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Engineering-Grade Metallic Mesh for Ultra-Precision Filtration, Electrochemistry, and New Energy Systems
In precision filtration, electrochemical reactors, new energy devices, and multiphase mass-transfer systems, materials must provide not only stable structural strength and corrosion resistance, but also highly uniform pore structures, controlled surface states, and optimized wettability. These factors directly determine mass-transfer efficiency, reaction stability, and long-term operational durability.
Based on mature 316L austenitic stainless steel precision weaving technology, Youveim® introduces two product series:
Youveim® 316L Stainless Steel Mesh Cloth
Youveim® Hydrophilic 316L Stainless Steel Mesh Cloth
Together they cover multi-level application demands ranging from ultra-precision filtration to electrochemical functional substrates.
High Precision · High Strength · Ultra-Fine Filtration & Conductive Substrate
Youveim® 316L Stainless Steel Mesh Cloth is manufactured from 316L low-carbon austenitic stainless steel wires, using precision weaving with differentiated warp and weft wire diameters and mesh counts.
Compared with conventional equal-diameter square stainless steel meshes, this structure offers significant advantages in:
pore size precision
filtration density
structural stability
It enables micron-scale and even sub-micron filtration while maintaining excellent mechanical strength.
Its structural design is suitable not only for filtration and separation, but also naturally applicable as:
conductive substrates
structural support layers
functional coating carriers
Low Carbon Design (316L)
Effectively prevents intergranular corrosion and offers better weldability and heat-treatment adaptability than 316.
Outstanding Corrosion Resistance
Molybdenum-containing alloy performs reliably in acidic, alkaline, and chloride-containing environments, superior to 304 stainless steel.
Excellent High-Temperature Resistance
Capable of long-term operation in environments up to approximately 800 °C.
High Mechanical Strength
Resistant to deformation with strong pressure tolerance, suitable for continuous operation systems and scale-up engineering applications.
Warp–Weft Differential Weaving
Warp wires are typically thicker for structural strength
Weft wires are finer for high-precision filtration
Extremely Small and Uniform Pore Size
Suitable for high-precision particle separation and contamination control.
Contrast Weaving Structure
Improves filtration stability and service life while maintaining good throughput.
High Load Capacity
Suitable for filtration of high-viscosity fluids, high solid-content materials, and heavy loading processes.
✅ This weaving technology breaks the precision limits of conventional stainless steel meshes, making it an ideal choice for ultra-precision filtration.
Enhanced Wettability · Improved Mass Transfer · Multiphase System Friendly
Youveim® Hydrophilic 316L Stainless Steel Mesh Cloth uses standard 316L stainless steel mesh cloth as the base material and applies a proprietary surface hydrophilization treatment.
Without altering the original:
pore structure
mechanical strength
electrical conductivity
this treatment significantly improves wettability in aqueous and polar media.
