Types of Reinforced Fibreglass Mesh
Reinforced fibreglass mesh is a versatile composite material engineered to enhance structural integrity across various industries. Its high tensile strength, resistance to moisture, chemicals, and temperature fluctuations make it ideal for applications ranging from construction to marine and automotive engineering. This guide explores the most common types of reinforced fibreglass mesh, their unique properties, benefits, and optimal use cases.
Reinforced Fibreglass Roving Mesh
Made from continuous high-tensile fibreglass strands woven into an open-grid pattern, this mesh is designed for resin-based reinforcement systems.
Advantages
- Exceptional tensile strength and structural reinforcement
- Large mesh openings allow deep resin saturation (epoxy, polyester)
- Flexible and conforms easily to curved or complex surfaces
- Resistant to water, UV radiation, and chemical exposure
- Ideal for laminating and composite layering processes
Limitations
- Requires resin application for full effectiveness
- Not self-adhesive—needs additional bonding agents
- Less suitable for drywall or quick patch applications
Best for: Boat hulls, automotive body repairs, industrial tanks, and structural laminates in marine and chemical environments
Reinforced Fibreglass Self-Adhesive Mesh
Features a pressure-sensitive adhesive backing that bonds instantly to surfaces without extra glue, making it perfect for drywall and surface repair tasks.
Advantages
- Quick and tool-free installation
- Stays securely in place during joint compound or plaster application
- Prevents cracking at seams, corners, and joints
- Lightweight and easy to cut to size
- Improves durability of interior walls and ceilings
Limitations
- Lower structural strength compared to resin-reinforced types
- Not suitable for exterior or high-moisture environments unless sealed
- Limited use in load-bearing or high-stress applications
Best for: Drywall taping, wall and ceiling repairs, interior renovations, and crack prevention in residential and commercial buildings
Reinforced Fibreglass Mesh for Concrete
Specially engineered to be embedded within concrete slabs to control cracking and improve tensile strength.
Advantages
- Effectively reduces plastic shrinkage and thermal cracking
- Distributes stress evenly across the concrete matrix
- Improves impact resistance and long-term durability
- Chemically inert—does not corrode like steel rebar
- Lightweight alternative to traditional metal reinforcement
Limitations
- Not a substitute for structural steel in heavy-load applications
- Must be properly positioned within the concrete pour
- Less effective if not fully encapsulated by concrete
Best for: Concrete slabs, driveways, pavements, bridge decks, foundations, and industrial flooring where crack resistance is critical
Reinforced Fibreglass Roving Mesh with 1mm Adhesive
Combines the structural strength of roving mesh with a 1mm-thick adhesive layer for superior bonding on challenging surfaces.
Advantages
- High-strength fibreglass core with instant adhesive attachment
- Excellent for uneven, vertical, or hard-to-reach areas
- Reduces labor time and eliminates need for separate adhesives
- Withstands vibration, moisture, and mechanical stress
- Compatible with additional resin coating for enhanced performance
Limitations
- Higher cost than standard roving or self-adhesive mesh
- Adhesive may degrade under prolonged UV exposure
- Requires clean, dry surface for optimal adhesion
Best for: Automotive body reinforcements, marine hull repairs, industrial patching, and high-stress structural bonding applications
| Type | Primary Use | Adhesive | Strength Level | Environmental Resistance |
|---|---|---|---|---|
| Reinforced Fibreglass Roving Mesh | Resin-based laminates | No (requires resin) | Very High | Excellent (moisture, UV, chemicals) |
| Self-Adhesive Mesh | Drywall & surface repair | Yes (pressure-sensitive) | Moderate | Good (interior only) |
| Mesh for Concrete | Crack control in slabs | No (embedded in concrete) | High (tensile) | Excellent (alkali, moisture) |
| Roving Mesh with 1mm Adhesive | High-stress bonding | Yes (1mm thick layer) | Very High | Excellent (moisture, vibration) |
Expert Tip: For outdoor or high-moisture applications, always seal fibreglass mesh edges and surfaces with a compatible resin or protective coating to prevent fraying and maximize longevity, especially when using self-adhesive or hybrid variants.
Industrial Applications of Reinforced Fibreglass Mesh
Reinforced fibreglass mesh is a high-performance composite material renowned for its exceptional strength-to-weight ratio, corrosion resistance, thermal stability, and durability. Its versatility makes it a critical component across a wide range of industrial sectors, where structural reinforcement, crack resistance, and long-term reliability are paramount. By integrating fibreglass mesh into various manufacturing and construction processes, industries achieve enhanced performance, reduced maintenance costs, and extended service life of critical components.
