Hunan Yibeinuo New Material Co., Ltd.
About Us
Your Professional & Reliable Partner.
YIbeino New Materials focuses on the research and development of new wear-resistant ceramic materials and is committed to providing material conveying, pneumatic conveying system engineering design and equipment wear problems under various complex working conditions for cement, thermal power, steel, coal, port, chemical, new energy, mineral processing, engineering machinery, concrete pipe pile, and other industries. We have 20 years of industry experience in the field of wear-resistant materials...
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Year Established

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Million+
Employees

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Million+
Customers Served

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Million+
Annual Sales
China Hunan Yibeinuo New Material Co., Ltd. Strict quality assurance system
Each process is strictly carried out in accordance with quality standard procedures, and the quality control process is strictly supervised to ensure that each factory product meets the national standards for wear-resistant ceramics.
China Hunan Yibeinuo New Material Co., Ltd. Leading design and R&D capabilities
Our company has a professional R&D team composed of experts in alumina ceramics and wear-resistant ceramic installation engineers. Through nearly 20 years of accumulated equipment anti-wear experience, we provide customers with customized equipment anti-wear solutions and provide enterprises with reduced costs and increased efficiency.
China Hunan Yibeinuo New Material Co., Ltd. Strong production capacity
It has advanced alumina ceramic production lines and modern steel structure processing plants.
China Hunan Yibeinuo New Material Co., Ltd. Quick response service
Quotation provided within 12 hours Provide anti-wear solutions 24 hours a day Convenient delivery channels: car, train, plane, sea transportation, etc.

