Sintered sheets

some description about product

Sintered sheets are advanced filtering media composed of metal particles that are bonded together through a sintering process. Sintering involves applying heat and pressure to the metal particles, causing them to fuse and form a porous and rigid structure. The resulting it exhibits high mechanical strength, excellent chemical resistance, and precise filtration capabilities.

These sheets are commonly made from stainless steel, bronze, or other metal alloys. The choice of material depends on the specific application requirements, such as temperature resistance, corrosion resistance, and compatibility with the substances to be filtered.

The porosity of the sintered sheet can be tailored to achieve different filtration efficiencies. These sheets can offer high filtration precision with micron-level filtration capability. They can withstand high temperatures and differential pressures, making them suitable for demanding operating conditions.

Metal sintered sheets have advantages over traditional filter media, such as wire mesh or paper, due to their superior strength, durability, and resistance to clogging. They are easy to clean and can be reused multiple times, reducing waste and maintenance costs. The high performance and versatility of metal sintered sheets make them a reliable choice for critical filtration applications in various industries.


sintered stainless steel sheets

sintered stainless steel sheets

Sintered stainless steel sheets are made from stainless steel particles that are fused together through a sintering process.

The sintering method involves subjecting the stainless steel particles to high heat and pressure, causing them to bond and form a porous, rigid structure. The resulting sintered sheet exhibits excellent mechanical strength, high-temperature resistance, and outstanding corrosion resistance due to the inherent properties of stainless steel.

Sintered stainless steel sheets are widely used in various industrial applications, including petrochemical, pharmaceutical, food and beverage, aerospace, and automotive industries. These sheets are utilized for precise filtration, separation, and purification processes, effectively removing solids, impurities, and contaminants from liquids and gases.

The controlled porosity of the sintered sheet allows for micron-level filtration, offering high filtration efficiency and long-lasting performance. Sintered stainless steel sheets are a reliable and cost-effective solution for critical filtration requirements in challenging and harsh operating conditions.

porous metal sheet

porous metal sheet

Porous metal sheet is a specialized type of material with a network of interconnected pores or voids throughout its structure.These sheets are typically made

from metal particles or fibers that are bonded together through various methods like sintering, powder metallurgy, or metal foaming processes.

The controlled porosity of porous metal sheets allows them to exhibit unique properties that make them valuable in a wide range of applications. They offer high surface area, excellent permeability, and precise filtration capabilities. The size and distribution of the pores can be engineered to achieve specific filtration efficiency and flow rates.

Porous metal sheets find applications in diverse industries, including aerospace, automotive, chemical processing, electronics, healthcare, and environmental technologies. They are used for filtration, separation, diffusion, fluidization, and gas or liquid dispersion processes.

high porosity sintered sheets

high porosity sintered sheets

High porosity sintered sheets are typically composed of metal particles or fibers that are tightly fused together through a

sintering process, creating a porous structure with a high volume fraction of interconnected voids.

The high porosity of these sintered sheets enables them to offer excellent permeability and filtration efficiency. They can effectively capture and retain particles, impurities, and contaminants from gases or liquids while allowing for smooth fluid flow.

Due to their metal construction, these sheets exhibit remarkable mechanical strength, resistance to high temperatures, and corrosion resistance. They can endure harsh and demanding operating conditions, making them a preferred choice for critical filtration and separation tasks in various industrial settings.

titanium sintered filter sheet

titanium sintered filter sheet

Titanium sintered filter sheet is a specialized filtering media made from titanium particles that are sintered together to form a porous and rigid 

structure. This sintered sheet exhibits high mechanical strength, excellent corrosion resistance, and biocompatibility, making it ideal for use in a wide range of applications. Titanium sintered filter sheets are commonly used in industries like pharmaceuticals, aerospace, medical devices, and chemical processing, where precise and reliable filtration is crucial.

