments is to create a barrier between the metal surface and the surrounding environment, preventing the metal from coming into contact with moisture, oxygen, and other corrosive agents. This helps to prolong the lifespan of metal structures and equipment, reducing maintenance and replacement costs. Anti-corrosive pigments can be classified into two main categories: inhibitive pigments and barrier pigments. The anti-corrosive pigment industry serves various sectors, including: 1. Coatings industry: Anti-corrosive pigments are widely used in the production of corrosion-resistant coatings for metal structures, such as bridges, pipelines, tanks, and offshore platforms. These coatings help to protect the metal surfaces from the harsh environmental conditions, including saltwater, humidity, and chemical exposure. 2. Automotive industry: Anti-corrosive pigments are used in automotive coatings to protect the metal body and components from corrosion. They are especially important in areas exposed to road salt, moisture, and other corrosive elements. 3. Construction industry: Anti-corrosive pigments are used in construction coatings for metal structures, such as steel beams, roofs, and facades. These coatings help to prevent corrosion and extend the lifespan of the structures. 4. Marine industry: Anti-corrosive pigments are used in marine coatings to protect ships, boats, and offshore structures from corrosion caused by saltwater exposure. These coatings are essential for maintaining the integrity and safety of marine vessels and infrastructure. 5. Industrial equipment industry: Anti-corrosive pigments are used in the production of coatings for industrial equipment, machinery, and appliances. These coatings protect the metal surfaces from corrosion caused by chemicals, moisture, and other harsh conditions. Overall, the anti-corrosive pigment industry plays a crucial role in providing solutions to protect metal surfaces from corrosion in various industries. The demand for these pigments is expected to grow as the need for durable and long-lasting coatings continues to rise. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

Eco solvent polyester canvas made by silica powder is a type of canvas material that is produced using eco-friendly solvents and incorporates silica powder in its composition. Silica powder is a fine white powder made from silicon dioxide, which is derived from natural sources such as quartz. The addition of silica powder to the polyester canvas enhances its properties and performance. Silica powder is known for its high strength, durability, and resistance to heat, chemicals, and UV radiation. When incorporated into the polyester canvas, it improves the canvas's resistance to tearing, stretching, and fading, making it suitable for long-lasting outdoor use. Moreover, the use of eco-friendly solvents in the production process reduces the environmental impact associated with traditional solvent-based manufacturing methods. These solvents are often derived from renewable sources and have lower VOC emissions, making them safer for both the environment and human health. Eco solvent polyester canvas made by silica powder is commonly used in various applications, including outdoor banners, signage, art prints, and backdrops. Its durability and resistance to environmental factors make it ideal for outdoor use, where it can withstand harsh weather conditions without deteriorating. Overall, eco solvent polyester canvas made by silica powder offers a sustainable and durable alternative to traditional canvas materials, providing excellent print quality and longevity while reducing the environmental footprint. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

Cast coated paper is a type of paper that has a smooth, glossy finish. It is commonly used for printing high-quality images and graphics, such as in magazines, brochures, and advertisements. One of the key components in the production of cast coated paper is silica powder. Silica powder is a fine white powder made from silica, which is a naturally occurring mineral found in rocks and sand. It is primarily composed of silicon dioxide (SiO2). Silica powder is added to the paper coating mixture to enhance the smoothness and glossiness of the paper surface. It acts as a filler and helps to fill in any irregularities or roughness on the paper surface, resulting in a more even and glossy finish. In addition to improving the paper's appearance, silica powder also contributes to the printability and ink absorption of the paper. It helps to prevent ink from spreading or bleeding on the paper surface, ensuring sharp and vibrant print results. Furthermore, silica powder also enhances the paper's durability and resistance to moisture. It helps to make the paper more resistant to smudging, smearing, and water damage, making it suitable for applications that require high-quality and long-lasting prints. Overall, the addition of silica powder in cast coated paper production plays a crucial role in achieving the smooth, glossy, and high-quality finish that is desired for printing purposes. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

Medical PET film is a type of film made from polyethylene terephthalate (PET) that is used in various medical applications. PET is a strong, transparent, and flexible plastic material that is commonly used in packaging, but its properties also make it suitable for medical purposes. Medical PET film is often used as a protective barrier in medical devices and equipment. It can be used to cover and protect medical instruments, such as surgical tools, to prevent contamination and maintain sterility. PET film can also be used as a barrier in medical packaging, such as blister packs, to protect the contents from moisture, oxygen, and other contaminants. In addition to its protective properties, medical PET film is also used in medical imaging. PET imaging is a type of nuclear medicine imaging technique that uses radioactive tracers to visualize metabolic processes in the body. PET film is used as a substrate for the radioactive tracer, allowing for accurate detection and imaging of various medical conditions, such as cancer, cardiovascular diseases, and neurological disorders. Overall, medical PET film plays a crucial role in maintaining sterility, protecting medical instruments and devices, and enabling accurate medical imaging in various healthcare settings. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent

Of a product by enhancing its appearance, improving its durability, and increasing its performance. Matting agents are additives that are used in various industries, including paints, coatings, inks, plastics, and cosmetics. In the paint and coatings industry, matting agents are added to achieve a matte or satin finish. They reduce the glossiness of the surface, giving it a more subdued and elegant appearance. This is especially useful in applications where a glossy finish is not desired, such as in furniture, automotive interiors, and architectural coatings. Matting agents also improve the durability of the product by providing scratch and abrasion resistance. They create a protective layer on the surface, preventing damage from daily wear and tear. This is particularly important in applications where the product is exposed to harsh conditions or frequent handling. Furthermore, matting agents can enhance the performance of a product by improving its adhesion properties. They promote better bonding between the coating and the substrate, ensuring a long-lasting and reliable finish. This is crucial in applications where the product needs to withstand extreme temperatures, moisture, or chemical exposure. In the cosmetics industry, matting agents are used in various products such as foundations, powders, and lipsticks. They help to control shine and oiliness, giving the skin a matte and velvety appearance. Matting agents also improve the longevity of the product, preventing it from smudging or fading throughout the day. Overall, matting agents play a vital role in enhancing the visual appeal, durability, and performance of various products. They can transform a glossy surface into a matte one, improve the product's resistance to wear and tear, and enhance its adhesion properties. Whether it's in paints, coatings, plastics, or cosmetics, matting agents can truly change the life of a product. Anticorrosion Pigments, Inkjet Receptive Coating, Matting Agent