A Compact Thermally Driven Cooling System Based on Metal Hydrides
Abstract
:1. Introduction
- No consumption of electrical power, thus no dependency in driving range on AC operation;
- No moving parts leading to a quiet and low maintenance system;
- No environmentally unfriendly refrigerants are required (hydrogen as working fluid);
- Potentially small systems due to high thermal power density of MH based systems (this aspect is material intrinsic but its effect on the complete system depends highly on the available reactor design).
2. Experimental
2.1. Metal Hydride Working Pair
2.2. Reactor Design
2.3. Description of the Modular MHCS
2.4. MHCS Operation and Optimization Strategy
3. Results and Discussion
3.1. Results of the Reference Experiment
3.2. Sensitivity Study on Cooling Power
3.2.1. Temperature of the Heat Source
3.2.2. Ambient Temperature
- For lower in the regeneration HC, the absorption process in reactor B proceeds at a lower pressure leading to an improved desorption in reactor A at . Therefore, Δwmax is increased during the following cooling HC.
- For lower in the cooling HC, the pressure level is lower as well, leading to improved thermodynamic conditions for desorption at . This, again, leads to an increase in Δwmax.
- For lower additionally, the thermal losses in the cooling HC are reduced due to a smaller temperature difference ΔT = Tamb-Tc of reactor B, when the HCs are switched. As a consequence, Δwmax can be better utilized for effective cold generation.
3.2.3. Cooling Temperature
3.2.4. Cooling HTF Flow Rate
3.2.5. HC Time
3.2.6. Operation Optimization
3.2.7. Evaluation of Cooling Power, Specific Cooling Power and Efficiency for Ooptimal Experimental Conditions
3.3. Recommendations for System Improvement
4. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
AC | Air-conditioning |
C | Connection |
COP | Coefficient of Performance |
FM | Flowmeter |
FS | Full scale |
FM | Flowmeter |
HC | Half-cycle |
HTF | Heat transfer fluid |
HV | Hand valve |
M | Metal |
MH | Metal hydride |
MHCS | Metal hydride cooling system |
OPV | Overpressure valve |
P | Pump |
PS | Pressure sensor |
repro | Reproduced experiment |
Rd | Reading |
TB | Thermostatic bath |
V | Valve |
Nomenclature
b | Reactor width, m |
Reactor height, m | |
Mass ratio, - | |
Reactor length, m | |
Molar weight | |
Number, - | |
Thermal Energy, J | |
Entropy of reaction, J mol−1K−1 | |
Greek Letters
Subscripts
abs | Absorption |
amb | Ambient |
avg | Average |
c | Cooling |
des | Desorption |
eq | Equilibrium |
H2 | Hydrogen |
hs | Heat source |
in | Inlet |
max | Maximum |
min | Minimum |
mr | Mass recovery |
Appendix A
Uncertainty Analysis
Description | Type |
---|---|
Hydrogen section | |
Electromagnetic valves VH2,1–2 | Bürkert 0355-C |
Hand valve HV1–4 | Swagelok SS-6P4T-MM-BK |
Overpressure valve OPV1-2 | Swagelok SS-6R3A-MM |
Pressure sensors PS1-2 | Wagner P-3278 0.5% FS) |
HTF infrastructure section | |
Electromagnetic three-valves VHTF,1–8 | Bürkert 0355-C |
Impeller HTF flow meter FM | Meister DHGA-10 (A: 2% v.Rd) |
Thermocouples | 1.5 K, temperature difference calibrated) |
Control unit and data acquisition | |
Control unit | Arduino Mega 2560 microcontroller |
Data acquisition | Agilent 34970A |
Testing infrastructure | |