These sheets are capable of withstanding high temperatures, aggressive chemicals, and harsh environments, offering long-lasting performance and durability in demanding operating conditions.

sintered aluminum sheet

sintered aluminum sheet

Sintered aluminum sheet is a specialized filtering material created by fusing aluminum particles

together through a sintering process. The sintering method involves subjecting the aluminum particles to high heat and pressure, causing them to bond and form a porous, rigid structure with interconnected voids.

Sintered aluminum sheets offer efficient filtration and separation of gases and liquids, capturing impurities and contaminants while allowing for smooth flow. These sheets are commonly used in industries such as automotive, aerospace, electronics, and environmental technologies.

The lightweight nature of sintered aluminum sheets makes them suitable for applications where weight reduction is essential. They are also corrosion-resistant, making them suitable for use in aggressive and corrosive environments.

Overall, sintered aluminum sheets are a versatile and cost-effective solution for various applications that require high porosity, lightweight, and reliable filtering capabilities.

sintered wire mesh with perforated metal sheet

sintered wire mesh with perforated metal sheet

Sintered wire mesh with perforated metal sheet is a unique combination

of two advanced filtering materials. It consists of layers of its stacked together and bonded to form a robust and versatile filtering media.

The sintered wire mesh provides fine filtration capabilities due to its uniform pore size and excellent particle retention. It can remove fine particles and contaminants from gases and liquids effectively.

The perforated metal sheet, on the other hand, contributes to the overall structural integrity and mechanical strength of the composite filter. It also offers additional support and protection to the sintered wire mesh layers.

The combination of sintered wire mesh and perforated metal sheet makes the composite filter ideal for applications that require precise filtration, high flow rates, and mechanical durability. Industries such as petrochemicals, pharmaceuticals, food processing, and aerospace often utilize this composite filter for critical filtration and separation processes.

sintered bronze sheet

sintered bronze sheet

Sintered bronze sheets are a type of porous metal material formed by compacting and heating bronze powder particles

until they fuse together without melting. The sintering process involves applying controlled heat and pressure, resulting in a sheet with interconnected pores of varying sizes and shapes.

The porous structure of sintered bronze sheets provides several advantageous properties. Firstly, it offers excellent permeability and fluid retention capabilities, making it suitable for various filtration and separation applications. The controlled porosity allows fluids or gases to flow through while capturing particles and impurities.

Moreover, sintered bronze sheets exhibit remarkable self-lubricating properties, reducing friction and wear when used in sliding or rotating applications. This makes them valuable in manufacturing bushings, bearings, and other components for machinery and automotive systems.

multi-layer sintered metal sheet

multi-layer sintered metal sheet

Multi-layer sintered metal sheet is a composite material composed of multiple layers of its stacked

on top of each other and then bonded together through a sintering process. Each individual layer is created by compacting and heating metal powder particles until they fuse into a solid sheet without reaching the melting point. The layers are stacked in a way that their pores are aligned, allowing for uniform and controlled permeability throughout the structure.

The multi-layer structure also enhances the material’s overall mechanical integrity, making it more resistant to deformation and increasing its load-bearing capacity. This feature is especially valuable in applications where the material will be subjected to high pressures or mechanical stresses.

Furthermore, the design of multi-layer sintered metal sheets enables them to handle a wider range of operating conditions, including variations in temperature, chemical exposure, and fluid flow rates.

These characteristics make multi-layer sintered metal sheets highly sought after in various industries, including automotive, aerospace, oil and gas, chemical processing, and medical. Common applications include filters, spargers, catalytic converters, porous bearings, and fluid distribution devices.


Our company provides a kind of metal alloy to solve the problem of providing products with excellent

performance in high temperature and high corrosive environment. Our products are very strong

and welded or sintered. Length, diameter, thickness, alloy, medium grade and other specifications

can be adjusted during the production process, so that the product is suitable for a variety of

filtration, flow and chemical compatibility in different customer processes.


