EVantage™

EVantage™ is strong choice when creating a more comfortable and energy-efficient home. This versatile range includes both clear and toned glass options, each featuring a reflective pyrolytic Low-E coating that enhances your living space’s performance.

Whilst a sensible choice for single glazing applications, when used in double glazed units (like our DGU Pro), it doesn’t offer the optimal performance you might be looking for. For those seeking top-tier results in double glazed units, we recommend exploring our Premium and Max ranges, which are designed to provide even greater insulation and solar control for the best in home comfort and efficiency.

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Exploring The Benefits

Energy Efficiency

Keep the temperature of your room controlled, lowering your energy consumption and reducing the need for additional heating and cooling.

Low E Coating

Coating is applied that allows natural light through without emitting radiant heat, maximising light and energy efficiency.

Climate

Designed with a consideration for mixed and warmer climates or where mid-range solar control and insulation are desired.

DGU Application

Our DGU Pro range allows EVantage to be used in a double-glazed unit. 

Range of Tones

Colour options are available within the EVantage™ range.

Easy Processing

Can be toughened, laminated or used in DGU Pro. 

Performance Data

  • Calculation method: LBNL WINDOW Calc Engine v2.4.0, Optics 6.0
  • Environmental Condition: NFRC 100-2000
  • Results are for center-of-glass; does not include effect of frames
  • Location of LowE coating is indicated with surface number
    • #1 indicates exterior surface, #4 indicates the interior surface in a typical double-glazed unit
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Tilt

Tilt-angle (°)

Angle of the glass relative to the horizon

  • Typical skylights with a slight pitch: 3-5°
  • Typical windows in vertical walls: 90°
Ug.w

Ug (W/m².K)

Heat-transfer coefficient (center-of-glass)

  • Heat transfer (W) per square meter (m²) of glass for each degree (C) of temperature difference
  • Lower implies better insulation

.w

NFRC 100-2010 Winter Condition

  • The standard environmental condition for Ug quoted in the Window industry
  • Useful as a reference for performance comparison between different glazing systems but can lead to inaccuracies if used to estimate energy consumption
  • Inside Condition:
    • Air and effective room temperature: 21 deg C
    • Room emissivity: 1
  • Outside Condition:
    • Air and effective sky temperature: -18 deg C
    • Effective sky emissivity: 1
    • Convection coefficient: 26 W/m².K
    • Wind speed: 5.5m/s windward
Ug.s

Ug (W/m².K)

Heat-transfer coefficient (center-of-glass)

  • Heat transfer (W) per square meter (m²) of glass for each degree (C) of temperature difference
  • Lower implies better insulation

.s

NFRC 100-2010 Summer Condition

  • The condition used to calculate SHGC
  • Ug.s better represents performance in warm environmental conditions
  • Inside Condition:
    • Air and effective room temperature: 24 deg C
    • Room emissivity: 1
  • Outside Condition:
    • Air and effective sky temperature: 32 deg C
    • Effective sky emissivity: 1
    • Convection coefficient: 15 W/m².K
    • Wind speed: 2.75m/s windward
    • Direct solar radiation: 783W/m²
SHGC

SHGC (Range: 0 – 1)

Solar heat gain coefficient

  • Proportion of solar heat radiation transmitted
  • Generally lower SHGC is desirable for north and west facing windows for reducing air-conditioning cost in summer
  • However, higher SHGC for north and west facing windows would help reduce heating cost in winter
VLT

VLT (Range: 0 – 1)

Visible light transmittance

  • Proportion of visible light (380 - 720nm) transmitted
  • Generally higher VLT is more desirable
VLRf

VLRf (Range: 0 – 1)

Front Visible light reflectance

  • Proportion of visible light reflected on the external side of the IGU
VLRb

VLRb (Range: 0 – 1)

Back Visible light reflectance

  • Proportion of visible light reflected on the room side of the IGU
Tdw

Tdw-ISO (Range: 0 – 1)

Damage weighted transmittance

  • Proportion of colour fading radiation transmitted
  • Lower Tdw-ISO means lower risk of colour fading
  • Accounts for the colour fading potential of both UV and visible spectrum
Tuv

Tuv (Range: 0 – 1)

UV transmittance

  • Proportion of UV radiation (280 - 380nm) transmitted (Range: 0 – 1)
  • Not recommended as a metric for assessing colour fading potential
  • Visible spectrum could account for as much as 40% of the fading from solar radiation
Sel.

