Heat Transfer Performance and Piping Strategy Study for Chilled Water Systems at Low Cooling Loads

Li, Nanxi 1986-

14 March 2013

The temperature differential of chilled water is an important factor used for evaluating the performance of a chilled water system. A low delta-T may increase the pumping energy consumption and increase the chiller energy consumption. The system studied in this thesis is the chilled water system at the Dallas/Fort Worth International Airport (DFW Airport). This system has the problem of low delta-T under low cooling loads. When the chilled water flow is much lower than the design conditions at low cooling loads, it may lead to the laminar flow of the chilled water in the cooling coils. The main objective of this thesis is to explain the heat transfer performance of the cooling coils under low cooling loads. The water side and air side heat transfer coefficients at different water and air flow rates are calculated. The coefficients are used to analyze the heat transfer performance of the cooling coils at conditions ranging from very low loads to design conditions. The effectiveness-number of transfer units (NTU) method is utilized to analyze the cooling coil performance under different flow conditions, which also helps to obtain the cooling coil chilled water temperature differential under full load and partial load conditions. When the water flow rate drops to 1ft/s, laminar flow occurs; this further decreases the heat transfer rate on the water side. However, the cooling coil effectiveness increases with the drop of water flow rate, which compensates for the influence of the heat transfer performance under laminar flow conditions. Consequently, the delta-T in the cooling coil decreases in the transitional flow regime but increases in the laminar flow regime. Results of this thesis show that the laminar flow for the chilled water at low flow rate is not the main cause of the low delta-T syndrome in the chilled water system. Possible causes for the piping strategy of the low delta-T syndrome existing in the chilled water system under low flow conditions are studied in this thesis: (1) use of two way control valves; and (2) improper tertiary pump piping strategy.

delta-T

Chilled water system

Chilled Water System Modeling & Optimization

Trautman, Neal L.

08 1900

Indiana University-Purdue University Indianapolis (IUPUI) / The following thesis looks into modeling a chilled water system equipped with variable speed drives on different piece of equipment and optimization of system setpoints to achieve energy savings. The research was done by collecting data from a case-study and developing a system of component models that could be linked to simulate the overall system operation.

Chilled Water

Chilled Water System Modeling

Chilled Water System Optimization

Cooling Tower

Condenser Water Pump

Variable Frequency Drive

Variable Speed Chilled Water System Modeling & Optimization

Neal Louis Trautman (9192728)

04 August 2020

The following thesis looks into modeling a chilled water system equipped with variable speed drives on different piece of equipment and optimization of system setpoints to achieve energy savings. The research was done by collecting data from a case-study and developing a system of component models that could be linked to simulate the overall system operation.

Mechanical Engineering

Chilled Water

Cooling Tower

System Optimization

Condenser Pump

Chilled water system Modeling

Potential advantages of applying a centralized chilled water system to high-density urban areas in China

Kang, Di

January 1900

Master of Science / Department of Architectural Engineering and Construction Science / Fred L. Hasler / This paper discusses the advantages of applying a utility centralized chilled water system as the district cooling choice for facilities in the high-density urban areas of China and how it will influence China’s development in the next decades. Presently, the Chinese government is trying to contribute to the world’s energy-saving goals as well as determine its sustainable development framework. As air pollution has become one of the main problems in China, indoor air quality (IAQ) is likely to gain priority as a building design consideration in the future. Consistent with this fact, this paper proposes an optimum HVAC system for cooling purposes to the Chinese government. Compared to unitary HVAC systems, the centralized HVAC system has significant advantages in system efficiency, energy reduction and cost savings and can, therefore, be a better choice. Furthermore, the paper will focus on the centralized chilled water system and demonstrate why they better match the development model in China. The application of the system in high-density urban areas will also be discussed. Due to a lack of understanding that the energy consumption of unitary systems, the first comparison presented is between unitary HVAC systems and centralized HVAC systems in individual buildings. The comparison presented will focus on the energy-saving benefits of the centralized HVAC system in individual buildings and its contribution to sustainable development. Consequently, prescribing a centralized chilled water system as a utility district cooling system and applying a centralized chilled water system to each individual building in the highdensity urban areas will be compared. Cost savings, including initial cost and life cycle cost, are the metrics used in this comparison. Additionally, energy consumption and system reliability will be explored in determining which model will be more appropriate for China's development. The paper concludes that the centralized chilled water system should become the mainstream in the high-density urban area in China. Several recommendations are also made to the Chinese government on setting up utility centralized chilled water systems.

