test_variable_chp - Code Metrics - oemof/oemof-solph - Measure and Improve Code Quality continuously with Scrutinizer

test_variable_chp A
last analyzed 2025-11-04 19:41 UTC

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Complexity

Total Complexity

Size/Duplication

Total Lines	207
Duplicated Lines	0 %

Importance

Changes

Metric	Value
wmc	3
eloc	112
dl	0
loc	207
rs	10
c	0
b	0
f	0

1 Function

Rating	Name	Duplication	Size	Complexity
B	test_variable_chp()	0	182	3

# -*- coding: utf-8 -*-

"""
This test contains a ExtractionTurbineCHP class.


This file is part of project oemof (github.com/oemof/oemof). It's copyrighted
by the contributors recorded in the version control history of the file,
available from its original location
oemof/tests/test_scripts/test_solph/test_variable_chp/test_variable_chp.py

SPDX-License-Identifier: MIT
"""

import logging
import os

import pandas as pd
import pytest

from oemof import solph
from oemof.solph import views


def test_variable_chp(filename="variable_chp.csv", solver="cbc"):
    logging.info("Initialize the energy system")

    # create time index for 192 hours in May.
    date_time_index = pd.date_range("5/5/2012", periods=5, freq="h")
    energysystem = solph.EnergySystem(
        timeindex=date_time_index, infer_last_interval=True
    )

    # Read data file with heat and electrical demand (192 hours)
    full_filename = os.path.join(os.path.dirname(__file__), filename)
    data = pd.read_csv(full_filename, sep=",")

    ##########################################################################
    # Create oemof.solph objects
    ##########################################################################

    logging.info("Create oemof.solph objects")

    # create natural gas bus
    bgas = solph.buses.Bus(label=("natural", "gas"))
    energysystem.add(bgas)

    # create commodity object for gas resource
    energysystem.add(
        solph.components.Source(
            label=("commodity", "gas"),
            outputs={bgas: solph.flows.Flow(variable_costs=50)},
        )
    )

    # create two electricity buses and two heat buses
    bel = solph.buses.Bus(label=("electricity", 1))
    bel2 = solph.buses.Bus(label=("electricity", 2))
    bth = solph.buses.Bus(label=("heat", 1))
    bth2 = solph.buses.Bus(label=("heat", 2))
    energysystem.add(bel, bel2, bth, bth2)

    # create excess components for the elec/heat bus to allow overproduction
    energysystem.add(
        solph.components.Sink(
            label=("excess", "bth_2"), inputs={bth2: solph.flows.Flow()}
        )
    )
    energysystem.add(
        solph.components.Sink(
            label=("excess", "bth_1"), inputs={bth: solph.flows.Flow()}
        )
    )
    energysystem.add(
        solph.components.Sink(
            label=("excess", "bel_2"), inputs={bel2: solph.flows.Flow()}
        )
    )
    energysystem.add(
        solph.components.Sink(
            label=("excess", "bel_1"), inputs={bel: solph.flows.Flow()}
        )
    )

    # create simple sink object for electrical demand for each electrical bus
    energysystem.add(
        solph.components.Sink(
            label=("demand", "elec1"),
            inputs={
                bel: solph.flows.Flow(
                    fix=data["demand_el"], nominal_capacity=1
                )
            },
        )
    )
    energysystem.add(
        solph.components.Sink(
            label=("demand", "elec2"),
            inputs={
                bel2: solph.flows.Flow(
                    fix=data["demand_el"], nominal_capacity=1
                )
            },
        )
    )

    # create simple sink object for heat demand for each thermal bus
    energysystem.add(
        solph.components.Sink(
            label=("demand", "therm1"),
            inputs={
                bth: solph.flows.Flow(
                    fix=data["demand_th"], nominal_capacity=741000
                )
            },
        )
    )
    energysystem.add(
        solph.components.Sink(
            label=("demand", "therm2"),
            inputs={
                bth2: solph.flows.Flow(
                    fix=data["demand_th"], nominal_capacity=741000
                )
            },
        )
    )

    # create a fixed converter to distribute to the heat_2 and elec_2 buses
    energysystem.add(
        solph.components.Converter(
            label=("fixed_chp", "gas"),
            inputs={bgas: solph.flows.Flow(nominal_capacity=1e11)},
            outputs={bel2: solph.flows.Flow(), bth2: solph.flows.Flow()},
            conversion_factors={bel2: 0.3, bth2: 0.5},
        )
    )

    # create a fixed converter to distribute to the heat and elec buses
    energysystem.add(
        solph.components.ExtractionTurbineCHP(
            label=("variable_chp", "gas"),
            inputs={bgas: solph.flows.Flow(nominal_capacity=1e11)},
            outputs={bel: solph.flows.Flow(), bth: solph.flows.Flow()},
            conversion_factors={bel: 0.3, bth: 0.5},
            conversion_factor_full_condensation={bel: 0.5},
        )
    )