Sizes of the sintered sheets

Sizes of the sintered sheets

Sintered sheets come in various sizes to accommodate diverse industrial and engineering applications. The sizes typically range from small dimensions, such as a few centimeters in length and width, to larger dimensions reaching tens of centimeters or even meters. The thickness of its can vary as well, from thin sheets with a few millimeters to thicker sheets with several centimeters.





Micron size

0.5um – 200um





What is the sintering process used to produce the sheets?

sintering process used to produce the sheets

Sintering process used to produce sintered sheets involves compacting metal powder particles into a desired shape or form, followed by heating the compacted powder in a controlled atmosphere below the metal’s melting point.

During the heating phase, the metal particles fuse together through a process called diffusion, forming a solid piece without reaching a full liquid state. The sintering temperature and time are carefully controlled to achieve the desired level of porosity, strength, and density in the final sintered sheet.

This process allows for the creation of porous metal sheets with interconnected voids, making them suitable for various filtration, separation, and engineering applications.

Sintered sheets installation

Sintered sheets installation

The installation of sintered sheets depends on their intended application and the specific requirements of the project. Here are some general guidelines for installing its:

1.Preparing the surface: Ensure that the surface where the sintered sheet will be installed is clean, smooth, and free from any debris or contaminants.

2.Cutting and shaping: If needed, cut the sintered sheets to the required size and shape using appropriate cutting tools or techniques.

3.Securing the sheets: Sintered sheets can be attached to the supporting structure using adhesives, welding, or mechanical fasteners like bolts and screws. The method of attachment will depend on the application and the material being used.

4.Sealing (if required): In some applications, sintered sheets may need to be sealed to prevent leaks or ensure proper fluid flow. This can be achieved using suitable sealing materials or techniques.

5.Testing: After installation, perform any necessary tests to ensure that the sintered sheets are functioning as intended and meeting the required performance criteria.

Always refer to the manufacturer’s guidelines and consult with experienced professionals to ensure the correct and safe installation of sintered sheets for your specific application.

What is the flow rate capacity of the sintered sheets and how does it change with varying differential pressures?

The flow rate capacity of sintered sheets depends on various factors, including the material used, pore size, thickness, and the specific application. Generally, its have high flow rates due to their interconnected porosity, which allows fluids or gases to pass through with minimal resistance. However, the exact flow rate capacity can vary significantly based on the aforementioned factors.

As for the impact of varying differential pressures, sintered sheets typically exhibit a non-linear relationship. At lower differential pressures, the flow rate tends to increase rapidly since the fluid or gas can easily pass through the larger available pores.

As the differential pressure increases, the flow rate may become more constrained, and it may reach a point where the flow rate stabilizes due to a balance between the applied pressure and the resistance offered by the sintered sheet’s porosity.

Understanding the flow rate capacity and its behavior under different differential pressures is crucial for selecting the appropriate sintered sheet for specific filtration, separation, or fluid handling applications. Manufacturers often provide flow rate charts and data to help users determine the most suitable sintered sheet for their desired operating conditions.

Can the sintered metal sheets be customized to specific shapes and sizes for different applications?

sintered metal sheets

Sintered metal sheets can be customized to specific shapes and sizes to meet the requirements of different applications.

The manufacturing process of sintered sheets allows for flexibility in designing and producing various shapes, including complex geometries, as well as adjusting the dimensions according to the application’s needs.

Engineers and manufacturers can tailor the composition, thickness, and pore size distribution of the sintered sheets to achieve the desired mechanical properties, permeability, and filtration characteristics for a wide range of industrial and engineering applications.

What is the maximum operating temperature and pressure?

The maximum operating temperature and pressure of sintered metal sheets depend on the specific material used and the manufacturing process.

Generally, sintered metal sheets can withstand temperatures ranging from several hundred to over a thousand degrees Celsius, making them suitable for high-temperature applications.

As for pressure, they can endure a broad range, from relatively low pressures to several hundred bar (tens of thousands of PSI), depending on the material’s thickness, porosity, and mechanical strength.