quality Wear Resistant Ceramic Pipe & Alumina Ceramic Pipe manufacturer

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Reducing Hydrocyclone Wear in a Sand Washing Plant with 95% Alumina Ceramic Lining
Background A sand washing plant was experiencing frequent wear inside its hydrocyclone system. The hydrocyclone was used for fine particle separation, mud removal, and sand classification. Because the slurry contained abrasive sand particles and operated at high velocity, the internal wall of the cyclone was exposed to continuous impact and erosion. At the beginning of the operation, the system could maintain normal classification performance. However, after several months of use, the plant began to notice changes in the hydrocyclone’s performance. The inner wall became rough, the liner showed local wear, and the classification result became less stable. Maintenance teams had to inspect and repair the cyclone more frequently, which increased downtime and labor costs. The customer’s main concern was not simply replacing a worn liner. Their real concern was production stability. Every shutdown affected the sand washing line, reduced output, and increased the pressure on maintenance planning. The Problem The original liner material could not provide enough resistance against long-term slurry abrasion. In this type of working condition, sand particles continuously hit the cyclone wall under high-speed rotational flow. The most serious wear usually appears near the feed inlet, cone section, and underflow area. Once these areas are worn, the internal geometry of the cyclone changes, which affects the slurry flow pattern. The plant faced several practical problems: Frequent liner inspection and replacement Localized wear near high-impact areas Unstable classification performance after internal surface wear Higher spare parts and maintenance labor costs Production interruptions caused by unplanned maintenance For the plant manager, the biggest issue was that the hydrocyclone had become a maintenance-sensitive component. Even if the replacement cost of each liner was acceptable, the hidden cost of shutdown was much higher. Root Cause Analysis After reviewing the operating conditions, the main cause was identified as high-abrasion slurry impact. The hydrocyclone was handling sand and slurry with continuous particle movement. Under centrifugal force, abrasive particles repeatedly contacted the internal wall. Traditional metal or rubber surfaces could not maintain their shape and smoothness for long periods under these working conditions. The problem was not only material wear. Once wear developed on the inner wall, the cyclone’s separation environment also changed. The flow became less stable, and this affected classification consistency. In other words, the liner was not just a protective layer. It directly influenced the equipment’s operating performance. Engineering Solution To improve wear resistance and stabilize long-term operation, a hydrocyclone with 95% alumina ceramic lining was recommended. The solution used a metal shell as the structural body and high-density alumina ceramic tiles as the internal wear protection layer. The ceramic lining was designed according to different areas of the hydrocyclone, including the cylinder section, cone section, feed inlet, overflow area, and underflow nozzle. Small ceramic tiles were used to match the curved internal surface. This allowed the ceramic lining to fit the cyclone geometry more closely and reduce gaps between tiles. A staggered ceramic layout was selected for better bonding stability. During installation, the internal surface was cleaned and prepared before ceramic bonding. The ceramic tiles were installed tightly, and the gaps were controlled to help prevent slurry penetration behind the liner. After curing, the inner surface formed a smooth and wear-resistant protection layer. Why 95% Alumina Ceramic Was Selected 95% alumina ceramic was selected because it provides high hardness, strong abrasion resistance, and good stability under slurry erosion. Compared with rubber liners, ceramic lining has much higher resistance to hard particle impact. Compared with metal liners, ceramic does not suffer the same level of erosion and corrosion under abrasive slurry flow. For this application, the plant needed a lining material that could do more than survive wear. It had to maintain a smooth flow surface and support stable classification performance over time. This is why alumina ceramic was a better choice than simply increasing metal thickness. Result and Value After upgrading to the ceramic-lined hydrocyclone, the plant expected a significant improvement in service life and maintenance stability. The ceramic lining provided a more durable internal wear surface, reducing the need for frequent liner replacement. The smoother inner wall also helped maintain a more stable slurry flow path, supporting consistent particle classification. The key value for the customer included: Longer hydrocyclone liner service life Reduced maintenance frequency Lower spare parts consumption Less unplanned downtime More stable classification performance Lower total maintenance cost over time For the plant, the most important benefit was not only the ceramic material itself, but the improvement of production continuity. When the hydrocyclone runs longer without frequent maintenance interruption, the entire sand washing system becomes easier to manage. Engineering Conclusion In abrasive slurry systems, hydrocyclone wear is not just a spare parts problem. It is a production stability problem. If the internal surface wears too quickly, the classification system becomes unstable, maintenance costs increase, and plant operation becomes harder to control. The 95% alumina ceramic-lined hydrocyclone provides a practical solution by protecting the internal wear surface directly. For sand washing plants, mining beneficiation systems, coal preparation plants, and other slurry classification operations, ceramic lining can help extend service life, reduce downtime, and improve long-term operating reliability.
Extending Rotary Valve Service Life in a Fly Ash Pneumatic Conveying System
Project Background A thermal power plant operating multiple fly ash collection and conveying systems was experiencing persistent maintenance issues with its rotary discharge valves. The plant used conventional alloy steel rotary valves beneath baghouse dust collectors to discharge fly ash into a dense-phase pneumatic conveying system. Although the valves met the original design specifications, actual operating conditions proved far more demanding than anticipated. The fly ash contained a high percentage of hard silica particles, resulting in continuous erosion of the rotor blades and valve chamber. Challenges Faced by the Customer Within several months of operation, maintenance personnel observed significant wear in the rotor assembly. The primary problems included: Increasing air leakage Loss of conveying pressure stability Reduced feeding consistency Frequent valve replacement Unexpected production interruptions Maintenance records showed that each shutdown required not only valve replacement but also line cleaning and system recalibration, increasing labor costs and reducing overall plant efficiency. The customer was seeking a longer-term solution capable of surviving continuous abrasive service. Solution Implemented After reviewing the operating conditions, an alumina ceramic-lined rotary discharge valve was selected. The replacement valve featured: CF8 stainless steel valve body High-purity alumina ceramic-lined rotor Fully ceramic-lined rotating chamber Integrated ceramic bushing structure Precision ceramic-to-ceramic sealing surfaces Unlike conventional wear-resistant coatings, the ceramic liner formed the primary wear surface throughout the material contact zone. This design prevented direct exposure of the metal structure to abrasive fly ash Operational Results Following installation, plant operators monitored the valve during routine inspections. Several performance improvements became immediately apparent. First, conveying pressure remained significantly more stable because internal clearances showed minimal wear progression. Second, the ceramic-lined surfaces reduced material accumulation inside the valve chamber, helping maintain consistent discharge performance. Most importantly, the valve demonstrated substantially longer operational life compared with the previous alloy steel design. The maintenance team reported a significant reduction in unscheduled downtime, allowing maintenance resources to be allocated to other critical equipment. Engineering Analysis The success of the project was largely attributed to the wear resistance of high-purity alumina ceramic. In fly ash conveying applications, wear occurs primarily through particle impact and sliding abrasion. Traditional metal surfaces gradually deform and erode under these conditions. Alumina ceramic, however, maintains its dimensional stability and surface integrity for much longer periods, preserving both sealing performance and feeding accuracy. Because wear progression is dramatically slowed, the entire conveying system benefits from improved reliability. Conclusion For facilities handling fly ash, cement powder, silica powder, mineral fines, or battery materials, rotary valve wear is often one of the leading causes of maintenance-related downtime. This project demonstrates that upgrading to a ceramic-lined rotary discharge valve can significantly improve operational reliability, reduce maintenance frequency, and lower overall lifecycle costs. Rather than repeatedly replacing worn metal components, many plants are now investing in wear-resistant ceramic technology to achieve longer production cycles and more predictable equipment performance.
Why Ceramic-Lined Rotary Valves Are Replacing Traditional Metal Airlocks in Abrasive Powder Handling
In many pneumatic conveying systems, rotary discharge valves are often considered minor components. However, experienced maintenance engineers know that airlocks are frequently among the first pieces of equipment to fail when handling abrasive powders. Across industries such as cement production, lithium battery materials, fly ash processing, silica powder handling, and mineral powder conveying, plant operators are reporting the same problem: traditional metal rotary valves wear far faster than expected, resulting in unstable feeding, air leakage, increased maintenance costs, and unexpected shutdowns. As production lines continue to pursue higher efficiency and longer operating cycles, ceramic-lined rotary valves are rapidly becoming the preferred solution for severe wear applications. The Hidden Cost of Rotary Valve Wear In abrasive conveying systems, the rotor blades and valve chamber are continuously exposed to high-velocity particles. While conventional cast iron, carbon steel, or even alloy steel rotary valves may perform adequately during the early stages of operation, continuous particle impact gradually enlarges internal clearances between the rotor and housing.   Once wear reaches a critical level, several operational problems begin to appear: Loss of airlock efficiency Increased pressure fluctuation within the conveying line Material leakage and dust emissions Reduced feeding accuracy Frequent maintenance interruptions For facilities operating 24 hours a day, these seemingly small failures often translate into substantial production losses. Why Alumina Ceramic Has Become the Preferred Wear Material The growing adoption of alumina ceramic technology is largely driven by its exceptional resistance to abrasive wear. High-purity alumina ceramic exhibits hardness levels approaching those of industrial diamonds, allowing it to withstand continuous particle erosion that rapidly damages conventional metals. Unlike surface coatings or spray-applied wear layers, integrated ceramic liners provide a complete wear-resistant structure throughout the critical material flow path. This is particularly important in rotary valves because both the rotor and the valve chamber experience constant contact with abrasive materials. By isolating metal components from direct material impact, ceramic-lined designs significantly extend service life while maintaining sealing performance over longer operating periods. Growing Demand from the Lithium Battery Industry One of the fastest-growing application sectors for ceramic-lined rotary valves is lithium battery material processing. Battery manufacturers handle highly abrasive powders such as: Lithium iron phosphate (LFP) Graphite powder Cathode materials Anode materials Conductive additives In addition to wear resistance, these applications require a low risk of contamination and consistent conveying performance. Traditional metal valves can introduce metallic contamination through wear debris, creating potential quality concerns during battery production. Ceramic-lined structures help minimize this risk while simultaneously improving equipment durability. A Shift from Reactive Maintenance to Predictive Reliability Historically, many plants accepted rotary valve replacement as a routine maintenance activity. Today, manufacturers are increasingly focusing on lifecycle cost rather than initial purchase price. Although ceramic-lined rotary valves typically involve a higher upfront investment, many operators find that the reduction in spare parts consumption, maintenance labor, and production downtime delivers a substantially lower total cost of ownership over the equipment's operating life. For facilities handling highly abrasive powders, the discussion is no longer whether wear will occur, but how effectively it can be controlled. As industries continue to demand longer operating cycles and more stable conveying performance, ceramic-lined rotary discharge valves are emerging as one of the most practical upgrades available for modern powder handling systems.  

