Möjligheter till ökad driftsäkerhet och kostnadseffektivitet i fjärrvärmenät : En simulerings- och optimeringsstudie på Kalmar Energi

Sammanfattning: Since district heating is the most common way of space heatingin Sweden, continual improvements of theefficiency of production and distribution of district heating is crucial. The purposeof this report is therefore to, using Kalmar Energi as an example, study how the production and distribution of district heating is affected by introducing a bypass pipeat a critical point in the network, and to investigate howcost efficiency might be achieved. To fulfill this task, the network simulation software NetSim and the cost optimizing software MODEST was used. Most ofthe heat in the district heating network in Kalmar comesfrom the bio-fueled combined heat and power plant Moskogen and the top load production plantDraken covers the top load when the heat from Moskogen is not enoughto fulfill the heating demand. However, the studied scenario does not represent normal operationbut a temporary solution for when Draken and its circulation pumps for some reason cannot be used.In that scenario, all heat in the city mustbe delivered using the bypass pipeor usingthe two smaller reserve production plantsLindsdal and Dvärgen. The simulations performed in NetSim consist of three primary cases; one reference modelwhich represents the currentsituation, one model with only Moskogenand the bypass and one model with Moskogen, bypass, Lindsdal and Dvärgen. To study the possibility for improvements of the network further simulations were performed with measures like new circulation pumps, upgradeto bigger pipes and addition of new pipes. The optimization in MODEST also consist of three cases; normaloperation, operation using the bypassand possible benefits ofusing RME instead of oil in reserve plants. The simulations in NetSimshows that the bypass pipe enables fulfillment of the heating demand of Kalmar without the use ofDraken or otherreserveproduction plantsdown to an outside temperature around 1°C.If the reserve units in the periphery parts of the city are used, the bypass of Draken enables fulfillmentof the heating demand until an outside temperature of approximately -3°C. The limiting factorsare mainlycirculationpump capacity and the differential pressure. If a higher supply temperature than normal is usedor newcirculationpumps and bigger pipes are introduced, a working network can be achieved for loweroutsidetemperatures. However, a highersupply temperature means higherheatlosses and no additional electricity production and a new pumping station just to handle a worst-case scenario is most likely not economically feasible. New pipes connecting areas with high and low differential pressures was also found to improve the system, but might not be profitable in the short term. If the city is expected to expand in the certain areas that the new pipesweretested, the new pipes might become amore feasiblemeasurein the future.The optimizing in MODEST shows that from a cost minimizing perspective, it is optimal to use the biomass-fueled combined heat and power plant Moskogenas much as possibleand to cover the remaining heat demand using wood powderboilersand if necessary, oilboilers.It is also evident thatregardless ofthe bypass beingused or not, it is always more profitable to lower the electricity production of Moskogen in favor of heat production during periods when the electricity price is low or whentheuse of oilboilerswould otherwise be needed.This measure also lowers the amount ofcarbon dioxideemissionsfor the systemwith up to 250 tons/yearsince oil use can be exchanged for biomass use.An alternative way of eliminating carbon dioxide emissionsis to replace the oilfuelwith a renewable fuel like RME. However, this would be associated with higher costs for Kalmar Energi, since RME is currently more expensive per MWh than the oil that is currentlyused.