FAQs

• Quality Assurance:
Lvyuan prioritizes quality as a cornerstone of its operations. We adhere to rigorous quality control standards throughout the manufacturing process to ensure that our products meet the highest industry standards.

• Innovative Technology:
We leverage cutting-edge technologies in the design and production of our products. By staying at the forefront of technological advancements, we provide our customers with innovative solutions that meet their evolving needs.

• Diverse Product Range:
Lvyuan offers a comprehensive and diverse range of products, catering to various industries and applications. Our extensive product portfolio allows customers to find solutions tailored to their specific requirements.

• Customization Capabilities:
Recognizing the unique needs of our customers, we provide customizable options for our products. This ensures that our clients receive tailored solutions that align with their individual preferences and applications.

• Competitive Pricing:
We are committed to offering competitive prices without compromising on quality. Our cost-effective solutions enable customers to access high-quality products at reasonable and competitive market rates.

Lvyuan was established on October 12, 2009

Lvyuan is located in Guangzhou, Guangdong Province, China.

Of course, we are in Panyu District, Guangzhou City, Guangdong Province, China.

Stainless steel filter housing, sintered metals, plastic PE filters, and other filter elements.

• Sintered metal filters: 10,000 sets per month.
• Filter housings: 5000 sets/month.
• PE filters: 100000 pcs/month.
• And our production capacity is growing.

Please tell me the model or specification you need, such as material, length, size, industry, etc.

We maintain high-quality standards and competitive prices to ensure mutual benefits for our customers. We treat every customer with respect, considering them not only as clients but also as friends. We engage in sincere business dealings and aim to build lasting friendships, regardless of their geographical location.

Certainly, we have the capability to customize filter housing and filter elements according to your specific application. Our customization process adheres completely to your provided drawings, requirements, logo, and any other specifications you may have.

Yes, we can produce your samples or technical drawings. We can build the molds and fixtures.

Tooling charges only once per first order; all future orders would not be charged again, even for tooling repairs or maintenance.

We can supply the sample if we have ready parts in stock, but the customers have to pay the sample cost and the courier cost.

Always take a pre-production sample before mass production.

Our state-of-the-art testing equipment and rigorous adherence to quality control standards ensure that our filter housings and filter elements comply with ISO 9001.

Yes, we have a 100% test before delivery.

Generally, it will take 10 to 15 days after receiving your advance payment. The specific delivery time depends on the items and the quantity of your order, and if the item is nonstandard, we have to consider an extra 10-15 days for tooling.

Yes, we offer customization services to tailor sintered metal filters to your unique specifications. This includes variations in size, shape, material, and micron rating to ensure the filter meets the specific demands of your application.

Sintered metal filters are porous materials made by compacting and heating metal powders without melting them completely. The process results in a rigid structure with interconnected pores, offering filtration capabilities for various applications.

We offer sintered metal filters in a range of materials, including stainless steel, bronze, nickel, and other alloys. The material selection depends on the specific requirements of the application.

Sintered metal filters are versatile and find applications in various industries such as pharmaceuticals, petrochemicals, food and beverage, water treatment, and more. They are commonly used for gas and liquid filtration.

Our sintered metal filters come in a variety of sizes and shapes to meet different application needs. Common configurations include cylindrical, disc, and tube shapes, with customizable dimensions to fit specific requirements.

The filtration efficiency depends on the micron rating and the type of material chosen. We offer a range of micron ratings to accommodate different filtration needs, ensuring the efficient removal of particles and contaminants.

Cleaning methods for sintered metal filters include backwashing, ultrasonic cleaning, and chemical cleaning. The method depends on the type of contaminants and the filter's specifications.

To select the appropriate sintered metal filter, consider factors such as the type of fluid or gas, desired flow rate, temperature, pressure, and particle size to be filtered. Our technical team can provide guidance based on your specific requirements.

Yes, our sintered metal filters conform to industry standards, and we ensure compliance with quality management systems such as ISO9001. This commitment reflects our dedication to delivering high-quality filtration solutions.

