Energy balance in Basel: Difference between revisions

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Question

What are the amounts of energy produced, consumed, imported, and exported in Basel?

Answer

Energy balance in Basel Model run 17.5.2015 (based on model from June 2014)

+ Show code - Hide code


## This code was run from page [[Energy balance in Basel#Answer]]

library(OpasnetUtils)
library(ggplot2)

N <- 10 # Number of iterations

objects.latest("Op_en5141", code_name = "initiate")

balance <- Ovariable("balance", ddata = "Op_en6349.equations")

nonlinearity <- Ovariable("nonlinearity", ddata = "Op_en5141", subset = "No nonlinearities")

directinput <- Ovariable("directinput", ddata = "Op_en5141", subset = "No modelled upstream variables")

energy.balance <- EvalOutput(energy.balance) 

oprint(summary(energy.balance))

ggplot(energy.balance@output, aes(x = energybalanceVars, y = energy.balanceResult)) + 
	geom_boxplot() +
	facet_wrap(~Year, ncol = 1) +
	theme_grey(base_size = 24) + 
	theme(axis.text.x = element_text(angle = 90, hjust = 1, vjust= 0.2)) + 
	ggtitle("Energy balance in Basel")

ggplot(energy.balance@output, aes(x = Year, y = energy.balanceResult, fill = Year)) + 
	geom_boxplot() +
	facet_wrap(~energybalanceVars, scales = "free") +
	theme_grey(base_size = 24) + 
	theme(axis.text.x = element_blank(), axis.title.x = element_blank()) + 
	ggtitle("Energy balance variable-time comparison")

See Energy balance.

Rationale

There are several energy transformations that each describe a specific process of energy production or use. Per unit activity, there is a constant amount of different inputs and outputs into and from this process, respectively. These unit processes are used for Suzhou in such a way that one critical input or output from each relevant energy transformation is listed here; all other inputs and outputs logically follow from the nature of the transformation process.

Data

Equations(TJ)
Obs	Year	Equation
1	2010	H_other_in + H_oil_in + H_gas_in + H_electricity_in + H_environment_in = H_electricity_out + H_heat_out + H_loss
2	2010	H_other_in + H_gas_in + H_electricity_in + H_environment_in = 18.759336099585 * H_oil_in
3	2010	H_other_in + H_oil_in + H_electricity_in + H_environment_in = 1.00505263157895 * H_gas_in
4	2010	H_other_in + H_oil_in + H_gas_in + H_environment_in = 94.2399999999989 * H_electricity_in
5	2010	H_other_in + H_oil_in + H_gas_in + H_electricity_in = 92.3725490196079 * H_environment_in
6	2010	H_heat_out = 4.04461371055495 * H_loss
7	2010	H_electricity_out = 0.137105549510337 * H_loss
8	2010	Loss_electricity = 10.6690825426753 * H_electricity_out
9	2010	Loss_oil = 0.0445888958928925 * H_oil_in
10	2010	Loss_gas = 0.00967082506829371 * H_gas_in
11	2010	Loss_heat = 0.142050040355125 * H_heat_out
12	2010	Import_electricity + H_electricity_out + Recovery_electricity = Loss_electricity + Household_electricity + Industry_electricity + Commerce_electricity + Transport_electricity
13	2010	Recovery_heat + H_heat_out = Loss_heat + Household_heat + Industry_heat + Commerce_heat
14	2010	Household_electricity = 1344.1095890411
15	2010	Industry_electricity = 1341.96428571429
16	2010	Commerce_electricity = 2940.97142857143
17	2010	Transport_electricity = 260
18	2010	Household_heat = 932
19	2010	Industry_heat = 333
20	2010	Commerce_heat = 1633
21	2010	H_heat_out = 3175.00900202918
22	2010	Recovery_electricity = 50.965586548236
23	2020	H_other_in + H_oil_in + H_gas_in + H_electricity_in + H_environment_in = H_electricity_out + H_heat_out + H_loss
24	2020	H_other_in + H_gas_in + H_electricity_in + H_environment_in = 18.7593360995851 * H_oil_in
25	2020	H_other_in + H_oil_in + H_electricity_in + H_environment_in = 1.00505263157895 * H_gas_in
26	2020	H_other_in + H_oil_in + H_gas_in + H_environment_in = 94.24 * H_electricity_in
27	2020	H_other_in + H_oil_in + H_gas_in + H_electricity_in = 92.3725490196077 * H_environment_in
28	2020	H_heat_out = 4.04461371055495 * H_loss
29	2020	H_electricity_out = 0.137105549510337 * H_loss
30	2020	Loss_electricity = 11.5997703806749 * H_electricity_out
31	2020	Loss_oil = 0.0346903754680064 * H_oil_in
32	2020	Loss_gas = 0.0052086734616975 * H_gas_in
33	2020	Loss_heat = 0.142050040355125 * H_heat_out
34	2020	Import_electricity + H_electricity_out + Recovery_electricity = Loss_electricity + Household_electricity + Industry_electricity + Commerce_electricity + Transport_electricity
35	2020	Recovery_heat + H_heat_out = Loss_heat + Household_heat + Industry_heat + Commerce_heat
36	2020	Household_electricity = 2037.58613013699
37	2020	Industry_electricity = 2515.1765625
38	2020	Commerce_electricity = 3505.32
39	2020	Transport_electricity = 286.65
40	2020	Household_heat = 1541.295
41	2020	Industry_heat = 367.1325
42	2020	Commerce_heat = 1800.3825
43	2020	H_heat_out = 4139.40285868165
44	2020	Recovery_electricity = 72.24238550163

