Modelling and simulation of building components : thermal interaction between multilayer wall and hydronic radiator

Brembilla, Christian

January 2016

Background and Scope: The scope of this thesis is to investigate the thermal behaviour of building components as hydronic radiator and multilayer walls subjected to dynamic conditions. The modelling and simulation of these building components provide information on how these components thermally interact among each other. The thermal interaction is fundamental to know how the energy is used in buildings. In particular, the thermal energy used in rooms can be expressed as the efficiencies for emission in a space heating system. This thesis analyzes the efficiencies for emission of a space heating system equipped with hydronic radiator for Swedish buildings by providing a comprehensive and detailed approach on this topic. Methodology: The methods used in this thesis are: experiment, modelling of multilayer wall and hydronic radiator, the dynamic simulation of the building and the efficiencies for emission of a space heating system. Here, the experiment, known as step response test, shows the heating up process of a hydronic radiator. The observation of the qualitative measurements suggests the most suitable technique of modelling the radiator known as transient modelling with multiple storage elements. The multilayer wall has been discretized both in space and time variable with a Finite Difference Method. Dynamic simulation of the building provides the efficiencies for emission of a space heating system. Findings: The experimental results show how the radiator performs the charging phase. The performance of the transient model is compared with lumped steady state models in terms of temperature of exhaust flow and total heat emitted. Results of the dynamic simulation show how buildings located in a Northern climate use the energy in a better way than Southern climates in Sweden. Heavy active thermal mass provides higher efficiencies for emission than light thermal mass. Radiators with connection pipes located on the same side react faster at the thermodynamic changing of the mass flow rate by providing higher efficiencies for emission than radiators with connection pipes located on the opposite side. Conclusion and Outlook: This thesis increases the knowledge about the modelling and simulation of hydronic radiators and multilayer walls. More research is needed on this topic to encompass modelling details of building components often ignored. The modelling and simulation of building components are the key to understand how building components thermally interact with each other. The thermal interaction among building components is a fundamental parameter for the assessment of efficiencies of emission of the space heating system. In the near future, the concept of efficiencies of emission can be implemented in National Building Code, therefore, this study provides guidelines on how to assess these efficiencies. / <p>Advisors: Ronny Östin and Mohsen Soleimanni Mohseni, Department of Applied Physics and Electronics, Umeå University</p>

Hydronic radiator

multilayer wall

efficiencies of emission

Building Technologies

Husbyggnad

Simulation of thermal plant optimization and hydraulic aspects of thermal distribution loops for large campuses

Chen, Qiang

29 August 2005

Following an introduction, the author describes Texas A&M University and its utilities system. After that, the author presents how to construct simulation models for chilled water and heating hot water distribution systems. The simulation model was used in a $2.3 million Ross Street chilled water pipe replacement project at Texas A&M University. A second project conducted at the University of Texas at San Antonio was used as an example to demonstrate how to identify and design an optimal distribution system by using a simulation model. The author found that the minor losses of these closed loop thermal distribution systems are significantly higher than potable water distribution systems. In the second part of the report, the author presents the latest development of software called the Plant Optimization Program, which can simulate cogeneration plant operation, estimate its operation cost and provide optimized operation suggestions. The author also developed detailed simulation models for a gas turbine and heat recovery steam generator and identified significant potential savings. Finally, the author also used a steam turbine as an example to present a multi-regression method on constructing simulation models by using basic statistics and optimization algorithms. This report presents a survey of the author??s working experience at the Energy Systems Laboratory (ESL) at Texas A&M University during the period of January 2002 through March 2004. The purpose of the above work was to allow the author to become familiar with the practice of engineering. The result is that the author knows how to complete a project from start to finish and understands how both technical and nontechnical aspects of a project need to be considered in order to ensure a quality deliverable and bring a project to successful completion. This report concludes that the objectives of the internship were successfully accomplished and that the requirements for the degree of Degree of Engineering have been satisfied.

