| Title | Feasibility of Deep Direct-Use for District-Scale Applications in a Low-Temperature Sedimentary Basin |
|---|---|
| Authors | Andrew J. STUMPF, Scott M. FRAILEY, Roland T. OKWEN, Yongqi LU, Franklin H. HOLCOMB, James M. TINJUM, Yu-Feng F. LIN |
| Year | 2020 |
| Conference | Stanford Geothermal Workshop |
| Keywords | feasibility study, deep direct-use, ddu, geothermal energy system, low-temperature, sedimentary basin, Illinois Basin, geothermal reservoir modeling, life cycle analysis, lcoh, doublet well system, agricultural research facilities, military installations, University of Illinois |
| Abstract | A feasibility study of using deep direct-use (DDU) geothermal energy to heat agricultural research facilities (ARFs) was conducted at the University of Illinois at Urbana-Champaign (U of IL) and its similar application to military facilities in the Illinois Basin (ILB). The geothermal energy system (GES) investigated utilizes low-temperature (30–90°C; 90–190°F) geothermal fluid (i.e., brine) from an extraction well that is part of a deep, two-well (doublet) system that extends to the bottom of the ILB. The geothermal reservoir modeled, the Mt. Simon Sandstone (MSS), is about 1,280 m (4,200 feet) deep and 457 m thick (1,500 feet) beneath the U of IL. The DDU GES surface infrastructure includes heat exchangers connected in-parallel to pipelines carrying the geothermal fluid and fresh cold and hot water. Analysis of the GES indicated that the MSS can provide a baseload of 2 MMBtu/hr to heat the ARFs by extracting 954 m³/d (6,000 barrels/day [bbl/d]) of geothermal fluid that has a temperature of 44–46 ℃ (111–115 ℉). In addition to analyzing the levelized cost of heat (LCOH) and life cycle costs, the environmental effects of the DDU GES were evaluated, including reduced greenhouse gas (GHG) emissions and water consumption. Multiple system designs were evaluated and then ranked based on their maximum heating performance, energy efficiency, and cost recovery. This study addressed the major issues associated with DDU implementation in the ILB and met the following objectives: (1) reduce geologic uncertainty, (2) minimize drilling risk, (3) optimize system performance and flexibility with reliable fluid delivery, and (4) support task expertise through established partnerships. |