For inquiries, quotes, or additional information about our sintered metal filters, please contact our sales team through our website or by reaching out to [contact information]. We are happy to assist you with any questions or requirements you may have.

Yes, these cartridges can be customized in terms of dimensions, filtration ratings, materials, and end connections to suit the specific needs of different industrial processes.

How often should industrial-sintered metal filter cartridges be replaced?

The replacement frequency depends on the operating conditions and the level of contaminants in the process. Regular inspection and monitoring help determine the optimal replacement schedule.

An industrial sintered filter cartridge is a filtration component made through a sintering process, combining metal powders to create a porous structure. These cartridges are designed for industrial applications to remove contaminants from liquids and gases.

What materials are commonly used in industrial-sintered metal filter cartridges?

Common materials include stainless steel (304, 316, and 316L), bronze, Inconel, Monel, titanium, and other alloys, depending on the specific requirements of the application.

What are the key advantages of using industrial-sintered metal filter cartridges?

Advantages include high filtration efficiency, durability, wide temperature resistance, chemical compatibility, customization options, high flow rates, ease of cleaning, and versatility across various industries.

These cartridges find applications in petrochemicals, pharmaceuticals, water treatment, food processing, automotive, aerospace, and many other industries where precise and reliable filtration is essential.

What is the temperature range that industrial sintered metal filter cartridges can handle?

The temperature range varies based on the material used, but they can typically withstand temperatures from -200°C to 1000°C or even higher for certain alloys.

The replacement frequency depends on the operating conditions and the level of contaminants in the process. Regular inspection and monitoring help determine the optimal replacement schedule.

Yes, these cartridges are environmentally friendly due to their reusability and longer lifespan, contributing to reduced waste generation compared to disposable filters.

Cleaning methods include backwashing, ultrasonic cleaning, chemical cleaning, or a combination of these, depending on the type of contaminants and the cartridge material.

Consult with the manufacturer or supplier, providing details about your specific requirements, such as filtration needs, operating conditions, and industry standards, to receive guidance on selecting the most suitable cartridge for your application.

Yes, stainless steel filter housings can be customized to meet specific application requirements, including size, material of construction, inlet/outlet connections, pressure ratings, and mounting options.

The 304 or 316 stainless steel cartridge filter housing is a durable enclosure designed to hold filter cartridges or filter bags for the filtration of liquids or gases in industrial processes.

Stainless steel cartridge filter housings offer corrosion resistance, durability, and hygiene, making them suitable for use in a wide range of industries, including food and beverage, pharmaceuticals, chemicals, and water treatment.

Stainless steel filter housings are compatible with various types of filter elements, including cartridge filters, bag filters, membrane filters, and depth filters, allowing for flexibility in filtration applications.

Stainless steel filter housings come in different configurations, such as single-cartridge, multi-cartridge, and multi-bag designs, as well as inline and side-entry styles, catering to different flow rates and filtration requirements.

Stainless steel filter housings operate by passing the process fluid through the filter element, where contaminants are captured on the filter media, allowing the clean fluid to pass through and exit the housing.

Regular maintenance tasks for stainless steel filter housings may include replacing filter elements, cleaning or replacing gaskets and seals, inspecting for leaks or corrosion, and ensuring proper operation of valves and controls.

Yes, sintered porous filter discs are highly customizable. You can specify pore sizes, material preferences, disc diameter, and other parameters to meet the unique requirements of your application.

Yes, sintered plastic porous filters can be customized to meet specific application requirements, including pore size, shape, dimensions, and surface properties. Customizations may also include the addition of additives or reinforcements for enhanced performance.

Sintered plastic porous filters are available in a wide range of pore sizes, typically ranging from submicron to several hundred microns, allowing for precise control of filtration performance and particle retention.

A sintered plastic porous filter is a filtration device made from polymeric materials that are compressed and heated to form a porous structure with controlled pore sizes and distribution.

Sintered plastic porous filters offer several advantages, including chemical resistance, high temperature resistance, compatibility with a wide range of fluids, uniform pore size distribution, and excellent filtration efficiency.

Sintered plastic porous filters are used in various industries, such as pharmaceuticals, food and beverage, water treatment, automotive, aerospace, and electronics, for filtration, separation, venting, and fluidization applications.

