FAQ - Composite-Tech Equipment and GFRP Technology
GFRP Technology & Steel Comparison
What is GFRP rebar and how is it made??
GFRP (Glass Fiber Reinforced Polymer) rebar is a non-metallic, corrosion-resistant reinforcing material made by pultruding glass fibers through a thermosetting resin. It is widely used in infrastructure, marine, and chemical environments.
How does GFRP rebar compare to traditional steel reinforcement?
GFRP is 4x lighter, 2x stronger in tensile strength, non-corrosive, and non-magnetic. Unlike steel, it does not rust, making it ideal for long-lasting structures.
Learn more: GFRP Rebar vs Steel Rebar: Technical Comparison
Where is GFRP rebar used most often?
GFRP is commonly used in bridges, tunnels, precast panels, coastal constructions, retaining walls, foundations, and water treatment plants.
Composite-Tech Equipment
What types of machines does Composite Tech manufacture?
We build production lines for GFRP rebar, fiberglass mesh, bent elements, and fiber cutting systems. Our top models include CT-2, CT-4, CT-6, CT2M, CT1M, CT-BE, and CT-Fiber, CT-Pipe.
Which machine should I choose for high-volume production?
For maximum output, our CT-6 line produces up to 6 GFRP rods simultaneously at speeds up to 6 m/min, yielding over 50,000 meters per day.
Do you offer mesh production equipment?
Yes, our CT2M line is optimized for continuous production of fiberglass mesh used in plastering, wall reinforcement, and facade systems.
Can your machines be customized?
Installation, Training & Support
How long does installation take?
Standard installation takes 2–3 working days. Our engineers can travel to your site or support you remotely.
Do you provide training for machine operators?
Yes. On-site or remote training is provided, usually within 1–2 days.
Is post-installation support available?
Of course. We offer lifetime remote support, technical consultations, and spare part supply.
Production Process & Materials
What raw materials are needed to produce GFRP?
You need fiberglass roving, thermosetting resin (polyester, vinyl ester, or epoxy), sand coating (optional), catalysts, and packaging materials.
Learn more: How to Choose Raw Materials for the Production of Composite Rebar
Can your machines work with basalt fiber or carbon fiber?
Yes. With specific adaptations, our machines can handle basalt or carbon fiber for high-performance applications.
How much resin is consumed per meter of GFRP rebar?
Typically, around 90–130 grams of resin per meter depending on diameter and coating.
Can I automate the cutting and packaging process?
Pricing & Payment
What is the price of a GFRP rebar production line?
Prices vary depending on capacity and automation. Our standard CT-4 line starts at around $95,000. Mesh and bent element lines are priced separately.
Are discounts available for bulk purchases?
Yes. We offer discounted pricing for partners buying multiple machines or becoming exclusive representatives.
What are your payment terms?
Standard terms: 50% advance and 50% before shipping. For some countries, we accept Letters of Credit or staged payments.
Do you offer leasing or financing?
We don’t offer in-house financing, but we provide pro-forma invoices and documentation to support bank loans or government subsidies.
Are taxes included in the price?
Our prices are quoted EXW or CIF. VAT, customs duties, and local taxes are buyer’s responsibility.
Logistics & Delivery
Do you deliver worldwide?
Yes. We export to over 30 countries. Delivery is organized via sea or road freight, depending on location.
How long does delivery take after payment?
Production takes 4–6 weeks. Delivery adds 1–6 weeks depending on your country.
Who is responsible for customs clearance?
We assist with all export documentation. Final clearance is handled by the buyer or their customs broker.
Can I arrange my own transport?
Absolutely. You’re welcome to use your preferred freight forwarder. We’ll coordinate packaging and loading.
Warranty & Spare Parts
What warranty do you provide?
All equipment comes with a 12-month warranty covering all manufacturing defects. Extended warranties are available.
Do you supply spare parts internationally?
Yes. We maintain stock and ship globally. Most parts are shipped within 1–2 working days.
Is remote troubleshooting available?
Yes. We provide remote diagnostic support via video, photos, or direct chat with engineers.
