Thermal Performance of MEMS-Based Heat Exchanger with Micro-Encapsulated PCM Slurry

doi:10.4236/jpee.2014.29003

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Journal of Power and Energy Engineering, 2014, 2, 15-22

Published Online September 2014 in SciRes. http://www.scirp.org/journal/jpee

http://dx.doi.org/10.4236/jpee.2014.29003

How to cite this paper: Mehravar, S. and Sabbaghi, S. (2014) Thermal Performance of MEMS-Based Heat Exchanger with

Micro-Encapsulated PCM Slurry. Journal of Power and Energy Engineering, 2, 15-22.

http://dx.doi.org/10.4236/jpee.2014.29003

Thermal Performance of MEMS-Based Heat

Exchanger with Micro-Encapsulated PCM

Slurry

Samira Mehravar, Samad Sabbaghi

Department of Nano Chemical Engin eering, Faculty of Advanced Technologies, Shiraz University, Shiraz, Iran

Email: sabbaghi@shirazu .ac.ir, s.mehravar98@gmail.c om

Received May 2014

Abstract

Latent heat thermal energy storage technique has demonstrate to be a better engineering option

mainly due to its benefit of supplying higher energy storage density in a smaller temperature dif-

ference between retrieval and storage. For this purpose, a micro electro-mechanical system,

MEMS-based heat exchanger with microencapsulated PCM (MEPCM) slurry as cold fluid, has been

simulated three dimensionally. This work investigates the influence of using MEPCM-slurry on the

temperature of the cold and hot fluids. The MEPCM and water properties have been considered

temperature dependent. MEPCM-slurry is used with different volume fractions. The result shows

that using MEPCM with 25% volume fraction leads to the improvement in fluids temperatures,

that is, for hot fluid the rate of temperature reduction increases up to 23.5% and for cold fluid the

rate of temperature rise decreases to 9%, compared to using only water in the MEMS.

Keywords

MEMS, Microchannel, MEPCM-Slurry, Latent Heat, Simulate

1. Introduction

Phase change materials (PCMs) are materials with the ability to change phase in a certain temperature range.

They absorb or release high energy during melting or solidifying. Their ability to storage high energy indicates

their high latent heat. Due to PCMs have inherent low thermal conductivity, their application in the latent heat

thermal storage (LHTS) systems has lower heat transfer rates. Different procedures have been offered for the

enhancement of PCMs thermal conductivity like dispersing nanoparticles with high thermal conductivity in

PCMs [1] and microencapsulating them. A large number of researchers have investigated the performance of

different types of heat exchangers used as latent heat thermal storage units, among which MEMS-heat ex-

changer has higher efficient for micro scales [2]. Fluids used in heat exchangers have significant influence on

cooling efficiency rate. Moreover, the fluids individual thermophysical properties are the major key for their

cooling ability.

Using encapsulated PCMs improves the performance of the heat exchanger heat storage due to their high la-

S. Mehravar, S. Sabbaghi

tent heat. At first Tuckerman and Pease [3] offered a microchannel heat exchanger for electronic cooling by us-

ing water. They demonstrated that the heat flux rate of 790 W/m2 could be dissipated in that microchannel heat

exchanger. Goel et al. [4] investigated the convective heat transfer performance of an MEPCM-slurry in volume

fraction from 0% - 20% in a circular tube. They showed that MEPCM-slurry affected by Stefan number and the

volumetric concentration considerably decreases the wall temperature rise up to 50% compared to water. Sabbah

et al. [5] studied the influence of MEPCM slurry on the microchannel heat sink. They observed that enhance-

ment of the heat transfer coefficient is significantly affected by MEPCM melting temperature, channel inlet and

outlet temperature. Yu et al. [6] examined the convective heat transfer of MEPCM with an average of 4.97 µm

at volume fraction range of 0% - 20% in rectangular minichannel. The result showed that the 5% suspension has

a better effect on cooling performance than water in lower wall temperature and improved heat transfer coeffi-

cients. In the presented work, a 3D-dimensional MEMS-heat exchanger has been designed. In this work effect of

MEPCM-slurry with octadecane core and polymethylmethacrylat shell on the thermal performance of micro-

channel has been investigated.