2026

06/01

New Anti-Wear Solution Gains Global Traction: Alumina Ceramic Embedded Rubber Hose Optimizes Conveying Systems for Minin
As a professional anti-wear solution provider serving global industrial clients for years, we are pleased to announce that our core product — alumina ceramic embedded rubber hose — has been widely adopted across mining, oil & refinery, chemical, metallurgy, and bulk material transportation industries worldwide. This composite hose perfectly balances wear resistance, flexibility, oil resistance, and pressure resistance, effectively solving the long-standing pain points of frequent hose replacement, high maintenance costs, and production downtime that trouble procurement and operation teams across multiple sectors. Traditional rubber hoses suffer from severe abrasion when transporting slurry, granular materials, and oily media, while rigid steel pipes are bulky, inflexible, and costly to install. To bridge this gap, we adopted a dual-material composite structure: inner walls are inlaid with high-purity hexagonal alumina ceramic tiles (Al₂O₃ ≥ 95%) with ultra-high hardness to resist continuous scouring and chemical corrosion. The outer layer is made of high-toughness nitrile rubber, reinforced with polyester canvas and high-elasticity steel wire, enabling the hose to withstand a working pressure of 1.0–2.5 MPa and continuous operation under temperatures up to 100°C. Different from ordinary wear-resistant hoses, the neatly arranged hexagonal ceramic tiles allow large-angle bending without lining detachment, which adapts to complex pipeline layouts in factories, mines, and oilfields. From the perspective of procurement and operational management, this product brings tangible economic benefits to enterprises. Its service life is 3 to 10 times longer than standard rubber hoses, which greatly cuts down purchasing frequency, inventory pressure, and emergency procurement risks. The lightweight design (only 30% of the weight of steel pipes) simplifies transportation and installation work. The smooth ceramic inner wall reduces flow resistance and pressure loss, helping enterprises save energy consumption of pumping equipment. Meanwhile, multiple connection methods, including flanges, threaded joints, and quick couplers, are available, and customized sizes ranging from DN25 to DN300 mm with a maximum length of 10 meters can be provided to meet the personalized demands of different working conditions. Up to now, our ceramic-embedded rubber hoses have been exported to Southeast Asia, the Middle East, South America, Africa, Eastern Europe, and Oceania. We maintain a stable delivery cycle of 15–30 days for regular orders, and support sea, air, and land transportation with both FCL and LCL services to guarantee on-time delivery for overseas clients. In the future, our anti-wear technical team will continue to optimize product formulas and structural design according to the operating characteristics of different regions and industries. We will provide one-stop customized anti-wear pipeline solutions for global partners, helping every customer reduce comprehensive operating costs and achieve stable and efficient production.