Can I order a spare parts kit with the machine?
Yes. We recommend a startup kit with essential components for 6–12 months of operation.
Business Opportunities & ROI
What is the expected return on investment (ROI)?
Depending on your production scale and local prices, ROI is usually 6–12 months. Many clients recover costs within the first year.
Learn more: Why Producing GFRP Rebar is Profitable? Complete Cost Calculation
Do you provide business plans or investment models?
Yes. We can provide ROI calculators and sample business plans to help you attract investors or banks.
How profitable is a GFRP rebar business?
Very profitable: high margins, growing global demand, and minimal labor costs due to automation. Rebar prices range from $0.5 to $1.5 per meter depending on diameter and region.
Can I become your exclusive dealer in my country?
Yes. We are open to exclusive representation agreements with partners who can promote and sell effectively in their markets.
Technical Standards & Certification
Does your equipment produce rebar that meets ASTM or ISO standards?
Yes. Our machines are designed to produce rebar that complies with ASTM D7957, ISO 10406-1, and other international standards.
Do I need certification to sell GFRP in my country?
In many countries, certification is required for infrastructure projects. We assist with sample testing and certification procedures.
Can you provide test reports or documentation for authorities?
Yes. We can supply technical datasheets, testing results, and third-party lab reports upon request.
Resins & Raw Materials
What resin types are compatible with your machines?
Polyester, vinyl ester, and epoxy resins are compatible. The choice depends on application and chemical resistance needs.
Do you supply raw materials?
We can recommend trusted global suppliers for fiberglass, resins, catalysts, and sand coatings. We don’t sell materials directly.
Is sand coating necessary?
For construction applications where adhesion to concrete is critical, sand coating improves bonding. It’s optional but highly recommended.
Customization & Special Requests
Can I request custom diameters or shapes for GFRP rebar?
Yes. We can supply custom mandrels for various diameters (4 mm to 32 mm) or design molds for flat, spiral, or specialty profiles.
Is automation available for quality control?
Yes. Optional vision systems and sensors can monitor diameter, resin impregnation, and cure consistency.
Can I integrate your line into an existing automation system?
Yes. Our lines support PLC integration, and we can work with your automation team to sync systems.
Site Setup & Factory Layout
How much space is needed to install a GFRP rebar production line?
A typical CT-6 line requires about 80–100 m². Additional space is needed for material storage and packaging.
Do you provide factory layout drawings?
Yes. After order confirmation, we provide detailed layout plans for optimal equipment placement and workflow.
What are the electrical requirements?
Standard voltage is 380V, 3-phase, 50/60 Hz. Power consumption varies between 15–25 kW depending on the line.
Can I operate the line in extreme climates?
Yes. Our equipment functions in temperatures from -10°C to +45°C. Special adaptations are available for harsher environments.
Safety & Compliance
Is the equipment CE certified?
Yes. All machines are CE-marked and built according to European safety regulations.
What safety features are included in the equipment?
Emergency stops, protective panels, thermal overload relays, resin spill containment, and optional smoke extractors.
Do operators need special licenses?
No formal license is required, but basic technical skills and training (provided by us) are necessary.
Environmental Benefits & Sustainability
Is GFRP an eco-friendly alternative to steel?
Yes. GFRP rebar is non-corrosive, requires no maintenance, and extends the service life of structures—reducing CO₂ emissions over time.
Learn more: Environmental Performance of FRP
Can recycled materials be used in GFRP production?
Recycled fibers are not recommended due to reduced mechanical performance. However, GFRP itself is recyclable via thermal or mechanical processes.
Does your equipment produce hazardous emissions?
No. Our production lines operate with closed resin systems. With proper ventilation and safety measures, emissions are minimal and within regulations.
Can GFRP be used in green-certified projects (e.g., LEED)?
Yes. GFRP is recognized for its contribution to durability, sustainability, and reduction of maintenance needs.
Representation & Partnership
Can I represent Composite-Tech in my region?
We are actively seeking exclusive partners in various countries. Contact us to discuss dealership or JV opportunities.
What are the requirements to become an exclusive distributor?