cogeneration plant simulation

hydronic distribution modeling

hydraulics

steam power plant

waste heat boilers

Simulation of thermal plant optimization and hydraulic aspects of thermal distribution loops for large campuses

Chen, Qiang

29 August 2005

Following an introduction, the author describes Texas A&M University and its utilities system. After that, the author presents how to construct simulation models for chilled water and heating hot water distribution systems. The simulation model was used in a $2.3 million Ross Street chilled water pipe replacement project at Texas A&M University. A second project conducted at the University of Texas at San Antonio was used as an example to demonstrate how to identify and design an optimal distribution system by using a simulation model. The author found that the minor losses of these closed loop thermal distribution systems are significantly higher than potable water distribution systems. In the second part of the report, the author presents the latest development of software called the Plant Optimization Program, which can simulate cogeneration plant operation, estimate its operation cost and provide optimized operation suggestions. The author also developed detailed simulation models for a gas turbine and heat recovery steam generator and identified significant potential savings. Finally, the author also used a steam turbine as an example to present a multi-regression method on constructing simulation models by using basic statistics and optimization algorithms. This report presents a survey of the author??s working experience at the Energy Systems Laboratory (ESL) at Texas A&M University during the period of January 2002 through March 2004. The purpose of the above work was to allow the author to become familiar with the practice of engineering. The result is that the author knows how to complete a project from start to finish and understands how both technical and nontechnical aspects of a project need to be considered in order to ensure a quality deliverable and bring a project to successful completion. This report concludes that the objectives of the internship were successfully accomplished and that the requirements for the degree of Degree of Engineering have been satisfied.

cogeneration plant simulation

hydronic distribution modeling

hydraulics

steam power plant

waste heat boilers

Modelling the dynamics of domestic low-temperature heat pump heating systems for improved performance and thermal comfort : a systems approach

Sakellari, Dimitra

January 2005

<p>The present environmental concerns and the rising human requirement for solutions with better comfort and lower costs have resulted in an increased awareness for the energy use in the built environment. Technical advances in building structural systems and materials, heating and other comfort-providing systems and controlling strategies all lead to the integration of building technology with the function of buildings and the aesthetics. Therefore, in the process of improving the performance of energy systems and increasing the energy efficiency, integrated system approaches are of high importance. Performing the necessary energy analysis before any construction-installation occurs can help designers and decision makers reach guided solutions. Hence, a broad range of calculation tools for evaluating the operation of energy systems and the controls in buildings have been developed the latest years with different levels of complexity and angles of focus.</p><p>However, research and development regarding holistic energy system designs and techniques are in their infancy. The standard tactic has been to isolate system parts, study them as stand-alone sub-systems and focus on optimising components or processes of a complex function. In the present study, it is demonstrated the necessity for uniting energy engineers, architects, installers and technicians regarding decision making upon the energy use for heating, ventilation and air-conditioning (HVAC) in the built environment. Systems approach has been employed for studying the research issue that is presented in the current thesis. An extended part of this treatise has been devoted to systems thinking in practice.</p><p>The thesis demonstrates systematic methods of modelling and analysing certain, integrated, domestic, HVAC applications. The reference system boundaries enclose the building as a construction and as a dynamic function, a comfort-providing system based on a heat pump, a low-temperature hydronic heat distribution system and controls in a residential application. Obviously, these are not the only components met in a hydronic heating system. Numerous pieces of equipment, as piping, circulating pumps, expansion tanks, zone valves, relief valves and other essential elements are needed to make a safe and functional heating system. However, this study focuses on the analysis of the chosen reference system. Several models have been developed in the computational tools of TRNSYS and EES. These tools have been employed because they allow co-solving, hence the integrated system as well as the interaction between the different parts of the system can be studied.</p><p>The foremost result of this study is that approaching the system as a whole provides a better picture of the operation of every system component and the interaction between them. Explanations are given for the parameters that have a significant impact on the system’s performance. The thesis shows the importance of factors that are not easy to predict, as well as the difference in the building’s behaviour under fast changing thermal loads when the incorporated thermal mass is altered. Finally, implementing sophisticated controls for reducing the energy costs without compromising thermal comfort is vital.</p>

