Fluid Flow in Axial Reentrant Grooves with Application to Heat Pipes

Thomas, Scott K.; Damle, Vikrant C.

doi:10.2514/1.10711

Cited by 21 publications

(7 citation statements)

References 13 publications

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“…The friction between liquid and substrate is described in Eq. (7) with no concern about the friction between liquid and vapor. The differential form of liquid velocity and radius of meniscus can be obtained from the Eqs.…”

Section: B Working Principle Of the Mhpmentioning

confidence: 99%

“…1b and 1c. Besides those different designs of cross section of MHP, several different grooves were also proposed and fabricated with metal material as substrate, such as OMEGA groove [7,8] and swallow tailed groove [9], which can enhance the thermal performance of heat pipe. Unfortunately, it seems impossible to apply in our silicon-based MHP due to the difficulties of fabrication processes.…”

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confidence: 99%

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Investigation on Microheat Pipe Array with Arteries

Kang

Liu

et al. 2010

Journal of Thermophysics and Heat Transfer

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A novel design of microheat pipe array with arteries that can limit the onset of the dryout region is proposed. Additional pipes are inserted between adjacent microheat pipes to improve liquid transportation ability from the condenser section to the evaporator section. These additional pipes have smaller cross-sectional dimensions than the microheat pipe and serve as an artery of the microheat pipe. Because of the liquid pressure difference in the meniscuses between the two ends of the microheat pipe, an additional amount of working liquid can be effectively transported to the evaporator section through these arteries, which definitely improves the performance of the microheat pipe. The working principle and optimal design of the arteries are numerically investigated with a onedimensional steady-state model of the artery microheat pipe array. To verify the idea, a silicon-based artery microheat pipe array and traditional microheat pipe sample with the same dimensional parameters are fabricated by lithographic technique and anodic bonding process. The validation has been carried out by the comparison observation experiments of the novel microheat pipe and the traditional microheat pipe through a microscopic camera. Both the model's numerical solution and the observation results indicate that the artery microheat pipe array can effectively extend thermal working range.Nomenclature A = liquid area in the V-groove of the microheat pipe, m 2 A 0 = area of the cross section, m 2 A 0 L = liquid area in the cross section at the cold end (x 1), m 2 a A = width of the artery, m a = width of the microheat pipe, m B 1 = constant in expression for A 1 B 2 = constant in expression for dR =dx c = constant in expression for a 1 =a f = friction factor g = acceleration due to gravity, m=s 2 K 0 = constant in expression for w L = length of heat pipe, m L h = half of total wetted length, m P = liquid pressure, N=m 2 P = nondimensional liquid pressure P R = reference pressure, N=m 2 Q = heat supplied to the liquid, W=m 2 R = radius of meniscus curvature in the V-grooves of the microheat pipe, m R 0 = radius of meniscus curvature in the V-grooves of the microheat pipe at x 0, m R L = radius of meniscus curvature in the V-grooves of the microheat pipe at x L, m R R = reference radius of meniscus curvature, m V = axial liquid velocity, m=s V A = liquid velocity in the artery, m=s V = nondimensional liquid velocity V R = reference liquid velocity, m=s x = coordinate along the heat pipe, m x = nondimensional coordinate along microheat pipe = half apex angle of V-groove, rad = inclination of substrate with horizontal, rad = contact angle, rad = correction coefficient = fill charge = latent heat of vaporization of coolant liquid, J=kg = viscosity of coolant liquid, kg=ms = density of coolant liquid, kg=m 3 = surface tension of coolant liquid, N=m wA = shear stress between liquid and substrate of the artery, N=m 2 w = shear stress between liquid and substrate of the microheat pipe, N=m 2 = curvature, m 1

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Section: B Working Principle Of the Mhpmentioning

confidence: 99%

mentioning

confidence: 99%

Investigation on Microheat Pipe Array with Arteries

Kang

Liu

et al. 2010

Journal of Thermophysics and Heat Transfer

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“…This causes the liquid fill amount inside the liquid channel to be so critical that a small decrease in liquid fill may result in a significant decrease in the capillary pumping pressure and, hence, a significant decrease in the maximum heat transport capacity. Heat pipe with axial "X"-shaped groove has been introduced as an attractive option for a wide variety of advanced electronic devices, such as in the spacecraft thermal control system and microelectronic cooling system, due to the high efficiency heat transfer capability, stable operation under microgravity conditions and the high degree of temperature uniformity [18][19][20]. As an optimum choice of high capacity heat pipe with axial grooves in the frame provided by the European Space Agency [21], heat pipe with axial "X"-shaped grooves combines a high capillary pumping pressure with a low axial pressure drop in the return liquid, whose cross-sectional structure is shown in Fig.…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, the liquid viscous pressure drop is minimal because the liquid flows through a channel with a much larger cross-sectional area compared with that of traditional groove geometries. The circumferential grooves in the vapor channel not only provide an effective liquid distribution but also maximize the heat transfer area for the evaporation of liquid in the evaporator section [3,5,[12][13][14][15][16][17][18]. At present, among all the groove geometries, heat pipe with axial monogroove has the largest heat transport capability with high heat transfer coefficient.…”

Section: Introductionmentioning

confidence: 99%

Evaporative Heat Transfer Analysis of a Heat Pipe With Hybrid Axial Groove

Bai¹,

Lin

Peterson

2013

Journal of Heat Transfer

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Through the application of thin film evaporation theory and the fundamental operating principles of heat pipes, a hybrid axial groove has been developed that can greatly enhance the performance characteristics of conventional heat pipes. This hybrid axial groove is composed of a V-shaped channel connected with a circular channel through a very narrow longitudinal slot. During the operation, the V-shaped channel can provide high capillary pressure to drive the fluid flow and still maintain a large evaporative heat transfer coefficient. The large circular channel serves as the main path for the condensate return from the condenser to the evaporator and results in a very low flow resistance. The combination of a high evaporative heat transfer coefficient and a low flow resistance results in considerable enhancement in the heat transport capability of conventional heat pipes. In the present work, a detailed mathematical model for the evaporative heat transfer of a single groove has been established based on the conservation principles for mass, momentum and energy, and the modeling results quantitatively verify that this particular configuration has an enhanced evaporative heat transfer performance compared with that of conventional rectangular groove, due to the considerable reduction in the liquid film thickness and a corresponding increase in the evaporative heat transfer area in both the evaporating liquid film region and the meniscus region.

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“…As such, this dynamic contact angle could be any value. Certain authors have given a range of 0 to 40 degrees [39]. Other authors have noted that the dynamic contact angle is an unknown that, with internal surface contamination, could be in excess of 45 degrees [6].…”

Section: Improved Model Resultsmentioning

confidence: 99%

An experimental and numerical investigation of capillary limit in an arterial heat pipe

Siddiqui¹

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Fluid Flow in Axial Reentrant Grooves with Application to Heat Pipes

Cited by 21 publications

References 13 publications

Investigation on Microheat Pipe Array with Arteries

Investigation on Microheat Pipe Array with Arteries

Evaporative Heat Transfer Analysis of a Heat Pipe With Hybrid Axial Groove

An experimental and numerical investigation of capillary limit in an arterial heat pipe

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