facat/multi_energy_complementarity
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity

考虑了储能上限。

Browse Source
This commit is contained in:
dmy
2025-12-25 21:14:11 +08:00
parent 974ac6d6db
commit bdfabd7eba
2 changed files with 103 additions and 16 deletions
Download Patch File Download Diff File Expand all files Collapse all files

85
example_usage.py
View File

@@ -230,46 +230,104 @@ def plot_results(result, title, solar_output, wind_output, thermal_output, load_
plt.show() plt.show()
def example_4_capacity_limited_scenario():
"""示例4: 储能容量限制场景"""
print("\n=== 示例4: 储能容量限制场景 ===")
# 使用基础场景的数据
solar_output = [0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.5, 2.0, 4.0, 6.0, 8.0, 9.0,
8.0, 6.0, 4.0, 2.0, 0.5, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0]
wind_output = [4.0, 4.5, 5.0, 5.5, 5.0, 4.5, 4.0, 3.5, 3.0, 2.5, 2.0, 1.5,
1.5, 2.0, 2.5, 3.0, 3.5, 4.0, 4.5, 5.0, 5.5, 5.0, 4.5, 4.0]
thermal_output = [8.0] * 24
load_demand = [6.0, 5.5, 5.0, 5.0, 5.5, 7.0, 9.0, 12.0, 15.0, 18.0, 20.0, 19.0,
18.0, 17.0, 16.0, 15.0, 14.0, 13.0, 12.0, 10.0, 8.0, 7.0, 6.0, 6.0]
# 系统参数 - 设置储能容量上限为10 MWh
params = SystemParameters(
max_curtailment_wind=0.1,
max_curtailment_solar=0.05,
max_grid_ratio=0.15,
storage_efficiency=0.9,
discharge_rate=1.0,
charge_rate=1.0,
max_storage_capacity=10.0 # 限制储能容量上限为10 MWh
)
result = optimize_storage_capacity(solar_output, wind_output, thermal_output, load_demand, params)
print(f"所需储能容量: {result['required_storage_capacity']:.2f} MWh")
print(f"储能容量上限: {result['max_storage_limit']:.2f} MWh")
print(f"是否达到容量上限: {'' if result['capacity_limit_reached'] else ''}")
print(f"实际弃风率: {result['total_curtailment_wind_ratio']:.3f} (约束: {params.max_curtailment_wind})")
print(f"实际弃光率: {result['total_curtailment_solar_ratio']:.3f} (约束: {params.max_curtailment_solar})")
print(f"实际上网电量比例: {result['total_grid_feed_in_ratio']:.3f} (约束: {params.max_grid_ratio})")
print(f"能量平衡校验: {'通过' if result['energy_balance_check'] else '未通过'}")
return {
'result': result,
'solar_output': solar_output,
'wind_output': wind_output,
'thermal_output': thermal_output,
'load_demand': load_demand
}
def compare_scenarios(): def compare_scenarios():
"""比较不同场景的结果""" """比较不同场景的结果"""
print("\n=== 场景比较 ===") print("\n=== 场景比较 ===")
# 运行个场景 # 运行个场景
data1 = example_1_basic_scenario() data1 = example_1_basic_scenario()
data2 = example_2_high_renewable_scenario() data2 = example_2_high_renewable_scenario()
data3 = example_3_winter_scenario() data3 = example_3_winter_scenario()
data4 = example_4_capacity_limited_scenario()
# 比较结果 # 比较结果
scenarios = ['基础场景', '高可再生能源场景', '冬季场景'] scenarios = ['基础场景', '高可再生能源场景', '冬季场景', '容量限制场景']
storage_capacities = [ storage_capacities = [
data1['result']['required_storage_capacity'], data1['result']['required_storage_capacity'],
data2['result']['required_storage_capacity'], data2['result']['required_storage_capacity'],
data3['result']['required_storage_capacity'] data3['result']['required_storage_capacity'],