The metal surface is transformed from its intrinsic weak wettability to a stable hydrophilic state, effectively avoiding:
liquid repulsion
droplet retention
local dry zones
This makes the material particularly suitable for:
electrochemical reactions
multiphase flow systems
catalyst coating processes
Rapid wetting — liquids spread immediately upon contact
More uniform liquid distribution — reduced dry spots
Reduced bubble and droplet retention — more stable operation
Improved mass-transfer efficiency — enhanced reactant/product diffusion
Better catalyst loading performance — improved coating uniformity and adhesion
| Model | Mesh | Wire Diameter (mm) | Aperture (μm) | Open Area (%) | Thickness (mm) | Weight (kg/m²) |
|---|---|---|---|---|---|---|
| SSC316-1 | 20×250 | 0.25×0.20 | 119 | 17.6 | 0.65 | 3.01 |
| SSC316-2 | 20×200 | 0.35×0.28 | 118 | 12.1 | 0.91 | 4.58 |
| SSC316-3 | 24×300 | 0.28×0.18 | 110 | 19.6 | 0.64 | 3.01 |
| SSC316-4 | 20×150 | 0.45×0.35 | 100 | 7.5 | 1.16 | 6.00 |
| SSC316-5 | 30×340 | 0.28×0.16 | 89 | 17.9 | 0.60 | 2.84 |
| SSC316-6 | 30×360 | 0.25×0.15 | 80 | 17.0 | 0.55 | 2.48 |
| SSC316-7 | 30×250 | 0.25×0.20 | 78 | 11.2 | 0.55 | 3.20 |
| SSC316-8 | 40×560 | 0.18×0.10 | 70 | 23.5 | 0.36 | 1.73 |
| SSC316-9 | 40×400 | 0.19×0.12 | 63 | 15.4 | 0.43 | 2.00 |
| SSC316-10 | 50×600 | 0.12×0.09 | 50 | 17.2 | 0.32 | 1.47 |
| SSC316-11 | 80×700 | 0.11×0.08 | 30 | 9.8 | 0.27 | 1.39 |
| SSC316-12 | 80×800 | 0.10×0.07 | 25 | 12.2 | 0.23 | 1.15 |
| SSC316-13 | 90×760 | 0.10×0.07 | 25 | 9.6 | 0.24 | 1.24 |
| SSC316-14 | 200×600 | 0.07×0.05 | 23 | 12.0 | 0.15 | 0.52 |
| SSC316-15 | 100×850 | 0.10×0.063 | 22 | 10.0 | 0.23 | 1.14 |
| SSC316-16 | 100×760 | 0.10×0.071 | 20 | 7.4 | 0.24 | 1.26 |
| SSC316-17 | 130×1100 | 0.07×0.05 | 17 | 9.5 | 0.17 | 0.88 |
| SSC316-18 | 165×800 | 0.07×0.05 | 15 | 13.5 | 0.17 | 0.74 |
| SSC316-19 | 165×1400 | 0.063×0.04 | 13 | 8.8 | 0.14 | 0.73 |
| SSC316-20 | 200×1400 | 0.05×0.032 | 10 | 9.2 | 0.12 | 0.58 |
| SSC316-21 | 250×1600 | 0.05×0.032 | 8 | 3.8 | 0.11 | 0.63 |
| SSC316-22 | 280×2200 | 0.036×0.025 | 7 | 7.2 | 0.08 | 0.45 |
| SSC316-23 | 300×2100 | 0.036×0.025 | 6 | 6.0 | 0.08 | 0.44 |
| SSC316-24 | 325×2300 | 0.036×0.025 | 4 | 4.2 | 0.08 | 0.46 |
| SSC316-25 | 400×2800 | 0.03×0.018 | 3 | 4.7 | 0.06 | 0.36 |
Note: Custom warp-weft combinations can be designed based on filtration precision, flow rate, and structural requirements.
High-viscosity material filtration
Acid/alkali liquid precision separation
Chemical, petroleum, and pharmaceutical filtration systems
⚡ Lithium battery / fuel cell current collectors
⚡ Supercapacitor electrode supports
⚡ Conductive structural substrates for electrolyzers
⚡ AEM water electrolysis hydrogen production (direct catalyst spraying possible)
Wastewater treatment
Flue gas dust removal
Multiphase flow and interfacial mass-transfer research
Catalyst spraying: IrO₂, RuO₂, Pt
Precious metal plating: gold / platinum plating
Surface roughening or activation
Hydrophilic treatment (forming hydrophilic 316L mesh cloth)
| Parameter | 316L Stainless Steel Mesh Cloth | Hydrophilic 316L Stainless Steel Mesh Cloth |
|---|---|---|
| Base Material | 316L Austenitic Stainless Steel Wire | 316L Austenitic Stainless Steel Wire |
| Weaving Method | Precision Plain / Twill Weave | Precision Plain / Twill Weave |
| Pore Structure | Highly uniform pores | Highly uniform pores |
| Wettability | Standard metal surface | Stable hydrophilic surface |
| Fluid Distribution | Standard | More uniform and stable |
| Bubble Retention | Easier to attach | Significantly reduced |
| Main Applications | Precision filtration, structural support | Electrolysis, electrochemistry, multiphase systems |
| Surface Functionalization | Roughening / plating / coating possible | Same as left |
For filtration applications:
Edge sealing is recommended after cutting to prevent wire fraying.
