Abstract

The Heliostat Consortium (HelioCon) was launched in 2021 to advance heliostat technology. One of its first efforts was to do a detailed analysis of gaps in technology and capabilities in the heliostat industry and complete a roadmap study describing high-priority gaps. HelioCon gathered gaps through a series of outreach activities with representatives and experts from industries and research institutes. This paper discusses the gap analysis for the techno-economic analysis (TEA) topic. One of the main objectives of the TEA topic is to relate the cost and performance of heliostats and heliostat components to the overall system performance. In this study, we limit the scope of this topic to the heliostat field, tower, and receiver and do not consider downstream applications or uses of thermal energy. We conducted a thorough review of existing models and compiled a list of the state of the art in open-source tools currently available to researchers. We collected an initial list of gaps for the TEA of heliostats from industry developers and experts. Each gap is briefly described, and the heliostat development cycle stages that the gap impacts are indicated. We ranked the initial list of TEA gaps into tiers depending on their potential impact. For TEA, most of the gaps identified are related to developing models or data. Strictly speaking, none of these gaps are essential for heliostat development, but all would aid in the heliostat development process.

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References

1.
Zhu
,
G.
,
Augustine
,
C.
,
Mitchell
,
R.
,
Muller
,
M.
,
Kurup
,
P.
,
Zolan
,
A.
,
Yellapantula
,
S.
, et al
,
2022
, Roadmap to Advance Heliostat Technologies for Concentrating Solar-Thermal Power, Report No. NREL/TP-5700-83041. https://www.osti.gov/servlets/purl/1888029/.
2.
Cox
,
J. L.
,
Hamilton
,
W. T.
,
Newman
,
A. M.
,
Wagner
,
M. J.
, and
Zolan
,
A. J.
,
2022
, “
Real-Time Dispatch Optimization for Concentrating Solar Power With Thermal Energy Storage
,”
Optim. Eng.
,
24
(
2
), pp.
847
884
.
3.
National Renewable Energy Laboratory
. “System Advisor Model Version 2021.12.02 (SAM 2021.12.02).” https://sam.nrel.gov/download/version-2021-12-02.html.
4.
National Renewable Energy Laboratory
. “Solar Power Tower Integrated Layout and Optimization Tool Version 1.1 (SolarPILOT 1.1).” https://www.nrel.gov/csp/solarpilot.html.
5.
Australian Solar Thermal Research Initiative (ASTRI)
. “SolarTherm Version 0.1.” https://build.openmodelica.org/Documentation/SolarTherm.html.
6.
National Renewable Energy Laboratory
. “SolTrace Version 3.0.” https://www.nrel.gov/csp/soltrace.html.
7.
“SUNNTICS,” Sunntics
. https://www.sunntics.com/. Accessed June 16, 2023.
8.
Potter
,
D. F.
,
Kim
,
J.-S.
,
Khassapov
,
A.
,
Pascual
,
R.
,
Hetherton
,
L.
, and
Zhang
,
Z.
,
2018
, “
Heliosim: An Integrated Model for the Optimisation and Simulation of Central Receiver CSP Facilities
,”
AIP Conf. Proc.
,
2033
(
1
), p.
210011
.
9.
Gebreiter
,
D.
,
Weinrebe
,
G.
,
Wöhrbach
,
M.
,
Arbes
,
F.
,
Gross
,
F.
, and
Landman
,
W.
,
2019
, “
SbpRAY—A Fast and Versatile Tool for the Simulation of Large Scale CSP Plants
,”
AIP Conf. Proc.
,
2126
(
1
), p.
170004
.
10.
Armstrong
,
P.
, and
Izygon
,
M.
,
2014
, “
An Innovative Software for Analysis of Sun Position Algorithms
,”
Energy Proc.
,
49
, pp.
2444
2453
.
11.
Cardoso
,
J. P.
,
Mutuberria
,
A.
,
Marakkos
,
C.
,
Schoettl
,
P.
,
Osório
,
T.
, and
Les
,
I.
,
2018
, “New Functionalities for the Tonatiuh Ray-Tracing Software,” Santiago, Chile, p. 210010. http://aip.scitation.org/doi/abs/10.1063/1.5067212.
12.
Ahlbrink
,
N.
,
Belhomme
,
B.
,
Flesch
,
R.
,
Maldonado Quinto
,
D.
,
Rong
,
A.
, and
Schwarzbözl
,
P.
,
2012
, “
STRAL: Fast Ray Tracing Software With Tool Coupling Capabilities for High-Precision Simulations of Solar Thermal Power Plants
,”
Proceedings of the SolarPACES 2012 Conference
,
Marrakesch, Marokko
,
Sept. 11–14
.
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