Market knowledge, technical capacity, and a minimum annual target (usually 12 machines/year).
How do you protect your equipment from being copied?
Our contracts contain strong IP protection clauses, and our designs are registered. We also pursue legal action in case of violations.
Can you white-label the equipment with my brand?
In select cases — yes. OEM agreements are available under NDA with volume commitments.
Do you support co-branded marketing?
Yes. We can supply brochures, videos, and technical documentation with your company branding.
GFRP Fiber for Concrete
What is GFRP fiber and how is it different from steel fiber?
GFRP (Glass Fiber Reinforced Polymer) fiber is a high-performance, non-corrosive material used to reinforce concrete. Unlike steel fiber, GFRP fiber does not rust, is lighter, and has excellent tensile strength. It’s made of glass roving impregnated with resin and cut to precise lengths from 5 mm to over 50 mm.
Learn more: GFRP Fiber for Concrete: A Revolutionary Solution for Concrete Reinforcement
Can GFRP fiber fully replace steel fiber in concrete applications?
Yes. GFRP fiber can replace steel fiber in many applications, including industrial floors, precast elements, pavements, shotcrete, and slabs. It improves crack control, tensile performance, and durability while reducing weight and corrosion risks.
GFRP fiber has tensile strength up to 1,500 MPa, while steel fiber typically ranges 900–1,200 MPa.
What diameters and lengths are available for your GFRP fiber?
What is the recommended dosage of GFRP fiber per cubic meter of concrete?
The dosage varies by application:
• Light structural concrete: 1–2 kg/m³
• Industrial floors: 2–4 kg/m³
• Shotcrete or tunnel linings: up to 5 kg/m³
GFRP fiber has 3–4x lower density than steel fiber, so by weight you use less, and it distributes more evenly.
Is GFRP fiber compatible with standard concrete mixers?
Yes. Our fiber can be added directly into drum mixers, planetary mixers, or ready-mix trucks without the need for special equipment. No clumping, even at higher doses.
How does GFRP fiber improve crack resistance in concrete?
GFRP fiber forms a 3D reinforcement network inside concrete. It arrests microcracks at an early stage, redistributes stress, and improves post-crack toughness. It is especially effective in reducing shrinkage and thermal cracking.
Tested according to ASTM C1609 and EN 14651 for flexural performance.
Has the performance of GFRP fiber been tested and certified?
Yes. Our GFRP fiber has been tested in certified European laboratories. Key results:
• Flexural toughness index improvement: +40–70%
• Shrinkage crack reduction: up to 80%
• Improved concrete tensile strength: +20–30%
In which applications is GFRP fiber most effective?
• Industrial floors and slabs-on-grade
• Precast panels and elements
• Shotcrete and sprayed concrete
• Marine and water-exposed structures
• Tunnel linings and infrastructure projects
• Lightweight structures and facades
How does GFRP fiber affect concrete workability?
Our fiber is engineered for optimal dispersion and low impact on slump. Compared to steel or synthetic fibers, it maintains better flowability, especially in self-compacting concrete (SCC) and pumped mixes.
Can GFRP fiber be used in combination with rebar or mesh?
Yes. GFRP fiber can be used as secondary reinforcement alongside GFRP rebar or mesh to enhance crack control and improve ductility. Ideal for precast and structural elements where multi-directional reinforcement is needed.
Use Cases & Industries
Is GFRP rebar suitable for road construction?
Yes. GFRP rebar is ideal for roads, highways, airport runways, and concrete overlays. It eliminates corrosion problems caused by road salt, water ingress, and freeze-thaw cycles — significantly extending pavement lifespan.
Studies show up to 2x longer service life of concrete pavements reinforced with GFRP vs steel.
Learn more: Applications of GFRP rebar in Road Construction
Can GFRP rebar be used in bridge construction?
Example: 200-meter GFRP-reinforced bridge deck in Canada, 2018 – still corrosion-free.
Is GFRP reinforcement effective in tunnels or underground structures?
Unlike steel, GFRP does not interfere with signal equipment and does not require cathodic protection.
