HEAT TRANSFER AND PRESSURE DROP IN BANKS OF FINNED TUBES FOR HEAT RECOVERY STEAM GENERATORS

In this work the heat transfer and pressure drop experimental results obtained in a two step finned tube bank with conical fins are presented. The tube bank had an equilateral triangle array composed of nine finned tubes with conical fins inclined 45 degrees in respect with the tube axis. The heat exchange external area of a single tube is approximately 0.07 m2. All necessary thermal parameters, inlet/outlet temperatures, mass flows, for the heat balance in the tube bank were determined for different air velocities, Re = 3400–18400, and one constant thermal charge provided by a hot water flow with a temperature of 80 °C. As a result, the correlations for the heat transfer and pressure drop calculation were obtained. The experimental results were compared against the analytical results for a tube bank with annular fins with the same heat exchange area. It was found that the proposed tube bank using finned tubes with conical fins shows an increment of heat transfer up to 58%.

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Shellside Waterflow Pressure Drop Distribution Measurements in an Industrial-Sized Test Heat Exchanger

Journal of Heat Transfer ◽

10.1115/1.3250474 ◽

1988 ◽

Vol 110 (1) ◽

pp. 60-67 ◽

Cited By ~ 9

Author(s):

H. Halle ◽

J. M. Chenoweth ◽

M. W. Wambsganss

Keyword(s):

Heat Transfer ◽

Heat Exchanger ◽

Pressure Drop ◽

Operating Cost ◽

Power Requirement ◽

Pressure Drops ◽

Pressure Losses ◽

Finned Tubes ◽

Heat Exchanger Design ◽

Isothermal Water

Throughout the life of a heat exchanger, a significant part of the operating cost arises from pumping the heat transfer fluids through and past the tubes. The pumping power requirement is continuous and depends directly upon the magnitude of the pressure losses. Thus, in order to select an optimum heat exchanger design, it is is as important to be able to predict pressure drop accurately as it is to predict heat transfer. This paper presents experimental measurements of the shellside pressure drop for 24 different segmentally baffled bundle configurations in a 0.6-m (24-in.) diameter by 3.7-m (12-ft) long shell with single inlet and outlet nozzles. Both plain and finned tubes, nominally 19-mm (0.75-in.) outside diameter, were arranged on equilateral triangular, square, rotated triangular, and rotated square tube layouts with a tube pitch-to-diameter ratio of 1.25. Isothermal water tests for a range of Reynolds numbers from 7000 to 100,000 were run to measure overall as well as incremental pressure drops across sections of the exchanger. The experimental results are given and correlated with a pressure drop versus flowrate relationship.

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Experimental Study on Characteristics of Condensation and Flow Resistance Inside Horizontal Corrugated Low Finned Tubes

Volume 3A: Design and Analysis ◽

10.1115/pvp2018-84656 ◽

2018 ◽

Cited By ~ 5

Author(s):

Bin Ren ◽

Xiaoying Tang ◽

Hongliang Lu ◽

Dongliang Fu ◽

Yannan Du ◽

...

Keyword(s):

Heat Transfer ◽

Performance Evaluation ◽

Heat Transfer Coefficient ◽

Pressure Drop ◽

Flow Resistance ◽

Vapor Quality ◽

Transfer Coefficients ◽

Finned Tubes ◽

Heat Transfer Coefficients ◽

Inlet Conditions

It is the simplest and most feasible method to enhance heat transfer by replacing the smooth tube with various kinds of special-shaped enhanced tubes. In this paper, the characteristics of condensation and flow resistance inside horizontal corrugated low finned tubes were studied experimentally. The effects of steam inlet conditions and condensation tubes structural parameters were analyzed. The results showed that the heat transfer performance inside corrugated low finned tubes was greater than that inside smooth tubes. Like inside smooth tubes, the heat transfer coefficients increased with the vapor quality and steam mass flux. But the enhancement rate showed the opposite trend. And the heat transfer coefficients inside corrugated low finned tubes increased with the decrease of pitch and increase of protrusion height. Meanwhile, the variation trend of pressure drop gradient changing with inlet conditions and construal parameters was consistent with trend of heat transfer coefficient. The performance evaluation criteria were used to evaluate the comprehensive performance. It was found that the maximum performance evaluation factor was acquired at the minimum vapor quality and mass flux. The maximum value was 2.24 happened in the tube with pitch of 6 mm and height of 0.7mm. Finally, both the correlation for heat transfer coefficient and correlation for pressure drop gradient were developed by fitting experimental data. And this would provide calculation foundations for the design of horizontal condensers with corrugated low finned tubes.

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Flow and Heat Transfer in Heat Recovery Steam Generators

Journal of Energy Resources Technology ◽

10.1115/1.2751505 ◽

2007 ◽

Vol 129 (3) ◽

pp. 232-242 ◽

Cited By ~ 6

Author(s):

N. Hegde ◽

I. Han ◽

T. W. Lee ◽

R. P. Roy

Keyword(s):

Heat Transfer ◽

Heat Recovery ◽

Gas Flow ◽

Horizontal Tube ◽

Vertical Tube ◽

Computational Method ◽

Laboratory Model ◽

Steam Generators ◽

Combustion Gas ◽

Flow And Heat Transfer

Computational simulations of flow and heat transfer in heat recovery steam generators (HRSGs) of vertical- and horizontal-tube designs are reported. The main objective of the work was to obtain simple modifications of their internal configuration that render the flow of combustion gas more spatially uniform. The computational method was validated by comparing some of the simulation results for a scaled-down laboratory model with experimental measurements in the same. Simulations were then carried out for two plant HRSGs—without and with the proposed modifications. The results show significantly more uniform combustion gas flow in the modified configurations. Heat transfer calculations were performed for one superheater section of the vertical-tube HRSG to determine the effect of the configuration modification on heat transfer from the combustion gas to the steam flowing in the superheater tubes.

