Optimal Configuration of Power-to-Heat Equipment Considering Peak-Shaving Ancillary Service Market
Abstract
:1. Introduction
2. Deep Peak-Shaving Income of the CHP Plant
2.1. Deep Peak-Shaving Capacity Provided by the CHP Plant
2.2. Deep Peak-Shaving Capacity Required by the Power Grid
Scenario 1 (S1): | |
Scenario 2 (S2): | |
Scenario 3 (S3): | |
Scenario 4 (S4): | |
Scenario 5 (S5): |
2.3. Deep Peak-Shaving Income of the CHP Plant
3. Optimal Configuration of the P2H Equipment
3.1. Total Fixed Cost of the P2H Equipment
3.2. Operation Income of the P2H Equipment
4. Case Studies
4.1. Analysis of the Deep Peak-Shaving Ability of the CHP Plant without the P2H Equipment
4.2. Analysis of Economic Benefits with Different P2H Equipment
4.3. Analysis of Deep Peak-Shaving Ability of the CHP Plant with an HP
4.4. Analysis of Influence Factors of the Optimal P2H Equipment Capacity
5. Conclusions
- (1)
- It is necessary for the CHP plant to invest in P2H equipment in order to improve the peak-shaving ability of the CHP units.
- (2)
- It is beneficial for the CHP plant to invest in P2H equipment considering the economic benefits that may be obtained in the ancillary service market.
- (3)
- Due to higher energy conversion efficiency of the HP, investing in the HP has better economic benefits than investing in the EB. Furthermore, with the trend of continuous growth in wind power scale, the CHP plant will achieve higher investment returns.
- (4)
- The optimal capacity of the HP will not be affected by the deviation between historical and real-time data of quotation value, power load, and wind power. The optimization model proposed in this study is feasible and stable.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Nomenclature
thermal power output of the i-th CHP unit, MW | |
maximum thermal power output of the i-th CHP unit, MW | |
maximum thermal power output of the i-th CHP when the unit is operated at the minimum running power, MW | |
running power of the P2H equipment, MW | |
maximum running power of the P2H equipment, MW | |
power capacity of the P2H equipment, MW | |
heat load, MW | |
generated electric power of the i-th CHP unit, MW | |
minimum electric power output of the i-th CHP unit, MW | |
power capacity of the i-th CHP unit, MW | |
running power of the P2H equipment when CHP units running at the first base line of deep peak-shaving, MW | |
running power of the P2H equipment when CHP units running at the second base line of deep peak-shaving, MW | |
running power of the P2H equipment when CHP units running at the minimum power output, MW | |
deep peak-shaving capacity at the first level available from the CHP plant, MW | |
deep peak-shaving capacity at the second level available from the CHP plant, MW | |
deep peak-shaving capacity required by the power grid, MW | |
generated wind power, MW | |
minimum power output of non-coal-fired units, MW | |
power capacity of the j-th CON unit, MW | |
electric power load, MW | |
deep peak-shaving capacity at the first level available from the CON plant, MW | |
first level of deep peak-shaving capacity actually provided by CHP units, MW | |
second level of deep peak-shaving capacity actually provided by CHP units, MW | |
transaction price of the power capacity provided by the P2H equipment on the d-th day in heating season, ¥/kWh | |
transaction price of the deep peak-shaving capacity at the first level, ¥/kWh | |
transaction price of the deep peak-shaving capacity at the second level, ¥/kWh | |
daily modified power production value of wind power generators, MW | |
daily modified power production value of solar power generators, MW | |
daily modified power production value of nuclear power generators, MW | |
compensation cost apportioned by the CHP plant with the P2H equipment, ¥ | |
deep peak-shaving income of the CHP plant with the P2H equipment, ¥ | |
minimum power generated by the CON plant, MW | |
t | index of scheduling time interval |
N1 | total number of CHP units |
coefficient of performance | |
expression coefficient | |
expression coefficient | |
approximate value of the electrothermal ratio | |
first base line of deep peak-shaving set for the CHP unit | |
second base line of deep peak-shaving set for the CHP unit | |
N2 | total number of CHP units |
first base line of deep peak-shaving set for the CON unit | |
second base line of deep peak-shaving set for the CON unit | |
D | total days of the heating season |
lifetime of the P2H equipment | |
ratio of maintenance cost | |
carbon emission coefficient of standard coal | |
correction factor | |
deep peak-shaving income of the CHP plant, ¥ | |
daily income of the P2H equipment, ¥ | |
total fixed cost of the of the P2H equipment, ¥ | |
unit price of the P2H equipment, ¥/MW | |
reduced coal cost, ¥ | |
reduced carbon trading cost, ¥ | |
reduced compensation cost of deep peak-shaving apportioned by the CHP plant, ¥ | |
increased deep peak-shaving income, ¥ | |
unit price of coal, ¥/ton | |
unit price of carbon trading, ¥/ton | |
reduced coal for thermal power production, ton | |
daily modified power production value of CHP units, MW | |
compensation cost apportioned by the CHP plant without the P2H equipment, ¥ | |
deep peak-shaving income of the CHP plant without the P2H equipment, ¥ |
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Parameters | Ucoal | Qcoal | kav | ||||||
---|---|---|---|---|---|---|---|---|---|
Value | 114 MW | 105 MW | 56 MW | 73.4 MW | 840 ¥/ton | 135 kg/kWh | 56 ¥/ton | 2.66 | 0.45 |
Parameters | η | yPH | cPH | |
---|---|---|---|---|
EB | 95% | 20 years | 30% | 980 k¥/MW |
HP | 3.5 | 20 years | 15% | 4500 k¥/MW |
Parameters | /¥ × 104 | /¥ × 104 | /¥ × 104 | /¥ × 104 | /¥ × 104 | /¥ × 104 |
---|---|---|---|---|---|---|
Without P2H | 81.03 | 1952.36 | 0 | 0 | 0 | 0 |
EB = 67 MW | 563.15 | 787.18 | 780.33 | 138.38 | 2566.01 | 45,962 |
HP = 19 MW | 293.91 | 1074.30 | 904.04 | 160.32 | 2155.30 | 34,200 |
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Yu, Y.; Zhou, G.; Wu, K.; Chen, C.; Bian, Q. Optimal Configuration of Power-to-Heat Equipment Considering Peak-Shaving Ancillary Service Market. Energies 2023, 16, 6860. https://doi.org/10.3390/en16196860
Yu Y, Zhou G, Wu K, Chen C, Bian Q. Optimal Configuration of Power-to-Heat Equipment Considering Peak-Shaving Ancillary Service Market. Energies. 2023; 16(19):6860. https://doi.org/10.3390/en16196860
Chicago/Turabian StyleYu, Yanjuan, Guohua Zhou, Kena Wu, Cheng Chen, and Qiang Bian. 2023. "Optimal Configuration of Power-to-Heat Equipment Considering Peak-Shaving Ancillary Service Market" Energies 16, no. 19: 6860. https://doi.org/10.3390/en16196860
APA StyleYu, Y., Zhou, G., Wu, K., Chen, C., & Bian, Q. (2023). Optimal Configuration of Power-to-Heat Equipment Considering Peak-Shaving Ancillary Service Market. Energies, 16(19), 6860. https://doi.org/10.3390/en16196860