Automotive Industry
In the automotive sector, reinforced fibreglass mesh is extensively used to strengthen plastic components such as bumpers, fenders, and interior panels. By embedding the mesh within resin-based matrices, manufacturers significantly improve the rigidity and impact resistance of parts without adding substantial weight—contributing to fuel efficiency and vehicle performance.
The mesh is also a key ingredient in body fillers and repair adhesives, where it provides structural continuity when repairing cracks, dents, or worn-out areas. This integration ensures durable, weather-resistant repairs that resist shrinking, cracking, and delamination over time. Additionally, fibreglass-reinforced composites are used in under-hood components exposed to high temperatures, offering excellent thermal and chemical resistance.
Marine and Boating
Fibreglass mesh plays a foundational role in the construction and repair of marine vessels. It is laminated into polyester or epoxy resins to form the hulls, decks, bulkheads, and superstructures of boats, yachts, and commercial watercraft. This composite construction delivers a superior strength-to-weight ratio, enabling lighter vessels that are faster, more fuel-efficient, and capable of withstanding harsh marine environments.
The material’s inherent resistance to water, salt, UV radiation, and corrosion ensures long-term structural integrity, even in prolonged exposure to both freshwater and seawater. Unlike metal alternatives, fibreglass does not rust or degrade, significantly reducing maintenance requirements and extending vessel lifespan. It is also used in repairing damaged hulls, providing seamless, watertight reinforcement that restores original strength.
Aerospace Sector
The aerospace industry leverages the lightweight yet high-strength characteristics of reinforced fibreglass mesh for both structural and non-structural components. Used in fuselages, wing panels, fairings, and interior cabin elements, the mesh enhances structural stability while minimizing overall aircraft weight—a critical factor in improving fuel efficiency, payload capacity, and flight performance.
Fibreglass composites offer excellent fatigue resistance and dimensional stability under fluctuating temperatures and pressures. They are also non-conductive and non-magnetic, making them suitable for applications where electromagnetic interference must be avoided. While carbon fibre dominates in high-stress areas, fibreglass remains a cost-effective and reliable option for secondary structures and protective layers.
Construction and Infrastructure
In construction, reinforced fibreglass mesh is widely used to reinforce drywall joints, cementitious plasters, stucco systems, and external insulation finishing systems (EIFS). When embedded in adhesive or plaster, the mesh prevents cracking caused by thermal expansion, settling, or vibration, ensuring a smooth, durable finish on walls and ceilings.
Beyond surface applications, fibreglass mesh is increasingly used in concrete reinforcement, particularly in thin-section concrete elements or where corrosion resistance is essential. It serves as a non-metallic alternative to steel rebar in environments prone to moisture or chemical exposure—such as bridges, tunnels, wastewater treatment plants, and coastal structures. Its alkali-resistant coating ensures long-term performance in high-pH concrete environments.
Wind Energy
Reinforced fibreglass mesh is a cornerstone material in the production of wind turbine blades. These blades must endure constant mechanical stress, cyclic loading, and extreme weather conditions, including high winds, rain, ice, and UV exposure. Fibreglass composites provide the ideal balance of strength, flexibility, and fatigue resistance required for reliable long-term operation.
The mesh is layered within epoxy or polyester resins during the blade manufacturing process, forming a lightweight yet robust structure that can flex under load without fracturing. This enhances energy capture efficiency and reduces the risk of catastrophic failure. As a result, fibreglass-reinforced blades contribute significantly to the durability, safety, and economic viability of wind energy systems.
Oil and Gas Industry
In the oil and gas sector, reinforced fibreglass mesh is integral to the fabrication of corrosion-resistant piping systems, storage tanks, ductwork, and underground containment structures. These components are often exposed to aggressive chemicals, high pressures, and fluctuating temperatures, making traditional metals prone to degradation.