Can I use GFRP in marine or coastal structures?
• Seawalls and bulkheads
• Floating docks
• Bridge piers and abutments
• Offshore platforms
GFRP maintains structural integrity even after 1000+ hours of salt spray exposure (ASTM B117).
Is GFRP rebar accepted in government tenders and public infrastructure projects?
Yes. Many countries (USA, Canada, UAE, India, EU members) have approved GFRP in public projects. Our machines produce rebar compliant with ASTM D7957, ISO 10406-1, ACI 440, etc.
Is GFRP rebar suitable for precast concrete elements?
Definitely. It is widely used in precast:
• Retaining wall panels
• Precast slabs
• Noise barriers
• Vaults and tanks
• Lightweight prefab housing
GFRP’s low weight makes it perfect for crane-lifted elements and reduces transport costs.
Can GFRP be used in 3D concrete printing?
Yes. Short GFRP rods or fibers can be embedded into 3D-printed concrete layers to increase tensile strength and crack resistance without affecting printability.
Composite-Tech is developing integration modules for GFRP-based reinforcement in concrete printing systems.
Is GFRP used in dam or hydro project construction?
Yes. In spillways, sluice gates, and hydro channels, GFRP provides non-corrosive reinforcement where moisture and chemical exposure are extreme.
Is GFRP suitable for nuclear or electromagnetic-sensitive projects?
Yes. GFRP is non-conductive and non-magnetic, making it suitable for use in:
• Nuclear plants
• MRI rooms
• Electrical substations
• Data centers
GFRP eliminates induced currents and magnetic field distortions caused by steel.
Are there case studies of GFRP in large-scale infrastructure?
Yes. Projects worldwide:
• Dubai Metro (UAE)
• Champlain Bridge (Canada)
• Lusail Stadium precast panels (Qatar)
• Port installations in Norway
How does GFRP perform under freezing conditions?
Unlike steel, GFRP does not expand or degrade under freeze–thaw cycles. It retains mechanical properties in extreme cold (tested to -40°C)
Fiberglass Mesh Applications
What is fiberglass mesh used for in construction?
Fiberglass mesh is primarily used for reinforcing floors and road bases, as well as plaster, EIFS systems, and facade coatings. It improves tensile strength, crack resistance, and structural durability in concrete and cement-based layers.
Learn more: The Impact of GFRP Mesh: Transforming the Construction Industry
Can fiberglass mesh be used for roads and industrial floors?
Yes. It is increasingly used in road overlays, industrial slabs, and subbase reinforcement to control shrinkage and thermal cracking. GFRP mesh offers high strength-to-weight ratio and corrosion resistance, making it ideal for demanding environments.
Tested under heavy load simulations: crack width reduction up to 70% in floor applications.
What mesh diameters do you offer?
• Standard fiberglass mesh: from 2 mm to 6 mm diameter, suitable for floors, slabs, and road bases.
• Structural mesh (GFRP bars): from 6 mm to 16 mm, made using heavy-duty machinery for structural applications.
Do you manufacture equipment for heavy structural mesh production?
What are the available mesh opening sizes?
We provide meshes with cell dimensions of:
• 50×50 mm
• 100×100 mm
• 150×150 mm
• 200×200 mm
Custom sizes are available upon request, depending on your project needs.
Is fiberglass mesh suitable for facade systems?
Yes. Our mesh is used in EIFS and ETICS facade systems for insulation layer reinforcement. It provides crack bridging and weather resistance in both base and finish coats.
What is alkali-resistant fiberglass mesh?
Alkali-resistant (AR) fiberglass mesh resists degradation from the high pH of cement. It is coated with acrylic or PVC binder to ensure long-term durability when embedded in concrete or plaster.
Can fiberglass mesh be used in self-leveling floors?
Yes. It is particularly effective in thin floor toppings, screeds, or heated flooring systems, enhancing tensile strength and preventing microcracking.
How does fiberglass mesh compare to metal mesh in concrete?
Fiberglass mesh is lighter, rust-proof, easier to cut and install, and does not corrode over time. It is also more elastic, which helps distribute stresses more evenly.