2. Methodology

2.1. MEMS—Heat Exchanger

Figure 1(a) shows a schematic of MEMS-heat exchanger made of Aluminum, modeled in this study. It consists

of 14 circular microchannels with 100 µm diameter. Due to the symmetry of the channel, we modeled only half

of the doubled channels as shown in Figure 1(b). The simulations are developed with water and then are re-

peated with MEPCM-slurry with volume fractions of 5%, 10%, 15%, 20% and 25%.

In order to solve this problem following assumptions are adopted: 1) fluid flow is laminar, steady state and

incompressible; 2) The viscous dissipation is ignored; 3) The thermophysical properties of water, PCM and

MEPCM-slurry are dependent on temperature; 4) External body force and gravitational body force are ignored.

The Governing Equations Are:

• Continuity equation

.0)

.( =∇ U

(1)

.wkvjuiU++=

(2)

(a)

(b)

Figure 1. (a) Geometry of the MEMS; (b) MEMS modeled.

S. Mehravar, S. Sabbaghi

• Momentum equation

()UUP gF

ρ ρτ

∇⋅=−∇++∇⋅ +

(3)

where:

: External body forces (

0F=

: The gravitational body force (

• Energy equation

()()UHK TS

∇⋅=∇⋅ ∇ +

(4)

where:

H: The carrier fluid enthalpy.

S: volumetric heat source (S = 0).

The total enthalpy (

) is described by Equation (5).

.Hh H= +∆

(5)

where:

H: sensible enthalpy.

ΔH: MEPCM latent heat.

The sensible heat is calculated by Equation (6).

ref p

ref d

h hcT

=+ ∫

(6 )

where

href: reference enthalpy.

Tref: reference temperature.

The latent heat of slurry content is calculated by Equation (7).

.HL

βφ

∆=

(7)

where:

: liquid fraction.

: NEPCM mass fraction.

L: PCM latent heat.

The mass ratio of melted PCM to the total mass of PCM is defined as the liquid fraction. The PCM melting

temperature ranges from

solidus

liquidus

. Therefore

is described by Equation (8).

solidus

0TT

if <

liquidus

1TT

if >=

liquidussolidus

solidusliquidus

solidus TTTif

TT <<

−

(8)

2.2. Numerical Method

The governing equations in the three dimensional system are solved by using CFD software Fluent. The distri-

bution of temperature and velocity are calculated by using finite volume technique with SIMPLE algorithm.

2.3. Fluids Properties

In this study, MEPCM-slurry with the core (PCM) and shell made of octadecane and polymethylmethacrylat

(PMMA) respectively is mathematically analyzed. The average diameter of ME PCM is 4.9 µm [4]. The core

material includes 70% of the MEPCM volume. The PCM latent heat is equal to 244 J/g [7]. The thermophysical

properties of octadecane and PMMA are shown in Table 1 [1] [8] [9].

The density, specific heat and thermal conductivity of microcapsules [4] are defined as Equations (9)-(11)

S. Mehravar, S. Sabbaghi

Table 1. The thermophysical properties of MEPCM.

Octadecane PMMA

Density

(kg/m)

( )

750

0.001 T319.151−+

1190

Specific heat

(J/kg∙K)

2000 1470

Thermal conductivity

(W/m∙K)

0.358 if

solidus

TT <

0.148 if

liquidus

TT >

0.21

liquidus

302 -

solidus

299 -

PCM c

PCM

10 c

ρρ



=



(9)

( )

()

pcpshc sh

pPCM csh PCM

ρρ

ρ ρρ

(10)

PCM c

PCM PCMc cshPCM c

kdkdk dd

−

= +

(11)

where

d: diameter.

c: PCM particles (core).

sh: PMMA (shell).

PCM: MEPCM particle (core + shell).

Equations (12)-(15) are used to calculate the density, specific heat [6], viscosity [4], and thermal conductivity

[10], of MEPCM-slurry.

f npw

(1 )

ρρ ρ

= +−

(12)

pf pnppw

(1) .cc c

ϕϕ

= +−

(13)

( )

2.5

1 1.16.cc

µµ

−

= −−

(14)

( )

w npnpw

fnp np

k kckk

kkk

++ −

=

+− −





(15)

where

W: water.

: volume fraction.

: mass fraction of NEPCM.