Fibreglass-reinforced polymer (FRP) systems offer exceptional resistance to acids, alkalis, hydrocarbons, and saline environments, ensuring safe and reliable transportation and storage of crude oil, natural gas, refined products, and wastewater. The lightweight nature of FRP reduces installation costs and energy consumption in pumping operations. Additionally, its non-conductive and non-sparking properties enhance safety in hazardous environments.
| Industry | Primary Use | Key Benefits |
|---|---|---|
| Automotive | Component reinforcement, body repair | Lightweight, impact-resistant, durable repairs |
| Marine | Hull and deck construction | Corrosion-resistant, buoyant, low maintenance |
| Aerospace | Structural and interior components | High strength-to-weight ratio, thermal stability |
| Construction | Crack prevention, concrete reinforcement | Alkali-resistant, flexible, improves tensile strength |
| Wind Energy | Turbine blade reinforcement | Fatigue-resistant, flexible, weatherproof |
| Oil & Gas | Piping, tanks, containment systems | Chemical-resistant, non-corrosive, safe in explosive environments |
Note: While reinforced fibreglass mesh offers numerous advantages, proper installation and compatibility with resins, adhesives, and environmental conditions are crucial for optimal performance. Always follow manufacturer guidelines for handling, curing, and application techniques to ensure structural integrity and longevity. In industrial settings, using certified materials and trained personnel helps maintain safety and compliance with industry standards.
Product Specifications and Features of Reinforced Fibreglass Mesh
Reinforced fibreglass mesh is a high-performance construction material widely used for crack prevention, structural reinforcement, and surface stabilization in both residential and commercial applications. Its unique combination of strength, flexibility, and durability makes it ideal for drywall, stucco, plaster, and concrete projects. Below is a detailed breakdown of its technical specifications and key features to help professionals and DIYers make informed decisions.
Technical Specifications
- Material Composition: Made from high-tensile, alkali-resistant fibreglass yarn, this mesh is engineered for long-term durability. The fibreglass is treated to be mildew-resistant and dimensionally stable, ensuring consistent performance in humid or damp environments.
- Thickness: Features a standard 1mm profile with a self-adhesive backing, enabling quick and secure installation without the need for additional fasteners or adhesives. This thin yet robust design integrates seamlessly into wall systems.
- Mesh Size (Aperture): Available in a range of aperture sizes from 2mm to 10mm, allowing customization based on project requirements. Smaller apertures (2–4mm) are ideal for fine crack control in drywall, while larger openings (6–10mm) provide enhanced reinforcement for stucco and exterior plasters.
- Roll Dimensions: Supplied in convenient 20-meter long by 1-meter wide rolls, offering 20 square meters of coverage per roll. This standardized size is suitable for both large-scale renovations and minor repair jobs, minimizing waste and improving efficiency.
- Weight: Weighs approximately 150g/m², striking an optimal balance between lightweight handling and structural strength. This low weight reduces labor strain during installation while maintaining excellent tensile resistance.
- Adhesive Type: Equipped with a high-strength, permanent acrylic pressure-sensitive adhesive. This bond remains effective on a variety of substrates including drywall, concrete, plaster, and wood, ensuring reliable adhesion even under thermal expansion and contraction cycles.
Key Features and Benefits
Exceptional Strength & Durability
The tightly woven fibreglass structure provides superior tensile strength, resisting tearing and stretching during and after installation. Its resistance to mildew, rot, and biological degradation ensures long-term integrity in moist environments such as bathrooms, basements, and exterior walls.
- Withstands structural movement and vibration without compromising bond integrity
- Ideal for high-stress areas like corners, joints, and transitions between materials
- Maintains performance over time, reducing the need for repairs or rework
Lightweight & Easy to Handle
Unlike traditional metal lath or wire mesh, reinforced fibreglass mesh is significantly lighter, making it easier to transport, cut, and apply. No heavy tools or protective gear are required, which enhances worker safety and speeds up project timelines.
- Can be easily cut with utility knives or scissors for precise fitting
- Flexible enough to conform to curved or irregular surfaces
- Reduces fatigue during extended installations
Corrosion & Weather Resistance
Fibreglass is inherently non-metallic, meaning it will not rust, corrode, or degrade when exposed to moisture, salt, or harsh chemicals. This makes it particularly suitable for exterior applications, coastal regions, and industrial environments where metal components would fail prematurely.
- Performs reliably in freeze-thaw cycles and high-humidity conditions
- Resists UV degradation when used under proper coatings
- Maintains structural integrity in both indoor and outdoor settings
Versatile Application Range
This mesh is compatible with a wide range of construction materials and techniques, serving as a universal reinforcement solution across multiple trades.
