Analysis of a Phase Change Energy Storage System for Pulsed Power Dissipation

Krishnan, Shankar; Garimella, Suresh V.

doi:10.1109/tcapt.2004.825758

Cited by 86 publications

(20 citation statements)

References 25 publications

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“…15,[23][24][25] Here, we show that they may also have unique benefits when applied to electrode designs for electroporation-based therapies. Specifically, electrodes containing a salt hydrate that transitions from solid-to-liquid during treatment can reduce the peak tissue temperature.…”

Section: 11mentioning

confidence: 76%

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Towards the development of latent heat storage electrodes for electroporation-based therapies

et al. 2012

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Section: 11mentioning

confidence: 76%

“…Similarly, the term P is a normalized pulse around the transition temperature defined by @(flc2hs((T-T T ), R T ))/@T. Smoothing is required for the solver to handle step changes. 15,16 In the PCM domain, the temperature, T, distribution was solved using a modified heat conduction equation, which includes Joule heating, Q J , due to the application of PEFs…”

mentioning

confidence: 99%

Towards the development of latent heat storage electrodes for electroporation-based therapies

et al. 2012

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“…As time progresses, buoyancy Table 5 Geometrical parameters [24][25][26]. Table 4 Thermo physical properties of PCM, wall and heat sources [20][21][22][23]. and directly contributes to the melting of the solid and hence more cooling of the bottom heat source occurs.…”

Section: Streamlines and Isotherms Plotsmentioning

confidence: 99%

Numerical study of melting in an enclosure with discrete protruding heat sources

Faraji

Qarnia

2010

Applied Mathematical Modelling

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a b s t r a c tIn order to explore the capability of a solid-liquid phase change material (PCM) for cooling electronic or heat storage applications, melting of a PCM in a vertical rectangular enclosure was studied. Three protruding generating heat sources are attached on one of the vertical walls of the enclosure, and generating heat at a constant and uniform volumetric rate. The horizontal walls are adiabatic. The power generated in heat sources is dissipated in PCM (neicosane with the melting temperature, T m = 36°C) that filled the rectangular enclosure. The advantage of using PCM is that it is able to absorb high amount of heat generated by heat sources due to its relatively high energy density. To investigate the thermal behaviour and thermal performance of the proposed system, a mathematical model based on the mass, momentum and energy conservation equations was developed. The governing equations are next discretised using a control volume approach in a staggered mesh and a pressure correction equation method is employed for the pressure-velocity coupling. The PCM energy equation is solved using the enthalpy method. The solid regions (wall and heat sources) are treated as fluid regions with infinite viscosity and the thermal coupling between solid and fluid regions is taken into account using the harmonic mean of the thermal conductivity method. The dimensionless independent parameters that govern the thermal behaviour of the system were next identified. After validating the proposed mathematical model against experimental data, a numerical investigation was next conducted in order to examine the thermal behaviour of the system by analyzing the flow structure and the heat transfer during the melting process, for a given values of governing parameters.

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“…Use of a PCM energy storage unit as an alternative to the copper heat sinks has the potential to lower junction temperatures, while at the same time yielding weight and volume savings. Since the thermal transients in these applications last only for short periods, the PCM has a chance to recharge (solidify) between pulses [57]. Fig.…”

Section: Phase Change Energy Storagementioning

confidence: 99%