Types of Monofilament Mesh High Transparency
A monofilament mesh with high transparency is a precision-engineered material composed of single continuous filaments woven into a fine, durable grid. These meshes are designed for applications where optical clarity, structural integrity, and controlled porosity are essential. Used across medical, industrial, and electronic fields, high-transparency monofilament meshes provide reliable performance in filtration, containment, and imaging processes.
PVA Monofilament Mesh
Made from polyvinyl alcohol (PVA), this water-soluble mesh dissolves at specific temperatures, making it ideal for temporary containment applications.
Advantages
- 100% water-soluble at controlled temperatures
- Leaves no residue after dissolution
- Environmentally friendly and biodegradable
- Excellent for encapsulation and release mechanisms
Limitations
- Not suitable for long-term use
- Limited mechanical strength when wet
- Sensitive to humidity and moisture
Best for: Fishing bait bags, specialty laundry nets, dissolvable packaging
Polyester Monofilament Mesh
Known for its robust mechanical and thermal properties, polyester monofilament offers exceptional durability in demanding environments.
Advantages
- High tensile strength and abrasion resistance
- Resistant to most chemicals and solvents
- Withstands repeated autoclaving (up to 130°C)
- Dimensionally stable under stress
Limitations
- Less flexible than nylon
- Can degrade under prolonged UV exposure
- Higher cost than polypropylene
Best for: Medical sterilization trays, filtration systems, high-temperature industrial processes
Nylon Monofilament Mesh
Premium-grade nylon mesh combines flexibility with excellent chemical resistance, ideal for fine filtration and sensitive handling applications.
Advantages
- Superior resistance to acids, alkalis, and organic solvents
- High flexibility and impact resistance
- Excellent for micron-level filtration
- Smooth surface reduces particle adhesion
Limitations
- Lower heat resistance (max ~120°C)
- Hygroscopic—absorbs moisture from air
- Can swell in humid environments
Best for: Biological filters, medical instrument trays, labware, chemical processing
Polypropylene Monofilament Mesh
A cost-effective, lightweight solution with strong chemical resistance, widely used in industrial and laboratory settings.
Advantages
- Exceptional resistance to acids, bases, and solvents
- Lightweight and easy to handle
- Low moisture absorption
- Economical for large-scale applications
Limitations
- Limited heat resistance (softens above 100°C)
- Lower UV and oxidative stability
- Less durable under mechanical stress
Best for: Industrial filtration, chemical strainers, cost-sensitive medical disposables
High-Transparency Monofilament Mesh
Engineered specifically for optical clarity and maximum airflow or fluid passage, this advanced mesh maintains structural integrity while offering near-invisible performance.
Advantages
- Exceptional visual transparency for monitoring and imaging
- High porosity with precise pore control
- Minimal interference with optical or electronic signals
- Ideal for precision scientific and medical devices
Limitations
- Higher manufacturing cost
- Requires careful handling to avoid damage
- Material base varies (PVC, PET, etc.), affecting compatibility
Best for: Cell culture supports, medical imaging components, electronic sensors, optical filters
| Type | Transparency | Chemical Resistance | Heat Tolerance | Best Application |
|---|---|---|---|---|
| PVA Monofilament | High | Low (dissolves in water) | Low-Medium (60–80°C) | Dissolvable packaging, bait bags |
| Polyester Monofilament | Medium-High | Excellent | Excellent (up to 130°C) | Sterilization trays, high-temp filtration |
| Nylon Monofilament | Medium | Superior (solvents, acids) | Fair (up to 120°C) | Biofilters, medical trays |
| Polypropylene Monofilament | Medium | Excellent (acids/alkalis) | Fair (up to 100°C) | Industrial strainers, chemical processing |
| High-Transparency Mesh | Very High | Varies by base material | Medium | Imaging, cell culture, electronics |
Expert Tip: When selecting a high-transparency monofilament mesh, consider both the optical clarity and the chemical compatibility with your operating environment. For medical imaging or biological applications, nylon or specialty-coated polyester often provides the best balance of clarity, durability, and biocompatibility.
Features of Monofilament Mesh: High Transparency and Performance
Monofilament mesh, manufactured from continuous single-fiber strands, is engineered to deliver exceptional performance across diverse industrial, medical, and technological applications. Its unique construction enables superior clarity, durability, and functional reliability. These attributes make it a preferred choice in environments demanding precision, hygiene, and resilience.