- Drywall Taping: Replaces paper tape for stronger, more flexible joint reinforcement
- Stucco & EIFS: Acts as a base coat reinforcement layer for exterior insulation systems
- Plaster Repair: Prevents cracking in new or repaired plaster surfaces
- Concrete Overlays: Enhances bond and crack resistance in thin-set cementitious toppings
Crack Prevention & Surface Stability
The fine mesh structure distributes stress across the surface, effectively minimizing the formation and propagation of cracks caused by settling, thermal movement, or substrate shifts.
- Creates a monolithic surface that moves uniformly with the substrate
- Improves finish quality by reducing hairline cracks and surface imperfections
- Extends the lifespan of coatings and finishes by stabilizing the underlying layer
Pro Tip: For best results, embed the mesh fully into the compound or adhesive to ensure maximum adhesion and performance.
Cost-Effective & Time-Saving
Its self-adhesive design eliminates the need for staples, nails, or separate adhesives, significantly reducing labor time and material costs. The durability of the mesh also lowers long-term maintenance expenses.
- Reduces call-backs due to cracking or delamination
- Minimizes material waste with easy-to-measure roll format
- Compatible with most standard finishing products, avoiding specialized training or tools
Smart Choice: Ideal for contractors looking to improve job quality while maintaining efficiency and budget control.
Professional Recommendation: For critical applications such as exterior insulation systems or high-moisture areas, opt for alkali-resistant (AR) fibreglass mesh with a proven track record in demanding environments. Always ensure the surface is clean, dry, and free of contaminants before applying the mesh to achieve optimal adhesion and long-term performance.
| Application Type | Recommended Mesh Size | Installation Method | Primary Benefit |
|---|---|---|---|
| Drywall Joint Taping | 2mm – 4mm | Self-adhesive + joint compound | Smooth, crack-free seams |
| Stucco & EIFS | 4mm – 6mm | Adhered to sheathing or insulation | Structural reinforcement and impact resistance |
| Plaster Repair | 4mm – 8mm | Bonded with plaster or patching compound | Prevents recurring cracks |
| Concrete Crack Control | 6mm – 10mm | Embedded in overlay or repair mortar | Enhances tensile strength and durability |
Additional Considerations
- Storage: Keep rolls in a dry, cool environment away from direct sunlight to preserve adhesive integrity and prevent moisture absorption.
- Compatibility: Works with most water-based and cementitious coatings; always test for adhesion on specialty substrates.
- Sustainability: Non-toxic, recyclable material with no volatile organic compounds (VOCs), contributing to healthier indoor air quality.
- Fire Resistance: Fibreglass is non-combustible and contributes to improved fire ratings in wall assemblies.
- Warranty: Reputable brands often offer 10+ year performance guarantees when installed correctly.
How To Choose Reinforced Fibreglass Mesh: A Comprehensive Buyer’s Guide
Reinforced fibreglass mesh is a versatile and durable construction material widely used to strengthen surfaces and prevent cracking in various building applications. From plastering and drywall installations to concrete reinforcement and resin-based composites, selecting the right type of fibreglass mesh can significantly impact the longevity and performance of your project. This guide provides detailed insights into the key factors to consider when choosing reinforced fibreglass mesh, ensuring you make an informed decision based on application needs, durability, ease of use, and cost-efficiency.
Safety Note: Always wear protective gloves and a dust mask when handling fibreglass materials to avoid skin irritation and inhalation of fine particles. Work in a well-ventilated area, especially during cutting or adhesive application.
Key Factors When Choosing Reinforced Fibreglass Mesh
- Assess Your Project Requirements
Understanding the specific demands of your project is the first step in selecting the appropriate mesh. Reinforced fibreglass mesh is commonly used for:
- Plaster Reinforcement: Prevents cracking and delamination on interior and exterior walls.
- Drywall Joint Taping: Provides seamless joints and strengthens corners and seams.
- Cementitious Applications: Enhances tensile strength in renders, stucco, and EIFS (Exterior Insulation and Finish Systems).
- Overlay Systems: Ideal for repairing or reinforcing existing concrete surfaces.
- Select the Appropriate Mesh Size (Aperture)
The mesh size—measured by the width of the openings between the fibres—determines its suitability for different tasks:
- Fine Mesh (2mm–4mm): Best for thin-set applications like plastering, skim coating, and drywall taping where a smooth finish is required.