The following relation is used to measure

Equation (16).

pnp

wnp w

()

φρ ρρ

=+−

(16)

3. Results and Discussion

Simulations were carried out first with pure water, and then were repeated with MEPCM-slurry with volume

fractions of 5%, 10%, 15%, 20% and 25%. Considering that, the inlet velocity (Vin) is equals to 1 m/s and inlet

temperatures of cold and inlet fluid are 298 and 300 K respectively.

S. Mehravar, S. Sabbaghi

3.1. The Mean Temperatures of Hot and Cold Fluids

Figure 2 shows the mean temperature of cold and hot water versus channel length. Figure 3 shows the mean

temperature of hot water and MEPCM-slutty at the volume fraction of 5% versus channel length. The results

show that using MEPCM-slurry reduces the rate of temperature rise of cold flow, moreover increases the rate of

temperature reduction of hot flow compared to using only water. It can be seen that hot water temperature de-

creases without significant increasing in MEPCM-slurry temperature. In this way, it can be found that PCMs

have capability of energy storage due to its high latent heat. In addition, Sabbah et al. [5] indicated the signifi-

cant influence of the channel inlet and outlet temperature on the heat transfer coefficient in the microchannels.

The mean flow temperature is described by Equation (17).

vc TA

Tvc A

=∫

∫

(17)

where

: channel cross-sectional area (m2).

Figure 4 shows the mean temperature of hot water when MEPCM-slurry in 5%, 10%, 15%, 20% and 25% of

volume fractions is used as cold fluid. As a result the increase of the rate of the hot water temperature reduction

is observed for all MEPCM volume fractions. Figure 5 shows the mean temperature of MEPCM-slurry as cold

fluid in various volume fractions. From Results, It can be seen that MEPCM-slurry in all of its volume fractions

Figure 2. Mean temperature of cold and hot water.

Figure 3. Mean temperature of MEPCM-slurry and hot water.

S. Mehravar, S. Sabbaghi

Figure 4. Mean temperature of hot water by using MEPCM-slurry as

cold fluid in various volume fractions.

Figure 5. Mean temperature of MEPCM-slurry in various volume

fractions.

reduces the rate of temperature rise of cold fluid. To illustrate, consider the list of data in Table 2. The results

show that increasing volume fraction of MEPCM reduces the temperature of both hot and cold fluids. The best

performance of thermal storage in MEMS-heat exchanger is observed at the volume fraction of 25%. It should

be noted that MEPCM particles must be less than 25% to be considered Newtonian [11].

3.2. Inlet Velocity

Figure 6 shows the mean temperature of hot water in various inlet velocities, Vin = 0.5, 1, 1.5 and 2 m/s versus

channel length. MEPCM-slurry in 25% of volume fraction is used as cold fluid. The results show that in all inlet

velocities the rate of temperature reduction of hot water increases. Besides, it can be seen that higher inlet veloc-

ity leads to lower water temperature. Figure 7 shows the mean temperature of MEPCM-slurry at the volume

fraction of 25% and in various inlet velocities. The results show that the rate of temperature rise of MEPCM-

slurry is decrease for all inlet velocities. In addition, it can be seen that higher inlet velocity leads to lower

MEPCM-slurry temperature. As a result, inlet velocity is one of the important factors for enhancement of ther-

mal performance of MEMS-heat exchanger.

S. Mehravar, S. Sabbaghi

Table 2. List of fluids temperature.

MEPCM

volume fraction

out

(K)

hot water

out

(K)

cold fluid

0% 305.57 315.52

5% 304.52 313.15

10% 303.82 311.38

15% 303.32 310

20% 302.96 308.92

25% 302.68 308

Figure 6. Mean temperature of hot water in various inlet velocities by

using MEPCM-slurry as cold at the 25% of volume fraction.

Figure 7. Mean temperature of MEPCM-slurry at the 25% of volume

fraction in water in various inlet velocities.

4. Conclusions

• Using MEPCM-slurry instead of water reduces The MEMS temperature due to high-energy storage capabil-

ity of PCM.

S. Mehravar, S. Sabbaghi

• Increasing volume fraction of MEPCM-slutty and inlet velocity are the most important factors for the ther-

mal performance enhancement of the MEMS-heat exchanger.

• An improvement of 23.5% can be achieved by using MEPCM-slurry as cold fluid at the volume fraction of

25%, compared to using only water in MEMS-heat exchanger.

Considering the temperature dependent of fluids properties, the achieved results are accurate and more similar

to the real situation.

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