Tom Andrew Henry Poor Lumber/ Homeworks.  Objective: after this brief you should have a better understanding of ; 1. Materials that don’t primarily affect.

Slides:



Advertisements
Similar presentations
Common Terminology Emittance Winter U-Factor or U-Value R-Value
Advertisements

What should you think about when deciding where to put your building? The direction a building faces will impact on a lot more than the view – how do you.
Dr. Ruth Collins TrinityHaus
Framing Assignment 4 Print SetSingle Family Dwelling SFD.
Passive house. Definition A Passive house is a buildings with good comfort conditions during winter and summer, without traditional space heating systems.
Sustainable Residential Design Project Project 9 DS413: Design Studio 413 May 9, 2012.
Carpentry Green Application 5. Key Lessons from Carpentry In Carpentry, we learned about: Tool and equipment use, safety, and maintenance Primary materials,
Guidelines and Required Codes That Affect Building Design
Sustainable Construction
Green Building Tammy Thompson Energy Production and Policy Fall 2005.
Images and text from HKT Architects – Project Architects.
Chapter 6: Windows and Doors To be used with the Guide to Building Energy Efficient Homes in Kentucky.
GREEN BUILDING MATERIALS AND TECHNIQUES S O L A R S T R A T E G I E S TARA HAGAN.
Hope VI Residents Deserve Green Housing Affordable, Healthy Home Design Choices.
Green Building Materials
The Energy Star Home Drew Tepper. Overview What is an energy star home? What is an energy star home? New Homes New Homes Existing Homes Existing Homes.
SUSTAINABLE RESIDENTIAL DESIGN PROJECT SIKESTON HOUSE Project 12 DS 413 MAY 8 TH, 2012.
A Sustainable Residential Design Project Project 14 Design Studio 413 May 09, 2012.
The Energy Performance of Fenestrations What is Fenestration? Fenestration: Any opening in a building's envelope including windows, doors, curtain walls.
A SUSTAINABLE RESIDENTIAL DESIGN PROJECT Project 1 DS 413: Design Studio 413 May 9, 2012.
Tour Stop 1: Outside The Building. Community Connectivity Encourages A Walkable Neighborhood At least 10 community services, and high density residential.
Sustainable Buildings Going Green. Green Building Building the Future with Intention Building to ensure that waste is minimized at every stage during.
 Site  Requirements  Local Resources  Initial layout ideas  Brief material selection  Supply options.
BECOMING GREEN Santa Margarita High School Academic Building.
Windows. Huge variety of available building components and several important roles Thermally most important they admit solar radiation Advantageous in.
Heat Loss and Gain Heat Loss and Gain
A SUSTAINABLE RESIDENTIAL DESIGN PROJECT Project 4 DS413: Design Studio 413 May 9, 2012.
Project 6 DS 413: Design Studio 413 May 9, 2012.
PASSIVE SOLAR DESIGN. Design Techniques
CONSTRUCTION TECHNOLOGY UNIT 4. THINK, PAIR, SHARE IN YOUR OPINION, WHAT IS CONSTRUCTION TECHNOLOGY? THINK – 2 MINUTES PAIR – 1 MINUTE SHARE – 2 MINUTES.
A Sustainable Residential Design Project Project 16 DS 413: Design Studio 413 May 9, 2012.
Green Building. Green building  Is the practice of creating structures and using processes that are environmentally responsible  Designed to reduce.
LEED New Construction & Major Renovations Rating System
Green Building Residential Construction
Conservation and Environmental Design and Construction
Sustainable Design Chad Sims Jason Sells.
Environmentally Friendly Framing Methods
THIS IS Created by: Chad Sims Jason Sells Green Building Materials Sustainable Design Systems LEED Categories
Project 5 DS 413: Design Studio May 9, A: 1A: Site is near a residential area. 1B: 1B: Existing trees were considered when planning heating,
Energy Conservation February 8, Steve Wilson, MBA, CEM, CDSM, BEP The Energy Guy.
Passive House Seminar for Professionals from the Building Sector.
9. THERMAL MASS  Thermal mass is a measure of a material's capacity to absorb heating or cooling energy. Materials such as concrete or bricks are highly.
Features & Benefits of ENERGY STAR Qualified New Homes.
ENGR330-1 Engineering Service Projects Project: Window Technology Benefits: HEALTH: Reduced drafting and improved daylight COST: Reduce furniture fading.
QUIZQUIZ Check your knowledge before starting your practical tasks Energy Efficient Renovation of Old & Historic Buildings START YOUR TEST.
Resources Bamboo used in flooring, benches and paneling.
VENTILATION AND FENESTRATION
GCSE ENERGY; THERMAL ENERGY TRANSFER 2
Common Components of a Traditional Wood Framed Building
APPLICATIONS OF TECHNOLOGY
Heat Loss and Gain Civil Engineering and Architecture
Technology in Architecture
Wood Frame Systems Civil Engineering and Architecture®
Heat Loss and Gain.
Heat Loss and Gain Heat Transfer Winter Heat Loss Summer Heat Gain
Common Components of a Traditional Wood Framed Building
Technology in Architecture
Heat Loss and Gain Heat Loss and Gain
Heat Loss and Gain Heat Loss and Gain
Technology in Architecture
Heat Loss and Gain Civil Engineering and Architecture
Technology in Architecture
Technology in Architecture
Design Development Approach
Common Components of a Traditional Wood Framed Building
Heat Loss and Gain Heat Loss and Gain
Common Components of a Traditional Wood Framed Building
A Sustainable Residential Design Project
Heat Loss and Gain Heat Loss and Gain
Presentation transcript:

