Local Heating Networks with Waste Heat Utilization: Low or Medium Temperature Supply?

Kauko, Hanne; Rohde, Daniel; Hafner, Armin

doi:10.3390/en13040954

Cited by 15 publications

(11 citation statements)

References 25 publications

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“…Kauko et al said that since the energy supply failed to catch up with the increase of demand, two world oil crises broke out successively in the 1970s. e rise of oil prices led to global economic recession and social unrest [4]. Martinez Cesena et al said that in the middle of this century, with the exhaustion of fossil fuel resources, the surge of energy demand for economic development and the change of energy consumption structure will inevitably lead to a global energy crisis again and ultimately destroy the whole modern market economy [5].…”

Section: Literature Reviewmentioning

confidence: 99%

Modeling and Optimization of Ship Waste Heat Utilization System Based on Genetic Algorithm and Sensing

Lyu

2022

International Transactions on Electrical Energy Systems

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In order to solve the optimization problem of ship waste heat utilization system, the modeling and optimization method of ship waste heat utilization system based on genetic algorithm and sensing is proposed. The 6S50ME-C8.2 volume method model was established based on Matlab/Simulink simulation platform. According to the test data of the 6S50ME-C8.2 diesel engine, the simulation value is very close to the test value, which verifies the accuracy of the simulation model. The experimental results show that the thermal efficiency of high-power medium and low-speed two-stroke diesel engines is high, the exhaust temperature of the main engine is generally maintained at about 230°C, and the energy content of exhaust gas is relatively low. If no other measures are taken, the waste gas is directly channeled into the waste heat boiler, which cannot effectively recover the heat in the waste gas. Conclusion. The model can well simulate the actual working condition of the diesel engine, and the exhaust temperature has reached 298°C. The energy quality of waste gas at the inlet of the waste heat boiler is improved to meet the requirements of the waste heat recovery system.

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Section: Literature Reviewmentioning

confidence: 99%

Modeling and Optimization of Ship Waste Heat Utilization System Based on Genetic Algorithm and Sensing

Lyu

2022

International Transactions on Electrical Energy Systems

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“…Annual simulations of a small DHN with 25 HCs and decentralized prosumers were carried out using Modelica in order to evaluate different scenarios [14]. Waste heat integration was evaluated for a small DHN [15], as well as a medium-sized DHN with about 100 HCs [16]. The latter article demonstrates that dynamic simulations allow for identification of the share of waste heat that can be integrated into an existing DHN and to analyze hydraulic bottlenecks and temperature undersupply that arises from lower supply temperatures.…”

Section: Simulation Of District Heating Network: Tools and Applicationsmentioning

confidence: 99%

Heat Consumer Model for Robust and Fast Simulations of District Heating Networks Using Modelica

Zipplies,

Orozaliev,

Jordan

et al. 2024

Electronics

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Dynamic thermo-hydraulic simulations of district heating networks (DHN) are essential to investigate novel concepts for their sustainable design and operation. To develop solutions for a particular case study, numerous long-term simulations are required. Therefore, computational effort for simulation is critical. Heat consumers (HC) are numerous and determine the dynamics of mass flows and return temperatures in the DHN. Thus, the way in which HCs are modeled has significant impact on the computational effort and the results of the simulation. This article presents a novel Modelica-based model for HCs that builds on an existing simplified modeling approach (open-loop design). The calculation of mass flow and return temperature is improved in terms of robustness, plausible behavior and low computational effort. In particular, the model reacts to limited differential pressure and supply temperatures to ensure plausible behavior across all operating conditions, including undersupply situations. The model is successfully tested using an exemplary DHN. The analysis proves that the HC model itself requires little time to simulate. Nevertheless, it significantly influences the simulation time for the entire DHN, which varies by a factor of five for the investigated system depending on the HC model. Fast dynamics, including a bypass in the model and correction of deviations between set point and actual heat load increase the simulation time, so users should sensibly choose how to use these options. HC models triggering many state events result in high computational effort. Compared to other simple HC models, the proposed model produces more plausible results while maintaining at least equal simulation performance (for models without bypass) or even improving it (for models with bypass, CPU time is reduced by at least 35%).

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“…Waste heat can be recovered and stored (Figure 13) in a wide variety [143] of mediatypically water (e.g., as part of a district heating system) [144], sand [145], zeolite [146], phase change materials [147] (possibly mixed, e.g., with either regular [148] or volcanic [149] sand for improved heat capacity), graphite matrices filled with paraffin wax [150], or molten metals [151] or salts [152]. According to Tetteh et al [153], thermal energy storage can be more efficient and cheaper than the transformation of waste heat to electricity coupled with the utilization of Li-ion batteries.…”

Section: Thermal Energy Storagementioning

confidence: 99%

Industrial Waste Heat Utilization in the European Union—An Engineering-Centric Review

Turek,

Kilkovský,

Daxner

et al. 2024

Energies

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The efficient utilization of waste heat from industrial processes can provide a significant source of energy savings for production plants, as well as be a driver of sustainable operations and the abatement of emissions. Industrial waste heat usually is contained in liquid or gaseous outlet streams. Although the possible ways to utilize waste heat are discussed in a wide variety of papers, these either provide only a general overview of utilization options and opportunities or focus on a narrow range of industrial processes. The aim of the present paper is to discuss the practical aspects of waste heat utilization in the European Union so that the reader can gain perspective on (i) the thermal classification of waste heat, (ii) liquid and gaseous waste streams and their typical temperatures for industrial use cases, (iii) the technical, economic, physical, and environmental aspects barring full utilization of the available waste heat, (iv) waste heat sources in various industries, and (v) standardized equipment and technologies applicable to industrial waste heat utilization, including their advantages, disadvantages, and weak points.

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Local Heating Networks with Waste Heat Utilization: Low or Medium Temperature Supply?

Cited by 15 publications

References 25 publications

Modeling and Optimization of Ship Waste Heat Utilization System Based on Genetic Algorithm and Sensing

Modeling and Optimization of Ship Waste Heat Utilization System Based on Genetic Algorithm and Sensing

Heat Consumer Model for Robust and Fast Simulations of District Heating Networks Using Modelica

Industrial Waste Heat Utilization in the European Union—An Engineering-Centric Review

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