    ##########################################################################
    # Optimise the energy system and plot the results
    ##########################################################################

    logging.info("Optimise the energy system")

    om = solph.Model(energysystem)

    logging.info("Solve the optimization problem")
    om.solve(solver=solver)

    optimisation_results = solph.processing.results(om)
    parameter = solph.processing.parameter_as_dict(energysystem)

    myresults = views.node(optimisation_results, "('natural', 'gas')")
    sumresults = myresults["sequences"].sum(axis=0)
    maxresults = myresults["sequences"].max(axis=0)

    variable_chp_dict_sum = {
        (("('natural', 'gas')", "('variable_chp', 'gas')"), "flow"): 2823024,
        (("('natural', 'gas')", "('fixed_chp', 'gas')"), "flow"): 3710208,
        (("('commodity', 'gas')", "('natural', 'gas')"), "flow"): 6533232,
    }

    variable_chp_dict_max = {
        (("('natural', 'gas')", "('variable_chp', 'gas')"), "flow"): 630332,
        (("('natural', 'gas')", "('fixed_chp', 'gas')"), "flow"): 785934,
        (("('commodity', 'gas')", "('natural', 'gas')"), "flow"): 1416266,
    }

    for key in variable_chp_dict_max.keys():
        logging.debug("Test the maximum value of {0}".format(key))
        assert maxresults[[key]].iloc[0] == pytest.approx(
            variable_chp_dict_max[key]
        )

    for key in variable_chp_dict_sum.keys():
        logging.debug("Test the summed up value of {0}".format(key))
        assert sumresults[[key]].iloc[0] == pytest.approx(
            variable_chp_dict_sum[key]
        )

    assert (
        parameter[(energysystem.groups["('fixed_chp', 'gas')"], None)][
            "scalars"
        ]["label"]
        == "('fixed_chp', 'gas')"
    )
    assert (
        parameter[(energysystem.groups["('fixed_chp', 'gas')"], None)][
            "scalars"
        ]["conversion_factors_('electricity', 2)"]
    ) == pytest.approx(0.3)

    # objective function
    assert solph.processing.meta_results(om)["objective"] == pytest.approx(
        326661590, abs=0.5
    )


