Peristaltic flow of a realistic fluid in a compliant channel

Peristaltic flow of a realistic fluid in a compliant channel

Journal Pre-proof Peristaltic flow of a realistic fluid in a compliant channel Maryiam Javed, R. Naz PII: DOI: Reference: S0378-4371(19)32162-4 http...
Download PDF
909KB Sizes 0 Downloads 85 Views
Report

Journal Pre-proof Peristaltic flow of a realistic fluid in a compliant channel Maryiam Javed, R. Naz

PII: DOI: Reference:

S0378-4371(19)32162-4 https://doi.org/10.1016/j.physa.2019.123895 PHYSA 123895

To appear in:

Physica A

Received date : 23 May 2019 Revised date : 6 November 2019 Please cite this article as: M. Javed and R. Naz, Peristaltic flow of a realistic fluid in a compliant channel, Physica A (2020), doi: https://doi.org/10.1016/j.physa.2019.123895. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

© 2019 Published by Elsevier B.V.

Journal Pre-proof *Highlights (for review)

Jo

urn

al

Pr e-

p ro

of

Highlights:  Peristaltic transport of a Jeffrey fluid model has been discussed in an asymmetric channel with compliant walls.  Small amplitude assumption is taken into account to solve the required boundary value problem.  The possibility of flow reversal increases in the narrow part of the channel and increases in the wider part of the channel.

Journal Pre-proof *Manuscript Click here to view linked References

Peristaltic flow of a realistic fluid in a compliant channel

of

Maryiam Javed and R. Naz Department of Applied Mathematics and Statistics,

p ro

Institute of Space Technology 2750 Islamabad-44000, Pakistan

Abstract: Goal of the present analysis is to explore the elastic wall effect on the peri-

Pr e-

staltic flow in an asymmetric channel. Formulation of the flow problem is based upon the constitutive equation of a Jeffrey fluid. Resulting problem is solved for a stream function and the peristaltic mean flow. The salient features of involved key parameters are also discussed. Keywords: Asymmetric channel, Jeffrey fluid, compliant walls. Nomenclature Main author Tel.: + 92-51-9075585

al

0∗

Jo

urn

E-mail address: [email protected]

Journal Pre-proof

Symbol

Description

SI Units

Symbol

Description

e V

velocity;

m/sec

t

time;

m/sec

x

velocity components in x,

of

u, v

y-directions, respectively;

a1

N/m2

extra stress tensor;

amplitude of the wave along

a2

m

amplitude of the wave along

y

the channel walls;

spatial coordinate nor

the channel walls; ρ

fluid density;

m

δ

dimensionless wave num

m

c

wave speed;

m

k

spring stiffness coefficie

Pr e-

the upper channel wall;

p ro

S

spatial coordinate alo

the lower channel wall; η1

vertical displacement corresponding to the upper wall;

vertical displacement corresponding

al

η2

to the lower wall; phase difference;

radians

p

pressure;

d

coefficient of viscous damping;

Kg/m2 sec

d1

upper half channel wid

¯ B

flexural rigidity of the plate;

Kg m2 /sec2

d2

lower half channel widt

T

elastic tension in the membrane;

Kg/sec2

m

plate mass per unit are

relaxation time

sec−1

λ2

retardation time

wavelength

m

Ψ

stream function.

λ

1

Jo

λ1

urn

θ

Introduction

It is known that physical activity of peristaltic transport is nature’s way of moving the contents by repeated contractions of muscular fibers. It is an essential property of several

Journal Pre-proof

biomedical and engineering systems. In physiology, it appears in transport of urine towards bladder from kidney, chyme motion in the gastrointestinal tract, motion of small blood ves-

of

sels, ovum movement in the female fallopian tube, transport of male reproductive tract and in many glandular ducts. Engineers have used the peristaltic activity in pumping technol-

p ro

ogy that has numerous industrial applications. Particularly, roller and finger pumps operate under this principle. Besides this the peristalsis has been used for sanitary fluid transport of corrosive fluids when the contact of the fluid is prohibited with the parts of machinery.