For electrochemical applications:
Clean and degrease before use; surface activation or hydrophilic treatment may be applied if necessary.
Storage:
Store in a dry and light-protected environment. Functionalized materials should be sealed for long-term preservation.
Youveim® 316L Stainless Steel Mesh Cloth is an engineering-grade metallic mesh material that combines high filtration precision, corrosion resistance, and structural stability.
Youveim® Hydrophilic 316L Stainless Steel Mesh Cloth further optimizes interface properties and mass-transfer performance for aqueous, electrochemical, and new energy systems.
Together they form a comprehensive material solution covering:
Filtration → Structural Support → Conductive Substrate → Catalyst Carrier
suitable for applications ranging from scientific research to large-scale industrial implementation.
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| Model | Mesh Count (Mesh) | Wire Diameter (mm) | Aperture (μm) | Thickness (mm) | 10x10cm | 20x20cm | 30x30cm |
|---|---|---|---|---|---|---|---|
| SSC316-1 | 20×250 | 0.25×0.20 | 119 | 0.65 | |||
| SSC316-2 | 20×200 | 0.35×0.28 | 118 | 0.91 | |||
| SSC316-3 | 24×300 | 0.28×0.18 | 110 | 0.64 | |||
| SSC316-4 | 20×150 | 0.45×0.35 | 100 | 1.16 | |||
| SSC316-5 | 30×340 | 0.28×0.16 | 89 | 0.60 | |||
| SSC316-6 | 30×360 | 0.25×0.15 | 80 | 0.55 | |||
| SSC316-7 | 30×250 | 0.25×0.20 | 78 | 0.55 | |||
| SSC316-8 | 40×560 | 0.18×0.10 | 70 | 0.36 | 16 | 40 | 80 |
| SSC316-9 | 40×400 | 0.19×0.12 | 63 | 0.43 | |||
| SSC316-10 | 50×600 | 0.12×0.09 | 50 | 0.32 | 16 | 40 | 80 |
| SSC316-11 | 80×700 | 0.11×0.08 | 30 | 0.27 | |||
| SSC316-12 | 80×800 | 0.10×0.07 | 25 | 0.23 | 16 | 40 | 80 |
| SSC316-13 | 90×760 | 0.10×0.07 | 25 | 0.24 | |||
| SSC316-14 | 200×600 | 0.07×0.05 | 23 | 0.15 | 16 | 40 | 80 |
| SSC316-15 | 100×850 | 0.10×0.063 | 22 | 0.23 | |||
| SSC316-16 | 100×760 | 0.10×0.071 | 20 | 0.24 | |||
| SSC316-17 | 130×1100 | 0.07×0.05 | 17 | 0.17 | |||
| SSC316-18 | 165×800 | 0.07×0.05 | 15 | 0.17 | |||
| SSC316-19 | 165×1400 | 0.063×0.04 | 13 | 0.14 | |||
| SSC316-20 | 200×1400 | 0.05×0.032 | 10 | 0.12 | |||
| SSC316-21 | 250×1600 | 0.05×0.032 | 8 | 0.11 | |||
| SSC316-22 | 280×2200 | 0.036×0.025 | 7 | 0.08 | |||
| SSC316-23 | 300×2100 | 0.036×0.025 | 6 | 0.08 | |||
| SSC316-24 | 325×2300 | 0.036×0.025 | 4 | 0.08 | |||
| SSC316-25 | 400×2800 | 0.03×0.018 | 3 | 0.06 |
**Note: Custom sizes are available. For example, rolls (width 1m, length 30m) can be priced per square meter.**
Partial references citing our materials (from Google Scholar)
Carbon Dioxide Reduction
1. ACS Nano Strain Relaxation in Metal Alloy Catalysts Steers the Product Selectivity of Electrocatalytic CO2 Reduction
The bipolar membrane (Fumasep FBM) in this paper was purchased from SCI Materials Hub, which was used in rechargeable Zn-CO2 battery tests. The authors reported a strain relaxation strategy to determine lattice strains in bimetal MNi alloys (M = Pd, Ag, and Au) and realized an outstanding CO2-to-CO Faradaic efficiency of 96.6% with outstanding activity and durability toward a Zn-CO2 battery.