- Medium Mesh (5mm–8mm): Suitable for general rendering and lightweight concrete reinforcement.
- Coarse Mesh (10mm and above): Recommended for heavy-duty concrete reinforcement, structural repairs, and external insulation systems requiring maximum strength.
- Prioritize Quality and Durability
High-quality fibreglass mesh resists degradation in harsh environments. Look for these critical features:
- Alkali Resistance: Essential for cement-based applications, as standard glass fibres can deteriorate when exposed to high pH levels. Alkali-resistant (AR) glass is specially treated to withstand these conditions.
- UV Stability: If the mesh will be exposed to sunlight before covering, choose UV-resistant varieties to prevent premature weakening.
- Tensile Strength: Measured in N/50mm, higher tensile values indicate greater resistance to stretching and tearing under stress.
- Choose the Right Thickness and Adhesion Type
The thickness (weight per square meter, typically 120g–220g) affects durability and support:
- Lightweight (120–150g/m²): Ideal for interior drywall and decorative finishes.
- Medium Weight (160–180g/m²): Suitable for exterior plaster and general reinforcement.
- Heavy-Duty (200–220g/m²+): Used in structural applications and high-stress environments.
- Self-Adhesive Mesh: Features a pre-applied adhesive backing for quick and easy installation, especially useful for patching and corner reinforcement.
- Ensure Compatibility with Resins (For Composite Applications)
If using fibreglass mesh in conjunction with resins for laminating, moulding, or waterproofing:
- Epoxy Resin: Offers superior bonding strength, chemical resistance, and durability. Fibreglass mesh works exceptionally well with epoxy, making it ideal for marine, industrial, and high-performance applications.
- Polyester Resin: More affordable but less durable than epoxy. Ensure the mesh is compatible with styrene-based resins to avoid delamination.
- Always confirm resin compatibility with the manufacturer’s specifications to ensure proper saturation and curing.
- Consult Suppliers for Expert Guidance
With a wide variety of products available, professional advice can be invaluable. Reputable suppliers can provide:
- Technical data sheets (TDS) and safety data sheets (SDS)
- Sample materials for testing
- Recommendations based on regional climate, substrate type, and project scale
- Information on certifications (e.g., ISO, CE marking)
- Optimize Budget Without Compromising Quality
Cost-effective purchasing strategies include:
- Bulk Buying: Purchasing from wholesalers or distributors in larger quantities reduces per-unit cost, especially for large-scale construction projects.
- Comparing Brands: Evaluate performance versus price—premium brands often offer better longevity and fewer callbacks.
- Calculating Coverage: Measure your surface area accurately to avoid over-ordering or shortages.
- Consider long-term savings: higher-quality mesh may have a higher upfront cost but reduces maintenance and repair expenses over time.
| Mechanical Property | Standard Range | Recommended Use | Key Benefit |
|---|---|---|---|
| Mesh Size (Aperture) | 2mm – 10mm+ | Fine: Plastering | Coarse: Concrete | Match to application for optimal finish and strength |
| Weight (g/m²) | 120 – 220+ | Light: Drywall | Heavy: Structural | Higher weight = greater impact resistance |
| Tensile Strength | 75 – 300 N/50mm | Depends on fibre density and coating | Prevents cracking under stress |
| Alkali Resistance | AR-glass compliant | Cement, render, stucco | Long-term durability in alkaline environments |
| UV Resistance | Limited to 30–60 days (unless coated) | Temporary outdoor exposure | Prevents fibre degradation before covering |
Expert Tip: Always perform a small test patch before full-scale application. This allows you to evaluate adhesion, compatibility with your compound or resin, and ease of finishing—helping avoid costly mistakes on larger surfaces.
Final Recommendations
- Store fibreglass mesh in a dry, cool place away from direct sunlight to preserve its integrity.
- Cut mesh with sharp utility knives or scissors to prevent fraying.
- Overlapping seams by at least 50mm ensures continuous reinforcement across joints.
- Follow manufacturer instructions for embedding depth and curing times when used with coatings or resins.
- For exterior applications, always seal the mesh completely to protect against moisture and environmental exposure.
Selecting the right reinforced fibreglass mesh is a balance of technical requirements, environmental conditions, and budget considerations. By understanding the nuances of mesh size, material quality, adhesion type, and compatibility, you can ensure a strong, crack-resistant finish that stands the test of time. When in doubt, consult with material specialists or suppliers to match the best product to your project’s unique demands.