Key Features and Benefits
High Chemical Resistance
Monofilament meshes are fabricated from chemically inert materials such as nylon and polypropylene, offering outstanding resistance to solvents, acids, alkalis, and other aggressive substances. This stability ensures that the mesh maintains its structural integrity even under prolonged exposure to corrosive environments.
This property is particularly advantageous in chemical processing, wastewater treatment, and pharmaceutical manufacturing, where filtration systems must withstand harsh reagents without degradation. The ability to resist chemical attack extends service life and reduces maintenance costs.
Uniform Porosity for Consistent Flow
Precision-engineered monofilament mesh features uniform pore distribution across the entire surface, enabling consistent and predictable fluid or air flow. This uniformity is critical in filtration and separation processes where accuracy and repeatability are paramount.
Inconsistent porosity in alternative mesh types can lead to channeling, clogging, or uneven pressure drops—issues that compromise efficiency and product quality. With monofilament, operators achieve reliable particle retention and optimal throughput, enhancing process control and yield.
Exceptional Transparency and Optical Clarity
One of the defining characteristics of monofilament mesh is its high transparency. Due to the smooth, continuous fibers and minimal light scattering, these meshes offer excellent visibility through the material—making them ideal for applications requiring visual monitoring.
This clarity is especially valuable in medical imaging devices, optical sensors, and electronic displays where unobstructed viewing is essential. Unlike woven or opaque meshes, monofilament allows real-time observation of processes such as filtration or cell growth without removing the mesh.
Superior Durability and Long Service Life
Built to endure demanding operational conditions, monofilament mesh resists abrasion, tearing, and fatigue. The high-tensile strength of the individual fibers ensures long-term performance even under continuous mechanical stress.
Its robust nature makes it suitable for heavy-duty industrial uses, including conveyor belts, screen printing, and mining operations. The extended lifespan reduces downtime and replacement frequency, contributing to lower total cost of ownership.
Heat Resistance for Sterilization and High-Temp Use
Polyester-based monofilament mesh exhibits excellent thermal stability, capable of withstanding high temperatures encountered in autoclaving and industrial drying processes. It retains its shape, strength, and dimensional accuracy even after repeated exposure to heat.
In healthcare and biotechnology, this heat resistance enables safe and effective sterilization of equipment and filters without compromising mesh integrity—ensuring compliance with strict hygiene standards and regulatory requirements.
Easy to Clean and Maintain
The smooth surface of monofilament fibers minimizes particle adhesion, making the mesh highly resistant to fouling and easy to clean. It can be efficiently washed using water, detergents, or ultrasonic cleaning methods without damage.
This ease of maintenance is crucial in food processing, pharmaceuticals, and medical devices, where contamination risks must be minimized. Regular cleaning not only ensures hygiene but also preserves filtration efficiency and prolongs the mesh’s usable life.
| Feature | Material Contribution | Primary Applications |
|---|---|---|
| High Chemical Resistance | Nylon, Polypropylene | Chemical processing, wastewater treatment, lab filtration |
| Uniform Porosity | Precisely extruded monofilaments | Filtration, sieving, separation systems |
| High Transparency | Smooth, low-scatter fibers (e.g., polyester) | Medical imaging, electronic displays, optical sensors |
| Heat Resistance | Polyester (up to 150°C) | Sterilization, industrial drying, high-temp filtration |
| Durability & Wear Resistance | High-tensile synthetic polymers | Conveyor screens, mining, printing |
| Easy Cleaning & Hygiene | Non-porous, smooth fiber surface | Pharmaceuticals, food processing, medical devices |
Why Choose Monofilament Mesh?
Note: While monofilament mesh offers excellent performance, proper selection based on operating conditions (temperature, chemical exposure, pressure) is essential. Always consult manufacturer specifications before deployment in critical applications to ensure compatibility and safety. Improper use may lead to premature failure or compromised process integrity.
Uses of Monofilament Mesh High Transparency
Monofilament mesh with high transparency is a specialized engineered material composed of single-filament threads woven into a uniform grid structure. Its unique combination of optical clarity, mechanical strength, chemical resistance, and precise pore sizing makes it indispensable across a wide range of advanced industries. The high transparency not only allows for real-time visual monitoring but also supports microscopic evaluation and process control, enhancing both safety and efficiency.