There are no nonlinearities.

Dependencies

Energy balance

**Urgenche research project 2011 - 2014: city-level climate change mitigation**
Urgenche pages Urgenche main page · Category:Urgenche · Urgenche project page (password-protected) Relevant data Building stock data in Urgenche‎ · Building regulations in Finland · Concentration-response to PM2.5 · Emission factors for burning processes · ERF of indoor dampness on respiratory health effects · ERF of several environmental pollutions · General criteria for land use · Indoor environment quality (IEQ) factors · Intake fractions of PM · Land use in Urgenche · Land use and boundary in Urgenche · Energy use of buildings Relevant methods Building model · Energy balance · Health impact assessment · Opasnet map · Help:Drawing graphs · OpasnetUtils‎ · Recommended R functions‎ · Using summary tables‎ City Kuopio Climate change policies and health in Kuopio (assessment) · Climate change policies in Kuopio (plausible city-level climate policies) · Health impacts of energy consumption in Kuopio · Building stock in Kuopio · Cost curves for energy (prioritization of options) · Energy balance in Kuopio (energy data) · Energy consumption and GHG emissions in Kuopio by sector · Energy consumption classes (categorisation) · Energy consumption of heating of buildings in Kuopio · Energy transformations (energy production and use processes) · Fuels used by Haapaniemi energy plant · Greenhouse gas emissions in Kuopio · Haapaniemi energy plant in Kuopio · Land use in Kuopio · Building data availability in Kuopio · Password-protected pages: File:Heat use in Kuopio.csv · Kuopio housing City Basel Buildings in Basel (password-protected) Energy balances Energy balance in Basel · Energy balance in Kuopio · Energy balance in Stuttgart · Energy balance in Suzhou

Keywords

References

Related files

@@ Line 10: / Line 10: @@
 == Answer ==
-<rcode name="answer" graphics="1" live="1">
+* {{#l:Energy balance in Basel.pdf}} [http://en.opasnet.org/en-opwiki/index.php?title=Special:RTools&id=fdOaiitVDTPO1tjn Model run 17.5.2015] (based on model from June 2014)
+<rcode name="answer" graphics=1>
+## This code was run from page [[Energy balance in Basel#Answer]]
 library(OpasnetUtils)
 library(ggplot2)
@@ Line 26: / Line 31: @@
 energy.balance <- EvalOutput(energy.balance)
-#oprint(summary(energy.balance))
+oprint(summary(energy.balance))
 ggplot(energy.balance@output, aes(x = energybalanceVars, y = energy.balanceResult)) +
@@ Line 41: / Line 46: @@
 	theme(axis.text.x = element_blank(), axis.title.x = element_blank()) +
 	ggtitle("Energy balance variable-time comparison")
-# objects.store(energy.balance)
 </rcode>