first step towards agriculture, forestry and fishing

config.default.yaml

@@ -173,6 +173,9 @@ sector:
     2050: 0.85
   transport_fuel_cell_efficiency: 0.5
   transport_internal_combustion_efficiency: 0.3
+  agriculture_machinery_electric_share: 0.12  # approximately as today
+  agriculture_machinery_fuel_efficiency: 0.7 # for conversion of fuel oil to use
+  agriculture_machinery_electric_efficiency: 0.3 # for conversion of electricity to use
   shipping_average_efficiency: 0.4 #For conversion of fuel oil to propulsion in 2011
   time_dep_hp_cop: true #time dependent heat pump coefficient of performance
   heat_pump_sink_T: 55. # Celsius, based on DTU / large area radiators; used in build_cop_profiles.py

scripts/build_energy_totals.py

@@ -117,6 +117,7 @@ to_ipcc = {
     "total energy": "1 - Energy",
     "industrial processes": "2 - Industrial Processes and Product Use",
     "agriculture": "3 - Agriculture",
+    "agriculture, forestry and fishing": '1.A.4.c - Agriculture/Forestry/Fishing',
     "LULUCF": "4 - Land Use, Land-Use Change and Forestry",
     "waste management": "5 - Waste management",
     "other": "6 - Other Sector",
@@ -182,7 +183,7 @@ def idees_per_country(ct, year):
 
     ct_idees = idees_rename.get(ct, ct)
     fn_residential = f"{base_dir}/JRC-IDEES-2015_Residential_{ct_idees}.xlsx"
-    fn_services = f"{base_dir}/JRC-IDEES-2015_Tertiary_{ct_idees}.xlsx"
+    fn_tertiary = f"{base_dir}/JRC-IDEES-2015_Tertiary_{ct_idees}.xlsx"
     fn_transport = f"{base_dir}/JRC-IDEES-2015_Transport_{ct_idees}.xlsx"
 
     # residential
@@ -214,7 +215,7 @@ def idees_per_country(ct, year):
 
     # services
 
-    df = pd.read_excel(fn_services, "SER_hh_fec", index_col=0)[year]
+    df = pd.read_excel(fn_tertiary, "SER_hh_fec", index_col=0)[year]
 
     ct_totals["total services space"] = df["Space heating"]
 
@@ -231,7 +232,7 @@ def idees_per_country(ct, year):
     assert df.index[31] == "Electricity"
     ct_totals["electricity services cooking"] = df[31]
 
-    df = pd.read_excel(fn_services, "SER_summary", index_col=0)[year]
+    df = pd.read_excel(fn_tertiary, "SER_summary", index_col=0)[year]
 
     row = "Energy consumption by fuel - Eurostat structure (ktoe)"
     ct_totals["total services"] = df[row]
@@ -239,6 +240,34 @@ def idees_per_country(ct, year):
     assert df.index[50] == "Electricity"
     ct_totals["electricity services"] = df[50]
 
+    # agriculture, forestry and fishing
+
+    start = "Detailed split of energy consumption (ktoe)"
+    end = "Market shares of energy uses (%)"
+    
+    df = pd.read_excel(fn_tertiary, "AGR_fec", index_col=0).loc[start:end, year]
+
+    rows = [
+        "Lighting",
+        "Ventilation",
+        "Specific electricity uses",
+        "Pumping devices (electric)"
+    ]
+    ct_totals["total agriculture electricity"] = df[rows].sum()
+
+    rows = ["Specific heat uses", "Low enthalpy heat"]
+    ct_totals["total agriculture heat"] = df[rows].sum()
+
+    rows = [
+        "Motor drives",
+        "Farming machine drives (diesel oil incl. biofuels)",
+        "Pumping devices (diesel oil incl. biofuels)",
+    ]
+    ct_totals["total agriculture machinery"] = df[rows].sum()
+
+    row = ["Agriculture, forestry and fishing"]
+    ct_totals["total agriculture"] = df[row]
+
     # transport
 
     df = pd.read_excel(fn_transport, "TrRoad_ene", index_col=0)[year]
@@ -540,10 +569,13 @@ def build_eea_co2(year=1990):
         "international aviation",
         "domestic navigation",
         "international navigation",
+        "agriculture, forstry and fishing"
     ]
     emissions["industrial non-elec"] = emissions["total energy"] - emissions[to_subtract].sum(axis=1)
 
-    to_drop = ["total energy", "total wL", "total woL"]
+    emissions["agriculture"] += emissions["agriculture, forestry and fishing"]
+
+    to_drop = ["total energy", "total wL", "total woL", "agriculture, forestry and fishing"]
     emissions.drop(columns=to_drop, inplace=True)
 