Medical Applications
Monofilament meshes play a critical role in modern medical technology, particularly in devices requiring sterile filtration and biocompatible materials. The monofilament filter mesh is integral to equipment used in blood processing, dialysis, and intravenous (IV) filtration systems, where ultra-fine particle removal is essential for patient safety.
- Used in sterilization trays and surgical instrument packaging to allow steam or gas penetration while blocking microbial contamination
- Employed in cell culture inserts and transwell systems for tissue studies, enabling nutrient exchange and cell migration under direct microscopic observation
- Integrated into implantable devices and wound care products due to its non-reactive, non-shedding properties
Key benefit: Visual transparency enables medical staff to inspect for clogs, tears, or contamination without disassembling equipment—improving procedural reliability and reducing infection risks.
Bioscience and Laboratory Use
In bioscience research, high-transparency monofilament mesh serves as a foundational component in experimental setups requiring both structural support and optical access. Its inert composition ensures compatibility with sensitive biological samples and reagents.
- Used in 3D cell culture platforms and organ-on-a-chip devices where scaffold visibility is crucial for live imaging and monitoring cell growth
- Facilitates microfluidic filtration and separation of proteins, DNA fragments, or cellular components based on size exclusion
- Applied in tissue engineering scaffolds that guide cell alignment and regeneration while allowing researchers to track progress via microscopy
Research advantage: Enables non-invasive observation of biological processes over time, supporting longitudinal studies and reducing the need for sample disruption.
Fishing Industry
The fishing industry leverages monofilament mesh for manufacturing selective fishing gear designed to improve sustainability and operational efficiency. These nets are engineered with precise mesh sizes to allow juvenile fish and non-target species to escape, aligning with conservation regulations.
- Used in trawl nets, gillnets, and fish traps where durability and water flow are critical
- High transparency reduces underwater visibility, making the net less detectable to fish and improving catch rates
- Resistant to UV degradation, saltwater corrosion, and biofouling, extending service life in marine environments
Sustainability impact: By promoting selective harvesting, monofilament mesh helps maintain healthy fish populations and reduces bycatch—key goals of modern eco-conscious fisheries.
Industrial Filtration
Across heavy industries, monofilament mesh is a preferred filtration medium due to its robustness, consistent pore structure, and resistance to harsh chemicals and high temperatures.
- Widely used in chemical processing plants for filtering catalysts, pigments, and slurries
- Essential in pharmaceutical manufacturing for sterile filtration of liquids and separation of active ingredients
- Applied in wastewater treatment systems for screening solids and protecting downstream equipment
Performance edge: Unlike woven fabrics or porous membranes, monofilament mesh maintains dimensional stability under pressure and can be easily cleaned or backflushed—ensuring long-term reliability and reduced downtime.
Food Processing
The food and beverage industry relies on high transparency mesh for hygienic, precision filtration processes where product purity and quality control are paramount.
- Used in juice clarification, wine filtration, and edible oil refining to remove pulp, sediment, and particulates
- Integrated into sifting machines for powdered foods like flour, sugar, and spices to ensure consistent texture and particle size
- Employed in dairy processing for curd separation and whey filtration
Quality assurance: Transparency allows operators to monitor filter performance in real time, detect blockages early, and verify product clarity—critical for meeting food safety standards and consumer expectations.
Emerging and Niche Applications
Beyond traditional sectors, high-transparency monofilament mesh is finding innovative uses in cutting-edge technologies and specialized fields.
- Aquaculture: Used in fish pens and hatcheries to protect young stock while allowing optimal water circulation
- Electronics: Serves as a protective screen in sensors and optical devices requiring dust filtration without light obstruction
- Biotechnology: Applied in microencapsulation systems for controlled drug release and cell encapsulation
- Environmental Monitoring: Utilized in water sampling devices to filter debris while preserving sample integrity
Innovation potential: As demand grows for smart materials with multifunctional properties, monofilament mesh is being enhanced with antimicrobial coatings, conductive filaments, and nanoscale modifications.