Common polymers used in the production of sintered plastic porous filters include polyethylene (PE), polypropylene (PP), polytetrafluoroethylene (PTFE), and polyvinylidene fluoride (PVDF), among others.

Sintered plastic porous filters are manufactured through a process of molding, sintering, and machining. This involves compacting the polymer particles into a desired shape, heating them to a specific temperature to fuse the particles together, and then machining the filter to achieve the desired dimensions and surface finish.

Cleaning methods depend on the material used. For metal discs, methods may include backwashing, ultrasonic cleaning, or chemical cleaning. Polyethylene discs are often cleaned with mild detergents. Regular maintenance ensures a prolonged operational life.

Porous metal filters stand as specialized filtering tools employed in applications where conventional filtration equipment falls short. Typically, metals undergo a sintering process, transforming them into porous or powdered structures, ensuring a more effective filtration process.

Technically, sintering is a metallurgical method applied to solidify metals or alloys into a powdered form. This involves heating the metal or alloy below its melting point to create an intense solid structure with a specific number of pores.

Here are some main types of porous filters used across various industrial applications:

• Sintered Porous Metal Filter: These filters boast pores for effective filtration and are crafted to withstand high pressure and mechanical stress. Manufacturing involves sintering plastic and high molecular polymer powder at elevated temperatures.

• Porous Stainless Steel: Utilizing grade 316 steel, these high-performance filters offer excellent pressure and temperature resistance, ideal for harsh conditions.

• Porous Discs: Shaped as filter discs, these filters are designed with precise pore sizes and numbers for efficiency in specific applications.

• Sintered Metal Filter: Tailored for high industrial and commercial demands, these filters accommodate the effective filtration of gases, liquids, and semi-solids.

• Porous Bronze Filter: Manufactured with spherical bronze powder, these filters excel in noise reduction and turbulence-proofing, making them a reliable choice across various industries.

Porosity, in the context of filtration, measures the pores on the filter surface, determining its efficiency and capabilities. Higher porosity indicates more open structures (pores), allowing maximum flow with minimal pressure drops.

However, it's crucial to note that a higher porosity rate doesn't necessarily guarantee greater efficiency. When selecting the right material for your porous metal filter, consider aspects such as pore size, pressure drop, temperature resistance, and strength.

• Size of Pores: Micron rating is crucial. A material rated at 5 microns will likely stop particles of 5 microns or larger.

• Pressure Drop: Choose a material with a minimum pressure drop for uniform flow.

• Temperature Resistance: Analyze the material's capability to perform efficiently under specific temperatures.

• Strength: Opt for a filter with the strength to withstand changing environmental conditions.

Filter porosity is classified into three major types: Primary Porosity, Secondary Porosity, and Effective Porosity. The calculation involves determining the ratio of the volume of gaps in the filter to the total volume, expressed as a percentage.

Porosity = (Volume of Empty Gaps/Total Volume of Filter) x 100

Other methods include:

• Direct Methods: Calculate the entire volume of the porous filter and the volume of a skeletal filter (without pores) to find the porosity.

• Computed Methods: Use modern computer technology to obtain a 3D image of a porous filter and employ defect analysis techniques.

• Water Evaporation Technique: Calculate porosity by determining the difference in weight between the saturated filter in water and the dried filter.

Consider factors such as the nature of the substances being filtered, operating conditions (temperature, pressure), chemical compatibility, and desired filtration precision. Consulting with filtration experts can help guide the selection process.

They are widely used in industries such as petrochemicals, pharmaceuticals, water treatment, food and beverage, automotive, and more, owing to their versatility and effective filtration capabilities.

Yes, depending on the material selected (e.g., stainless steel or nickel alloys), sintered porous filter discs can withstand high temperatures, making them suitable for applications involving elevated temperatures.

Yes, sintered porous filter discs can be designed for sterile filtration applications, especially when made from materials suitable for high-temperature and chemical sterilization methods.

They are designed for easy integration into existing filtration systems. The compact design allows for straightforward installation and replacement.

