Skylight

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This article is about roof windows. For other uses, see Skylight (disambiguation).
Skylight in rotunda of Centro Cultural Banco do Brasil center in Rio de Janeiro.
Large skylighting element, in the Star Ferry Pier, Hong Kong.

Skylights are light transmitting fenestration (elements filling building envelope openings) forming all, or a portion of, the roof of a building's space for daylighting purposes.

History

Open skylights were used in Ancient Roman architecture, such as the oculus of the Pantheon. Glazed 'closed' skylights have been in use since the Industrial Revolution made advances in glass production manufacturing. Mass production of pre-made units since the mid-20th century have brought skylights to many uses and contexts. Energy conservation has brought new motivation, design innovation, transmission options, and efficiency rating systems for skylights.

Description

Skylighting types include roof windows, unit skylights, tubular daylighting devices (TDDs), sloped glazing, and custom skylights. Uses include:

  • daylighting elements used to allow direct and/or indirect sunlight, via toplighting.
  • providing a visual connection to the outdoor environment to interior occupants.
  • sustainable building — passive solar heating, and with operable units; ventilation for passive cooling and fresh air exchange.
Fixed unit skylight, roof view.
Fixed unit skylights, interior view.
Active daylighting uses a tubular daylight device—TDD.
Fixed unit skylight

A fixed unit skylight consists of a structural perimeter frame supporting one panel of glazing infill (the light-transmitting portion, which is made primarily of glass or plastic). An operable (venting) unit skylight uses a glazed sash attached to and supported by the frame. When within reach of the occupants, this type is also called a roof window.

Tubular daylight device

Active daylighting uses a tubular daylight device—TDD. It is a roof-mounted fixed unit skylight element, condensing sunlight, distributed by a light conveying optic conduit to a light diffusing element. Being small in diameter, they can be used for daylighting smaller spaces such as hallways, and bounce light in darker corners of spaces.

Sloped glazing

Sloped glazing differs from other “skylights” in that one assembly contains multiple infill panels in a framing system, usually designed for a specific project and installed in sections on site.

Solar architecture

Skylights are widely used in designing daylighting for residential, public, and commercial buildings. Increased daylighting can result in less electical lighting use and smaller sized window glazing (sidelighting), saving energy, lowering costs, and reducing environmental impacts. Daylighting can cut lighting energy use in some buildings by up to 80%.[1]

Toplighting (skylights) works well with sidelighting (windows) to maximize daylighting:

  1. toplighting is able to bring light into centralized areas of a building
  2. daylight is available throughout the day from both ambient lighting from the sky and direct exposure to the sun.
  3. modern transparent and/or translucent glazing can be utilized to avoid glare, aid in capturing sunlight at low angles and diffuse light to wider areas of floor space.

Even on overcast days, toplighting from skylights is three to ten times more efficient than sidelighting.[2]

Materials

Glass

Many recent advances in both glass and plastic infill systems have greatly benefited all skylight types. Some advances increase thermal performance, some are focused on preserving and utilizing daylight potential, and some are designed to enhance strength, durability, fire resistance and other performance measures.

Contemporary skylights using glass infill (windows) typically use sealed insulating glass units (IGU) made with two panes of glass. These types of products are NFRC-ratable for visible transmittance. Assemblies with three panes can sometimes be cost-justified in the coldest climate zones, but they lose some light by adding the third layer of glass.

Glass units typically include at least one low emissivity (Low-E) coating applied to one or more glass surfaces to reduce the U-factor and especially SHGC by suppressing radiant heat flow. Many varieties of Low-E coatings also reduce daylight potential to different degrees. High purity inert gas is frequently used in the space(s) between panes, and advances in thermally efficient glass spacing and supporting elements can further improve thermal performance of glass-glazed skylight assemblies.

Plastic

Plastic glazing infill is commonly used in many skylights and TDDs. These assemblies typically contain thermally formed domes, but molded shapes are not uncommon. Domed skylights are typically used on low slope roofs. The dome shape allows for shedding of water and burning embers.

Plastics used in skylights are UV stabilized and may feature other advances to improve thermal properties. Lack of accepted standards for measuring light transmittance is a disadvantage for comparing and choosing skylights with plastic glazing.

Acrylic is the most common plastic glazing used for dome skylights. However, Polycarbonate and Copolyester materials are also used as glazing, where additional properties such as impact resistance may be required.[3]

Rating systems

NFRC — rating for visible transmittance

U-factor — expresses the heat loss performance of any building assembly.

SHGC—Solar Heat Gain Coefficient — measures the assembly’s transfer of heat from outside to inside that is caused by sunlight.

These properties are labeled in the U.S. as a decimal between zero and one, with lower numbers indicating lower heat transfer rates. Depending on the geographic region, optimal U-factor and SHGC performance will vary. In the sunny southern climate zones, a lower SHGC is more important than lower U-factor. In the cooler northern climate zones, lower U-factor is more important, and higher SHGC can be justified.

Oculus of the Pantheon, an open skylight.

In selection of skylights, a balance is sought between low U-factor and optimal SHGC values, while preserving enough daylight supply to minimize artificial light use. Automatic light sensing controls for electric lighting maximize energy savings.

Benefits

A study concluded that students have significantly higher test scores in classrooms that optimize daylighting, than classrooms that do not. [4] Other studies show that daylight positively affects physiological and psychological well-being, which can increasing productivity in many contexts, such as sales in retail spaces.

In terms of cost savings, U.S. DOE reported that many commercial buildings can reduce total energy costs by up to one-third through the optimal use of daylighting. The majority of commercial warehouses and 'big box stores' built in recent years have used skylights extensively for energy/costs savings.

See also

References

  1. U.S. Department of Energy (DOE): Federal Energy Management Program; toplighting_final_report
  2. AAMA: Daylighting Fact Sheet
  3. AAMA Skylight Council
  4. coe.uga.edu/sdpl/research/daylightingstudy: study of 21,000 students.

External links

Wikimedia Commons has media related to Skylights.


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