Industry Insight: When selecting monofilament mesh for any application, consider not only pore size and transparency but also filament diameter, weave pattern (plain, twill, or Dutch), and material composition (typically nylon, polyester, or PTFE). These factors directly influence flow rate, tensile strength, chemical compatibility, and optical clarity—ensuring optimal performance in your specific use case.
| Application Sector | Primary Function | Material Type | Key Advantage |
|---|---|---|---|
| Medical Devices | Sterile filtration & cell culture | Nylon or PTFE | Biocompatibility + visual integrity check |
| Bioresearch | Microscopic observation & separation | Polyester or Polycarbonate | Optical clarity under magnification |
| Fishing & Aquaculture | Selective capture & containment | UV-stabilized nylon | Durability + reduced visibility |
| Pharmaceuticals | Precise liquid filtration | PTFE or Polypropylene | Chemical resistance + cleanability |
| Food & Beverage | Product purification & sifting | Food-grade polyester | Real-time process monitoring |
Additional Considerations
- Cleanability: Smooth monofilament surfaces resist particle adhesion and can be sanitized using autoclaving, chemical washes, or ultrasonic cleaning
- Customization: Meshes are available in custom pore sizes (from 10μm to several millimeters) and can be laser-cut or heat-sealed to specific shapes
- Regulatory Compliance: Meets FDA, USP Class VI, and ISO 10993 standards for medical and food contact applications
- Environmental Impact: Recyclable materials and reusable designs contribute to sustainable operations in multiple industries
- Integration: Can be laminated with membranes or embedded with sensors for advanced filtration and monitoring systems
How to Choose Monofilament Mesh with High Transparency
Selecting the right high-transparency monofilament mesh is essential for achieving optimal performance in filtration, screening, and separation applications. These meshes are widely used across industries such as medical devices, biotechnology, food processing, and industrial manufacturing due to their clarity, durability, and precision. To make an informed decision, several key factors must be evaluated based on your specific application requirements.
Important Note: High transparency in monofilament mesh refers not only to optical clarity but also to minimal obstruction of flow or visibility—critical in applications requiring visual monitoring or low resistance to fluid/gas passage.
Key Factors in Selecting High-Transparency Monofilament Mesh
- Material Compatibility
The choice of material is the foundation of mesh performance and is directly influenced by the operational environment and application. For example:
- Nylon mesh is highly valued in medical and laboratory settings due to its excellent resistance to chemicals, moderate temperature tolerance, and high tensile strength. It maintains structural integrity when exposed to alcohols, oils, and many solvents.
- Polyvinyl Alcohol (PVA) mesh is ideal for biological and pharmaceutical applications because of its water-soluble nature, making it perfect for temporary scaffolding in cell cultures or controlled-release systems.
- Other materials like polyester offer UV resistance and dimensional stability, while polypropylene provides excellent chemical resistance and is commonly used in aggressive environments.
Selecting a chemically compatible material ensures long-term reliability and prevents degradation that could compromise filtration efficiency or product safety.
- Mesh Size and Density (Pore Size & Open Area)
The pore size and overall density of the mesh determine its ability to filter particles, allow fluid passage, or support fine materials. Transparency is closely linked to open area—the percentage of space between filaments.
- Larger pore sizes (e.g., 100–500 microns) are suitable for coarse filtration, such as removing debris from liquids or air ventilation systems.
- Finer mesh densities (e.g., 10–50 microns) are used in precision applications like cell straining, microfiltration, or optical screens where both clarity and particle retention are critical.
- High-transparency meshes typically have a higher open area (up to 80% or more), allowing maximum light transmission and minimal flow resistance.
Always match the mesh specifications to the smallest particle size you need to retain or exclude. Use sieve analysis or manufacturer charts to select the appropriate mesh count (measured in threads per inch).
- Mechanical Strength and Durability
In industrial or high-pressure environments, the mesh must withstand mechanical stress without stretching, tearing, or deforming. Monofilament construction—where each strand is a single continuous fiber—provides superior strength compared to multifilament alternatives.
- Applications involving continuous fluid flow, vibration, or physical contact (e.g., conveyor screens, pressure filters) require robust materials with high tensile and flexural strength.
- Thicker filaments increase durability but may reduce transparency; therefore, a balance must be struck between strength and optical/flow performance.
- Reinforced edge binding or laminated supports can enhance longevity in demanding setups.
Consider dynamic loading conditions and cycle life when selecting mesh thickness and weave pattern (plain, twill, or Dutch weave).