Is your mesh suitable for machine plastering or automated installation?
Yes. Mesh rolls unroll smoothly and can be integrated with semi-automatic or fully automated plastering systems.
Business & Marketing
How can I start a GFRP rebar production business?
1. A production line (like CT-4 or CT-6)
2. Workspace of ~100 m² with 3-phase electricity
3. Access to raw materials: roving, resin, catalyst
4. 1–2 trained operators
5. Sales channel (construction companies, distributors, tenders)
We assist with factory setup, training, and sales strategies.
How profitable is a GFRP rebar or mesh production business?
Example: A CT-6 line producing 40,000 meters/day at $0.50/m = $20,000/day revenue potential.
Do you provide a business plan or ROI calculator?
Can I get support for raw material sourcing?
Do you help with product certification in my country?
Yes. We provide test samples, technical datasheets, and assistance with local laboratory testing. GFRP rebar is already accepted in many national standards.
Can I get marketing support as a reseller or distributor?
Yes. We offer:
• Product brochures with your logo
• Social media visuals
• Presentation templates
• Technical data sheets
• Guidance on tender participation
What is the minimum monthly production to be profitable?
In most markets, producing 15,000–25,000 meters/month of GFRP rebar ensures profitability. For mesh or fiber, volume depends on regional demand and material costs.
Do you offer exclusivity in a specific region or country?
Yes. We offer exclusive representation contracts with performance targets (e.g., 12 machines/year). This protects your market and ensures stable pricing.
Can I get financing through government programs?
In many countries, FRP production is eligible for:
• Innovation grants
• Circular economy subsidies
• Energy-efficiency funding
We help prepare documentation for such applications.
What is the average investment required to launch a full line?
A full GFRP rebar or mesh plant costs from $80,000 to $250,000 depending on automation level, additional modules, and production targets.
Do you offer modular expansion options?
Yes. Our equipment is designed for scalable growth. You can start with a basic setup and later add:
• Additional pulling lines
• Cutting and packaging automation
• Online QC modules
• Mesh or fiber production lines
Can I produce both rebar and mesh in the same facility?
Yes. Many clients operate both systems side-by-side. This allows diversification and better use of raw materials and staff.
Technology & Process
What makes Composite-Tech GFRP rebar and mesh production lines different from other fiberglass rebar machines?
Our lines are built around a patented technological chain: controlled roving pre-heating, three-stage resin impregnation, programmable rib winding at any angle, short-wave infrared booster ovens and two-stage cooling (air + water). This combination gives higher fiber wet-out, more stable geometry and better surface quality than conventional FRP lines that use only simple baths and single-stage water cooling.
Why do you pre-heat the glass roving before the resin bath?
Pre-heating is the first module on our lines. It gently evaporates residual moisture and removes excess silane from the rovings. This frees up space inside the fiber bundles for resin, so the resin can penetrate much deeper, which directly improves bond strength, durability and consistency of the final GFRP rebar or mesh.
How does silane removal improve GFRP rebar quality?
Silane is necessary in glass fiber production, but in pultrusion it can partially block resin penetration. When we remove the excess silane in our pre-heating unit, the resin can reach each individual filament. That increases the effective glass–resin contact area, giving higher tensile strength, better shear performance and more predictable long-term behavior in concrete.
What is special about your three-stage resin impregnation system?
Our impregnation bath combines three methods in one compact module:
- Pneumatic squeezing rollers that mechanically press resin deep between the filaments,
- Ultrasonic impregnation that breaks surface tension and pushes resin into the smallest capillaries,
- A special grid (sieve) section that stabilizes fiber alignment, improves final wet-out and removes excess resin.
This multi-stage approach is patented and unique to Composite-Tech, and it is a key reason why our customers consistently achieve top-tier mechanical properties.
Why is ultrasonic impregnation important for fiberglass rebar and mesh?
Ultrasonic waves help the resin penetrate even micro-filaments inside the roving bundle. Instead of just coating the outside of the bundle, ultrasound drives the resin into the core, reducing dry spots and voids. This leads to higher tensile strength, better fatigue performance and more uniform quality along the entire length of the bar or mesh strand.