Pr e-

After the pioneering work of Latham [1], the peristaltic mechanism has been widely studied via theoretical and experimental approaches. Mitra and Prasad [3] extended Fung and Yih [2] model and considered the two-dimensional analysis of peristaltic motion with flexible (elastic or viscoelastic) wall. Much attention has been given to the development of mathematical models for peristaltic transport in a two-dimensional infinitely long axisymmetric

al

tubes or symmetric channel containing hydrodynamic/magnetohydrodynamic viscous and non-Newtonian fluids. Few recent attempts in this direction are made by the investigators

urn

in the studies [4 − 22].

It has been recently observed by the physiologists that in view of myometrial contractions, the intrauterine fluid flow represents a peristaltic mechanism. By De Varies et al. [23], these

Jo

contractions occur in both asymmetric and symmetric directions. During the poliferative and the menstruation phase, the myometrial activity is symmetric but asymmetric contractions are seen when embryo goes into the uterus for implementation. With these facts in mind, some authors [24 − 30] discussed the peristaltic phenomena of viscous and non-Newtonian fluids in an asymmetric channel. Consideration of wall properties in peristalsis is of special value in study of blood flow in arteries and veins, urine flow in the urethras and air flow in the lungs. However no investigation is presented yet for the peristaltic transport of a

Journal Pre-proof

non-Newtonian fluid in an asymmetric compliant wall channel. The main purpose of present study is to examine such analysis for a Jeffrey fluid. Hence, we introduce the model by

of

analyzing the governing equations and related boundary conditions in Section 2. Section 3 derives the perturbation solution for small amplitude ratio. Graphical discussion is stated in

2

Problem development

p ro

Section 4. Section 5 includes the final remarks.

Pr e-

An incompressible Jeffrey fluid is considered in a channel having width d¯1 + d¯2 . The asymmetry is induced by considering peristaltic waves with different phases and amplitudes on the channel walls. Further, the channel walls are of elastic nature. We consider a Cartesian coordinate system in such a manner that x-axis is along the centre line and y-axis is taken

Jo

urn

al

normal to it.

Fig. 1: Coordinate Geometry of the physical model of the problem.

The equations governing the flow are e div V=0,

ρ

e dV = −∇e p + div S, dt

(1) (2)

Journal Pre-proof

e denotes the velocity field, ρ denotes the density, d/dt defines the material derivawhere V

tive and pe is the pressure. For Jeffrey fluid, the extra stress tensor S is ∂ 1 + λ1 ∂t



  ∂ ¯ S=µ 1 + λ2 A1 , ∂t

of



(3)

p ro

in which t is the time, µ defines the dynamic viscosity, λ1 is the relaxation time, λ2 is the ¯ 1. retardation time and the first Rivlin-Erickson tensor is A Invoking Eqs. (1) and (3) into Eq. (2) we obtain 

Pr e-

    ∂ ∂ u¯ 1 ∂ ∂e p ∂ u¯ ∂ u¯ 1 + λ1 u¯ =− 1 + λ1 + v¯ + ∂t ∂x ∂y ∂t ρ ∂t ∂x   ∂ +ν 1 + λ2 ∇2 u, ∂t     ∂¯ v 1 ∂ ∂e p ∂¯ v ∂¯ v ∂ u¯ =− 1 + λ1 + v¯ + 1 + λ1 ∂t ∂x ∂y ∂t ρ ∂t ∂y   ∂ +ν 1 + λ2 ∇2 v, ∂t

(5)

al



(4)

where ν (= µ/ρ) is the viscosity.

urn

Defining the stream function as u¯ =

∂Ψ , ∂y

v¯ = −

∂Ψ ∂x

(6)

equation

Jo

and using it in Eqs. (4) and (5) we obtained, after removing the pressure the following



∂ 1 + λ1 ∂t



   ∂ 2 ∂ 2 2 ∇2 ∇2 Ψ, ∇ Ψ + Ψ y ∇ Ψ x − Ψ x ∇ Ψ y = ν 1 + λ2 ∂t ∂t

(7)

in which ∇2 represents the Laplacian and subscripts shows partial differentiation. The condition of incompressibility (1) is satisfied automatically. The compliant wall is modeled such that it is restricted to move in the vertical direction. Let η1 and η 2 represents the vertical displacements related to the upper and lower walls.