Sintered plastic porous filters can be cleaned using various methods, such as backwashing, ultrasonic cleaning, chemical cleaning, and steam sterilization, depending on the type of contaminants and the filter's compatibility with cleaning agents. Regular maintenance, such as inspection and replacement of filters, is essential to ensuring optimal performance.

Sintered titanium filters are porous metal components created through a sintering process, designed to provide efficient filtration in various applications.

Sintered titanium filters function by allowing fluid or gas to pass through their porous structure, capturing particles and impurities, resulting in effective filtration.

Sintered titanium filters are versatile and find applications in water treatment, gas diffusion, chemical experiments, and pharmaceutical processes due to their temperature resistance and corrosion resilience.

Yes, sintered titanium filters exhibit excellent resistance to corrosion from seawater and various chemicals, making them suitable for harsh and aggressive environments.

Machinability can be enhanced by selecting high-speed machining tools, creating conducive cutting environments, and using high-quality cutting tools to optimize cost, surface finishing, and integrity.

Yes, sintered titanium filters support easy cleaning, enabling reusability and minimizing operational costs over their extended lifespan.

With proper care and maintenance, sintered titanium filters can last up to 30 years, providing a durable and cost-effective solution for filtration needs.

Yes, sintered titanium filters support high flow rates at low-pressure drops, optimizing efficiency and ensuring consistent filtration performance.

Sintered titanium filters are capable of operating over a wide range of temperatures, adapting to diverse industrial settings and applications.

Sintered titanium filters are available in a wide range of micron ratings and configurations, offering tailored solutions for optimal performance across diverse applications.

Yes, sintered powder filters can be customized based on factors such as material, shape, pore size, micron rating, and filtration requirements to suit the unique needs of different applications.

A sintered powder filter is a porous filtration medium created by compacting and sintering metal powders. It is designed to provide efficient and precise filtration in various industrial applications.

Common materials include stainless steel (316L, 304L), bronze, Inconel®, Nickel, Monel®, Titanium, and other alloys. The material choice depends on the specific application's requirements.

Sintered powder filters offer high filtration efficiency, durability, resistance to temperature and corrosion, and customization options in terms of shape, pore size, and material.

The filtration accuracy is determined by the pore size and micron rating of the sintered powder filter. These parameters can be customized based on the application's particle filtration requirements.

Yes, sintered powder filters are designed to withstand high temperatures. The choice of material, such as stainless steel or other heat-resistant alloys, contributes to their temperature resistance.

Sintered powder filters are available in various shapes, including discs, tubes, metal filter cartridges, plates, porous metal sheets, and cups, providing versatility for different applications.

Many sintered powder filters are designed to be reusable. They can be cleaned through backwashing or other methods, contributing to their cost-effectiveness and sustainability.

Choosing the right sintered powder filter involves considering factors such as filtration accuracy, temperature and pressure requirements, material compatibility, and specific application needs. Consultation with experts is recommended for optimal selection.

Yes, sintered powder filters can be manufactured from corrosion-resistant materials, such as stainless steel or alloys like Inconel® and Monel®, making them suitable for use in corrosive environments.

Sintered metal filters are capable of withstanding a broad temperature range, often from -200°C to 1000°C, making them suitable for applications with extreme temperature variations.

Yes, sintered metal filters can be customized based on shape, size, material, filtration accuracy, and other specifications to meet the unique requirements of different applications.

A sintered metal filter is a porous material produced by compacting and heating metal particles to create a solid structure with interconnected pores. It is commonly used for filtration in various industries.

Sintered metal filters are typically made from stainless steel, such as 304 or 316, due to its corrosion resistance and durability. Other alloys, like Hastelloy or Inconel, may also be used based on specific application requirements.

Sintered metal filters offer high strength, durability, and resistance to temperature and corrosion. They provide precise filtration, are reusable, and suitable for diverse applications.

Sintered metal filters find applications in petrochemicals, water treatment, food and beverage, pharmaceuticals, automotive, and various industrial processes requiring precise filtration.

The filtration accuracy of sintered metal filters can vary. Common ranges include 1 to 200 microns, but customization allows for specific accuracy based on application needs.