How does the pneumatic squeezing in the impregnation bath work?
After the rovings are flooded with resin, they pass through pneumatic squeezing rollers that are precisely pressure-controlled. These rollers physically push resin between the filaments and remove the surplus from the surface. As a result, you get optimum fiber volume fraction: enough resin to fully wet the glass, but not so much that it increases cost or creates surface defects.
What does the special grid in the impregnation module do?
The grid section serves two functions: it gently “combs” and aligns the rovings, and it scrapes off excess resin without damaging the fibers. This stabilizes the shape of the future bar or mesh strand and guarantees consistent diameter and surface quality before the product enters the rib-winding unit and curing ovens.
How is the rib winding on Composite-Tech CT-4 and CT-6 lines different from other systems?
Our rib-winding module is fully programmable: it can apply ribs at any angle, with adjustable pitch and height, while maintaining high line speed. This means you can optimize rib geometry for different national standards and concrete mixes, instead of being limited to one fixed angle as on many conventional machines.
Why does rib angle matter for bond with concrete?
The rib angle, pitch and height directly affect bond strength and slip behavior in concrete. By tuning the rib angle to match the modulus of GFRP and the aggregate properties of your concrete, you can significantly improve adhesion and crack control. Our flexible rib-winding system allows you to fine-tune the profile for bridges, slabs-on-grade, precast elements or marine structures.
What is a short-wave infrared booster oven and why do you use it?
The first curing stage on our lines is a short-wave infrared (IR) booster oven. Short-wave IR penetrates into the core of the bar and starts polymerization from the inside out. This reduces internal stresses, prevents surface burning and helps avoid defects that can appear when heating is only from outside with long-wave IR or hot air.
Curing & Cooling
How is your curing system different from standard FRP lines?
Standard lines often rely on a single long oven and then drop the hot bar directly into cold water. Our technology splits the process:
- IR booster starts polymerization inside the bar,
- a secondary oven completes curing with controlled temperature profile,
- only then does the product enter our two-stage cooling system.
This sequence greatly reduces internal stresses, surface degradation and microcracking.
Why do you use two-stage cooling (air + water) instead of direct water cooling?
When GFRP rebar exits the oven, its temperature is usually over 200°C. If you put it directly into cold water, a severe thermal shock can create microcracks in the surface and interlaminar zones. We first use forced air cooling to reduce the peak temperature, and only after that send the bar into the water bath. This way, the surface stays intact, long-term durability increases and the product easily passes aggressive durability tests.
What problems can thermal shock cause in fiberglass rebar?
Thermal shock leads to microcracks and internal stresses that are not visible to the naked eye, but they reduce tensile strength, fatigue life and chemical resistance over time. Such bars may pass simple factory tests but degrade prematurely in service. Our controlled cooling sequence is designed specifically to eliminate this risk.
Does the two-stage cooling system reduce line productivity?
No. Our air-cooling section is compact and optimized for the actual heat capacity of the product, so the line speed remains high. In practice, our CT-4 and CT-6 lines combine high throughput with superior surface quality, which is crucial for customers working under stringent standards such as ACI 440.11-22 and ISO 10406-1.
How do you control the temperature profile during curing?
Temperature in each oven zone is controlled by independent sensors and PLC logic. Recipes for different diameters and resin systems can be saved and recalled from the HMI. This guarantees repeatable curing, stable mechanical properties and simplifies quality documentation for audits and certification.
Components, Reliability & Maintenance
What components do you use in Composite-Tech equipment?
We source only high-quality industrial components from leading European, American and Japanese manufacturers – including bearings, gearboxes, pneumatic systems, sensors, PLCs and HMIs. This ensures long service life, easy access to spare parts worldwide and high reliability of every production line.
How many operators are required to run a Composite-Tech rebar or mesh line?
Most of our lines are designed for two operators per shift: one handles the roving creels and resin system, the other supervises the line control panel, rib-winding and cutting. High automation reduces labor cost and human error, while keeping the process stable at high speeds.