- Environmental Resistance
Environmental exposure significantly affects mesh performance and lifespan. Evaluate the following conditions:
- Temperature: Some polymers like PTFE or high-temperature nylon can endure extremes from -100°C to over 200°C, while others may soften or become brittle.
- UV Exposure: Outdoor applications demand UV-stabilized materials (e.g., UV-resistant polyester) to prevent yellowing, embrittlement, or loss of transparency.
- Humidity & Moisture: Hydrolysis-resistant materials like polypropylene are preferable in wet environments.
- Chemical Exposure: Check compatibility with acids, bases, solvents, or sterilizing agents (e.g., autoclaving, ethylene oxide).
A mesh that maintains its physical and optical properties under expected environmental stresses will deliver consistent performance and reduce replacement frequency.
- Ease of Cleaning and Maintenance
In hygienic industries such as food processing, pharmaceuticals, and medical devices, the ability to clean and sterilize the mesh efficiently is crucial.
- Smooth-surface monofilaments resist biofilm formation and are easier to clean than textured or multifilament fibers.
- Many high-transparency meshes are compatible with backwashing systems, allowing automated cleaning without disassembly.
- Removable mesh panels facilitate manual scrubbing, ultrasonic cleaning, or steam sterilization (SIP – Steam-in-Place).
- Non-stick coatings or hydrophobic treatments can further enhance cleanability.
Easy maintenance reduces downtime, improves process efficiency, and ensures compliance with regulatory standards like FDA, ISO, or HACCP.
| Selection Factor | Ideal Applications | Recommended Materials | Performance Tips |
|---|---|---|---|
| Material Compatibility | Medical devices, chemical processing, biotech | Nylon, PVA, PTFE, Polypropylene | Verify chemical resistance using compatibility charts; avoid hydrolysis-prone materials in wet environments |
| Mesh Size & Open Area | Filtration, optical screens, particle separation | Fine-denier polyester, nylon | Higher open area improves transparency and flow; use micron-rated specs for precision filtering |
| Mechanical Strength | Industrial sieves, pressure filters, vibrating screens | Thick monofilament nylon, polyester | Use reinforced edges for high-tension applications; consider weave type for load distribution |
| Environmental Resistance | Outdoor use, sterilization, extreme temps | UV-stabilized polyester, PTFE, HT-nylon | Test under real-world conditions; monitor for discoloration or brittleness over time |
| Cleanability | Food processing, labs, medical equipment | Smooth-surface PTFE, polypropylene | Design for easy access; prefer backwash-compatible configurations |
Expert Tip: When evaluating transparency, consider both visual clarity and light transmission percentage. Some meshes appear clear but scatter light due to filament thickness or weave pattern—test samples under actual operating conditions before full-scale adoption.
Final Selection Recommendations
- Request sample swatches from suppliers to test optical clarity, flexibility, and fit in your system.
- Consult technical datasheets for pore size distribution, tensile strength, and chemical resistance ratings.
- Ensure the mesh meets relevant industry standards (e.g., ISO 3310-1 for test sieves, USP Class VI for biocompatibility).
- Partner with manufacturers who offer customization in size, shape, and finishing (e.g., heat-sealed edges, mounting frames).
- Document performance over time to refine future selections and improve process reliability.
Choosing the right high-transparency monofilament mesh involves balancing optical clarity, mechanical performance, chemical compatibility, and ease of maintenance. By carefully assessing your application’s demands and leveraging material science insights, you can select a mesh that enhances efficiency, ensures product quality, and extends service life. When in doubt, consult with material engineers or application specialists to validate your choice before integration.
Frequently Asked Questions About Monofilament Mesh
Monofilament mesh is manufactured using a single continuous filament yarn of uniform diameter, which results in highly consistent and precisely defined openings throughout the material. This structural uniformity offers several distinct advantages over traditional multifilament woven mesh:
- Superior Transparency: The use of smooth, single-filament threads allows for greater light transmission and visual clarity, making it ideal for applications requiring visibility, such as viewing screens or optical filters.
- Uniform Pore Size: Each opening in the mesh is nearly identical in size and shape, ensuring predictable and repeatable filtration performance—critical in industries like pharmaceuticals, food processing, and water treatment.
- No Stretch or Deformation: Unlike multifilament meshes that can stretch or deform under tension, monofilament mesh maintains its dimensional stability, providing long-term reliability in dynamic environments.