2026

06/09

New Ceramic-Lined Hydrocyclone Solution for Abrasive Slurry Classification
Hydrocyclones are widely used in sand washing, mineral processing, coal preparation, and slurry classification systems. In these operating environments, the equipment is not only responsible for separating fine particles, mud, and valuable minerals, but also exposed to continuous abrasion from high-speed slurry flow. For many plants, the real challenge is not whether the hydrocyclone can separate materials, but how long it can maintain stable performance before wear starts to affect production. To help plants reduce frequent maintenance and improve equipment stability, Elacera introduces a stainless steel hydrocyclone with 95% alumina ceramic lining, designed for high-abrasion slurry conditions. This solution combines the structural strength and corrosion resistance of stainless steel with the excellent wear resistance of high-density alumina ceramic tiles. In many field applications, traditional metal liners and rubber liners are still used inside hydrocyclones. However, under continuous impact from sand, ore particles, coal slurry, or other abrasive materials, these liners often wear quickly. Once the internal surface becomes rough or uneven, the cyclone flow pattern may become unstable. This can lead to lower classification accuracy, higher energy consumption, more frequent replacement, and unexpected production shutdowns. The new ceramic-lined hydrocyclone is designed to solve this problem from the wear surface itself. Instead of relying only on the steel shell, the internal working surface is protected by 95% alumina ceramic tiles. The ceramic lining provides high hardness, strong erosion resistance, and a smooth internal flow path, helping the cyclone maintain stable slurry movement during long-term operation. One of the key design features is the small-tile ceramic lining layout. Compared with large flat liners, small ceramic tiles can better adapt to the curved internal structure of the hydrocyclone, including the cylinder section, cone section, feed inlet, overflow area, and underflow nozzle. This mosaic lining design helps reduce gaps and improve the bonding strength between the ceramic and the metal shell. For high-impact and dynamic slurry conditions, the ceramic tiles are installed with a staggered layout to improve stability and reduce the risk of liner detachment. The smooth ceramic surface is also important for classification performance. In hydrocyclone operation, the slurry must maintain a stable tangential velocity and vortex flow. If the internal wall becomes rough due to wear, the flow path changes, and separation efficiency may decline. With a properly installed ceramic lining, the height difference between ceramic tiles can be controlled within a small range, helping maintain smoother slurry movement and reducing energy loss. This product is suitable for a wide range of industries, including sand washing plants, aggregate processing lines, coal preparation plants, ferrous and non-ferrous metal beneficiation, quartz sand processing, and other slurry classification systems. It is especially useful in working conditions where traditional liners require frequent replacement or where the shutdown cost is higher than the liner cost itself. For plant owners and maintenance teams, the value of ceramic lining is not only longer service life. It also helps reduce spare parts consumption, lower labor maintenance pressure, improve production continuity, and stabilize classification performance. In some abrasive slurry conditions, alumina ceramic liners can provide much longer service life than rubber or metal liners, helping customers reduce total operating cost over the equipment lifecycle. Elacera can customize hydrocyclone ceramic lining solutions according to equipment size, slurry properties, operating pressure, particle hardness, flow velocity, and maintenance requirements. Different ceramic thicknesses and lining structures can be selected based on actual working conditions. For large-diameter cyclones or high-hardness materials, a thicker ceramic lining can be recommended to improve wear protection. As an industrial wear protection solution provider, Elacera focuses not only on ceramic materials, but also on how the lining performs inside real equipment. From material selection and structural design to installation details and maintenance guidance, the goal is to help customers solve wear problems at the source and keep their production systems running longer and more reliably. If your hydrocyclone system is facing frequent liner replacement, unstable classification, or high maintenance costs, a stainless steel hydrocyclone with 95% alumina ceramic lining can be a practical engineering upgrade for long-term wear protection.

2026

07/01