Technology

heat pump

domestic heating and ventilation

systems approach

integration

simulation

energy efficiency

TEKNIKVETENSKAP

TECHNOLOGY

TEKNIKVETENSKAP

Modelling the dynamics of domestic low-temperature heat pump heating systems for improved performance and thermal comfort : a systems approach

Sakellari, Dimitra

January 2005

The present environmental concerns and the rising human requirement for solutions with better comfort and lower costs have resulted in an increased awareness for the energy use in the built environment. Technical advances in building structural systems and materials, heating and other comfort-providing systems and controlling strategies all lead to the integration of building technology with the function of buildings and the aesthetics. Therefore, in the process of improving the performance of energy systems and increasing the energy efficiency, integrated system approaches are of high importance. Performing the necessary energy analysis before any construction-installation occurs can help designers and decision makers reach guided solutions. Hence, a broad range of calculation tools for evaluating the operation of energy systems and the controls in buildings have been developed the latest years with different levels of complexity and angles of focus. However, research and development regarding holistic energy system designs and techniques are in their infancy. The standard tactic has been to isolate system parts, study them as stand-alone sub-systems and focus on optimising components or processes of a complex function. In the present study, it is demonstrated the necessity for uniting energy engineers, architects, installers and technicians regarding decision making upon the energy use for heating, ventilation and air-conditioning (HVAC) in the built environment. Systems approach has been employed for studying the research issue that is presented in the current thesis. An extended part of this treatise has been devoted to systems thinking in practice. The thesis demonstrates systematic methods of modelling and analysing certain, integrated, domestic, HVAC applications. The reference system boundaries enclose the building as a construction and as a dynamic function, a comfort-providing system based on a heat pump, a low-temperature hydronic heat distribution system and controls in a residential application. Obviously, these are not the only components met in a hydronic heating system. Numerous pieces of equipment, as piping, circulating pumps, expansion tanks, zone valves, relief valves and other essential elements are needed to make a safe and functional heating system. However, this study focuses on the analysis of the chosen reference system. Several models have been developed in the computational tools of TRNSYS and EES. These tools have been employed because they allow co-solving, hence the integrated system as well as the interaction between the different parts of the system can be studied. The foremost result of this study is that approaching the system as a whole provides a better picture of the operation of every system component and the interaction between them. Explanations are given for the parameters that have a significant impact on the system’s performance. The thesis shows the importance of factors that are not easy to predict, as well as the difference in the building’s behaviour under fast changing thermal loads when the incorporated thermal mass is altered. Finally, implementing sophisticated controls for reducing the energy costs without compromising thermal comfort is vital. / QC 20101008

Technology

heat pump

domestic heating and ventilation

systems approach

integration

simulation

energy efficiency

TEKNIKVETENSKAP

TECHNOLOGY

TEKNIKVETENSKAP

Simulation and comparison of vapor-compression driven, liquid- and air-coupled cooling systems