Auxiliary heating system | Webasto Thermo Pro 90, 24 V |
HTF gear type pumps P1-P3 | Kracht KF6 RF 3 |
Liquid-to-liquid heat exchanger | VAU VM 15/20 |
Thermostatic bath TBc | Lauda Proline P8 |
Thermostatic bath TBamb | Lauda Proline RP890 |
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Description | Value |
---|---|
Average channel thickness | 1.5 × 10−3 m |
Empty reactor mass | 5.3 kg (without connections) |
Free MH volume | 1.03 × 10−3 m3 |
Mass ratio of reactor A1 and A2 | |
Mass ratio of reactor B1 and B2 | |
Max. permitted pressure | 30 bar |
Max. permitted temperature | 195 °C |
MH mass of reactor A1 and A2 | |
MH mass of reactor B1 and B2 | |
Number of HTF channels | |
Number of MH channels | |
Number of separating steel plates | |
Reactor dimensions | 0.308 m × 0.072 m × 0.158 m |
Reactor volume | 3.5 × 10−3 m3 |
Reactor | A1 | B1 | A2 | B2 | ||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
Operation Mode | 1st HC: Cooling HC 2nd HC: Regeneration HC | 1st HC: Regeneration HC 2nd HC: Cooling HC | ||||||||||
HTF Valve Position | ||||||||||||
Valve | 1st HC | 2nd HC | Valve | 1st HC | 2nd HC | Valve | 1st HC | 2nd HC | Valve | 1st HC | 2nd HC | |
Phase 1 and Phase 2 | VHTF,3 | b-c | a-c | VHTF,1 | b-c | a-c | VHTF,4 | a-c | b-c | VHTF,2 | a-c | b-c |
VHTF,7 | a-b | a-c | VHTF,5 | a-c | a-b | VHTF,8 | a-c | a-b | VHTF,6 | a-b | a-c | |
Phase 3 | VHTF,3 | b-c | a-c | VHTF,1 | b-c | a-c | VHTF,4 | a-c | b-c | VHTF,2 | a-c | b-c |
VHTF,7 | a-c | a-b | VHTF,5 | a-b | a-c | VHTF,8 | a-b | a-c | VHTF,6 | a-c | a-b | |
H2 Valve Position | ||||||||||||
Valve | 1st HC (H2 Flow) | 2nd HC (H2 Flow) | Valve | 1st HC (H2 Flow) | 2nd HC (H2 Flow) | |||||||
Phase 1 | VH2,mr | Open (A1 A2) | Open (A2 A1) | VH2,mr | Open (A1 A2) | Open (A2 A1) | ||||||
VH2,1 | closed | closed | VH2,1 | closed | closed | |||||||
Phase 2 and Phase 3 | VH2,mr | closed | closed | VH2,mr | closed | closed | ||||||
VH2,1 | Open (B1 A1) | Open (A1 B1) | VH2,1 | Open (A2 B2) | Open (B2 A2) |
Parameter | Symbol | Reference Value | Range |
---|---|---|---|
Inlet temperature of the heat source HTF loop | 156.3 °C | 120–167 °C | |
Inlet temperature of the ambient HTF loop | 31.4 °C | 29–40 °C | |
Inlet temperature of the cooling HTF loop | 24.5 °C | 16–31 °C | |
Volume flow of the cooling HTF loop | 6.3 × 10−3 m3 min−1 | 2.1–8.1 × 10−3 m3 min−1 | |
Duration of the HC | 180 s | 120–420 s | |
Duration of the time-shifted switching | 20 s | 0–40 s | |
Duration of the mass recovery | 10 s | 0–20 s |
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Weckerle, C.; Dörr, M.; Linder, M.; Bürger, I. A Compact Thermally Driven Cooling System Based on Metal Hydrides. Energies 2020, 13, 2482. https://doi.org/10.3390/en13102482
Weckerle C, Dörr M, Linder M, Bürger I. A Compact Thermally Driven Cooling System Based on Metal Hydrides. Energies. 2020; 13(10):2482. https://doi.org/10.3390/en13102482
Chicago/Turabian StyleWeckerle, Christoph, Marius Dörr, Marc Linder, and Inga Bürger. 2020. "A Compact Thermally Driven Cooling System Based on Metal Hydrides" Energies 13, no. 10: 2482. https://doi.org/10.3390/en13102482
APA StyleWeckerle, C., Dörr, M., Linder, M., & Bürger, I. (2020). A Compact Thermally Driven Cooling System Based on Metal Hydrides. Energies, 13(10), 2482. https://doi.org/10.3390/en13102482