data4['result']['required_storage_capacity']
] ]
curtailment_wind = [ curtailment_wind = [
data1['result']['total_curtailment_wind_ratio'], data1['result']['total_curtailment_wind_ratio'],
data2['result']['total_curtailment_wind_ratio'], data2['result']['total_curtailment_wind_ratio'],
data3['result']['total_curtailment_wind_ratio'] data3['result']['total_curtailment_wind_ratio'],
data4['result']['total_curtailment_wind_ratio']
] ]
curtailment_solar = [ curtailment_solar = [
data1['result']['total_curtailment_solar_ratio'], data1['result']['total_curtailment_solar_ratio'],
data2['result']['total_curtailment_solar_ratio'], data2['result']['total_curtailment_solar_ratio'],
data3['result']['total_curtailment_solar_ratio'] data3['result']['total_curtailment_solar_ratio'],
data4['result']['total_curtailment_solar_ratio']
] ]
grid_feed_in = [ grid_feed_in = [
data1['result']['total_grid_feed_in_ratio'], data1['result']['total_grid_feed_in_ratio'],
data2['result']['total_grid_feed_in_ratio'], data2['result']['total_grid_feed_in_ratio'],
data3['result']['total_grid_feed_in_ratio'] data3['result']['total_grid_feed_in_ratio'],
data4['result']['total_grid_feed_in_ratio']
]
capacity_limit = [
'',
'',
'',
f"{data4['result']['max_storage_limit']:.1f}MWh"
] ]
print("\n场景比较结果:") print("\n场景比较结果:")
print(f"{'场景':<15} {'储能容量(MWh)':<12} {'弃风率':<8} {'弃光率':<8} {'上网比例':<8}") print(f"{'场景':<15} {'储能容量(MWh)':<12} {'容量限制':<10} {'弃风率':<8} {'弃光率':<8} {'上网比例':<8}")
print("-" * 55) print("-" * 75)
for i, scenario in enumerate(scenarios): for i, scenario in enumerate(scenarios):
print(f"{scenario:<15} {storage_capacities[i]:<12.2f} {curtailment_wind[i]:<8.3f} " limit_reached = "" if data4['result']['capacity_limit_reached'] and i == 3 else ""
f"{curtailment_solar[i]:<8.3f} {grid_feed_in[i]:<8.3f}") print(f"{scenario:<15} {storage_capacities[i]:<12.2f} {capacity_limit[i]:<10} {curtailment_wind[i]:<8.3f} "
f"{curtailment_solar[i]:<8.3f} {grid_feed_in[i]:<8.3f} {limit_reached}")
return data1, data2, data3 return data1, data2, data3, data4
if __name__ == "__main__": if __name__ == "__main__":
@@ -277,7 +335,7 @@ if __name__ == "__main__":
print("=" * 50) print("=" * 50)
# 运行示例 # 运行示例
data1, data2, data3 = compare_scenarios() data1, data2, data3, data4 = compare_scenarios()
# 绘制图表如果matplotlib可用 # 绘制图表如果matplotlib可用
try: try:
@@ -290,6 +348,9 @@ if __name__ == "__main__":
plot_results(data3['result'], "冬季场景储能运行情况", plot_results(data3['result'], "冬季场景储能运行情况",
data3['solar_output'], data3['wind_output'], data3['solar_output'], data3['wind_output'],
data3['thermal_output'], data3['load_demand']) data3['thermal_output'], data3['load_demand'])
plot_results(data4['result'], "容量限制场景储能运行情况",
data4['solar_output'], data4['wind_output'],
data4['thermal_output'], data4['load_demand'])
except ImportError: except ImportError:
print("\n注意: matplotlib未安装无法绘制图表") print("\n注意: matplotlib未安装无法绘制图表")
print("要安装matplotlib请运行: pip install matplotlib") print("要安装matplotlib请运行: pip install matplotlib")