1			# -- coding: utf-8 --
2
3			"""
4			This test contains a ExtractionTurbineCHP class.
5
6
7			This file is part of project oemof (github.com/oemof/oemof). It's copyrighted
8			by the contributors recorded in the version control history of the file,
9			available from its original location
10			oemof/tests/test_scripts/test_solph/test_variable_chp/test_variable_chp.py
11
12			SPDX-License-Identifier: MIT
13			"""
14
15			import logging
16			import os
17
18			import pandas as pd
19			import pytest
20
21			from oemof import solph
22			from oemof.solph import views
23
24
25			def test_variable_chp(filename="variable_chp.csv", solver="cbc"):
26			logging.info("Initialize the energy system")
27
28			# create time index for 192 hours in May.
29			date_time_index = pd.date_range("5/5/2012", periods=5, freq="h")
30			energysystem = solph.EnergySystem(
31			timeindex=date_time_index, infer_last_interval=True
32			)
33
34			# Read data file with heat and electrical demand (192 hours)
35			full_filename = os.path.join(os.path.dirname(__file__), filename)
36			data = pd.read_csv(full_filename, sep=",")
37
38			##########################################################################
39			# Create oemof.solph objects
40			##########################################################################
41
42			logging.info("Create oemof.solph objects")
43
44			# create natural gas bus
45			bgas = solph.buses.Bus(label=("natural", "gas"))
46			energysystem.add(bgas)
47
48			# create commodity object for gas resource
49			energysystem.add(
50			solph.components.Source(
51			label=("commodity", "gas"),
52			outputs={bgas: solph.flows.Flow(variable_costs=50)},
53			)
54			)
55
56			# create two electricity buses and two heat buses
57			bel = solph.buses.Bus(label=("electricity", 1))
58			bel2 = solph.buses.Bus(label=("electricity", 2))
59			bth = solph.buses.Bus(label=("heat", 1))
60			bth2 = solph.buses.Bus(label=("heat", 2))
61			energysystem.add(bel, bel2, bth, bth2)
62
63			# create excess components for the elec/heat bus to allow overproduction
64			energysystem.add(
65			solph.components.Sink(
66			label=("excess", "bth_2"), inputs={bth2: solph.flows.Flow()}
67			)
68			)
69			energysystem.add(
70			solph.components.Sink(
71			label=("excess", "bth_1"), inputs={bth: solph.flows.Flow()}
72			)
73			)
74			energysystem.add(
75			solph.components.Sink(
76			label=("excess", "bel_2"), inputs={bel2: solph.flows.Flow()}
77			)
78			)
79			energysystem.add(
80			solph.components.Sink(
81			label=("excess", "bel_1"), inputs={bel: solph.flows.Flow()}
82			)
83			)
84
85			# create simple sink object for electrical demand for each electrical bus
86			energysystem.add(
87			solph.components.Sink(
88			label=("demand", "elec1"),
89			inputs={
90			bel: solph.flows.Flow(
91			fix=data["demand_el"], nominal_capacity=1
92			)
93			},
94			)
95			)
96			energysystem.add(
97			solph.components.Sink(
98			label=("demand", "elec2"),
99			inputs={
100			bel2: solph.flows.Flow(
101			fix=data["demand_el"], nominal_capacity=1
102			)
103			},
104			)
105			)
106
107			# create simple sink object for heat demand for each thermal bus
108			energysystem.add(
109			solph.components.Sink(
110			label=("demand", "therm1"),
111			inputs={
112			bth: solph.flows.Flow(
113			fix=data["demand_th"], nominal_capacity=741000
114			)
115			},
116			)
117			)
118			energysystem.add(
119			solph.components.Sink(
120			label=("demand", "therm2"),
121			inputs={
122			bth2: solph.flows.Flow(
123			fix=data["demand_th"], nominal_capacity=741000
124			)
125			},
126			)
127			)
128
129			# create a fixed converter to distribute to the heat_2 and elec_2 buses
130			energysystem.add(
131			solph.components.Converter(
132			label=("fixed_chp", "gas"),
133			inputs={bgas: solph.flows.Flow(nominal_capacity=1e11)},
134			outputs={bel2: solph.flows.Flow(), bth2: solph.flows.Flow()},
135			conversion_factors={bel2: 0.3, bth2: 0.5},
136			)
137			)
138
139			# create a fixed converter to distribute to the heat and elec buses
140			energysystem.add(
141			solph.components.ExtractionTurbineCHP(
142			label=("variable_chp", "gas"),
143			inputs={bgas: solph.flows.Flow(nominal_capacity=1e11)},
144			outputs={bel: solph.flows.Flow(), bth: solph.flows.Flow()},
145			conversion_factors={bel: 0.3, bth: 0.5},
146			conversion_factor_full_condensation={bel: 0.5},
147			)
148			)
149
150			##########################################################################
151			# Optimise the energy system and plot the results
152			##########################################################################
153
154			logging.info("Optimise the energy system")
155
156			om = solph.Model(energysystem)
157
158			logging.info("Solve the optimization problem")
159			om.solve(solver=solver)
160
161			optimisation_results = solph.processing.results(om)
162			parameter = solph.processing.parameter_as_dict(energysystem)
163
164			myresults = views.node(optimisation_results, "('natural', 'gas')")
165			sumresults = myresults["sequences"].sum(axis=0)
166			maxresults = myresults["sequences"].max(axis=0)
167
168			variable_chp_dict_sum = {
169			(("('natural', 'gas')", "('variable_chp', 'gas')"), "flow"): 2823024,
170			(("('natural', 'gas')", "('fixed_chp', 'gas')"), "flow"): 3710208,
171			(("('commodity', 'gas')", "('natural', 'gas')"), "flow"): 6533232,
172			}
173
174			variable_chp_dict_max = {
175			(("('natural', 'gas')", "('variable_chp', 'gas')"), "flow"): 630332,
176			(("('natural', 'gas')", "('fixed_chp', 'gas')"), "flow"): 785934,
177			(("('commodity', 'gas')", "('natural', 'gas')"), "flow"): 1416266,
178			}
179
180			for key in variable_chp_dict_max.keys():
181			logging.debug("Test the maximum value of {0}".format(key))
182			assert maxresults[[key]].iloc[0] == pytest.approx(
183			variable_chp_dict_max[key]
184			)
185
186			for key in variable_chp_dict_sum.keys():
187			logging.debug("Test the summed up value of {0}".format(key))
188			assert sumresults[[key]].iloc[0] == pytest.approx(
189			variable_chp_dict_sum[key]
190			)
191
192			assert (
193			parameter[(energysystem.groups["('fixed_chp', 'gas')"], None)][
194			"scalars"
195			]["label"]
196			== "('fixed_chp', 'gas')"
197			)
198			assert (
199			parameter[(energysystem.groups["('fixed_chp', 'gas')"], None)][
200			"scalars"
201			]["conversion_factors_('electricity', 2)"]
202			) == pytest.approx(0.3)
203
204			# objective function
205			assert solph.processing.meta_results(om)["objective"] == pytest.approx(
206			326661590, abs=0.5
207			)
208

oemof / oemof-solph

test_variable_chp A last analyzed 2025-11-04 19:41 UTC

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test_variable_chp A
last analyzed 2025-11-04 19:41 UTC