Tom Andrew Henry Poor Lumber/ Homeworks

 Objective: after this brief you should have a better understanding of ; 1. Materials that don’t primarily affect energy efficiency 2. Environmentally friendly building methods 3. How these methods reduce landfill waste 4. Healthy indoor air quality

 Lot Construction  Intent- Environmental impact during construction is avoided to the extent possible; Impacts that do occur are minimized, and any significant impacts are mitigated. 1) Limits of clearing and grading are staked out 2) Top Soil is stockpiled 3) Cleared vegetation is grounded and used as silt fence

 Reused or salvaged materials  Products from Habitat Restore  Scrap Materials  Facilitation for sorting and reuse of scrap building material. (e.g. provide a central storage area or dedicated bins)

 Advanced framing techniques are implemented that optimize material usage. 1) Single top plate walls 2) 19.2” or 24” OC spacing 3) Right sized or insulated headers 4) On –site material cut lists 5) Building dimensions and layouts are designed to reduce material cuts and waste 6) Precut or preassembled components, or panelized or precast assemblies are utilized for a minimum of 90% for ; floors, Walls, and roof

 Resource-efficient Material are used to achieve the same end-use requirements as conventional products. 1) Lighter, thinner brick with bed depth less than 3” 2) Engineered wood or engineered steel products 3) Roof or floor trusses

 Certified lumber FSC, SFI, ATFS  Recycled- content Building materials 1) 25%-75% of the content of material is recycled 2) Siding, decking, flooring, roofing  Renewable Materials/Biobased products 1) Engineered wood 2) Bamboo 3) Cotton 4) Cork 5) Straw 6) Natural fiber based products made from crops (soy- based, corn-based)

 Indoor Environmental Quality  Minimum of 85% of wall coverings, hard surface flooring, installed carpet area, carpet cushion, and adhesive are in accordance with the emission regulations certified by a third- party program

 Architectural coatings  Site applied interior/exterior products are low zero or low VOC.  Adhesives are low VOC  Products are pre-finished. Don’t require site application

 U-Factor (Thermal Transmittance)- The coefficient of heat transmission (air to air) through a building envelope component or assembly, equal to the time rate of heat flow per unit area and unit temperature difference between the warm side and cold side air films. UF-measures how well a product prevents heat from escaping a home or building. U-Factor ratings generally fall between 0.20 and The lower the U-Factor, the better a product is at keeping heat in. U-Factor is particularly important during the winter heating season.  Solar Heat Gain Coefficient (SHGC) The ratio of the solar heat gain entering the space through the fenestration assembly to the incident solar radiation. Solar heat gain includes directly transmitted solar heat and absorbed solar radiation that is then released into the space. Lower the number = less transmitted energy. Particularly important during summer cooling months.

 Visible Transmittance- measures how much light comes through a product. VT is expressed as a number between 0 and 1. Heavily tinted products have a relatively low VT.  Air Leakage-measures how much outside air comes into a home or building through a product. The lower the AL, the better a product is at keeping air out. AL is an optional rating, and manufacturers can choose not to include it on their labels.

 Fenestration Specifications  Energy Star maximum certified ratings table  Indiana is primarily zone 5 Climate ZoneU-factorSHGCO 1 and to 8.35Any

 Flashing detail on plan.  Air Barrier  Sealant  Window tape

 National Green Building Standards  Trade Magazines (LBM, ProSales, Builder Magazine, web based seminars, or EPIC/Habitat seminars. Henry Poor Lumber’s Webpage  Questions????