Journal Pre-proof

Furthermore, η 1 and η 2 are taken in the form as 2π η 1 = a1 cos (x − ct) , λ

  2π η 2 = a2 cos θ + (x − ct) . λ

(8)

of

In above equation a1 and a2 show the amplitude of the waves, c is the speed of wave, λ is

p ro

the wavelength, θ shows the phase difference that varies in range 0 ≤ θ ≤ π. Further, θ = 0 corresponds to symmetric channel case with waves out of phase and θ = π in phase. Also a1 , 2 a2 , θ, d¯1 , and d¯2 satisfies 2a1 a2 cos θ + a21 + a22 ≤ d¯1 + d¯2 .

Pr e-

The compliant wall equation can be written as [16]:        η1   4 2 2 ∂ ∂ ∂ ∂ ¯ B − T + m + d + K = pe − pe0 ,   ∂x4 ∂x2 ∂t2 ∂t    η2 

(9)

¯ is the flexural rigidity of plate, m is the mass of plate per unit area, K shows the where B spring stiffness, d is the coefficient of damping, T shows the tension and pe0 is the outside

al

surface pressure of the wall. Taking the walls of the channel inextensible and pe0 = 0. The

urn

displacement along horizontal axis is taken zero. The relevant conditions are        d¯1 + η 1  . Ψy = 0 at y =      −d¯2 − η2 

(10)

Continuity of the stresses requires that at the interfaces of the walls and fluid pe should be

Jo

the same as it is acting on the fluid at the boundaries. Using Eq. (4) we get             4 2 2 η 1 ∂ ¯ ∂ ∂ ∂ ∂ ∂ B 4 −T 2 +m 2 +d +K 1 + λ1   ∂t ∂x ∂x ∂x ∂t ∂t   η2         ∂ ∂ 2 = ρ ν 1 + λ2 ∇ Ψ y − 1 + λ1 (Ψyt + Ψy Ψyx − Ψx Ψyy ) . ∂t ∂t Introducing

(11)

Journal Pre-proof

x ct u¯ v¯ pe y , xˆ = , tˆ = , b u¯ = , b v¯ = , b pe = 2 , d1 d1 d1 c c ρc ¯ B η ˆ Ψ m ˆ dd1 b¯ ηˆ = , Ψ = ,m ˆ = ,d= ,B= , d1 cd1 ρd1 ρν ρd1 ν 2 T d1 ˆ Kd31 ˆ c ˆ 2 = c λ2 , Tˆ = , K = , λ1 = λ1 , λ 2 2 ρν ρν d1 d1

of

yˆ =

and removing the hats we obtain ∂ 1 + λ1 ∂t



   ∂ ∂ 2 1 2 2 1 + λ2 ∇2 ∇2 Ψ, ∇ Ψ + Ψy ∇ Ψx − Ψx ∇ Ψy = ∂t R ∂t

p ro



(12)

Pr e-

η1 = ǫ cos α (−t + x) , η 2 = aǫcos [α (−t + x) + θ] ,        −η 2 − h  Ψy = 0 at y = ,      η1 + 1 

      K  η1 

urn

al

  ¯ 4  ∂ B ∂2 d ∂ T ∂2 ∂ ∂ + m + − + 1 + λ1  ∂t ∂x R2 ∂x4 ∂t2 R ∂t R2 ∂x2 R2    η2            Ψ +Ψ Ψ  1 + η1  yt y yx  ∂ ∂ 1 2  at y =  1 + λ2 ∇ Ψ y − 1 + λ1 =   R ∂t ∂t    −h − η2 −Ψx Ψyy

(13) (14)

(15)       

,

where h = d2 /d1 , ǫ = a1 /d1 , a = a2 /a1 , α = 2πd1 /λ represents the wave number and

3

Jo

R = cd1 /ν represents the Reynolds number.