Selectivity (VLT/SHGC)

Ratio of visible light transmittance over solar heat gain coefficient

  • Useful for comparing spectral selectiveness of the low-E coating
  • Higher selectivity means less visible light is sacrificed to lower solar heat gain

Example:

  • Sel. in the 0.5 - 0.8 range results from the use of Grey glass; less visible light is transmitted vs infrared radiation
  • Sel. in the 1.9 - 2.2 range results from the use of LightTech LI Max; less infrared radiation is transmitted vs visible light
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Nom.

Nominal thicknesses (mm)

List of nominal thicknesses of the IGU components separated by the '+' symbol

Example:

17.52:

  • 17.52mm single-pane laminated glass

6+12+6:

  • DGU made up of:
    • 6mm glass
    • 12mm spacer
    • 6mm glass
Total.

Total thickness (mm)

Total thickness of the glazing system; sum of component thicknesses

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Applications

External
  • Doors
  • Windows
  • Shop Front
  • Roof Glazing
  • Frameless Glazing

*Application information attained from Oceania Glass

Specifications

How to Specify

Available colours and thicknesses:

  • Clear 6mm
  • Grey 6mm
  • Bronze 6mm
  • Blue Green 6mm
  • SuperGreen 6mm
  • SuperBlue 6mm

Select from: Annealed, Heat Strengthened, Toughened or Toughened Heat Soaked

*If unsure, select in compliance with AS1288–2021 or manufacturers recommendation. *

  • The glass shall comply with the following performance criteria:
  • U value
  • Solar Heat Gain Coefficient (SHGC)
  • Visible Light Transmission %
  • Glass Only Values
  • Total window

Annealed
Annealed glass is glass produced without internal stresses imparted by heat treatment, i.e., rapid cooling, or by toughening or heat strengthening. Annealed glass is not a Grade A safety glass.

Toughened
Glass converted to a safety glass by subjection to a process of pre-stressing so that, if fractured, the entire piece disintegrates into small, harmless particles. Toughened glass is a Grade A Safety Glass

Heat Soaking
Heat soak testing is a destructive test, which reduces the likelihood of spontaneous breakage by converting impurities such as nickel sulphide inclusions. Heat soaking is required in some but not all applications. If unsure, select in compliance with AS1288-2021 or manufacturers recommendation.

Heat Strengthening
All glass which requires extra strength and thermal resistance will be heat strengthened. Heat strengthening increases the strength of annealed glass; however, it is not a substitute for toughened glass

In the event of fracturing heat strengthened glass will crack and tends to remain in glazed position.

Toned Glass
Toned glass absorbs a proportion of solar radiation and may require a thermal assessment depending on application.

All glass is to be selected and installed in accordance but not exclusively with the following Australian and/or New Zealand Standards

  • AS 1288 Glass in Buildings Selection and Installation
  • AS 1170 Minimum Wind Loads on Structures
  • AS/NZ 2208 Safety Glazing Materials in Buildings
  • AS/NZ 4666 Insulating Glass Units
  • AS/NZ 4667 Quality Requirements for cut-to-size and Processed Glass

*Specifcation information attained from Oceania Glass

Considerations

Things to Consider

Application
EVantage™ when single glazed must be glazed with the exposed coating to the inside of the building (surface #2). When incorporated into IGUs solar control glass products are recommended to be glazed with coatings to surface #2. Please note that local councils may have specific requirements regarding the maximum allowable reflectivity of building materials. At night reflectivity may result in a mirror appearance making it difficult to see externally.

Thermal Stress and Fracture Risk
Recommended for thermal stress fracture risk assessment.

Large Projects
Oceania Glass recommends that for large glazing facades (particularly curtain wall) the customer should highlight this in writing to enable consideration of colour management of supplied product.