What is the typical installed power and energy consumption of your lines?
Installed power depends on configuration and diameter range, but most CT-series lines for GFRP rebar and mesh operate within 15–30 kW of active consumption during normal production. Thanks to efficient ovens, insulation and drives, energy cost per meter of rebar or per square meter of mesh stays very low compared with the product’s market value.
How difficult is it to maintain Composite-Tech equipment?
Our lines are designed for simple daily and weekly maintenance: cleaning resin tanks and filters, checking lubricant levels, inspecting bearings and guides, and calibrating sensors. We provide full maintenance schedules, spare parts lists and remote support. With minimal care, customers run our equipment 24/7 for many years.
Do you provide remote diagnostics and software updates?
Yes. The control system supports remote access (through a secure VPN or customer-approved channel). Our engineers can help diagnose process issues, optimize recipes and install software updates without interrupting production more than necessary.
Quality, Standards & Testing
Can your GFRP rebar and mesh meet ACI 440.11-22 requirements?
Yes. Our patented process was developed specifically to achieve and exceed ACI 440.11-22 mechanical property requirements for GFRP rebar. Customers using Composite-Tech lines regularly obtain tensile strength, modulus, bond and durability results that are at or above the levels specified in ACI and related ASTM standards, when correct raw materials and process settings are used.
Learn more: What Is ACI 440.11-22?
Can GFRP products from your lines comply with ASTM D7957 and ISO 10406-1?
Our technology, combined with proper quality control, allows producers to meet ASTM D7957 for solid GFRP bars and ISO 10406-1 for FRP reinforcement. We provide recommended testing programs, typical property ranges and documentation that helps you align your internal QC with these standards.
How do you help new plants build a quality control system?
Together with the equipment, we deliver sample QC procedures: incoming inspection of rovings and resin, in-process checks, destructive tests on finished bars and mesh, traceability templates and calibration guidelines. We also advise on setting up a small in-house laboratory or cooperating with accredited external labs.
What typical mechanical properties can customers expect from GFRP rebar produced on Composite-Tech lines?
Exact values depend on raw materials and bar diameter, but our customers typically achieve: high tensile strength (well above traditional steel yield strength), stable modulus, strong rib-to-core adhesion and excellent durability in alkaline and chloride environments. On request, we share anonymized test reports from different markets to illustrate achievable performance.
Do you support certification with organizations like FRP Institute, DOTs or independent labs?
Yes. We cooperate with certification bodies and independent institutes worldwide. Our role is to provide process documentation, equipment specs and technical support so that your plant can pass audits and qualification tests required by FRP Institute, DOT agencies or local standards organizations.
Business, ROI & Costs
What is the typical payback period for a GFRP rebar or mesh plant using Composite-Tech equipment?
Payback depends on local prices and production volume, but in many cases our customers reach full payback within 1–3 years. Low raw-material cost, high productivity and growing market demand for corrosion-free reinforcement make GFRP production a high-margin industrial business.
How low can the production cost of GFRP rebar be on your lines?
Using modern resin systems and bulk glass fiber, the raw material cost of #3 (10 mm, 3/8″) GFRP rebar is typically only a few cents per foot. With optimized energy, labor and depreciation, total production cost remains significantly below typical market prices, leaving attractive margins for both plant owners and distributors.
Is GFRP mesh production as profitable as GFRP rebar production?
Yes. GFRP mesh often offers even better economics because it is sold as a value-added product for industrial floors, slabs-on-grade and precast panels. Our CT M series mesh lines combine high square-meter output per shift with low labor requirements, so cost per square foot is very competitive against steel wire mesh.
What is the minimum production volume needed to run a profitable GFRP plant?
Even small plants with a single CT-series line can be profitable if they focus on niche local markets (for example marine structures, chemical plants or industrial floors). Larger multi-line plants reach better economies of scale and can supply national or regional distributors. During the feasibility stage we model realistic capacity and sales scenarios for each customer.
Can you help with business plans, financial models and bank documentation?
