Heat transfer coefficient: a review of measurement techniques

Moreira, Tiago Augusto; Colmanetti, Alex Roger Almeida; Tibiriçá, Cristiano

doi:10.1007/s40430-019-1763-2

Cited by 26 publications

(7 citation statements)

References 136 publications

(211 reference statements)

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“…According to the Newton's law of cooling, heat transfer coefficient of investigated heat exchanger is defined as [15]:…”

Section: Thermal Balance Methodsmentioning

confidence: 99%

“…Over the years the Wilson plot method has undergo series of modifications in order to extend its application to more sophisticated heat exchanger design and enhanced flow conditions. More detailed information concerning the application of both the original and modified Wilson plot method in various heat transfer problems can be found in literature [10][11][12][13][14][15] The aim of the paper is to present the available research methods widely applied in the investigations of heat transfer coefficient in minichannels. The main focus was put on thermal balance method and mass transfer method.…”

Section: Introductionmentioning

confidence: 99%

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Research methods in the study of heat transfer coefficient during flow in minichannels

Tychanicz-Kwiecień

Grosicki

2021

Journal of Mechanical and Energy Engineering

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The paper presents the specification of research methods commonly encountered in the studies of heat transfer processes in minichannels. In particular the following methods have been emphasized: electrochemical limiting current method as well as the thermal balance method. In thermal balance method the mean heat transfer coefficient is determined by the set of experimental thermal measurements of the investigated heat exchanger. In turn, limiting current method is based on heat and mass transfer analogy. The discussed research methods have been implemented on two specially designed and constructed test facilities with compact minichannel heat exchangers, which have been presented and described in details. In order to validate the designed setup, the preliminary experimental measurements of two minichannel heat exchangers with hydraulic diameter of 2 mm and rectangular cross sections during single-phase liquid flows have been carried out. In further perspective it is planned to extend the experimental studies of minichannel heat exchangers and to compare the results obtained by both methods described.

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“…According to the Newton's law of cooling, heat transfer coefficient of investigated heat exchanger is defined as [15]:…”

Section: Thermal Balance Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Research methods in the study of heat transfer coefficient during flow in minichannels

Tychanicz-Kwiecień

Grosicki

2021

Journal of Mechanical and Energy Engineering

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“…[3] Scholars mainly optimize the heat transfer coefficient from two aspects: measurement methods and measurement tools. [4,5] However, the heat transfer coefficient is influenced by many factors, such as the quenching medium type, [6] surface condition, [7] surface shape, [8] and stirring intensity. [9] Thus, the required heat transfer coefficient for different quenching process simulations is also different, which results in the need for an enormous database of heat transfer coefficients to accommodate different quenching processes.…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation and Experimental Research on the Quenching Process of 1045 Steel Based on Thermo–Fluid–Solid Coupling Model

Deng

Huo

2023

steel research int.

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In the numerical simulation research on quenching, the heat transfer coefficient is an important input parameter. However, owing to its complexity and various influencing factors, the measured results are not universal and will significantly increase the simulation complexity and error. This article proposes a new numerical simulation method for quenching processes by extending the simulation domain and introducing the coupled heat exchange between the liquid quenching medium and workpiece, replacing the role of the heat transfer coefficient in the numerical simulation. The method is validated through experimental studies on 1045 steel rod quenched in water, with the maximum relative errors of the simulation results compared to the experimental results being 3.6%, 9%, and 5.1% for hardness, cooling curve, and residual stress, respectively. Furthermore, the article investigates the effect of different flow parameters of quenching media on the quenching effect. Under the studied conditions, the 1045 steel rod has the lowest risk of cracking and the highest hardness value when quenched in water at 50°C. The proposed method improves the universality and convenience of numerical simulation for the quenching process. and can be used to guide the formulation of quenching process parameters when the heat transfer coefficient is unknown.This article is protected by copyright. All rights reserved.

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“…Refinement of methods for calculating heat transfer coefficients using experimental data in various equipment is a task to which many scientific works of scientists in different countries of the world are devoted [3][4][5][6][7][8][9][10]. But specifying the methods of calculating these coefficients for systems of drops or pellets and air, in their mutual movement, is a difficult task, the number of publications in this direction is limited, and similar studies are relevant.…”

Section: Introductionmentioning

confidence: 99%

Determination of the heat transfer coefficient between pellets and air during the modernization of a pelletizing tower based on industrial research

Nichvolodin,

Sklabinskyi

2023

TAPR

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The object of research is the heat transfer coefficient between pellets and air flow in industrial granulation towers. The problem lies in the difficulty of optimizing the heat transfer process. As a result of experiments and analysis, it was shown that each granulating tower for the production of mineral fertilizers has unique properties that significantly affect the efficiency of heat transfer. There are general mathematical models, but for accurate modeling and optimization of heat transfer, the unique characteristics of each production must be taken into account. The results showed that creating an accurate mathematical model for each specific fertilizer production is a difficult task due to the large number of unmeasured or difficult to reconcile factors. The method of calculating the heat transfer coefficient for the granulator tower obtained in the course of the work derives from a set of researches on the production of mineral fertilizers. This approach is based on the analysis of technical parameters and granulation composition of the product. The developed method makes it possible to reliably ensure the operating conditions of the device during modernization and changes in production volumes. These results are important for both practical and theoretical purposes. They can be used to accurately predict the operating conditions of equipment during modification and productivity growth. According to the research results, this approach allows obtaining fairly reliable data for forecasting the thermodynamic conditions of the tower equipment in the event of its modernization and transition of the granulation tower to the production of an increased amount of products. The specified method was tested in calculations of production modernization at urea production plants (Indian Farmers Fertilizer Cooperative (Iffco), India), Rustavi Azot LLC (Georgia), Grodno Azot LLC (Republic of Belarus) and others. This method has proven to be quite reliable in predicting the possible need for an additional amount of air supplied to the tower and forming requirements for the operating parameters of rotary vibrating granulators in the event of a significant increase in the load on the float in the tower and an increase in the amount of products planned for release.

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Heat transfer coefficient: a review of measurement techniques

Cited by 26 publications

References 136 publications

Research methods in the study of heat transfer coefficient during flow in minichannels

Research methods in the study of heat transfer coefficient during flow in minichannels

Numerical Simulation and Experimental Research on the Quenching Process of 1045 Steel Based on Thermo–Fluid–Solid Coupling Model

Determination of the heat transfer coefficient between pellets and air during the modernization of a pelletizing tower based on industrial research

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