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Two-Phase Loop with Capillary Pump operational principles and characteristics,
Two-phase flows:

Index

HEDH
A B C D E F G H I J K L M N O P Q R S T
Taborek, J, xlv-lvi Taitel and Dukler flow regime map, for horizontal and inclined gas- liquid flows, Tamura et al correlation, for surface tension of mixtures, Taylor Forge method, for mechanical design of flanges, comparison with EN13445 method, Taylor series expansion, Teflon, use in heat transfer enhancement: TEMA (Tubular Exchanger Manufacturers Association): Temperature distribution: Tenders for heat exchangers, Terminal free fall velocity, in fluidization, Testing and inspection of heat exchangers: Tetrabromomethane: 1,1,2,2-Tetrachloroethane: Tetrachloroethylene: Tetradecane: Tetradecene: Tetrachlorodifluoroethane (Refrigerant 112): 1,1,1,2-Tetrafluoroethane (Refrigerant R134a): Tetrafluoromethane (Refrigerant 14): Tetrahydrofuran: 1,2,3,4-Tetramethylbenzene: 1,2,3,5-Tetramethylbenzene: 1,2,4,5-Tetramethylbenzene: Thermal conductivity: Thermal contact conductance (TCC), Thermal contact resistance (TCR), Thermal design, constructional features affecting, in shell-and-tube heat exchangers Thermal diffusivity: Thermal expansion coefficient: Thermal leakage in F-type shell-and-tube heat exchangers, Thermal mixing in plate heat exchangers, Thermal stress: Thermocal, heat transfer media, Thermodynamic cycles in refrigeration, Thermodynamic properties: Thermodynamic surface in radiative heat transfer, Thermoexel surface, for enhancement of boiling, Thermofluids, heat transfer medium, Thermosiphon Theta-NTU method: Thickness of boundary layers (displacement, momentum, energy, density, temperature), Thin-wall-type expansion bellows, Thiophene: Thome, J R Three-phase flows: Tie rods in shell-and-tube heat exchangers, Tinker method for shell-side heat transfer in shell-and-tube heat exchangers, Titanium and titanium alloys, T-junctions, loss coefficients in, Tolerances Toluene: m-Toluidine: Tong F-factor method, for critical heat flux with nonuniform heating, Tooth, A S, Total emissivity in gases, Transcendental equations in transient conduction, Transient behavior: Transition boiling: Transition flow, heat transfer in free convective flow over vertical surfaces in, Transitional flow, in combined free and forced convection, Transmission of thermal radiation in solids: Transmissivity of solids: Transport properties: Transverse flow, combined free and forced convection in, Treated surfaces, for augmentation of heat transfer, Triangular duct: Triangular fins, in plate fin exchangers, Triangular relationship, in annular gas-liquid flow, Tribromomethane: 1,1,1-Trichloroethane (Refrigerant 140a): Trichloroethylene: Trichlorofluoromethane (Refrigerant 11) Trichloromethane (Chloroform) (Refrigerant 20): 1,1,2-Trichlorotrifluoroethane (Refrigerant 113): Tridecane: Tridecene: Triethylamine: 1,1,1-Trifluoroethane (Refrigerant 143a): Trifluoromethane (Refrigerant 23): Trimethylamine: 1,2,3-Trimethylbenzene: 1,2,4-Trimethylbenzene: 1,3,5-Trimethylbenzene: 2,2,4-Trimethylpentane (Isooctane): Triphenylmethane: Triple interface (gas/solid/liquid), True temperature difference, in double pipe exchangers, Truelove, J S, Tsotsas, E Tube-baffle damage, in heat exchangers, Tube banks, finned: Tube banks, plain: Tube banks, roughened tubes, effect of roughness on Euler number in, Tube bundles: Tube counts, in shell-and-tube heat exchangers: Tube end attachment, in shell-and-tube heat exchangers, Tube inserts, heat exchangers with, Tube-in-plate extended surface configurations, fin efficiency of, Tube plates, in shell-and-tube heat exchangers: Tube rupture in shell-and-tube heat exchangers, Tube-to-tubesheet attachment, in shell-and-tube heat exchangers, Tubes: Tucker, R J, Tunnel dryer, Turbine exhaust condensers: Turbines, lost work in Turbulence: Turbulent boundary layers: Turbulent buffeting, as source of tube vibration, Turbulent energy, integral equation for, Turbulent flow: Turnarounds, in heat exchangers, Turner, C W, Twisted tapes: Twisted tube heat exchangers, Twisted tubes Two-equation models, for turbulent boundary layers, Two-phase loop with capillary pump,
Two-Phase Loop with Capillary Pump operational principles and characteristics,
Two-phase flows:
U V W X Y Z
T Two-phase loop with capillary pump,
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Two-Phase Loop with Capillary Pump

DOI 10.1615/hedhme.a.000318

3.10.9 Two-phase loop with capillary pump

Leonid L. Vasiliev, Donatas Mishkinis

A. Introduction

The Two-Phase Loop with Capillary Pump (Figure 1) is a passive heat transfer device and is a form of heat pipe. Phase change take place in the regions of heat input (evaporation) and heat rejection (condensation). Thermal energy is transferred in latent form by vapor and condensed liquid is returned back by action of capillary forces (a unique characteristic of a heat pipe). The distinguishing characteristics of the Two Phase Loop with Capillary Pump are the placement of a capillary structure only in the evaporator and the presence of separated channels for vapor and liquid. There are no counter flows of vapor and liquid as in the classical heat pipes but only unidirectional flows in a closed loop. The separation of the vapor and liquid flows allows a significant reduction of the viscous pressure losses in the shielded (adiabatic) section (smooth wall tubing is usually used as the channels), and the elimination of entrainment of liquid by vapor, in comparison with classical heat pipes. The placement of the capillary pump in the evaporator allows the use of micron-size porous structures, which are capable of developing a very high capillary head. Sintered metal powder capillary pumps manufactured in the Institute of Thermal Physics (Ekaterinburg, Russia) are shown on Figure 2. The normal effective pore radii of such capillary pumps for Two Phase Loops are in the range 0.520 microns.

Figure 1 Functional schematic of two-phase loops with capillary pump

Figure 2 Sintered metal capillary pumps for Two-Phase Loops

The heat transfer in the evaporator can be organized in two ways: (1) the traditional way, where liquid evaporates from outer wick surface (Philips and Grove, 2003) (Figure 1a) and (2) by evaporation from an "inverted meniscus" where heat and mass flows in the wick have opposite directions (Figure 1b and c). The second approach is used in the great majority of the evaporators in todays Two-Phase Loops with Capillary Pumps. The phenomenon of "inverted meniscus" evaporation was considered in detail by Philips and Grove (2003) and Khrustalev and Faghri (1996). To reduce the wick hydraulic resistance (to minimize the flow path of the of liquid in the porous structure) a central core is usually inserted into the capillary pump (Figure 1c). However, an evaporator without a central core (Figure 1b) also has certain advantages such as preventing undesirable boiling in the wick body and the possibility to design compact flat evaporators for high-pressure working fluids (Philips and Grove, 2003). Due to their specific features, Two-Phase Loops with Capillary Pumps are more flexible and can transfer much higher heat fluxes over much longer distances than classical heat pipes. The Loops are capable of effective operation against gravity (up to several meters) or other body forces [one of the first names for such devices was "anti-gravitational heat pipe" (Philips and Grove, 2003)]. Because the heat pipe is a precursor and close cousin of the Two-Phase Loop with Capillary Pump it is logical to call this class of devices "heat loops" for consistency (Philips and Grove, 2003).

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