Effect of baffle spacing on pressure drop and local heat transfer in shell-and-tube heat exchangers for staggered tube arrangement

Li, Huadong; Kottke, Volker

doi:10.1016/s0017-9310(97)00201-9

Cited by 91 publications

(33 citation statements)

References 7 publications

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“…(7)- (9) correction factors are defined as [13] follows. accounts for the thermal-physics properties effects; accounts for the bundle-shell bypass streams; accounts for the baffle spacing in inlet and outlet sections; accounts for the change in the cross-flow characteristcs in heat exchanger; and accounts for the turbulent enhancement.The pressure drop in the inlet and outlet nozzles can be calculated by [11,12] ………………………………………… (10) Where is taken as 1.5 or 2.0 by referring to Refs. [11,12].The over-all pressure drop of the shell-side fluid is ………………………….………… (11) From above presentation it can be seen that the determination of factors and is the key issue to obtain the shellside fluid heat trasnfer coefficient and pressure drop.…”

Section: Particulars About the Helical Bafflesmentioning

confidence: 99%

Investigation on Performance of Shell and Tube Heat Exchanger with Assorted Baffle Parameters

John¹,

Sk²,

Jagadish³

et al. 2016

IOSR

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Section: Particulars About the Helical Bafflesmentioning

confidence: 99%

Investigation on Performance of Shell and Tube Heat Exchanger with Assorted Baffle Parameters

John¹,

Sk²,

Jagadish³

et al. 2016

IOSR

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“…Форма, розміри та розташування турбулізаторів впливають на характер потоку, сприяють виникненню дрібномасштабних вихорів, турбулізують приграничний ламінарний шар (ПЛШ), а значить інтенсифікують передачу кількості теплоти. Серед турбулізаторів найбільш вивчені і досліджені такі типи турбулізуючих вставок: спіральні пружинні, кільцеві, завдяки яким теплова потужність теплообмінника збільшується у 1,5-2,5 рази [7], хвилеподібні [8], вставки у вигляді гофрованої перегородки з гофрами, які розташовані одні відносно одних під кутом 90 0 , решітчасті [9], які дозволили підвищити коефіцієнт тепловіддачі на 29-30%, шнекові або стрічкові [10], які здійснюють закручування потоку. Інтенсифікувати теплообмін можна шляхом перемішування рідини [11], видаленням теплоносія з поверхні теплообміну механічними засобами, вібрацією або обертанням поверхні теплообміну.…”

Section: огляд літературиunclassified

Інтенсифікація Теплообмінних Процесів Шляхом Використання Поверхнево-Активних Речовин

Билонога¹,

Максисько²

2015

Харчова Наука Та Технологія

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“…It is also influences the heat transfer rate. The new baffle cut arrangement achieved higher heat transfer rates and lower pressure drops (Master et al 2006;Mukherjee 1992;Li & Kottke 1998c;Lei et al 2008), so it is required to develop a new type STHE using different baffle cut arrangements to achieve a higher heat transfer rate. For the last few years, already described methods have been used to calculate heat transfer and pressure drop in the shell side of the STHE with different baffles (Peng et al 2007).…”

Section: Introductionmentioning

confidence: 99%

Numerical and heat transfer analysis of shell and tube heat exchanger with circular and elliptical tubes

Rao

Raju

2016

Int J Mech Mater Eng

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Background: Heat exchanger is a device in many industrial applications and energy conversion systems. Various heat exchangers are designed for different industrial processes and applications. Shell and tube heat exchanger (STHE) has its own importance in the process industries. Methods: Experimental and numerical simulations are carried for a single shell and multiple pass heat exchangers with different tube geometries i.e. circular tubes to elliptical tubes. The experiment was carried out with hot fluid in tube side and cold fluid in shell side with circular tubes at 600 tube orientation and 25 % baffle cut. Heat transfer rates and pressure drops are calculated for various Reynolds numbers from 4000 to 20000. Fluent software is used for numerical investigations. Both circular and elliptical tube geometries with 450,600 and 900 orientations are used for the numerical studies. In addition to 25 % baffle cut, quarter baffle cut and mirror quarter baffle cut arrangements are used for comparison. The experimental values of heat transfer rates and pressure drops over shell side and tube side along the length of STHE are compared with those obtained from fluent software. Results and Conclusion: It is found that the elliptical tube geometry with mirror quarter baffle cut at 450 tube orientation is 10 % higher than existing shell and tube heat exchanger and the pressure drop decrement in tube side shows up to 25 %.

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Effect of baffle spacing on pressure drop and local heat transfer in shell-and-tube heat exchangers for staggered tube arrangement

Cited by 91 publications

References 7 publications

Investigation on Performance of Shell and Tube Heat Exchanger with Assorted Baffle Parameters

Investigation on Performance of Shell and Tube Heat Exchanger with Assorted Baffle Parameters

Інтенсифікація Теплообмінних Процесів Шляхом Використання Поверхнево-Активних Речовин

Numerical and heat transfer analysis of shell and tube heat exchanger with circular and elliptical tubes

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