Yes, sintered metal filters are designed to be cleaned and reused. Their durability and resistance to fouling make them suitable for applications where filter cleaning is necessary.

Sintered mesh filters work by trapping and retaining particles within the porous structure of the mesh. The sintering process fuses the mesh layers, creating a robust filter with uniform openings that allow controlled passage of fluids while capturing contaminants.

A sintered mesh filter is a porous metal filter element made by sintering multiple layers of woven wire mesh. It provides effective filtration for various applications, offering advantages such as durability, temperature resistance, and customizable filtration ratings.

Sintered mesh filters find applications in industries such as petrochemicals, pharmaceuticals, food and beverage, aerospace, and water treatment. They are used for filtration, dispersion, fluidization, and separation processes.

Yes, sintered mesh filters are highly customizable. They can be tailored based on factors such as filtration rating, material composition (e.g., stainless steel, monel), dimensions, and shape to meet the unique needs of different applications.

Sintered mesh filters can withstand a broad temperature range, typically from -200°C to 600°C. The temperature resistance depends on the material used in the filter construction.

Sintered mesh filters are generally easy to clean. They can be cleaned using methods such as backwashing, ultrasonic cleaning, or chemical cleaning. Regular maintenance helps extend the filter's lifespan and maintain optimal performance.

Sintered mesh filters provide advantages such as high filtration efficiency, strength, durability, and the ability to withstand challenging conditions. They offer a reliable and long-lasting solution for diverse filtration needs.

Yes, sintered mesh filters are suitable for high-pressure applications due to their robust construction. The sintering process enhances their mechanical strength, making them capable of withstanding high-pressure environments.

Yes, sintered mesh filters can be manufactured from corrosion-resistant materials such as stainless steel, making them suitable for use in corrosive environments.

To select the right sintered mesh filter, consider factors such as filtration requirements, material compatibility, temperature and pressure conditions, and specific application needs. Consult with the manufacturer for guidance on customization options.

Yes, sintered wire mesh can be customized in terms of material, pore size, thickness, and dimensions to suit specific filtration requirements. Customization allows for optimal performance in diverse applications.

Sintered wire mesh is a porous metal filtration material created by sintering multiple layers of woven wire mesh. The sintering process bonds the wires at their intersection points, creating a durable and uniform structure with precise filtration characteristics.

• High Strength: The sintered wire mesh filter exhibits excellent mechanical strength.

• Uniform Porosity: The sintering process creates a uniform pore structure for efficient filtration.

• Temperature Resistance: Suitable for applications with high temperatures.

• Easy to Clean: Can be cleaned and reused multiple times.

• Chemical Resistance: Resistant to corrosion and chemical exposure.

Sintered wire mesh filter finds applications in various industries, including:

• Filtration of liquids and gases.

• Polymer and chemical processing.

• Pharmaceutical and food processing.

• Aerospace and automotive industries.

• Environmental protection and water treatment.

While both types involve woven wires, sintered wire mesh undergoes an additional sintering process. This process fuses the wires together, creating a rigid and porous structure. Woven wire mesh relies on the mesh's openings for filtration, while sintered mesh utilizes the entire structure for efficient filtration.

Yes, sintered wire mesh is reusable. Its robust construction allows for cleaning and regeneration, making it a cost-effective and sustainable choice for filtration applications.

Sintered wire mesh can filter a wide range of contaminants, including particles, solids, and impurities from liquids and gases. The filtration efficiency depends on factors such as pore size and material selection.

Regular cleaning is the primary maintenance for sintered wire mesh. The cleaning frequency depends on the application and the type of contaminants being filtered. Follow the manufacturer's guidelines for proper maintenance.

Yes, sintered wire mesh is suitable for high-pressure applications due to its high strength and durable structure. However, specific pressure ratings may vary based on the material and design, so it's essential to consider these factors.

Consider factors such as material compatibility, pore size, thickness, and dimensions based on your application requirements. Consult with the manufacturer or supplier for expert guidance on selecting the most suitable sintered wire mesh for your specific needs.