Float glass

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Contents 1 Material analysis 1.1 Traditional uses 1.2 Emerging uses / trends 1.3 Applications 1.4 Finish and aesthetic qualities 1.5 Surface forms / shapes 2 Material properties 2.1 Primary structural use 2.2 Dimensions 2.3 Acoustic property 2.4 Manufacturing process 3 Environment and Life Safety 3.1 Environmental impact 3.2 Flammability rating 3.3 Coefficient of friction 4 References 4.1 Notes 4.2 Student contributions 5 See Also 5.1 Similar materials 6 External links 6.1 Additional resources 6.2 Leading manufacturers

Material analysis

MasterFormat Number: 08 44 26

Traditional uses

• The use of float glass can be traced as far back as 1840 when they were used as fishing floats.
• The Norwegians used a small egg-sized float on which they tied a fishing line and a hook.
• As the use of nets increased, Norway went on to produce other sizes of floats since an economical method of supporting the nets and offered plenty of buoyancy and many European countries soon began using glass floats.

Emerging uses / trends

• About 90% of the world’s flat glass is currently formed via the float method—which produces glass with extremely flat, parallel surfaces.
• This glass can then put through various applications such as Toughening,Staining,Tinting,Bending etc.

Applications

• Commercial
  • Glazing
  • Atriums
  • Skylights
• Residential
  • Furniture
  • Partitions
• Speciality glass
  • Night clubs
  • Window Display
• Automotive
  • Windscreens

Finish and aesthetic qualities

• High light transmission
• High transperancy
• Free from optical distortion and waviness

Surface forms / shapes

• Float glass is the term for perfectly flat, clear glass.
• This glass can then be treated :^[1]
  • Reflective Glass
  • Laminated Glass
  • Security Glass
  • Insulated Glass
  • Heat treated glass
  • Ceramic decorated glass

Material properties

Primary structural use

• Float glass has great tensile strength and is used in Atriums and Skylights.
• Due to its reflective use float glass is used as a Glazing material in high rise construction.

Dimensions

• Float glass can be cut into large standard sheets or cut to size
• Glass sheet sizes avry from manufacturers. Standard glaas sizes are 3.2m X 7.0m but could go up to 3.2m X 10.0m.
• Glass thickness varies from 2mm to 10mm.

Acoustic property

• Glass can transmit sound as well as light into a building's interior. Laminated glass can effectively reduce unwanted sound and noise better than conventional glazing systems.
• The shear dampening characteristics of laminated glass can reduce interference caused by disruptive noise - from traffic and jet aircraft to office machinery and industrial equipment.
• Laminated glass effectively reduces the coincidence dip in the 1,000 to 2,000 Hertz range common to glass products.

Manufacturing process

• It is made by melting raw materials consisting of sand, limestone, soda ash, dolomite, iron oxide and salt cake
• These materials are mixed together and fed into a large furnace that is natural gas or fuel oil fired at 1500°C.
• The molten glass is fed into the float bath (tin bath) through a delivery canal. The amount of glass allowed to pour onto the molten tin is controlled by a refractory gate called a tweel.
• The tin bath is provided with a protective atmosphere consisting of a mixture of nitrogen and hydrogen to prevent oxidation of the tin. The glass flows out onto the tin surface forming a floating ribbon with perfectly smooth glossy surface on both sides with an even thickness.
• Thinner glass is made by stretching the glass ribbon to achieve the proper thickness.
• Machines called attenuators are used in the tin bath to control both the thickness and the width of the glass ribbon.
• It then passes through the lehr where it is further cooled gradually so that it anneals without strain and does not crack from the change in temperature. The glass travels down the rollers in the lehr and comes out at the "cold end" where it is cut by machines.^[2]

Environment and Life Safety

Environmental impact

• Advanced laminate systems can help control solar heat gain and reduce cooling loads in commercial buildings.
• The interlayer absorbs energy in the ultraviolet (UV), visible and infrared wavelength spectrums and dissipates most of the absorbed energy to the outside.
• For increased solar or thermal performance, glass can be fabricated into insulating glass units.

Flammability rating

• Being incombustible it has an excellent flammability rating.

Coefficient of friction

• Glass is not recommended for floor use but custom glass surfaces can be treated to adhere to slip standards as needed.

References

Notes

1. ↑ http://www.buildingproducts.com
2. ↑ http://www.glassonweb.com

Student contributions

• Laura Druan, Fall 2005
• Nicole Dagle, Spring 2007
• Harshita Merchant, Spring 2008

See Also

Similar materials

• Glass
• Glass block
• Lightblocks
• Smart glass
• Structural glass

External links

Additional resources

• Brantley, L. Reed. Building Materials Technology. New York, NY: McGraw-Hill, Inc., 1996.

Leading manufacturers

• AGC Flat Glass website
• ASAHI Glass website
• Vanceva Glass website