For precise information, it is essential to refer to the manufacturer’s specifications and consult with experts in the field to determine the specific limits for a given sintered metal sheet.

Sintered filter sheets functions

Sintered filter sheets functions

Sintered filter sheets serve as efficient and reliable filtration media in various industries. Their primary function is to separate and remove solid particles, impurities, and contaminants from fluids or gases passing through them.

The interconnected pores in the sintered filter sheet allow fluid flow while capturing and retaining particles based on their size and shape.

These filter sheets offer high porosity, controlled permeability, and excellent mechanical strength, making them ideal for applications requiring precise particle removal, such as in pharmaceuticals, food and beverage processing, water treatment, chemical processing, and industrial gas filtration. Sintered filter sheets ensure product purity, protect equipment, and maintain process efficiency.

Can the sintered sheets withstand high-temperature environments without compromising their integrity?

Sintered sheets are designed to withstand high-temperature environments without compromising their integrity

The sintering process creates a solid and porous structure with strong interconnections between particles, resulting in excellent thermal stability and mechanical strength.

Depending on the material composition and manufacturing process, sintered sheets can withstand temperatures ranging from several hundred to over a thousand degrees Celsius.

This makes them suitable for applications in high-temperature environments, such as in industrial furnaces, gas filtration at elevated temperatures, aerospace components, and other applications where resistance to heat and thermal stability are essential.


Most frequent questions and answers

Various materials are available for the production of sintered stainless steel sheets, each offering specific properties and characteristics to suit different applications. Some common materials used for its include:

1.Stainless steel 316L: Known for its excellent corrosion resistance and high temperature stability, making it suitable for applications in aggressive environments and elevated temperatures.

2.Stainless steel 304L: Offers good general corrosion resistance and is widely used in various industrial applications.

3.Stainless steel 410: Provides good wear and abrasion resistance, making it suitable for applications where mechanical durability is crucial.

4.Stainless steel 430: Known for its magnetic properties and good corrosion resistance in mild environments.

5.Stainless steel 2205: A duplex stainless steel with higher strength and improved resistance to stress corrosion cracking.

6.Stainless steel 17-4PH: Known for its combination of high strength, hardness, and corrosion resistance.

These materials can be combined or customized with other alloying elements to enhance specific properties and meet the requirements of various industries, such as automotive, aerospace, oil and gas, chemical processing, and more.

Sintered sheets are widely used in various industrial applications due to their unique properties and versatility. The typical dimensions and standard sizes of these sheets can vary depending on the manufacturing process and the intended application.

Sintered sheets are commonly available in square or rectangular shapes. The DEZE offers typical sizes ranging from several centimeters to several meters. Standard thicknesses can vary from as thin as 0.5 millimeters to a few centimeters.

The thickness range of sintered sheets can vary widely depending on the specific application and manufacturing process. Typically, its can have a thickness ranging from as thin as 0.5 millimeters to several centimeters. However, in some specialized cases, the thickness may go beyond these ranges.

Sintered sheets can be customized to meet specific requirements. Manufacturers can tailor the thickness based on the intended application and the desired characteristics, such as filtration efficiency, mechanical strength, and porosity. Customization allows for a broad range of options to suit the diverse needs of different industries and applications.

The porosity or pore size distribution of sintered sheets can vary depending on the specific application and manufacturing specifications.

Sintered sheets are engineered to have controlled and customizable porosity, allowing for precise filtration and fluid flow characteristics.

The pore size distribution can range from micrometers to millimeters, depending on the desired filtration efficiency and particle retention requirements.

The filtration rating or micron size of sintered sheets refers to the particle size that the sheets can effectively filter or retain. Its are available in various grades with different filtration ratings to suit specific applications. The filtration rating can range from a few microns to several hundred microns, depending on the intended use.