We regularly assist customers with technical sections of business plans, ROI calculations, equipment lists and power requirements. While we cannot guarantee financing, we provide the engineering and production data banks and investors usually ask for when evaluating an FRP project.
Products, Applications & Markets
What products can I manufacture on Composite-Tech lines besides straight GFRP rebar?
Our portfolio includes equipment for straight rebar, coils, bent shapes, stirrups, cages and GFRP mesh. Depending on the configuration, you can cover reinforcing needs for bridges, slabs, foundations, retaining walls, marine works and industrial floors from a single plant.
Is GFRP reinforcement suitable for industrial floors and slabs-on-grade?
Yes. GFRP mesh and bars are increasingly used in warehouses, logistics hubs, cold stores and industrial facilities. They provide effective crack control, eliminate corrosion of reinforcement and reduce floor maintenance costs over the building’s lifetime. With correct design, they are a strong alternative to traditional steel wire mesh.
Where is GFRP reinforcement most competitive compared to steel?
GFRP is especially competitive in corrosive environments (marine, coastal, chemical, de-icing salts), in structures requiring long service life with minimal maintenance, in electromagnetically sensitive areas (MRI rooms, substations) and where weight reduction is important (modular buildings, precast elements, elevated slabs).
Can I export GFRP rebar and mesh produced on Composite-Tech lines?
Yes. Many of our customers successfully export their products to neighboring countries and even to other continents. Compliance with international standards, consistent quality and professional documentation make it easier to enter new markets and pass approvals by foreign authorities and engineering firms.
How does GFRP reinforcement help reduce CO₂ emissions and support ESG goals?
GFRP rebar and mesh do not rust, which means fewer repairs, less material replacement and longer service life for structures. Over the full lifecycle, this translates into lower CO₂ emissions from production, transport and repair works. For developers and infrastructure owners, switching from steel to composites can be part of a broader low-carbon and ESG strategy.
Training, Support & Patents
Do you provide training for operators and technologists?
Yes. Each line purchase includes on-site or remote training for operators, technologists and maintenance staff. We cover raw material handling, process parameters, quality control, troubleshooting and safe operation, so your team can reach stable industrial production as fast as possible.
Are Composite-Tech technologies patented?
Yes. Key elements of our process – including the pre-heating system, multi-stage resin impregnation, flexible rib-winding module and two-stage cooling concept – are protected by patents and know-how. This means our competitors cannot legally copy these solutions, and our customers benefit from truly unique production technology.
Can other manufacturers replicate your process if they study your equipment?
No. Even if someone sees the line, they cannot legally reproduce patented solutions, and they will not have access to our control algorithms, design calculations and process recipes. That is why many customers choose Composite-Tech: they know their plant is based on technology that is not available in generic, low-cost copies.
What kind of warranty and after-sales service do you offer?
We provide a standard warranty on equipment, plus long-term technical support for process optimization, upgrades and expansion. Our goal is not just to deliver a machine, but to help you build a successful and sustainable FRP business.
Do you help with raw material selection (rovings, resin, additives)?
Yes. We share our experience with glass fiber suppliers, resin systems and additives that have been successfully used on Composite-Tech lines in different countries. We can suggest several options depending on your local availability, price level and target standards.
Can your equipment be adapted for different diameters and new product types in the future?
Our lines are modular. You can start with a configuration focused on the most demanded diameters (for example, #3 and #4 rebar, or certain mesh sizes) and later upgrade with additional modules, guides or cutting systems. This protects your investment and allows you to follow market trends without buying a completely new line.
How can I know which configuration of Composite-Tech line is right for my market?
Share your target products, expected annual tonnage, local electricity cost and market prices with us. Based on that information, we will propose an optimal combination of rebar and mesh lines, automation level and auxiliary equipment, together with an indicative ROI calculation.
Why do many customers choose Composite-Tech instead of cheaper local equipment?
Because they look at total cost and risk, not just the initial price tag. Our technology gives higher and more stable product quality, easier certification, lower reject rates and better long-term support. For serious investors and manufacturers this usually means higher profit, stronger reputation and access to demanding infrastructure projects.