Problem solution

We obtain the solution for the stream function as a power series in terms of the small parameter ǫ, by expanding Ψ and

∂ pe ∂x

in the form (see Fung and Yih [2])

Ψ = Ψ0 + ǫΨ1 + ǫ2 Ψ2 + ...,  2  1  0 ∂e p ∂e p ∂e p ∂e p 2 +ǫ +ǫ + ..., = ∂x ∂x ∂x ∂x

(16) (17)

Journal Pre-proof

where the first term on the R. H. S in Eq. (17) represents the imposed pressure gradient and the remaining terms represents the peristaltic motion.

of

The ǫ0 set of differential equations subject to steady parallel flow and assumption of transverse symmetry corresponds to

(18)

p ro

  (h − 1) 2 y 3 Ψ0 (y) = K0 hy − + C, y − 2 3  0 R de p K0 = − , 2 dx where C is a constant.

Pr e-

In order to solve second and third sets of differential equations in Ψ1 and Ψ2 we express

  eiα(x−t) e−iα(x−t) ∗ Ψ1 (x, y, t) = Φ1 (y) , + Φ1 (y) 2 2   e−2iα(x−t) e2iα(x−t) Φ20 (y) ∗ . + Φ22 (y) + Φ22 (y) Ψ2 (x, y, t) = 2 2 2

(19) (20)

al

In above equations the asterisk represents the complex conjugate. Invoking above mentioned expressions into the differential equations and the relevant boundary conditions, we have three

urn

sets of coupled differential equations in linear form with their related boundary conditions. (∂p/∂x)0 = 0 in case of free pumping i.e. K0 = 0 and hence we have 

Jo

d2 − α2 + iαR dy 2       −h   ′ Φ1 = 0,     1  

Φ′′′ 1

=



      −h       1  

1 − λ1 iα 1 − λ2 iα

−α

      

2

Φ′1



1 − λ1 iα 1 − λ2 iα

 

 d2 2 − α Φ1 (y) = 0, dy 2

(21)

(22)       −h  

    1      aeiθ  Rδ,   1 

+ iαR



1 − λ1 iα 1 − λ2 iα



Φ′1

      −h       1   (23)

Journal Pre-proof

 iα 2 2 4 2 α R m + iαRd − α B − α T − K , R2 iαR ′ ∗ ′′ Φ′′′′ [Φ1 (y) Φ∗′′ 20 (y) = − 1 (y) − Φ1 (y) Φ1 (y)] ,  2                             −h  1  aeiθ   −h  1  ae−iθ   −h   ′ ∗′′ ′′ ∓ Φ20 Φ Φ ∓ = 0,   2     1   1  2    1    1   1   1   1                               −h    −h    −h     −h  −h    iαR ∗′′ ∗ ′′ ′′′  Φ Φ − Φ Φ Φ20 =− 1 1  1     1   2        1    1    1     1  1                     iθ       −h −h ae  1 ∗′′′′ ∗′′   ± − α (α + iR) Φ1 Φ1       2        1   1   1               −iθ     −h    −h    1  ae ′′ Φ′′′′ , ± (±1) − α (α − iR) Φ 1  1       2     1   1    1   

Pr e-

p ro

of

δ=−

   

    1

urn

   1 1

al

  2   d 1 − 2λ1 iα d2 2 2 − 4α + 2iαR − 4α Φ22 (y) dy 2 1 − 2λ2 iα dy 2   iαR 1 − 2λ1 iα [Φ′1 (y) Φ′′1 (y) − Φ1 (y) Φ′′′ = 1 (y)] , 2 1 − 2λ2 iα 