For example, in industrial applications that require fine filtration, sintered sheets with lower micron ratings (e.g., 1 to 50 microns) are commonly used to capture smaller particles and contaminants from liquids or gases. On the other hand, applications that involve coarser filtration may use sintered sheets with higher micron ratings (e.g., 100 to 500 microns).

Different grades of sintered sheets can be customized to offer specific levels of porosity, permeability, and particle retention efficiency.

Sintered sheets are designed to withstand high temperatures and pressure without degradation, making them suitable for demanding industrial applications.

The sintering process creates a strong and durable structure, ensuring the sheets can maintain their integrity under challenging conditions. The use of high-quality materials, such as stainless steel or other heat-resistant alloys, further enhances their ability to withstand elevated temperatures.

Sintered sheets are widely used in applications where they encounter high-temperature gases, fluids, or steam, as well as in processes that involve high-pressure environments, ensuring reliable performance and longevity even in harsh operating conditions.

Sintered sheets can be engineered to be chemically resistant to specific fluids or gases commonly encountered in various applications.

The choice of materials used in the sintering process can be tailored to withstand the corrosive effects of specific chemicals or gases.

For instance, sintered sheets made from stainless steel or other corrosion-resistant alloys can be selected to resist chemical attack from acids, bases, and other aggressive substances.

This chemical resistance ensures the sintered sheets maintain their structural integrity and performance when exposed to challenging environments, making them well-suited for a wide range of industrial applications that involve handling corrosive fluids or gases.

The flow rate capacity of sintered sheets can vary based on their porosity, pore size distribution, and operating conditions.

Sintered sheets are known for their excellent flow characteristics due to their interconnected porosity, which allows fluids or gases to pass through while retaining particles. The flow rate capacity typically increases with higher porosity and larger pore sizes.

However, factors like operating pressure, temperature, and the fluid’s viscosity can influence the flow rate.

Under different operating conditions, such as increased pressure or viscosity, the flow rate may decrease or become more restricted, but sintered sheets still maintain their effective filtration and flow control capabilities.

Sintered sheets can be used both as standalone filters and in combination with other filter media, depending on the specific application requirements.

As standalone filters, they offer excellent particle retention and can effectively filter liquids or gases.

However, in certain applications where fine filtration is necessary or where different filtration stages are required, sintered sheets might be combined with other filter media, such as filter papers, cartridges, or membranes, to achieve the desired level of filtration efficiency.

This flexibility allows industries to customize filtration systems and optimize performance based on their unique needs and the characteristics of the substances being filtered.

Sintered sheets can offer several unique advantages over traditional filter media, including longer service life and reduced maintenance requirements. Its are produced by sintering metal powders or fibers together to form a porous structure. This manufacturing process creates a durable and robust material that can be advantageous in various filtration applications. Some of the benefits of its include:

1.Longer service life: Sintered sheets are known for their excellent mechanical strength and resistance to wear and tear. They can withstand high pressures and temperatures, making them ideal for applications where the filter is subjected to harsh conditions. This extended durability often translates to a longer service life compared to traditional filter media, such as paper or cloth filters.

2.Reduced maintenance: Due to their high porosity and retention efficiency, sintered sheets can capture a large volume of contaminants before requiring cleaning or replacement. This reduced frequency of maintenance can lead to cost savings and less downtime in industrial processes or filtration systems.

3.Higher filtration efficiency: Sintered sheets have precise pore sizes and uniform distribution, allowing for efficient removal of particles and contaminants from the fluid or gas being filtered. This high filtration efficiency can lead to improved process performance and product quality.

4.Wide chemical compatibility: Sintered sheets are available in various materials, such as stainless steel, bronze, nickel, or polyethylene. This versatility allows them to be compatible with a wide range of chemicals and fluids, expanding their applications in different industries.

5.Ease of cleaning: Sintered sheets can be cleaned through various methods, including backwashing, chemical cleaning, or ultrasonic cleaning. Their robust structure enables them to withstand these cleaning processes without losing their filtration effectiveness.

