SBIR-STTR Award

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase I project is to advance the development of a fully flexible high-temperature (operating in the 200-400°C range) insulation product for industrial applications (e.g. pipes and other process systems). The proposed technology offers performance improvements compared to current solutions, such as fiberglass and mineral wool, while reducing costs through lower-cost manufacturing and easier installation. High-temperature industrial insulation can achieve significantly greater energy savings versus building insulation, leading to project paybacks as low as 1-2 years. This will reduce costs and energy loads in energy-intensive industries such as food, paper, chemicals, refining and metals.This Small Business Innovation Research (SBIR) Phase I project will utilize nanomaterials to produce a novel composite insulation material that is flexible and delivers high performance above 200°C. The inorganic materials will raise temperature durability while high-temperature specialty polymers will enable flexibility. The materials will be processed using high-volume chemical foaming processes (such as extrusion) scalable into mass production using off-the-shelf equipment, addressing cost and throughput issues. This work addresses a longstanding industry challenge to mass-produce a fully flexible high-temperature insulation material easily installable by a single individual using standard tools and supplies. A key activity is to reduce pore sizes below the mean free path of air (~100 nm). This minimizes all three forms of heat transfer - conduction, convection and radiation, the last of which becomes more prominent at high temperatures.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

The broader impact of this Small Business Innovation Research (SBIR) Phase II project is utilizing thermal energy management to simultaneously improve the affordability, comfort, and safety of buildings, with an initial focus on meeting urgent market demand for non-combustible building insulation. This project will focus on developing a lightweight, easy-to-install, non-combustible insulation product which is also eco-friendly and non-toxic. Structure fires represent 37% of all fires in the US. These fires caused $12.3 billion in property damage and 80% of civilian fire deaths. Wildfires in the Western US, where >$220 billion in residential construction is in “extreme” wildfire-prone areas, add to the urgency of this situation. Mineral wool is the only non-combustible insulation product available today but requires personal protective equipment for installation and was recently classified as carcinogenic. Fully non-combustible building insulation is a high growth market, and the broader market for all types of non-flammable insulation represents a significant opportunity. This Phase II project seeks to cost-effectively increase the supply of energy-efficient, non-combustible buildings for both new and retrofit construction, while also addressing high-temperature industrial markets which have the most intensive energy use.This Small Business Innovation Research (SBIR) Phase II project seeks to scale up a novel nanocomposite insulation product using a proprietary foaming process for inorganic aerogel-based insulation that minimizes shrinkage (thus maximizing porosity for insulation performance and minimizing material and processing cost). This approach leverages readily available materials such as clay and silica, as well as potentially renewable cellulose biomass, to produce an environmentally friendly, high performance insulation product for non-combustible buildings which is easy to install, lightweight, and non-toxic. Successfully scaling this approach on existing manufacturing equipment may solve a significant materials research challenge, creating organic-inorganic nanocomposites for thermal insulation with a competitive cost / performance ratio versus incumbent products such as fiberglass, mineral wool, and plastic foams. The Phase II project may result in the first industrially-engineered composite material for thermal insulation which is fully non-combustible. The integration of flexible polymers and radiation blocking additives would also enable use for high-temperature industrial pipe insulation, a critical energy-saving application where most existing products have significant limitations due to radiation loss.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.