Golden, Daniel Lee

02 September 2010

Industrial and military vehicles, including trucks, tanks and others, employ cooling systems that address passenger cooling and auxiliary cooling loads ranging from a few Watts to 50 kW or more. Such systems are typically powered using vapor-compression cooling systems that either directly supply cold air to the various locations, or cool an intermediate single-phase coolant closed loop, which in turn serves as the coolant for the passenger cabins and auxiliary loads such as electronics modules. Efforts are underway to enhance the performance of such systems, and also to develop more light weight and compact systems that would remove high heat fluxes. The distributed cooling configuration offers the advantage of a smaller refrigerant system package. The heat transfer between the intermediate fluid and air or with the auxiliary heat loads can be fine tuned through the control of flow rates and component sizes and controls to maintain tight tolerances on the cooling performance. Because of the additional loop involved in such a configuration, there is a temperature penalty between the refrigerant and the ultimate heat sink or source, but in some configurations, this may be counteracted through judicious design of the phase change-to-liquid coupled heat exchangers. Such heat exchangers are inherently smaller due to the high heat transfer coefficients in phase change and single-phase liquid flow compared to air flow. The additional loop also requires a pump to circulate the fluid, which adds pumping power requirements. However, a direct refrigerant-to-heat load coupling system might in fact be suboptimal if the heat loads are distributed across large distances. This is because of the significantly higher pressure drops (and saturation temperature drops) incurred in transporting vapor or two-phase fluids through refrigerant lines across long plumbing elements. An optimal system can be developed for any candidate application by assessing the tradeoffs in cooling capacity, heat exchanger sizes and configurations, and compression, pumping and fan power. In this study, a versatile simulation platform for a wide variety of direct and indirectly coupled cooling systems was developed to enable comparison of different component geometries and system configurations based on operating requirements and applicable design constraints. Components are modeled at increasing levels of complexity ranging from specified closest approach temperatures for key components to models based on detailed heat transfer and pressure drop models. These components of varying complexity can be incorporated into the system model as desired and trade-off analyses on system configurations performed. Employing this platform as a screening, comparison, and optimization tool, a number of conventional vapor-compression and distributed cooling systems were analyzed to determine the efficacy of the distributed cooling scheme in mobile cooling applications. Four systems serving approximately a 6 kW cooling duty, two with air-coupled evaporators and two with liquid-coupled evaporators, were analyzed for ambient conditions of 37.78°C and 40% relative humidity. Though the condensers and evaporators are smaller in liquid-coupled systems, the total mass of the heat exchangers in the liquid-coupled systems is larger due to the additional air-to-liquid heat exchangers that the configuration requires. Additionally, for the cooling applications considered, the additional compressor power necessitated by the liquid-coupled configuration and the additional power consumed by the liquid-loop pumps result in the coefficient of performance being lower for liquid-coupled systems than for air-coupled systems. However, the use of liquid-coupling in a system does meet the primary goal of decreasing the system refrigerant inventory by enabling the use of smaller condensers and evaporators and by eliminating long refrigerant carrying hoses.

Cooling systems

Air-conditioning

Vapor compression

Hydronic fluid

Liquid-coupled

Vehicles

Cooling load

Multidisciplinary design optimization

Computer simulation

Návrh vzduchotechniky a vytápění pro výrobní podnik / HVAC in a production plant

Černík, Václav

January 2013

This master’s thesis deals with heating and HVAC in production plant ELMET, spol. s r.o. The first part of the thesis concerns reconstruction of the central heating system, which is outdated and unreliable in the time of the writing of the thesis. The second part deals with cooling of mounting of electronics, where technological requirements are not met due to summer overheating. The third part of the thesis concerns ventilation of metalworking hall using waste heat from production machines.

Marketingový audit IMI Hydronic Engineering pro český trh / Marketing Audit of IMI Hydronic Engineering for the Czech Market

Drápelová, Zuzana

January 2014

The main objective of this thesis is to execute a marketing audit of IMI Hydronic Engineering at the Czech market in order to identify problem areas and opportunities, define key performance indicators (KPI) and follow recommended procedures to improve marketing performance of this company and increase the efficiency of the company as a whole. Marketing audit is a comprehensive analysis of the company and its surroundings, which does not contain only simple analysis of the current situation of the company but also the draft measure. Marketing audit in this thesis is carried out based on the methodology described in the theoretical part and consists of the analyses of six interrelated parts. The first part of the audit (audit of marketing environment) analyzes the external environment of IMI Hydronic Engineering realized through PESTLE analysis and Porter's five forces analysis. The following five sections are focusing on internal environmental audit of this company. These parts of the audit are: audit of marketing strategy, audit of marketing, audit of marketing systems, audit of marketing productivity and audit of marketing functions. The results are summarized in complex SWOT analysis. Recommendations, proposals for amendments, strategies, objectives and KPIs are listed in the conclusion.