6.Environmentally friendly: Sintered sheets are often reusable and can withstand multiple cleaning cycles. As a result, they contribute to reduced waste generation compared to disposable filter media, making them more environmentally friendly.

While sintered sheets offer numerous advantages, it’s essential to consider the specific requirements of each filtration application. Factors such as particle size, flow rate, operating conditions, and chemical compatibility should be taken into account when choosing the appropriate filter media for a given system.

Sintered sheets are typically installed or integrated into a filtration system in a few straightforward steps. The specific method may vary depending on the design and requirements of the filtration system, but the general process is as follows:

1.Selection and sizing: Choose the appropriate sintered sheet material and pore size based on the filtration requirements of the system, including the type and size of particles to be removed.

2.Housing or holder: Place the sintered sheet into a housing or holder that keeps it securely in place within the filtration system. The housing can be made of various materials, such as stainless steel or plastic.

3.Sealing: Ensure a proper seal between the sintered sheet and the housing to prevent bypass of particles through gaps or edges.

4.Integration: Install the sintered sheet housing within the filtration system, such as a filter vessel or cartridge, depending on the specific system’s configuration.

5.Inlet and outlet connections: Connect the inlet and outlet pipes or tubes to the filtration system to allow the fluid or gas to flow through the sintered sheet.

6.Testing: Conduct initial testing to check the integrity and efficiency of the filtration system with the sintered sheet in place.

Proper installation and integration are essential to ensure optimal filtration performance and longevity of the sintered sheet in the system. Regular maintenance and cleaning are also important to extend its service life and maintain effective filtration.

Sintered sheets can be cleaned, backwashed, or regenerated for reuse. Their durable and robust structure allows them to withstand various cleaning methods without losing their filtration effectiveness.

The cleaning process can involve backwashing to remove trapped particles and contaminants, chemical cleaning to dissolve or dislodge certain substances, or ultrasonic cleaning to dislodge contaminants from the sheet’s pores.

After cleaning and regeneration, the sintered sheets can be reintegrated into the filtration system, making them a sustainable and cost-effective solution for filtration applications.

The expected lifespan of sintered sheets under typical operating conditions can vary depending on several factors, including the material used, filtration application, operating temperature, and the level of contaminants in the fluid or gas being filtered.

Generally, sintered sheets are known for their durability and can have a longer service life compared to traditional filter media. They can often last several months to years before requiring replacement, especially when maintained and cleaned properly.

Sintered sheets are suitable for applications involving food, pharmaceuticals, and other sensitive industries. These industries often require high-quality filtration to meet strict regulatory standards and ensure product safety.

Sintered sheets made from food-grade or pharmaceutical-grade materials, such as stainless steel or polyethylene, are available to meet the specific requirements of these industries.

They offer excellent chemical compatibility, high filtration efficiency, and are easy to clean and sanitize.

Additionally, sintered sheets’ durability and long service life make them a reliable and cost-effective choice for maintaining the purity and integrity of the products in these sensitive applications.

Sintered sheets can have special features, such as anti-static properties and resistance to electromagnetic interference (EMI).

Some sintered sheets are engineered with materials that possess inherent anti-static properties, making them suitable for applications where static electricity buildup must be minimized, such as in certain industrial processes or electronics manufacturing.

Additionally, sintered sheets made from conductive materials, such as metal fibers, can provide EMI shielding properties, helping to block or attenuate electromagnetic radiation, which is crucial in electronics and communication equipment where EMI interference can cause operational issues. These special features add to the versatility and utility of sintered sheets in various applications.

Sintered sheets can be used in high-viscosity or high-pressure applications. Their robust and durable structure allows them to withstand high pressures and flow rates, making them suitable for applications involving fluids with high viscosity.

Additionally, sintered sheets with specific pore sizes can be chosen to accommodate the viscosity of the fluid being filtered.