2. Front. Chem. Boosting Electrochemical Carbon Dioxide Reduction on Atomically Dispersed Nickel Catalyst
In this paper, Vulcan XC-72R was purchased from SCI Materials Hub. Vulcan XC 72R carbon is the most common catalyst support used in the anode and cathode electrodes of Polymer Electrolyte Membrane Fuel Cells (PEMFC), Direct Methanol Fuel Cells (DMFC), Alkaline Fuel Cells (AFC), Microbial Fuel Cells (MFC), Phosphoric Acid Fuel Cells (PAFC), and many more!
3. Adv. Mater. Partially Nitrided Ni Nanoclusters Achieve Energy-Efficient Electrocatalytic CO2 Reduction to CO at Ultralow Overpotential
An AEM membrane (Sustainion X37-50 Grade RT, purchased from SCI Materials Hub) was activated in 1 M KOH for 24 h, washed with ultra-purity water prior to use.
4. Adv. Funct. Mater. Nanoconfined Molecular Catalysts in Integrated Gas Diffusion Electrodes for High-Current-Density CO2 Electroreduction
In this paper (Supporting Information), an anion exchanged membrane (Fumasep FAB-PK-130 obtained from SCI Materials Hub (www.scimaterials.cn)) was used to separate the catholyte and anolyte chambers.
SCI Materials Hub: we also recommend our Fumasep FAB-PK-75 for the use in a flow cell.
5. Appl. Catal. B Efficient utilization of nickel single atoms for CO2 electroreduction by constructing 3D interconnected nitrogen-doped carbon tube network
In this paper, the Nafion 117 membrane was obtained from SCI Materials Hub.
In this paper, Proton exchange membrane (Nafion 117), Nafion D520, and Toray 060 carbon paper were purchased from SCI Materials Hub.
7. National Science Review Confinement of ionomer for electrocatalytic CO2 reduction reaction via efficient mass transfer pathways
An anion exchange membrane (PiperION-A15-HCO3) was obtained from SCI Materials Hub.
8. Catalysis Communications Facilitating CO2 electroreduction to C2H4 through facile regulating {100} & {111} grain boundary of Cu2O
Carbon paper (TGPH060), membrane solution (Nafion D520), and ionic membrane (Nafion N117) were obtained from Wuhu Eryi Material Technology Co., Ltd (a company under SCI Materials Hub).
Batteries
1. J. Mater. Chem. A Blocking polysulfides with a Janus Fe3C/N-CNF@RGO electrode via physiochemical confinement and catalytic conversion for high-performance lithium–sulfur batteries
Graphene oxide (GO) in this paper was obtained from SCI Materials Hub. The authors introduced a Janus Fe3C/N-CNF@RGO electrode consisting of 1D Fe3C decorated N-doped carbon nanofibers (Fe3C/N-CNFs) side and 2D reduced graphene oxide (RGO) side as the free-standing carrier of Li2S6 catholyte to improve the overall electrochemical performance of Li-S batteries.
This paper used more than 10 kinds of materials from SCI Materials Hub and the authors gave detailed properity comparsion.
The commercial IEMs of Fumasep FAB-PK-130 and Nafion N117 were obtained from SCI Materials Hub.