Utility district cooling system

China

Chilled water systems

Cooling

Continued Development of a Chilled Water System Analysis Tool for Energy Conservation Measures Evaluation

Gaudani, Ghanshyam

01 January 2013

Chilled water systems constitute a major portion of energy consumption in air conditioning systems of commercial buildings and process cooling of manufacturing plants. These systems do not operate optimally in most of the cases because of the operating parameters set and/or the components used. A Chilled water system analysis tool software (CWSAT) is developed as a primary screening tool for energy evaluation. This tool quantifies the energy usage of the various chilled water systems and typical measures that can be applied to these systems to conserve energy. The tool requires minimum number of inputs to analyze the component-wise energy consumption and incurred overall cost. This thesis also examines various energy conservation measures that are available for chilled water systems. The components, arrangements, and the common energy conservation opportunities for chilled water systems are presented. The new version of the tool is developed in Object Oriented Programming Language Microsoft Visual Basic.Net© to maintain the tool latest with current technology, add and expand capabilities and avoid obsolescence. Many Improvements to the previous tool are made to improve quality and the types of the systems the tool can handle. The development of the new routines and interfaces is also accommodated in the new version to make the tool universal. In order to determine the accuracy of the new version of the tool, a comparison is made between the results from the previous and new version of the tool. The results of the comparisons are presented.

Chilled water system

Energy efficiency

software

Efficiency improvements

Mechanical Engineering

Thermal energy storage design for emergency cooling

Basgall, Lance Edgar

January 1900

Master of Science / Department of Mechanical and Nuclear Engineering / Donald L. Fenton / Emergency cooling systems are applied to any application where the loss of cooling results in damage to the product, loss of data, or equipment failure. Facilities using chilled water for cooling that experience an electrical power outage, even a small one, would cause the chiller to shut down for 20 minutes or more. If emergency cooling is not available, temperatures would continue to increase to dangerous levels, potentially damaging the facility. Examples of facilities that could be protected by having emergency cooling systems are data centers, hospitals, banks, control rooms, laboratories, clean rooms, and emergency shelters among others. This project addresses the current lack of information and methods needed to correctly design emergency cooling systems. Three application uses were investigated for the possible benefits of having emergency cooling systems. The software TRNSYS was used to simulate five typical emergency cooling systems for each of the three applications. The characteristics and differences of the systems developed from the simulations were then analyzed and documented. The five systems simulated include a pressurized chilled water tank (parallel), atmospheric chilled water tank (parallel and series), low temperature chilled water tank (parallel), and ice storage tank (series). Simulations showed that low temperature chilled water tanks were less stratified than regular chilled water tanks by approximately 10%. Simulations also showed that the differences between atmospheric and pressurized tanks were negligible. Each tank discharged energy in the same manner and managed to replenish itself in the same amount of time. Examination of the different system configurations showed that tanks in series with the thermal load have issues with recharging due to its inability to isolate itself from the thermal load. It was also observed that while low temperature chilled water and ice storage tanks had the potential of reducing the storage tank volume, the amount of time ragged cooling will last is decreased by at least a factor of two. The examination of the five systems produced the desired design methodologies needed to address the lack of information on emergency cooling systems. With the reported information designers can effectively engineer systems to meet their needs.

Thermal energy storage

Chilled water

Ice storage

Emergency cooling

Engineering, General (0537)

Engineering, Mechanical (0548)

The performance of the Energy Machine : A comparative study of the Energy Machine and a conventional heat pump system

Hemgren, Viktor

January 2013

The Achilles heel of the heat pump technology has for long been the low efficiency occurring during domestic hot water production. The problem is the high condensation pressure needed to reach high temperatures. To produce domestic hot water, the system need to deliver a supply temperature of about 60 °C, to be compared with a supply temperature of around 30-50 °C when heat is delivered to a radiator circuit. This drawback has for long held the heat pump technology back and instead gave room for alternative technologies on the market, like district heating.The Energy Machine is a heat pump system developed to bypass the poor efficiency during domestic hot water heating. The technology is based on the use of two heat pumps working together. The main heat pump delivers heat to the heating system, as usual, whilst the second smaller heat pump heats the domestic hot water. As the second heat pump is fed with reject heat from a subcooler in the main heat pump, it can operate at high efficiency, even when producing domestic hot water.The aim of this master thesis has been to investigate how the performance of the Energy Machine differs from that of a conventional heat pump system. In order to do so, models describing the two systems have been designed using MATLAB, Simulink. Simulations have then been performed to investigate how the two systems perform on an annual basis.The results of the simulations show that the Energy Machine performs much better than the conventional systems at most operating conditions, especially during domestic hot water heating. The annual COP- factor of the Energy Machine has proven to be 33,5 % higher than that of a conventional heat pump system. / Värmepumpsteknikens akilleshäl har sedan lång tid tillbaka varit den låga verkningsgraden som uppstår vid tappvarmvattenproduktion. Problemet är att det krävs mycket högt kondenseringstryck för att uppnå den höga framledningstemperatur som efterfrågas vid tappvarmvattenproduktion. Normalt krävs en temperatur omkring 60 °C vid tappvarmvattenproduktion, att jämföras med 30-50 °C då värme levereras ut på en radiatorkrets. Detta problem har länge hållt värmepumpstekninken tillbaka och istället givit utrymme för alternativ teknik på marknaden, såsom fjärrvärme.Energimaskinen, eller Energy Machine, är ett värmepumpssystem utvecklat för att kringgå problemet med den låga verkningsgraden vid tappvarmvattenproduktion. Tekniken bygger på två värmepumpar som arbetar tillsammans. En basmaskin används för att leverera värme ut på värmesystemet, medan en mindre värmepump används för att producera tappvarmvatten. Den mindre värmepumpen matas med värme från en underkylare i basmaskinen, vilket ger hög förångningstemperatur och därmed hög COP faktor, även vid tappvarmvattenproduktion.Målet med projektet har varit att jämföra prestandan hos en Energy Machine med ett konventionellt värmepumpssystem. För att kunna göra dettta har två modeller designats, en modell som beskriver en Energy Machine och en modell som beskriver ett konventionellt värmepumpssystem. Modellerna gjordes i MATLAB, Simulink, och simuleringar utfördes varpå resultaten tolkades och jämfördes.Resultaten från simuleringarna visar att en Energy Machine presterar mycket bättre än ett konventionellt värmepumpssystem i de allra flesta driftfallen , men särskilt vid tappvarmvattenproduktion. Simuleringarna visar att COP- faktorn på årsbasis för en Energy Machine är 33,5 % högre än den för ett konventionellt värmepumpssystem.

