Abstract

The carbon-free energy systems such as nuclear can benefit from compact and highly efficient heat exchanger technologies. The plate-type compact heat exchangers such as the printed circuit heat exchanger (PCHE) holds promise to fulfill these requirements. This work presents the thermal-hydraulic and structural analysis of PCHE for molten salt applications with thermal energy storage. In this study, three distinct types of geometry are chosen for the analysis, i.e., the zigzag channel type, the airfoil fin type, and the slotted fin type. For the working fluid, FLiBe (Li2BeF4) and solar salt (60% NaNO3 and 40% KNO3) are chosen for hot side and cold side, respectively. Titanium grade 5 is chosen as the structural material. The study is conducted by computational fluid dynamics (CFD) and finite element method (FEM) analysis. The thermomechanical behavior including pressure drop, fluid temperature, velocity profile, stress, and deformation of the flow channel were considered in this work. From the results, the zigzag channel geometry gives the best thermal hydraulic performance in terms of heat transfer and pressure drop. The structural analysis shows that the stress intensity has an exponential growth with power generation level with zigzag channel geometry being the highest out of three geometries. Overall, the zigzag channel PCHE is still the most suitable geometry for this application. Zigzag channel geometry should be substituted with an alternative geometry at a high-power application having both airfoil-fin and slotted-fin geometry at relatively identical stress intensity.

References

1.
Kairos Power, 2022, “Kairos Power,” Kairos Power, Alameda, CA, accessed May 14, 2022, https://kairospower.com/
2.
Heatric, 2022, “Printed Circuit Heat Exchangers - High-Integrity Equipment,” Heatric, Dorset, UK, accessed Apr. 30, 2022, https://www.heatric.com/heat-exchangers/
3.
Heatric, 2022, “Benefits of Diffusion Bonded Heat Exchangers,” Heatric, Dorset, UK, accessed Jan. 15, 2021, https://www.heatric.com/heat-exchangers/benefits-heatric-exchangers/
4.
Romatoski
,
R. R.
, and
Hu
,
L. W.
,
2017
, “
Fluoride Salt Coolant Properties for Nuclear Reactor Applications: A Review
,”
Ann. Nucl. Energy
,
109
, pp.
635
647
.10.1016/j.anucene.2017.05.036
5.
ANSYS
,
2013
,
ANSYS Fluent Theory Guide
,
ANSYS
,
Canonsburg, PA
, p.
779
.
6.
Ionescu
,
V.
,
2019
, “
Numerical Investigation of a MEMS Thermal Actuator Performance by Modifying Its Geometric Dimensions
,”
Procedia Manuf.
,
32
, pp.
820
830
.10.1016/j.promfg.2019.02.290
7.
Lee
,
Y.
, and
Lee
,
J. I.
,
2014
, “
Structural Assessment of Intermediate Printed Circuit Heat Exchanger for Sodium-Cooled Fast Reactor With Supercritical CO2 Cycle
,”
Ann. Nucl. Energy
,
73
, pp.
84
95
.10.1016/j.anucene.2014.06.022
8.
Romero, M., and González-Aguilar, J., 2017, “Next Generation of Liquid Metal and Other High-Performance Receiver Designs for Concentrating Solar Thermal (CST) Central Tower Systems,” Advances in Concentrating Solar Thermal Research and Technology, Part 3, Chapter 7, Blanco, M., and Santigosa, L. R., eds., Woodhead Publishing Series in Energy, Sawston, UK.
9.
Titanium, 2022, “Titanium Grade 5 Fasteners & Flanges,” Extreme-Bolt.Com, Newark, DE, accessed May 14, 2022, https://www.extreme-bolt.com/titanium-grade-5-fasteners-flanges.html
10.
Hidnert
,
P.
,
1943
, “
Thermal Expansion of Titanium
,”
J. Res. Natl. Bureau Stand.
,
30
(
2
), pp.
101
105
.10.6028/jres.030.008
11.
Rangaswamy
,
P.
,
Choo
,
H.
,
Prime
,
M. B.
,
Bourke
,
M. M.
, and
Larsen
,
J. M.
,
2000
, “
High Temperature Stress Assessment in SCS-6/Ti-6Al-4V Composite Using Neutron Diffraction and Finite Element Modeling
,” THERMEC International Conference on Processing & Manufacturing of Advance Materials, Las Vegas, NV, Dec. 4–8, p.
7
, Report No.
LA-UR-00-5277
.https://digital.library.unt.edu/ark:/67531/metadc721197/
12.
Fukuhara
,
M.
, and
Sanpei
,
A.
,
1993
, “
Elastic Moduli and Internal Frictions of Inconel 718 and Ti-6Al-4V as a Function of Temperature
,”
J. Mater. Sci. Lett.
,
12
(
14
), pp.
1122
1124
.10.1007/BF00420541
13.
Bennett
,
K.
, and
Chen
,
Y.
,
2020
, “
One-Way Coupled Three-Dimensional Fluid-Structure Interaction Analysis of Zigzag-Channel Supercritical CO2 Printed Circuit Heat Exchangers
,”
Nucl. Eng. Des.
,
358
, p.
110434
.10.1016/j.nucengdes.2019.110434
14.
Marchionni
,
M.
,
Chai
,
L.
,
Bianchi
,
G.
, and
Tassou
,
S. A.
,
2019
, “
Numerical Modelling and Transient Analysis of a Printed Circuit Heat Exchanger Used as Recuperator for Supercritical CO2 Heat to Power Conversion Systems
,”
Appl. Therm. Eng.
,
161
, p.
114190
.10.1016/j.applthermaleng.2019.114190
15.
Zhao
,
Z.
,
Zhou
,
Y.
,
Ma
,
X.
,
Chen
,
X.
,
Li
,
S.
, and
Yang
,
S.
,
2019
, “
Numerical Study on Thermal Hydraulic Performance of Supercritical LNG in Zigzag-Type Channel PCHEs
,”
Energies
,
12
(
3
), p.
548
.10.3390/en12030548
16.
Comprex, 2022, “High Temperature, High Pressure Heat Exchangers,” Comprex, La Crosse, WI, accessed May 14, 2022, https://www.comprex-llc.com/technology
17.
Turchi
,
C. S.
,
Vidal
,
J.
, and
Bauer
,
M.
,
2018
, “
Molten Salt Power Towers Operating at 600–650 °C: Salt Selection and Cost Benefits
,”
Sol. Energy
,
164
, pp.
38
46
.10.1016/j.solener.2018.01.063
18.
Çengel
,
Y. A.
, and
Ghajar
,
A. J.
,
2015
,
Heat and Mass Transfer: Fundamentals & Applications
, 5th ed.,
McGraw-Hill
,
New York
, p.
968
.
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