Frequently Asked Questions About Reinforced Fibreglass Mesh
Reinforced fibreglass mesh is a high-performance construction material made from premium-grade fibreglass strands that are precisely woven into a durable, flexible, and lightweight fabric. This mesh is engineered to significantly enhance the structural integrity of building materials such as plaster, stucco, concrete, and drywall.
It is inherently resistant to a wide range of environmental and chemical challenges, including mildew, alkalis, acids, and extreme weather conditions. These properties make it especially well-suited for both outdoor and industrial applications where longevity and reliability are critical.
One of its key functional benefits is its ability to evenly distribute stress across surfaces, which helps prevent cracks from forming and spreading. By reinforcing vulnerable areas, it contributes to the long-term durability and stability of the finished structure.
Reinforced fibreglass mesh offers several significant advantages over traditional metal mesh, making it a preferred choice in modern construction and renovation projects:
- Lightweight & Easy to Handle: Its low weight simplifies transportation, cutting, and installation, reducing labor time and physical strain.
- Corrosion-Resistant: Unlike steel or iron mesh, fibreglass does not rust or corrode, even in humid or chemically aggressive environments.
- Superior Crack Control: It effectively minimizes the formation of hairline cracks and structural fractures in plaster, drywall, and cementitious coatings.
- No Chemical Reactions: It remains inert when embedded in alkaline materials like concrete or stucco, avoiding the deterioration that can affect metal reinforcements.
- Versatility: Suitable for a wide range of applications including interior drywall joints, exterior insulation systems (EIFS), tile backing, and repair patches.
These benefits make reinforced fibreglass mesh a more durable, cost-effective, and maintenance-free alternative to metal mesh in most building scenarios.
Reinforced fibreglass mesh is widely used in both residential and commercial construction to strengthen and stabilize various building materials. It is typically embedded within or layered onto surfaces during the application of:
- Stucco and EIFS (Exterior Insulation and Finish Systems): Provides tensile strength and impact resistance to exterior walls.
- Plaster and Drywall: Reinforces joints and corners, preventing cracks in interior finishes.
- Concrete Overlays and Repair Mortars: Enhances flexural strength and reduces shrinkage cracking.
- Tiling Installations: Acts as a backing layer to improve adhesion and prevent substrate movement from affecting tiles.
The mesh works by distributing mechanical stresses across a broader area, increasing the flexibility and resilience of the surface. This integration not only improves the material’s resistance to cracking but also enhances overall durability, making it ideal for both interior and exterior construction projects.
Yes, reinforced fibreglass mesh is exceptionally well-suited for outdoor use due to its advanced material properties. It is specifically designed to withstand harsh environmental conditions without degrading.
Key features that make it ideal for exterior applications include:
- UV Resistance: Treated with special coatings to resist degradation from prolonged sun exposure.
- Alkali Resistance: Maintains strength and integrity when embedded in cement-based materials, which have high pH levels.
- Waterproof & Mold-Resistant: Does not absorb moisture and resists the growth of mould, mildew, and fungi—common issues in damp or humid climates.
- Thermal Stability: Performs reliably across a wide temperature range without warping or losing effectiveness.
These characteristics make it a top choice for exterior applications such as stucco reinforcement, roofing underlayment, siding support, and façade systems, where long-term performance and weather resistance are essential.
Reinforced fibreglass mesh plays a critical role in managing and preventing cracks in concrete and cement-based surfaces. While it is not a substitute for structural rebar in load-bearing applications, it excels at controlling non-structural, surface-level cracking caused by shrinkage, temperature changes, and minor ground movement.
Here’s how it works:
- Stress Distribution: The mesh spreads applied loads and internal stresses evenly across the surface, reducing localized pressure that can lead to cracks.
- Reinforcement of Weak Points: It is especially effective at strengthening joints, corners, and edges—areas most prone to cracking.
- Controlled Flexibility: Allows for slight movement and expansion without breaking the surface bond, maintaining integrity over time.
- Shrinkage Compensation: Helps counteract the natural shrinkage that occurs as concrete or mortar cures.
This makes reinforced fibreglass mesh an essential component in applications such as sidewalks, driveways, patios, industrial flooring, and wall overlays, where surface durability and aesthetic continuity are important. By minimizing cracks, it extends the lifespan of the structure and reduces maintenance costs.
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