Much of this energy is essential to provide a safe and a productive research environment, but when everyone is thoughtful about their individual and lab-group energy use, lab waste, and other habits, it makes a really big difference. Learn about simple actions to make labs more sustainable, environment friendly and efficient. The Certification Program is an easy, informative, and interactive way for individual laboratories and groups to discover the ways that they can save energy, resources, and more while conducting their research.
Guided Laboratory Tours The online version of this program will feature three laboratories. Credits and Logistics Please note: a laptop or other portable personal computing device is strongly recommended for course enrollees. Accommodations June Please check back for updated information.
Faculty Current faculty, subject to change. Janet S. Chan School of Public Health. Louis J. Jack T. James G. Walter E. Michael R. Anand K. John P. Daniel O. Jennifer J. June 13 — 17, back to top This agenda is subject to change. Code Classification. General Principals of Sustainable Site Design. Choosing and Appropriate Site. Site Assessment Study - Part 1. Site Assessment Study - Part 2. Designing a Project to Fit Sustainably on a Site.
Lab Specific Site Design Considerations. Stormwater Management Techniques. Below Grade Stormwater Storage Chambers. Pervious Pavements in Action. Landscaping Considerations. Site Design Strategies. Site Design Strategy. Energy Modeling. Laboratory Energy Estimation Basics. Energy Modeling Protocols.
Energy Analytics. Life-Cycle Cost Analysis. Metering for the Sustainable Laboratory Building. Introduction to Metering.
What to Meter? Components of a Metering System. Metering for the Multi-Tenant Laboratory Building. Metering in Federal Government Laboratories. Advancing Metering. The Laboratory Building Dashboard. Measurement and Verification. Comparison of Measured and Forecasted Loads. Laboratory Building Commissioning.
Key concepts. Mechanical and Electrical Demand Reduction. Heating and Cooling Load Profiling. Supply Air Required for Lab Dilution. Lab Driver Characterization. Reducing Demand with Envelope Improvement. Reducing Demand in Hood-Driven Labs. Energy-Efficient Systems to Meet the Demand.
Variable Air Volume Operation. Laboratory Air System Control Technology. Air Distribution Efficiency. Chilled Beams. Comparison of Energy Recovery Technologies. Low Pressure-Drop Air Distribution. Demand-Controlled Ventilation. Increase Return Air from Labs. Passive-Evaporative Downdraft Cooling. Radiant Heating Systems. Internal Ventilation Requirements and Design Considerations. Air Exhaust and Intake Design Considerations.
Exhaust Stack Design. Exhaust Treatment and Emission Reduction. Low-Energy Cooling and Heating. Heat Pump Systems. Chilled Water Distribution. Optimum Chiller Configuration. Lake Source Cooling Water. High Efficiency Condensing Boilers. Heat Recovery from Boilers. Active Solar Heating and Cooling. Refrigerant Selection. Power Generation and Renewable Energy.
Photovoltaic Arrays. Wind Turbines. Biomass-Fueled Power Generation. Landfill-Derived Methane Fueled Generation. Fuel Cells. Carbon Neutral Laboratory Buildings. Carbon Footprint Reduction. Corporate Carbon Emission Initiatives. Laboratory Water Conservation. Laboratory Water Demand and Consumption. Sustainable Water Systems.
Water Supply Concepts. Waste System Concepts. System Cleaning and Testing. Learning from Corporate Workplace Trends. Costs and Returns.
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