Gas diffusion layers of GDL340 (CeTech) and SGL39BC (Sigracet) and Nafion dispersion (Nafion D520) were obtained from SCI Materials Hub.
Zn foil (100 mm thickness) and Zn powder were obtained from the SCI Materials Hub.
Commercial 20% Pt/C, 40% Pt/C and IrO2 catalysts were also obtained from SCI Materials Hub.
3. Journal of Energy Chemistry Vanadium oxide nanospheres encapsulated in N-doped carbon nanofibers with morphology and defect dual-engineering toward advanced aqueous zinc-ion batteries
In this paper, carbon cloth (W0S1011) was obtained from SCI Materials Hub. The flexible carbon cloth matrix guaranteed the stabilization of the electrode and improved the conductivity of the cathode.
4. Energy Storage Materials Defect-abundant commercializable 3D carbon papers for fabricating composite Li anode with high loading and long life
The 3D carbon paper (TGPH060 raw paper) were purchased from SCI Materials Hub.
5. Nanomaterials A Stable Rechargeable Aqueous Zn–Air Battery Enabled by Heterogeneous MoS2 Cathode Catalysts
Nafion D520 (5 wt%), and carbon paper (GDL340) were received from SCI-Materials-Hub.
Carbon cloth (W0S1011) and other electrochemical consumables required for air cathode were provided by SCI Materials Hub.
Oxygen Reduction Reaction
1. J. Chem. Eng. Superior Efficiency Hydrogen Peroxide Production in Acidic Media through Epoxy Group Adjacent to Co-O/C Active Centers on Carbon Black
In this paper, Vulcan XC 72 carbon black, ion membrane (Nafion N115, 127 μL), Nafion solution (D520, 5 wt%), and carbon paper (AvCarb GDS 2230 and Spectracarb 2050A-1050) were purchased from SCI Materials Hub.
2. Journal of Colloid and Interface Science Gaining insight into the impact of electronic property and interface electrostatic field on ORR kinetics in alloy engineering via theoretical prognostication and experimental validation
The 20 wt% Pt3M (M = Cr, Co, Cu, Pd, Sn, and Ir) were purchased from SCI Materials Hub. This work places emphasis on the kinetics of the ORR concerning Pt3M (M = Cr, Co, Cu, Pd, Sn, and Ir) catalysts, and integrates theoretical prognostication and experimental validation to illuminate the fundamental principles of alloy engineering.
Water Electrolysis
1. International Journal of Hydrogen Energy Gold as an efficient hydrogen isotope separation catalyst in proton exchange membrane water electrolysis
The cathodic catalysts of Pt/C (20 wt%, 2–3 nm) and Au/C (20 wt%, 4–5 nm) were purchased from SCI Materials Hub.
2. Small Science Silver Compositing Boosts Water Electrolysis Activity and Durability of RuO2 in a Proton-Exchange-Membrane Water Electrolyzer
Two fiber felts (0.35 mm thickness, SCI Materials Hub) were used as the porous transport layers at both the cathode and the anode.
3. Advanced Functional Materials Hierarchical Crystalline/Amorphous Heterostructure MoNi/NiMoOx for Electrochemical Hydrogen Evolution with Industry-Level Activity and Stability
Anion-exchange membrane (FAA-3-PK-130) was obtained from SCI Materials Hub website.
Fuel Cells
1. Polymer Sub-two-micron ultrathin proton exchange membrane with reinforced mechanical strength
Gas diffusion electrode (60% Pt/C, Carbon paper) was purchased from SCI Materials Hub.
Characterization
1. Chemical Engineering Journal Electrochemical reconstitution of Prussian blue analogue for coupling furfural electro-oxidation with photo-assisted hydrogen evolution reaction
An Au nanoparticle film was deposited on the total reflecting plane of a single reflection ATR crystal (SCI Materials Hub, Wuhu, China) via sputter coater.
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