Their mechanical strength and resistance to wear and tear make them reliable for use in high-pressure environments, such as oil and gas industries, chemical processing, and other applications where filtration under challenging conditions is required.

Sintered sheets exhibit good chemical compatibility with a wide range of substances. The material used to manufacture it plays a significant role in determining its chemical resistance.

For instance, stainless steel sintered sheets are highly corrosion-resistant and can withstand exposure to various chemicals, including acids, alkalis, and organic solvents. Polyethylene sintered sheets offer excellent chemical resistance to many chemicals and are commonly used in food and pharmaceutical applications.

However, it’s essential to consider the specific material of the sintered sheet and the chemicals involved in the application to ensure optimal performance and longevity.

Sintered sheets can be used in applications involving corrosive or aggressive environments. The choice of material for it is crucial in such scenarios.

For example, stainless steel sintered sheets, which are highly corrosion-resistant, are commonly used in applications where the filter needs to withstand aggressive or corrosive fluids. They can handle exposure to acids, alkalis, and other harsh chemicals.

Additionally, sintered sheets made from other corrosion-resistant materials, such as bronze or nickel, can also be utilized in corrosive environments, offering reliable and long-lasting filtration performance in challenging conditions.

There are limitations on the sintered sheets’ maximum thickness and minimum pore size. The manufacturing process of sintering imposes practical constraints on these parameters.

Extremely thick sintered sheets may be challenging to produce uniformly and may result in issues like uneven porosity or structural integrity.

Similarly, extremely small pore sizes might be difficult to achieve due to the limitations of powder particle sizes and sintering processes.

The thickness and pore size of sintered sheets are typically optimized for specific applications, balancing filtration efficiency, mechanical strength, and ease of manufacturing.

Sintered sheets can be supplied in various forms to accommodate different filtration system configurations and applications.

They can be found in rolls, sheets, discs, tubes, and other custom shapes based on the specific needs of the user.

Rolls are commonly used for applications where continuous filtration is required, while discs and sheets are often used in filter cartridges and filter housings.

The versatility in form allows sintered sheets to be easily integrated into existing filtration systems or used in various industrial processes, providing flexibility and efficiency in meeting filtration requirements.

Sintered sheets can be supplied with various surface finishes to meet specific application requirements.

The surface finish can be tailored to enhance the sintered sheet’s performance in different filtration applications.

For instance, some applications may require a smooth surface to reduce the risk of particle adhesion or clogging, while others may benefit from a rougher surface that increases the surface area for improved filtration efficiency.

Additionally, specific surface coatings or treatments can be applied to enhance chemical resistance, anti-static properties, or other characteristics based on the intended use of the sintered sheet.

Sintered sheets are generally compatible with different fabrication processes, including cutting and machining.

Their robust structure allows them to be cut or machined to specific sizes or shapes to meet the requirements of various applications.

Common fabrication techniques used with sintered sheets include laser cutting, waterjet cutting, wire EDM (Electrical Discharge Machining), and conventional machining methods like milling or turning.

However, it’s essential to consider the material composition and pore structure of the sintered sheet, as certain materials may be more challenging to machine due to their hardness or brittleness.

At DEZE, we take pride in offering comprehensive technical support and assistance to help you select the most suitable sintered sheet for your specific application. Our team of experienced engineers and experts are well-versed in the properties and capabilities of different sintered sheet materials, pore sizes, and configurations. We take the time to understand your filtration needs, operating conditions, and any unique challenges you may face.

Based on your requirements, we will recommend the best sintered sheet material and design that aligns with your application’s demands. Whether you need high-temperature resistance, chemical compatibility, anti-static properties, or specific flow rates, we have the expertise to guide you towards an optimal solution.

Our goal is to ensure that you receive a sintered sheet that not only meets your technical needs but also offers long-lasting performance, cost-effectiveness, and reliability. With our technical support, you can have confidence in choosing the right sintered sheet for your filtration application.

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