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1213 Heat Transfer and Pressure Drop Characteristics in Latent Heat Recovery Type Heat Exchanger : Effects of Fin Pitch of Offset Type Fin

The Proceedings of Conference of Hokuriku-Shinetsu Branch ◽

10.1299/jsmehs.2005.42.405 ◽

2005 ◽

Vol 2005.42 (0) ◽

pp. 405-406

Author(s):

Kiyoshi KAWAGUCHI ◽

Kenichi OKUI ◽

Takahiro SHIMOURA ◽

Takaki OHKOUCHI ◽

Hiroyuki OSAKABE ◽

...

Keyword(s):

Heat Transfer ◽

Heat Exchanger ◽

Pressure Drop ◽

Latent Heat ◽

Heat Recovery

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Experimental and Numerical Investigation of the Gas Side Heat Transfer and Pressure Drop of Finned Tubes—Part I: Experimental Analysis

Journal of Thermal Science and Engineering Applications ◽

10.1115/1.4007124 ◽

2012 ◽

Vol 4 (4) ◽

Cited By ~ 6

Author(s):

Rene Hofmann ◽

Heimo Walter

Keyword(s):

Heat Transfer ◽

Pressure Drop ◽

Flow Direction ◽

Measurement Data ◽

Heat Transfer Correlation ◽

Average Deviation ◽

Finned Tubes ◽

Measurement Results ◽

Staggered Arrangement ◽

Industrial Boiler

In this study, a heat transfer and pressure drop correlation are determined for helically I- and U-shaped finned tubes as well as for solid I-finned tubes at constant transverse and longitudinal spacing. In the heat transfer correlation, the influence of the number of tube rows arranged in flow direction is taken into consideration. A detailed description of the test rig and the data reduction procedure is presented. A thorough uncertainty analysis was performed to validate the results. The investigation has shown that the influence of the fin geometry on the heat transfer of the helically segmented I- and U-shaped tubes can be disregarded. The heat transfer correlation, which is valid for the helically segmented I- and U-shaped tubes in a staggered arrangement, can describe 90% of all measurement data within ±15%. All measurements are performed for constant transverse and longitudinal spacing. For the pressure drop coefficient, two new correlations, which are only valid for helically segmented U shaped finned tubes in a staggered arrangement, show an average deviation of approximately ±13% for 90% of all measurement results. All new correlations are compared with correlations from open and established literature for industrial boiler applications. The new heat transfer and pressure drop correlations show a relative deviation of ±20% in comparison with correlations in open literature. The new pressure drop correlations show the same characteristic as most correlations in the open literature.

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CFD Simulations of Heat Recovery Steam Generators Including Tube Banks

Volume 2: Simple and Combined Cycles; Advanced Energy Systems and Renewables (Wind, Solar and Geothermal); Energy Water Nexus; Thermal Hydraulics and CFD; Nuclear Plant Design, Licensing and Construction; Performance Testing and Performance Test Codes; Student Paper Competition ◽

10.1115/power2014-32261 ◽

2014 ◽

Cited By ~ 2

Author(s):

Iván F. Galindo-García ◽

Ana K. Vázquez-Barragán ◽

Miguel Rossano-Román

Keyword(s):

Heat Transfer ◽

Porous Media ◽

Heat Recovery ◽

Steam Generators ◽

Cfd Simulations ◽

Length Scales ◽

Flow And Heat Transfer ◽

Porous Media Model ◽

Realistic Representation ◽

Tube Banks

CFD (Computational Fluids Dynamics) simulations of HRSGs (Heat Recovery Steam Generators) can improve and optimize the performance of combined cycle power plants. For example CFD results can help to analyze the effect that different working conditions such as changes in power or fuel quality can have on the uniformity of the flow. A uniform flow is important because the tubes inside the HRSG are more susceptible to corrosion and rupture when the flow distribution is strongly nonuniform. An accurate modeling of the flow and heat transfer characteristics is paramount in order to obtain a realistic representation of the process. However, a big problem in CFD modeling of HRSGs, or any equipment with tube-and-shell heat exchangers, is the different length scales of the equipment, which vary from a few centimeters for the tubes diameter to tens of meters for the HRSG vertical height. The problem is that these different length scales would require a very large computational mesh and consequently a very expensive simulation. To overcome this problem, a common approach in CFD simulations of HRSG has been to model the tube banks following a porous media approach, where the tubes are represented by a volume with a porosity factor which gives the volume fraction of fluid within the porous region. Using this model a pressure drop and the total heat absorbed due to the presence of the solid tubes is calculated. However, due to the recent advances and relatively lower prices of computer equipment it is now possible in a relatively economical way to explicitly include the tube banks in the CFD models of HRSGs. In this study a CFD model of a HRSG is presented where the tube banks are included in the geometric model. Results using this model show the fluid flow and heat transfer between the numerous tubes. A further advantage, in contrast to the porous media model, is that the flow inside the tubes is also modeled which gives a more realistic representation of the phenomena inside the tubes.

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