SBIR-STTR Award

Biological Treatment of Hydrocarbons in Shipboard Exhaust Gas Cleaning Systems
Award last edited on: 12/28/2023

Sponsored Program
SBIR
Awarding Agency
NSF
Total Award Amount
$1,183,954
Award Phase
2
Solicitation Topic Code
BC
Principal Investigator
Richard Penny

Company Information

EnSolve Biosystems Inc

5805 Departure Drive Suite B
Raleigh, NC 27616
   (919) 954-6196
   info@ensolve.com
   www.ensolve.com
Location: Single
Congr. District: 04
County: Wake

Phase I

Contract Number: 1013871
Start Date: 7/1/2010    Completed: 4/30/2011
Phase I year
2010
Phase I Amount
$149,622
This SBIR Phase I project proposes to test the efficacy of scrubber water treatment systems to treat hydrocarbon contaminants in the scrubber water from the exhaust gas cleaning system. What are the broader/commercial impacts of the proposed project? The broader/commercial impact of the proposed project will be to enable ships to meet new regulations adopted by the International Maritime Organization which become effective in July 2010. Ships will be required to either install scrubbing equipment for removal of sulfur compounds from residual fuels currently burned, or they will need to switch to more costly low sulfur distillate fuels. A switch to low sulfur fuel would increase current fuel costs by over 88%

Phase II

Contract Number: 1152257
Start Date: 4/1/2012    Completed: 7/31/2017
Phase II year
2012
(last award dollars: 2015)
Phase II Amount
$1,034,332

This Small Business Innovation Research (SBIR) Phase II project will address new regulations being enacted in the shipping industry requiring Sulfur Oxides (SOx) reduction from engine emissions. Many commercial scrubber systems effectively remove SOx from engine emissions, yet none are designed to remove polycyclic aromatic hydrocarbons (PAHs). EnSolve?s approach is to develop a combined biological and mechanical system that can remove PAHs from the scrubber system waste water. The results of the Phase I study confirmed the biomechanical approach was effective in reducing PAHs at rates exceeding 99%. The broader impacts of this research will be to provide the maritime industry with a cost effective, reliable, and environmentally conscious treatment system for removing toxic substances from the world?s oceans. Ships will be required to either install scrubbing equipment or they will need to switch to more costly low sulfur fuels. A switch to low sulfur fuel would increase current fuel costs by over 88%. A commercial ship owner could realize annual savings of $2 million per vessel in fuel costs using a scrubber system compared with purchasing low sulfur fuel. An estimated 35,000 ships will be impacted by these regulations, yielding a market opportunity for the proposed scrubber water treatment system exceeding $5 billion. Other technologies under development utilize pure physical separation methods that transfer the contaminants from the scrubber water to another medium (i.e., filters) for disposal. Conversely, the proposed biological approach is a regenerative process that would significantly reduce landfill disposal, consumable, labor, and liability costs.