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Research Tracker

This tool is intended for researchers and program managers to quickly find research projects around the country that are relevant to their work. The four organizations who provided content for this purpose represent the largest energy efficient buildings research portfolios in the country. These organizations each provided the content that they were comfortable sharing publically. Therefore, upon clicking on a particular project, it is possible that certain pieces of content are not present. Where possible, a point of contact is provided so that specific questions can be directed to that person. We welcome your comments! If you would like to provide any feedback on this tool (positive or constructive) please email basc@pnnl.gov.

Showing results 26 - 37 of 37

R25 Polyisocyanurate Composite Insulation Material

Oak Ridge National Laboratory will develop a thin insulation material that demonstrates comparable performance to existing insulation technology. ORNL estimates the energy savings potential of this insulation to be 1,319 TBtu for retrofit-only commercial roof and residential wall applications.

Robust Super Insulation at a Competitive Price

Heating and cooling represents the greatest energy consumption in buildings. This agreement develops thermal building insulation material with high R-value at a cost competitive to conventional insulation materials. The expected result provides a significant increase in energy efficiency for retrofitting buildings.

Robust Super Insulation at a Competitive Price

Lawrence Berkeley National Laboratory, in partnership with Oak Ridge National Laboratory will develop insulation that is 2 to 4 times more efficient than conventional materials and at a comparable installed cost. This insulation technology has the potential of reaching an installed cost of $2.00 per square foot for R-12/inch and targets a technical potential of 1.7 quads.

Solar-Reflective "Cool" Walls: Benefits, Technologies, and Implementation

Increasing the albedo (solar reflectance) of a building's envelope reduces solar heat gain in the cooling season. Raising envelope albedo can also cool the outside air, boosting energy savings and demand reduction by decreasing the air temperature difference across the building envelope. Lowering urban surface and air temperatures improves air quality by slowing the reactions that produce smog, and delays global warming through negative radiative forcing ("global cooling"). Current data are insufficient to accurately predict savings impacts for different cool wall materials; which prevents cool wall technology from being included in building standards or utility rebate programs.

Structural Support of Windows in Walls with Continuous Insulation

Home Innovation Research Labs will establish performance criteria and conduct comprehensive testing to evaluate the structural performance of continuous insulation walls with windows of varying shapes and sizes, insulation thicknesses, and installation methods.

Testing the Performance and Dynamic Control of Energy Efficient Cellular Shades in the PNNL Lab Homes

The objective of the research is to test the energy performance and demand reduction capabilities of the high-efficiency cellular shading devices and associated automated control strategies in the PNNL matched pair of laboratory homes. Tests outcomes will measure the cost-effective materials for existing homes. examine persistence of savings through Automated Operation of Dynamic Systems, and examine the benefits to of coordinating Cellular Shades with HVAC Demand-Response Events.

The Humidity Sponge: Mimicking the Termite Mound's Fungal Comb to Manage Building Humidity with a Low-Energy Passive Solution

This project involved researching the feasibility of commercial "humidity sponges", which could help even out daily and multi-day fluctuations of relative humidity in building spaces. This proof of concept study investigated the wicking and water vapor transfer properties of several materials, in addition to the topology and material properties of the structures termites use to manage humidity in their colonies. The project completed with a market analysis, in order to better understand the marketplace for passive or transient building controls in the energy-efficient dehumidification market space.

Tools and Materials for Zero Net Energy California Buildings

This project researched new phase change materials (PCM) to store thermal energy for wall assemblies, and develop associated software tools. Heat is absorbed or released when the materials change from solid to liquid or vice versa. PCMs absorb thermal energy and they can reduce the need for heating and cooling in some buildings. Their impact is similar to that of adding thermal mass to the building. Unlike air conditioning systems, they require no maintenance. The use of PCMs and associated software tools can contribute to zero net energy commercial buildings by reducing the energy needs of a building through passive design.

Vacuum Insulation for Windows

The National Renewable Energy Laboratory will develop high-performing vacuum insulation for use on installed windows. This technology could offer an alternative to replacing existing windows with highly insulting windows and save 2 - 3 quads of energy annually.