34
storage_optimization.py
View File

@@ -22,6 +22,7 @@ class SystemParameters:
storage_efficiency: float = 0.9 # 储能充放电效率 (0.0-1.0) storage_efficiency: float = 0.9 # 储能充放电效率 (0.0-1.0)
discharge_rate: float = 1.0 # 储能放电倍率 (C-rate) discharge_rate: float = 1.0 # 储能放电倍率 (C-rate)
charge_rate: float = 1.0 # 储能充电倍率 (C-rate) charge_rate: float = 1.0 # 储能充电倍率 (C-rate)
max_storage_capacity: Optional[float] = None # 储能容量上限 (MWh)None表示无限制
def validate_inputs( def validate_inputs(
@@ -75,6 +76,8 @@ def validate_inputs(
raise ValueError("储能效率必须在0.0-1.0之间") raise ValueError("储能效率必须在0.0-1.0之间")
if params.discharge_rate <= 0 or params.charge_rate <= 0: if params.discharge_rate <= 0 or params.charge_rate <= 0:
raise ValueError("充放电倍率必须大于0") raise ValueError("充放电倍率必须大于0")
if params.max_storage_capacity is not None and params.max_storage_capacity <= 0:
raise ValueError("储能容量上限必须大于0")
def calculate_energy_balance( def calculate_energy_balance(
@@ -293,11 +296,18 @@ def optimize_storage_capacity(
# 初始化搜索范围 # 初始化搜索范围
lower_bound = 0.0 lower_bound = 0.0
upper_bound = max(sum(solar_output) + sum(wind_output) + sum(thermal_output), sum(load_demand)) theoretical_max = max(sum(solar_output) + sum(wind_output) + sum(thermal_output), sum(load_demand))
# 应用储能容量上限限制
if params.max_storage_capacity is not None:
upper_bound = min(theoretical_max, params.max_storage_capacity)
else:
upper_bound = theoretical_max
# 二分搜索寻找最小储能容量 # 二分搜索寻找最小储能容量
best_capacity = upper_bound best_capacity = upper_bound
best_result = None best_result = None
solution_found = False # 标记是否找到可行解
for iteration in range(max_iterations): for iteration in range(max_iterations):
mid_capacity = (lower_bound + upper_bound) / 2 mid_capacity = (lower_bound + upper_bound) / 2
@@ -326,6 +336,7 @@ def optimize_storage_capacity(
# 满足条件,尝试减小容量 # 满足条件,尝试减小容量
best_capacity = mid_capacity best_capacity = mid_capacity
best_result = {**balance_result, **constraint_results} best_result = {**balance_result, **constraint_results}
solution_found = True
upper_bound = mid_capacity upper_bound = mid_capacity
else: else:
# 不满足条件,增大容量 # 不满足条件,增大容量
@@ -335,8 +346,20 @@ def optimize_storage_capacity(
if upper_bound - lower_bound < tolerance: if upper_bound - lower_bound < tolerance:
break break
# 如果没有找到可行解,使用最大容量 # 处理储能容量上限限制的情况
if best_result is None: if not solution_found and params.max_storage_capacity is not None:
print(f"警告:在储能容量上限 {params.max_storage_capacity:.2f} MWh 内无法找到满足所有约束的解")
print("使用最大允许容量进行计算,但某些约束条件可能无法满足")
# 使用最大允许容量计算结果
balance_result = calculate_energy_balance(
solar_output, wind_output, thermal_output, load_demand, params, params.max_storage_capacity
)
constraint_results = check_constraints(solar_output, wind_output, thermal_output, balance_result, params)
best_result = {**balance_result, **constraint_results}
best_capacity = params.max_storage_capacity
elif best_result is None:
# 如果没有找到可行解(且没有容量上限限制),使用最大容量
balance_result = calculate_energy_balance( balance_result = calculate_energy_balance(
solar_output, wind_output, thermal_output, load_demand, params, upper_bound solar_output, wind_output, thermal_output, load_demand, params, upper_bound
) )
@@ -380,7 +403,10 @@ def optimize_storage_capacity(
'total_curtailment_wind_ratio': best_result['total_curtailment_wind_ratio'], 'total_curtailment_wind_ratio': best_result['total_curtailment_wind_ratio'],
'total_curtailment_solar_ratio': best_result['total_curtailment_solar_ratio'], 'total_curtailment_solar_ratio': best_result['total_curtailment_solar_ratio'],
'total_grid_feed_in_ratio': best_result['total_grid_feed_in_ratio'], 'total_grid_feed_in_ratio': best_result['total_grid_feed_in_ratio'],
'energy_balance_check': energy_balance_check 'energy_balance_check': energy_balance_check,
'capacity_limit_reached': params.max_storage_capacity is not None and best_capacity >= params.max_storage_capacity,
'theoretical_optimal_capacity': best_capacity if solution_found else None,
'max_storage_limit': params.max_storage_capacity
} }