     # convert from Gg to Mt
@@ -588,7 +620,7 @@ def build_co2_totals(countries, eea_co2, eurostat_co2):
             # does not include industrial process emissions or fuel processing/refining
             "industrial non-elec": (ct, "+", "Industry"),
             # does not include non-energy emissions
-            "agriculture": (ct, "+", "+", "Agriculture / Forestry"),
+            "agriculture": (eurostat_co2.index.get_level_values(0) == 'NL') & eurostat_co2.index.isin(["Agriculture / Forestry", "Fishing"], level=3),
         }
 
         for i, mi in mappings.items():

scripts/prepare_sector_network.py

@@ -42,6 +42,10 @@ def emission_sectors_from_opts(opts):
             "domestic navigation",
             "international navigation"
         ]
+    if "A" in opts:
+        sectors += [
+            "agriulture"
+        ]
 
     return sectors
 
@@ -728,8 +732,9 @@ def insert_electricity_distribution_grid(n, costs):
         capital_cost=costs.at['electricity distribution grid', 'fixed'] * cost_factor
     )
 
-    # this catches regular electricity load and "industry electricity"
-    loads = n.loads.index[n.loads.carrier.str.contains("electricity")]
+    # this catches regular electricity load and "industry electricity" and
+    # "agriculture machinery electric" and "agriculture electricity"
+    loads = n.loads.index[n.loads.carrier.str.contains("electric")]
     n.loads.loc[loads, "bus"] += " low voltage"
 
     bevs = n.links.index[n.links.carrier == "BEV charger"]
@@ -1163,8 +1168,8 @@ def add_land_transport(n, costs):
 
         co2 = ice_share / ice_efficiency * transport[nodes].sum().sum() / 8760 * costs.at["oil", 'CO2 intensity']
 
-        n.madd("Load",
-            ["land transport oil emissions"],
+        n.add("Load",
+            "land transport oil emissions",
             bus="co2 atmosphere",
             carrier="land transport oil emissions",
             p_set=-co2
@@ -1901,6 +1906,69 @@ def add_waste_heat(n):
             n.links.loc[urban_central + " H2 Fuel Cell", "efficiency2"] = 0.95 - n.links.loc[urban_central + " H2 Fuel Cell", "efficiency"]
 
 
+def add_agriculture(n, costs):
+
+    nodes = pop_layout.index
+
+    # electricity
+
+    n.madd("Load",
+        nodes,
+        suffix=" agriculture electricity",
+        bus=nodes,
+        carrier='agriculture electricity',
+        p_set=nodal_energy_totals.loc[nodes, "total agriculture electricity"] / 8760
+    )
+
+    # heat
+
+    n.madd("Load",
+        nodes,
+        suffix=" agriculture heat",
+        bus=nodes + " services rural heat",
+        carrier="agriculture heat",
+        p_set=nodal_energy_totals.loc[nodes, "total agriculture heat"] / 8760
+    )
+
+    # machinery
+
+    electric_share = get(options["agriculture_machinery_electric_share"], investment_year)
+    assert electric_share <= 1.
+    ice_share = 1 - electric_share
+
+    machinery_nodal_energy = nodal_energy_totals.loc[nodes, "total agriculture machinery"]
+
+    if electric_share > 0:
+
+        efficiency_gain = options["agriculture_machinery_fuel_efficiency"] / options["agriculture_machinery_electric_efficiency"]
+
+        n.add("Load",
+            nodes,
+            suffix=" agriculture machinery electric",
+            bus=nodes,
+            carrier="agriculture machinery electric",
+            p_set=electric_share * efficiency_gain * machinery_nodal_energy / 8760,
+        )
+
+    if ice_share > 0:
+
+        n.add("Load",
+            "agriculture machinery oil",
+            bus="EU oil",
+            carrier="agriculture machinery oil",
+            p_set=ice_share * machinery_nodal_energy / 8760
+        )
+
+        co2 = ice_share * machinery_nodal_energy / 8760 * costs.at["oil", 'CO2 intensity']
+
+        n.add("Load",
+            "agriculture machinery oil emissions",
+            bus="co2 atmosphere",
+            carrier="agriculture machinery oil emissions",
+            p_set=-co2
+        )
+
+
 def decentral(n):
     """Removes the electricity transmission system."""    
     n.lines.drop(n.lines.index, inplace=True)
@@ -2027,6 +2095,9 @@ if __name__ == "__main__":
     if "I" in opts and "H" in opts:
         add_waste_heat(n)
 
+    if "A" in opts:  # requires H and I
+        add_agriculture(n, costs)
+
     if options['dac']:
         add_dac(n, costs)