Holistic Performance Evaluation of the Built Environment: The Olin Building Past, Present & Future

Laseter, Joel Tyler, III

29 January 2019

No description available.

Engineering

Electrical Engineering

Mechanical Engineering

design analysis

built environment

buildings

energy efficiency

building performance

building automation system

hydronic

air handler

Case Institute of Technology

fieldwork

fintube

variable air volume

centrifugal pumps

centrifugal fans

steam

Enhancing Comfort and Robustness in Hydronic Radiator Systems through Integration of Body Heat Predictions : A Study on a Novel LPV Controller / Förbättring av Komfort och Robusthet i Vattenburna Elementsystem genom Integration av Kroppsvärme beräkningar

Pirmohamed, Fahim

January 2023

The quest to balance occupant comfort with energy efficiency is a key challenge in the field of heating systems, particularly for hydronic radiators. This study addresses this issue by investigating the integration of body heat predictions into a gain-scheduling controller for a hydronic radiator system. Although the benefits of gain-scheduling control strategies are acknowledged in HVAC systems, this exploration into the integration of body heat predictions in hydronic radiator systems presents a novel approach. A Linear Parameter-Varying (LPV) controller was employed and its impact on comfort, energy consumption, and robustness in the face of varying parameters such as the number of occupants, inaccuracies in body heat prediction, and set-point temperature changes was examined. This proposed controller was tested in a simulated house heating system made in Simulink. Findings indicated a substantial enhancement in comfort, especially under low-load scenarios. The controller demonstrated notable robustness against disturbances, highlighting the system’s reliability. Although energy consumption did not show significant reduction, the ability to maintain comfort levels without increasing energy use is a valuable contribution to sustainable heating practices. The results of this study extend our understanding of control strategies in hydronic radiator systems, providing a promising approach towards more comfortable, robust, and energy-efficient solutions. Further research should focus on improving the accuracy of body heat prediction algorithms and incorporating renewable energy sources for increased energy efficiency. In sum, this work represents a significant step towards a more balanced and sustainable future in the operation of hydronic radiator systems. / Denna studie utforskar möjligheten att balansera komfort och energieffektivitet i vattenburna elementsystem genom att integrera kroppsvärmeberäkningar i en gain-scheduling regleralgoritm. Vi presenterar en nyanserad metod som använder en Linjär Parameterberoende (LPV) reglerare. Denna reglerare anpassar sig till varierande parametrar som antal personer i rummet, osäkerheter i kroppsvärmeberäkningar och förändringar i inställd temperatur. Den föreslagna regleraren testades i ett simulerat husvärmesystem skapat i Simulink. Resultaten indikerade en betydande förbättring i komfort, särskilt under låglastscenarier. Regleraren uppvisade också anmärkningsvärd robusthet mot störningar, vilket understrykersystemets tillförlitlighet. Även om ingen signifikant minskning i energiförbrukning observerades, är förmågan att bibehålla komfortnivåer utan att öka energianvändningen ett värdefullt bidrag till hållbara uppvärmningsmetoder. Denna studie utökar vår förståelse för reglerstrategier i vattenburna elementsystem och erbjuder en lovande väg framåt mot mer komfortabla, robusta och energieffektiva lösningar. För framtida forskning bör fokus ligga på att förbättra noggrannheten i kroppsvärmeberäkningsalgoritmer och att integrera förnybara energikällor för ökad energieffektivitet. Sammantaget representerar detta arbete ett betydande steg mot en mer balanserad och hållbar framtid i drift av vattenburna elementsystem.

Energy Efficiency

Hydronic Radiators

Linear Parameter-Varying Control

Gain-Scheduling

Occupancy Detection

Radiated Energy Estimation

Thermostatic Radiator Valves

Smart Heating Systems

Robustness

Energieffektivitet

Vattenburna Element

Linjär Parameterberoende Reglering

Gain-Scheduling

Detektering av Närvaro

Beräkning av Utstrålad Energi

Termostatiska Radiatorventiler

Smarta Värmesystem

Robusthet

Engineering and Technology

Teknik och teknologier