Method Article

Measurements of Local Instantaneous Convective Heat Transfer in a Pipe - Single and Two-phase Flow

DOI:

10.3791/57437

April 30th, 2018

In This Article

Summary

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This manuscript describes methods aimed at measuring the local instantaneous convective heat transfer coefficients in a single or two-phase pipe flow. A simple optical method to determine the length and the propagation velocity of an elongated (Taylor) air bubble moving at a constant velocity is also presented.

Abstract

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This manuscript provides step by step description of the manufacturing process of a test section designed to measure the local instantaneous heat transfer coefficient as a function of the liquid flow rate in a transparent pipe. With certain amendments, the approach is extended to gas-liquid flows, with a particular emphasis on the effect of a single elongated (Taylor) air bubble on heat transfer enhancement. A non-invasive thermography technique is applied to measure the instantaneous temperature of a thin metal foil heated electrically. The foil is glued to cover a narrow slot cut in the pipe. The thermal inertia of the foil is small enough to detect the variation in the instantaneous foil temperature. The test section can be moved along the pipe and is long enough to cover a considerable part of the growing thermal boundary layer.

At the beginning of each experimental run, a steady state with a constant water flow rate and heat flux to the foil is attained and serves as the reference. The Taylor bubble is then injected into the pipe. The heat transfer coefficient variations due to the passage of a Taylor bubble propagating in a vertical pipe is measured as function of the distance of the measuring point from the bottom of the moving Taylor bubble. Thus, the results represent the local heat transfer coefficients. Multiple independent runs preformed under identical conditions allow accumulating sufficient data to calculate reliable ensemble-averaged results on the transient convective heat transfer. In order to perform this in a frame of reference moving with the bubble, the location of the bubble along the pipe has to be known at all times. Detailed description of measurements of the length and of the translational velocity of the Taylor bubbles by optical probes is presented.

Introduction

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Numerous experimental studies of convective heat transfer, using different techniques to measure the wall and/or fluid temperature in a variety of flow configurations, have been performed during the last decades. One of the factors that limits the accuracy of temperature measurements in unsteady processes is the slow response of the sensors. To record local instantaneous wall temperature, the measuring equipment has to respond fast enough, while the surface at which the temperature is recorded has to be in thermal equilibrium with the time-dependent flow. Thus, the thermal inertia of the surface has to be sufficiently small. The relevant time scales are determined by ....

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Protocol

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1. Test Section for Measurements of Instantaneous Temperature

  1. Manufacturing process of test section (Figure 2)
    1. Cut a segment of a pipe at least 70 cm long.
      Note: The diameter and wall thickness of the test section should be identical to that of the pipe used in the experimental facility.
    2. Use a milling machine to cut 4 adjacent narrow windows along the pipe in the test section, each window is 6 mm wide and 80 mm long with a 25-mm gap between consecutive windows.
    3. From a 12 µm thin stainless-steel foil, cut 40-60 cmlong and 12 mm wide strip....

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Results

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An example of the optical sensors output records is presented in Figure 4 for a single Taylor bubble rising in a vertical pipe filled with stagnant water. The initial large drop represents the opening of the circuit due to the Taylor bubble tip, while the later much shorter drops following the rise to the initial value due to the passage of the elongated bubbles tail, represent the dispersed bubbles in the liquid wake behind the Taylor bubble. The time shift .......

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Discussion

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Experimental investigation of local heat transfer in transient pipe flow is a complicated task that requires high-end measuring instruments and methods, as well as a custom-built experimental facility, in particular, a specially designed test section. The present protocol displays a thermography technique that is capable of faithfully measuring fast temporal changes in wall temperature and in heat transfer rate due to variations in flow hydrodynamics.

A detailed description of the manufacturin.......

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Acknowledgements

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This work was supported by the Israel Science Foundation, grant # 281/14.

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Materials

List of materials used in this article
NameCompanyCatalog NumberComments
Infra red cameraOptrisPI-1450
Thermocouples A/D card National InstrumentsNI cDAQ-9714.
Labview programNational Instruments
Epoxy DP-4603M Scotch-weld

References

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  1. Hetsroni, G., Rozenblit, R., Yarin, L. P. A hot-foil infrared technique for studying the temperature field of a wall. Meas. Sci. Tech. 7, 1418(1996).
  2. Babin, V. Experimental investigation of the local heat transfer in gas-liquid slug flow. , Tel-Aviv university. Israel. Ph.D. dissertation (2015).
  3. Babin, V., Shemer, L., Barnea, D. Local instantaneous heat transfer around a raising single Taylor bubble. Int. J.....

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Tags

Local Instantaneous Heat TransferConvective Heat TransferSingle Phase FlowTwo Phase FlowTaylor BubbleThermography TechniqueInfrared CameraOptical ProbesTest Section ManufacturingPipe Flow Measurement

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