- 1. Overview
- 2. Primary Manufacturing — Float Glass Process
- 3. Secondary Processing — Converting Float Glass
- 4. Coating Technologies — Performance Layering
- 5. Quality & Defect Control
- 6. Sustainability in Manufacturing
- 7. Key Takeaways
1. Overview
Modern architectural glass is a precision-engineered material made primarily from silica sand, soda ash, and limestone. Manufacturing determines clarity, flatness, and performance.
Two major stages define the journey from raw batch to façade-ready glass:
- Primary manufacturing: float glass production of raw sheets
- Secondary processing: value-added treatments for performance and safety
2. Primary Manufacturing — Float Glass Process
Invented by Sir Alastair Pilkington in the 1950s, this remains the global standard.
Stage | Description | Key output / control |
1. Raw material batching | Silica sand (~70%), soda ash, dolomite, limestone, alumina; controlled colorants for tints | Composition accuracy drives optical purity |
2. Melting (furnace) | Batch melted at ~1,550 °C in refractory furnace | Homogeneous, bubble-free molten glass |
3. Floating on tin bath | Molten glass floats on molten tin (~1,000 °C), forming a flat ribbon | Parallel surfaces; thickness 0.4–25 mm |
4. Annealing (lehr) | Controlled cooling through annealing lehr | Stress relief for dimensional stability |
5. Inspection & cutting | Optical scanning for defects; cut to jumbo sheets (e.g., 3.21 × 6 m) | Float glass ready for processing |
6. Edge trimming & packing | Trimmed and packed vertically | Base stock for all architectural glazing |
Note: All solar-control, Low‑E, laminated, and insulated glasses start as float glass.
3. Secondary Processing — Converting Float Glass
Value-adding treatments tailor strength, safety, solar/thermal control, and appearance.
Process | Description | Purpose / result |
Tempering (toughening) | Heat to ~650 °C then rapid quench | 4–5× stronger; safety break pattern |
Heat strengthening | Heated and cooled slower than tempering | ~2× strength; retains break pattern |
Lamination | Sheets bonded with PVB/EVA in autoclave | Safety retention; acoustic, security options |
Coating (online/offline) | Metal-oxide layers for solar/thermal control | Hard coat = durable; soft coat = high performance |
IGU fabrication | Panes separated by spacer; sealed (PIB + secondary) | Lower U-value; condensation control |
Edge processing | Cut, grind, polish, drill | Reduces edge failures |
Bending / curving | Heat-softened forming on molds | Curved architectural elements |
Screen printing / ceramic frit | Enamel fused at high temp | Decoration, shading, spandrels |
Chemical strengthening | K⁺/Na⁺ ion exchange in salt bath | Strength in thin sections |
4. Coating Technologies — Performance Layering
Correct orientation in IGUs (face 2 or 3) and edge sealing are critical.
Type | Technology | Key features | Example families |
Hard coat (online/pyrolytic) | Applied on hot ribbon (~600 °C) | Durable; lower selectivity | Antelio Plus |
Soft coat (offline/magnetron) | Vacuum sputtered on cooled glass | High selectivity; handling care | Cool‑Lite, Envision/Xtreme |
Double/triple silver | Multi-layer nano silver stacks | Premium selectivity (>2.0) | Nano Silver, SKN series |
Low‑E | IR-reflective thin films | Low U‑values (~1.1 W/m²·K in IGU) | Planitherm, Evo |
5. Quality & Defect Control
Defect | Source | Impact | Control |
Bubbles / seeds | Melting impurities | Visible inclusions | Raw material quality; filtration |
Stones / inclusions | Unmelted batch | Optical distortion; break risk | Furnace control |
Tin stain / bloom | Tin bath contact | Coating adhesion issues | Tin oxidation control |
Roller wave | Tempering quench variance | Reflection distortion | Furnace calibration |
Edge chips | Cutting/handling | Crack initiation | Edge finishing; protection |
Anisotropy / quench marks | Uneven quenching | Polarized patterns in sun | Uniform air distribution |
NiS inclusion | Float contaminants | Spontaneous breakage (tempered) | Heat Soak Test (HST) |
HST is recommended for all façade tempered glass to mitigate NiS breakage risk.
6. Sustainability in Manufacturing
Parameter | Approach | Impact |
Energy use | Waste-heat recovery | Lower carbon footprint |
Raw material optimization | Cullet content up to ~30% | Reduced melting energy |
Water management | Closed-loop cutting/washing | Near zero discharge |
Emission control | ESP and filtration | Reduced NOx/PM |
Green compliance | EPDs; IGBC/LEED/GRIHA alignment | Project credit eligibility |
7. Key Takeaways
- All façade glass begins as float glass; processing creates performance
- Tempering, lamination, coatings, and IGU assembly target specific metrics
- Specify orientation (coating face), edgework, and HST to manage risk
- Performance specs over brand names preserve neutrality and quality