Environmentally Friendly Framing Methods Chapter 27 Environmentally Friendly Framing Methods
Introduction Structural drawings (e.g., framing plans, sections and details, and foundation plan) Require thorough understanding of materials and process of construction Wood, steel, masonry, and concrete are the most common materials used Each material has its own green properties, and methods of achieving Leadership in Energy and Environmental Design (LEED) credits
Wood Framing Methods Each method has many green properties that lead to LEED credits Common credits gained by use of wood framing methods include: Recycled content Building resources Rapidly renewable materials Certified wood products
Wood Framing Methods (cont’d.) Balloon or eastern framing Rarely used Exterior studs run from the top of the foundation to the top of the highest level
Wood Framing Methods (cont’d.) Platform or western framing Most common A platform is created by each floor
Wood Framing Methods (cont’d.) Post-and-beam framing Places framing members at greater distances apart than platform methods
Wood Framing Methods (cont’d.) Timber construction Not widely used in last 100 years Some are returning to timber framing methods Warmth and coziness
Energy-Efficient Framing Methods Energy-efficient platform framing Advanced framing techniques (AFTs) replace nonstructural wood with insulation Increases energy efficiency
Energy-Efficient Framing (cont’d.) Engineered lumber and materials Structural engineered members Small pieces of wood turned into framing members Usually made from wood scraps and young, small-diameter, fast-growing tree species Engineered lumber for framing Laminated veneer lumber (LVL) Laminated strand lumber (LSL) Parallel strand lumber (PSL)
Energy-Efficient Framing (cont’d.) Structurally insulated panels (SIPs) Structural strength High insulation rates Built-in vapor barriers Sound-deadening qualities Ease of installation
Energy-Efficient Framing (cont’d.) Steel framing Consistently straight and square Resists stress from weather Contains about 50% recycled metal and is 100% recyclable
Energy-Efficient Framing (cont’d.) Concrete masonry units Durable and economical building Excellent structural and insulation values Concrete blocks Classifications Patterns, colors, and shapes Concrete form masonry units
Energy-Efficient Framing (cont’d.) Solid masonry construction Can last for centuries Reduces temperature swings Variety of position and patterns Masonry walls must be reinforced Masonry veneer
Energy-Efficient Framing (cont’d.) Insulated concrete form construction Provide an energy-efficient wall-framing system for an entire structure
Energy-Efficient Framing (cont’d.) Modular framing methods Highly engineered method of construction Efficient and cost-effective Begin as components designed, engineered, and assembled in a factory using assembly-line techniques
Green Construction Goals Key questions: Can products be selected that are made from environmentally friendly materials? Can products be selected because of what they do not contain? Will the products reduce the environmental impact during construction?
Green Construction Goals (cont’d.) Key questions (cont’d.): Will the products reduce the environmental impact of operating the building? Will the products to contribute to a safe, healthy indoor environment?
Green Construction Goals (cont’d.) Major considerations: Environmentally friendly materials Salvaged products Products with recycled content Certified wood products Quick-growth and waste by-products Minimally processed products Removing materials Reducing construction impact
Green Construction Goals (cont’d.) Major considerations (cont’d.): Reducing impact after construction Reducing energy demands and maintenance Using renewable energy Conserving water Preventing pollution and eliminating pesticides Contributing to the environment Improving interiors with nonpolluting products Blocking, removing, and warning of contaminants