Kalwall Translucent Panel System
Transcription
Kalwall Translucent Panel System
Kalwall Translucent Panel System Kalwall Translucent Panel System What is Kalwell? • Kalwall is a translucent, highly insulating light diffusing building system for walls and roofing • Kalwall comprises of fiberglass sheets bonded to a grid core of aluminium I beams • A – External face sheet • B – Glass fiber insulation • C – Aluminium I-beams • D – Internal, shatterproof face sheet Benefits of Kalwall • Unmatched thermal performance and solar heat gain reduction creates climate stability within the environment that leads to a reduction in HVAC systems useage • Natural daylight reduces artificial lighting requirements leading to a reduction of building energy consumption • Natural light has a positive impact on health and wellbeing of workers • High impact resistance • Customisable solutions What is Kalwell? • Kalwall is a structural translucent sandwich panel that is either 70mm or 100mm thick. • I Beams can be solid aluminium or thermally broken to increase the thermal performance of the system. • The kalwall panel is encapsulated by an extruded aluminium cill and mullion section to keep it watertight. • Panel widths are 1200mm and 1500mm standard. • The Kalwall panel is the key to several systems available. System 1: Wall Panels Single span panels up to 6m run vertically using the standard fastening section Wall Panel Detailing System 2: Panel Unit Walls Multi storey panelling using horizontal storey battens creating a continuous facade Panel Unit Detailing System 3: Window Replacement Existing window openings with glass replaced with new Kalwall system with small viewing panes Window Replacement Detailing System 4: Standard Skylights Standard sizing geo dome, pyramid and flat skylights. Predetermined sizing only available in this system Standard Skylight Detailing System 5: Pre-Engineered Skylights Larger format skylights including self supporting ridge roofs pre engineered to withstand set loadings Pre-Engineered Skylight Detailing System 6: Custom Skyroofs Custom skyroofs are for any design outside of the standard and pre-engineered range. Specific engineering design by Kalwall is required for support locations to be determined. Custom Skyroof Detailing Benefits of Kalwall over Glass Facade NZ ‘R’ Value SHGR UV Filter Light Trans STC (Db) Single Glaze Glass 0.2 0% 23% 93% 13 Double Glazed Glass 0.6 70% 93% 55% 31 Single Skin Polycarbonate N/A 47% 90% 56% 8 Danpalon Multicell Polycarbonate 0.8 55% 99% 45% 18 Kalwall with Glass Fiber Insulation 1.0 -2.5 87% 99.9% 10 -30% 33 Kalwall with Nanogel Insulation 3.5 – 4.0 90% 99.9% 15 – 20% 35 “U” value vs “R” value “U” value measures thermal transmission through the product USA = BTU / hr . Ft². °F SI (System international) = w / m² . °C R Value measures the Thermal Resistance of the product R Value = m² . °C / w Note: Most imported products will be using the SI “U” value. As the “R” value is the inverse to this value, use the formula 1/U to convert the value. i.e: SI “U” value of 0.52 is “R” 1.9 (1 / 0.52) UV Exposure Face sheets are made with kalwalls unique resins and fiberglass design. Erosion veil barrier is integral to the resistance of fiber bloom and delamination. The face sheets are of full thickness color stability and not a coating. Why Kalwall? l GG Intense direct sun beams through glass and shadow blinding spots l Evenly diffused daylight and no thermal hot spots b Additional Features LED backlighting gives endless options for façade designs Daylight Modelling Daylight design is the use of translucent products that allow natural daylight from the sun to emit through the product and into the building. This can be in the form of walls / windows / roofs or skylights. There are a number of benefits of designing with natural light dispersion inside the building including the reduction of energy costs from less artificial lighting and health benefits for occupiers of the building are also improved using natural daylight. Lighting levels and requirements are at the forefront of design priority and the building is designed around it accommodating these parameters. How do we Design using Daylight? Computer generated daylight model simulations are the most effective way to design. Multiple scenarios can be generated at the touch of a button. Buildings and openings are modelled based on any time or date within the year to show typical light emitting patterns and real world weather data for a specific site. What is daylight modelling? • Simulation shows the behavior of natural light within a space – a visual tool to demonstrate design choices. • Ideally used in the design development. • Use daylight/sun as the first layer of ambient light. • The building itself = luminaire. • 300lux is becoming the average for daylighting levels in a building but the modelling can be tailored to custom requirements. Typical Daylight Studies Designing with the correct light levels and diffusion for a specific building Typical Daylight Studies Renders can give client realistic views of the end result Daylight analysis should look at: • • • • • • • • The building as a whole Its global position (site) Obstructions (external and internal) Surfaces Key design features that effect daylighting The intended use of the space – how much light needed? Size and location of skylights/walls How can we positively effect the outcome Radiance vs Daylight Autonomy • Radiance – a snapshot in time. A time on a day (noon, sept 21st) Shows exact light levels (within accuracy of solar deviations). • Daylight autonomy – yearly average/ sliding scale. Choose hours of operation Lux level – tied to space function What % of time does the space reach the target? 300 lux – 60% of the time during hours of Operation i.e.7 am to 6 pm…. goal is good ambient light as the first layer of light! Let’s work through a simulation Original design by architect Summer solstice at Noon Modelling shows way too much light in the pool area which can result in glare reflection off water Revision 1: Change upper 3m of glass wall to Kalwall Translucent Panel Note: Glass is transparent and not translucent which lets direct sunlight through causing extensive glare patches Result: Still too much daylight Revision 2: Reduce rooflight area Result: Improved but need to look at glare management Revision 3: Upper 3m of glass changed to Kalwall for glare reduction Upper 3m of glass area changed to Kalwall Upper 3m All glass walls = too much glare creating intense reflectivity on water surface and is a life safety hazard of glass area changed to Kalwall Result achieved with upper 3m of glass changed to Kalwall Direct sunlight is away from the pool area eliminating glare blinding on the water surface meaning lifeguards are able to see people in the pools at all times Modelling offers photo realistic renderings Computer rendering Actual Photograph Side by side comparison 3D analysis methods Volumetrics tells the story of how light travels within the space. A section through the model shows how light is distributed within the space. 3D section views Left: Using Kalwall wall panels and implementing a Kalwall rooflight Right: Without Kalwall translucent panels Advantages of Building Design using daylight modelling with Kalwall • • • • • • Specific light level requirements can be achieved Identifies excessive light or under-illumination Used as a submittal item for day lighting credits in programs such as LEED, Greenstar Compare different materials – glass / translucent / overhangs / light shelves Size and spacing of day lighting options – Bigger is not always better! Eliminates potential solar glare and hotspots for smooth diffused lighting throughout. Thank you for your time Questions? AUSTRALIA – Melbourne Michael McGarry PHONE: 03 5987 1856 MOBILE: 0419 326 120 EMAIL: michael.mcgarry@ibpaustralia.com AUSTRALIA – Brisbane Shane Cassady PHONE: 02 6672 8183 MOBILE: 0417 586 827 EMAIL: shane.cassady@ibpaustralia.com