Heat pump

Domestic hot water

Heating

Chilled water

Cooling

COP

Efficiency

Simulink

MATLAB

Methodology for Determining the Optimal Operating Strategies for a Chilled Water Storage System

Zhang, Zhiqin

2010 May 1900

This dissertation proposed a new methodology for determining the optimal operating strategies for a chilled water storage system under a Time-of-Use electricity rate structure. It is based on a new classification of operating strategies and an investigation of multiple search paths. Each operating strategy consists of a control strategy and the maximum number of chillers running during the off-peak and on-peak periods. For each month, the strategy with the lowest monthly billing cost and minimal water level higher than the setpoint is selected as the optimal operating strategy for the current month. A system model is built to simulate the tank water level at the end of each time step and the system total power during each time step. This model includes six sub-models. Specifically, the plant model is a forward model using a wire-to-water concept to simulate the plant total power. For the Thermal Energy Storage (TES) model, the tank state is described with total chilled water volume in the tank and its derivation is the tank charging or discharging flow rate. A regression model is adopted to simulate the loop supply and return temperature difference as well as the loop total flow rate demand. In the control strategy sub-model, except for three conventional control strategies and the operation without TES, a new control strategy is advanced to load the chiller optimally. The final results will be a table showing the monthly control strategy and maximal number of chillers staged on during the off-peak and on-peak periods, an approach which is easy for the operators to follow. Two project applications of this methodology are introduced in this dissertation. One is an existing TES system with state-of-the-art control and metering systems. The monthly optimal operating strategies are generated, which will achieve significant savings. The comparisons among different control strategies are also provided. The other application consists of multiple plants with little data. The purpose of the study is to evaluate the economic feasibility of designing a new chilled water storage tank and sharing it among four plants. This problem can be solved with a simplified system model, and an optimal tank size is recommended.

thermal energy storage

chilled water plant

Time-of-use rate structure

operating strategy

chiller plant model

Hydraulic modeling of large district cooling systems for master planning purposes

Xu, Chen

17 September 2007

District Cooling Systems (DCS) have been widely applied in large institutions such as universities, government facilities, commercial districts, airports, etc. The hydraulic system of a large DCS can be complicated. They often stem from an original design that has had extensive additions and deletions over time. Expanding or retrofitting such a system involves large capital investment. Consideration of future expansion is often required. Therefore, a thorough study of the whole system at the planning phase is crucial. An effective hydraulic model for the existing DCS will become a powerful analysis tool for this purpose. Engineers can use the model to explore alternative system configurations to find an optimal way of accommodating the DCS hydraulic system to the planned future unit. This thesis presents the first complete procedure for the use of commercial simulation software to construct the hydraulic model for a large District Cooling System (DCS). A model for one of the largest DCS hydraulic systems in the United States has been developed based on this procedure and has been successfully utilized to assist its master planning study.

Pipe Network

District Cooling System

Central Chilled Water System

Master Planning

Hydraulic Simulation

Comparison of Sensible Water Cooling, Ice building, and Phase Change Material in Thermal Energy Storage Tank Charging: Analytical Models and Experimental Data

Caliguri, Ryan P.

04 October 2021

No description available.

Mechanical Engineering

Thermal Energy Storage

HVAC

Ice Storage

Chilled Water

Phase Change Materials

Cold Storage