- Easier Cleaning: The smooth surface of monofilament fibers resists particle adhesion and is less prone to clogging, making it easier to clean and maintain in high-contamination settings.
These benefits make monofilament mesh a preferred choice for precision filtration, industrial screening, and architectural applications where consistency and durability are paramount.
Yes, monofilament mesh is well-suited for outdoor applications due to its robust construction and resistance to environmental stressors. Most monofilament meshes are fabricated from high-performance synthetic polymers such as nylon (polyamide) and polypropylene, both of which are inherently resistant to ultraviolet (UV) radiation.
- UV Resistance: UV-stabilized formulations prevent degradation, discoloration, and embrittlement when exposed to prolonged sunlight, maintaining structural integrity over time.
- Weather Durability: These materials resist moisture absorption, mold, mildew, and temperature fluctuations, making them suitable for use in rain, snow, and extreme heat.
- Common Outdoor Uses: Insect screening for windows and enclosures, solar shading systems, agricultural fencing, pond and pool filters, and ventilation covers on outdoor equipment.
For extended outdoor service life, it's recommended to select a UV-protected grade of monofilament mesh and ensure proper installation to minimize mechanical stress and wind load.
Pore size—defined as the width of the open spaces between the woven filaments—is a critical specification that directly determines the functional capability of monofilament mesh. It influences particle retention, flow rate, pressure drop, and overall filtration efficiency.
- Large Pore Sizes (e.g., 1–5 mm): Ideal for coarse filtration, debris removal, or ventilation applications. Commonly used in drainage systems, sifting machinery, and protective grilles.
- Medium Pore Sizes (e.g., 100–1000 µm): Suitable for separating sand, sediment, or larger particulates in industrial processes, water treatment, and food production.
- Fine Pore Sizes (e.g., 1–100 µm): Used in precision filtration tasks such as chemical processing, pharmaceutical manufacturing, and laboratory sieving, where microscopic contaminants must be removed.
Selecting the correct pore size ensures optimal performance: too large, and contaminants pass through; too small, and the mesh may clog prematurely or restrict flow. Always match the pore size to the smallest particle you intend to capture, while considering flow dynamics and cleaning requirements.
No, most monofilament meshes are not biodegradable. They are typically manufactured from synthetic thermoplastics such as nylon (PA6, PA66) and polypropylene (PP), which are engineered for durability and chemical resistance rather than environmental decomposition.
- Long Lifespan: These materials resist rot, microbial attack, and hydrolysis, allowing them to perform reliably for years—even in harsh conditions.
- Non-Biodegradable Nature: Under normal environmental conditions, monofilament mesh will not break down naturally, contributing to long-term waste if not properly recycled.
- Environmental Considerations: While not biodegradable, some types of monofilament mesh can be recycled at specialized facilities. Research into bio-based or compostable polymers is ongoing, but these are not yet widely available for industrial mesh applications.
For eco-conscious projects, consider end-of-life disposal options or explore alternative materials with lower environmental impact, keeping in mind potential trade-offs in strength and longevity.
Selecting the right monofilament mesh material requires a thorough evaluation of the operational and environmental conditions in which the mesh will be used. Key factors to assess include:
- Chemical Exposure: Determine whether the mesh will come into contact with acids, alkalis, solvents, or other aggressive substances. Polypropylene offers excellent resistance to most chemicals, while nylon performs well in alkaline environments but may degrade in strong acids.
- Temperature Range: Consider the operating temperature. Nylon typically withstands temperatures up to 80–100°C (176–212°F), whereas polypropylene has a lower heat tolerance (up to ~80°C) but performs well in cold environments.
- Mechanical Stress: Evaluate tension, abrasion, and vibration levels. Nylon provides higher tensile strength and elasticity, making it suitable for high-stress applications, while polypropylene is more rigid but lighter in weight.
- UV and Weather Exposure: For outdoor use, ensure the material includes UV stabilizers to prevent premature aging and brittleness.
- Regulatory Requirements: In food, medical, or potable water applications, the mesh must comply with standards such as FDA, NSF, or REACH.
Consulting with a material specialist or supplier and reviewing technical data sheets can help match the ideal monofilament mesh to your specific requirements, balancing performance, cost, and service life for optimal results.
浙公网安备
33010002000092号
浙B2-20120091-4
Comments
No comments yet. Why don't you start the discussion?