Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength.
Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength.
Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength.
Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength.
Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength.
Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength.
Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength.
Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength.
Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength.
Usage: 90%-99% inert alumina ceramic rings are widely used in petroleum, chemical, natural gas, and environmental protection industries. They are used as support materials for catalyst coverage in the reactor. Their main function is to increase gas or liquid distribution points and support and protect active catalysts with low strength
With its high strength, high hardness, high wear resistance, large specific gravity, small size, heat and corrosion-resistant and pollution-free, the product is widely used in precision processing and deep processing of various ceramics, enamels, glasses and thick and hard materials in chemical factories, as grinding media for fine crushing machines like ball mills, can-type mills, and vibration mills, with significantly higher crushing and milling efficiency and wear resistance than common ball stone or natural cobblestone
With its high strength, high hardness, high wear resistance, large specific gravity, small size, heat and corrosion-resistant and pollution-free, the product is widely used in precision processing and deep processing of various ceramics, enamels, glasses and thick and hard materials in chemical factories, as grinding media for fine crushing machines like ball mills, can-type mills, and vibration mills, with significantly higher crushing and milling efficiency and wear resistance than common ball stone or natural cobblestone.
Widely used as underlying packing material for the hydrocracking systems, refining systems, CRCC systems, isomerizing systems and demethylating systems of petrochemical plants, chemical fiber plants, alkyl benzene plants, aromatic plants, ethylene plants and natural gas plants, and as the supporting or covering material for catalysts, molecule sieves and dryers inside reactors and packing material for towers. Its primary purpose is to increase the gas or liquid distribution points, and support and protect less strong active catalysts. Features: High purity, large strength; heat, high pressure, and strong acid corrosion resistant; sound thermal vibration stability and stable chemical performance
Widely used as underlying packing material for the hydrocracking systems, refining systems, CRCC systems, isomerizing systems and demethylating systems of petrochemical plants, chemical fiber plants, alkyl benzene plants, aromatic plants, ethylene plants and natural gas plants, and as the supporting or covering material for catalysts, molecule sieves and dryers inside reactors and packing material for towers. Its primary purpose is to increase the gas or liquid distribution points, and support and protect less strong active catalysts. Features: High purity, large strength; heat, high pressure, and strong acid corrosion resistant; sound thermal vibration stability and stable chemical performance
Widely used as underlying packing material for the hydrocracking systems, refining systems, CRCC systems, isomerizing systems and demethylating systems of petrochemical plants, chemical fiber plants, alkyl benzene plants, aromatic plants, ethylene plants and natural gas plants, and as the supporting or covering material for catalysts, molecule sieves and dryers inside reactors and packing material for towers. Its primary purpose is to increase the gas or liquid distribution points, and support and protect less strong active catalysts. Features: High purity, large strength; heat, high pressure, and strong acid corrosion resistant; sound thermal vibration stability and stable chemical performance
Widely used as underlying packing material for the hydrocracking systems, refining systems, CRCC systems, isomerizing systems and demethylating systems of petrochemical plants, chemical fiber plants, alkyl benzene plants, aromatic plants, ethylene plants and natural gas plants, and as the supporting or covering material for catalysts, molecule sieves and dryers inside reactors and packing material for towers. Its primary purpose is to increase the gas or liquid distribution points, and support and protect less strong active catalysts. Features: High purity, large strength; heat, high pressure, and strong acid corrosion resistant; sound thermal vibration stability and stable chemical performance
Widely used as underlying packing material for the hydrocracking systems, refining systems, CRCC systems, isomerizing systems and demethylating systems of petrochemical plants, chemical fiber plants, alkyl benzene plants, aromatic plants, ethylene plants and natural gas plants, and as the supporting or covering material for catalysts, molecule sieves and dryers inside reactors and packing material for towers. Its primary purpose is to increase the gas or liquid distribution points, and support and protect less strong active catalysts. Features: High purity, large strength; heat, high pressure, and strong acid corrosion resistant; sound thermal vibration stability and stable chemical performance
Widely used as underlying packing material for the hydrocracking systems, refining systems, CRCC systems, isomerizing systems and demethylating systems of petrochemical plants, chemical fiber plants, alkyl benzene plants, aromatic plants, ethylene plants and natural gas plants, and as the supporting or covering material for catalysts, molecule sieves and dryers inside reactors and packing material for towers. Its primary purpose is to increase the gas or liquid distribution points, and support and protect less strong active catalysts. Features: High purity, large strength; heat, high pressure, and strong acid corrosion resistant; sound thermal vibration stability and stable chemical performance
The high alumina heat storage ball is also called a spherical heat storage body, and the spherical heat storage body has the advantages of good thermal shock stability, large heat storage capacity, high strength, easy cleaning, and reusability. Working principle and characteristics of high alumina heat storage ball 1. High alumina heat storage ball is a small ball that divides the airflow into small streams. When the airflow flows through the heat conductor, it forms a strong turbulent flow, effectively breaks the surface layer of the heat conductor surface, and because the ball diameter is very small, small conduction radius, small thermal resistance, high density, good thermal conductivity, so the requirements of frequent and rapid commutation of the heat-conductive burner can be realized. 2. The heat conductor can be reversed by 20~30 times/h. After the high-temperature smoke flow passes through the bed of the heat conductor, the flue gas can be reduced to about 130 °C. 3. The high-temperature gas and air flowing through the heat conductor can be preheated to the same temperature only about 100 ° C lower than the flue gas temperature, and the temperature efficiency is as high as 90% or more. 4. Due to the compact size of the thermal conductor, coupled with the high circulation capacity of the high aluminum heat storage ball bed, even if the resistance increases after the accumulation of ash does not affect the heat exchange index. 5. High alumina heat storage ball has the characteristics of strong oxidation resistance and slag resistance. 6. High alumina heat storage ball replacement and cleaning are very convenient and can be reused. High alumina heat storage ball use: widely used in steel, metallurgical industry heating furnace, alumina melting furnace, forging furnace and other industrial furnaces. It is especially suitable for air storage equipment regenerators and steel furnace blast furnace gas heating furnaces as heat storage fillers. By double preheating the gas and air, the combustion temperature can quickly reach the requirements of steel slab heating. High alumina heat storage ball main specifications: Φ3, 6, 8, 10, 13, 16, 19, 25mm High alumina heat storage ball alumina content: 92% 95% 99 High alumina heat storage ball packaging: double-layer polyethylene woven bag with a net weight of 25kg, plus tray Win-Ceramic product advantages: high strength, wear resistance, rapid cold resistance, long use time, and cost-effective with imported porcelain balls
With its high strength, high hardness, high wear resistance, large specific gravity, small size, heat and corrosion-resistant and pollution-free, alumina grinding column is widely used in precision processing and deep processing of various ceramics, enamels, glasses and thick and hard materials in chemical factories, as grinding media for fine crushing machines like ball mills, can-type mills, and vibration mills, with significantly higher crushing and milling efficiency and wear resistance than common ball stone or natural cobblestone. The alumina produced by Shandong Aluminum is used as the base material, which provides high purity, little impurity, and stable quality. Production is implemented on kanban basis and the entire production process is controllable and traceable. Each batch of product is strictly tested. The process and result guarantee stable performance and proven quality of the final product.