Φ′22 (±1) = ∓

   

(24)

(25)         

(26)

(27)

Jo

Φ′′1 , (28)    2      aeiθ   −h                         1   1    1  1 − 2λ iα 1 − 2λ iα 1 1 ′ ′2 ′′′ + iαR Φ22 Φ1 = 4α 2α − iR 2Φ22       1 − 2λ2 iα 1 − 2λ2 iα        −h   −h   −h                       1   1       1   1    1 − 2λ1 iα Φ′′′′ −iαR Φ1 Φ′′1 ∓       1   1 − 2λ2 iα    −h   −h       aeiθ   −h           1    1 − 2λ1 iα ′′ Φ1 . (29) −α (α − iR)   1 − 2λ2 iα   −h  

Here prime shows the derivative w.r.t. y.

Journal Pre-proof

The solution of Eqs. (21)-(23) is (30)

of

e1 sinh yα + L e2 cosh yα + L e3 sinh yβ + L e4 cosh yβ, Φ1 (y) = L "

Pr e-

p ro

# e2 α sinh α + L e3 β cosh β + L e4 β sinh β L e1 = − L , α cosh α ! e3 + N5 N9 L3 e σRδ N e2 = − L , e1 N e5 N   e1 N8 − N e3 N6 − aeiθ N e1 N5 σRδ N e3 =   , L e e e N5 N6 N9 − N1 N10   e2 N e1 + L e3 N2 L e4 = L , e3 N   1 − λ1 iα 2 2 β = α − iαRσ, σ = 1 − λ2 iα

N7

N8



 sinh α cosh αh + sinh αh cosh α = −iα Rσ , cosh α " #  β 2 − α2 + iαRσ cosh α cosh βh − iαRσ cosh αh cosh β = β , cosh α # "  β 2 − α2 + iαRσ cosh α sinh βh + iαRσ cosh αh sinh β , = −β cosh α 2

Jo

N6

urn

al

  sinh α cosh hα + cosh α sinh hα e , N1 = α cosh α   cosh β cosh hα − cosh α cosh hβ N2 = β , cosh α   e3 = β cosh α sinh hβ + sinh β cosh hα , N cosh α   e5 = β β 2 − α2 sinh β, N4 = β β 2 − α2 cosh β, N

The solution of Eqs. (24)-(26) can be written as Φ′20 (y) = Fe (y) + e g (y) + c1 y 2 + c2 y + c3 .

(31)

Journal Pre-proof

The peristaltic mean flow is given by ǫ2 ′ Φ (y) 2 20  ǫ2  e = F (y) + e g (y) + c1 y 2 + c2 y + c3 . 2

of

u¯ (y) =

Fe (y) = −

   2 2 e3 L e∗ + L e∗ L e4  L α − β 1 2 iαR

p ro

In expressions (31) and (32) we have

(32)

Pr e-

cosh (α + β) y 4  (α + β)2    ∗  2 ∗2 2 ∗e 2 ∗ ∗ e e e e e e e α −β L1 L3 − L2 L4 β −α L2 L4 + L1 L3 − cosh y (α − β) + cosh y (α + β ∗ ) 2 2 ∗ (−β + α) (β + α)      ∗2 2 e1 L e∗ − L e2 L e∗ e3 L e∗ + L e4 L e∗ β ∗2 − α2 L L β − β 3 4 3 4 ∗ − cosh y (α − β ) + cosh y (β + β ∗ ) 2 2 ∗ ∗ (α − β ) (β + β)     e3 L e∗ − L e4 L e∗  β ∗2 − β 2 L 3 4 ∗ cosh y (β − β ) , −  (β − β ∗ )2

al

g (y) = − e

   ∗ 2 2 e1 L e4 + L e3 L e∗2  L α − β iαR

Jo

urn

sinh (α + β) y 4  (α + β)2    ∗  2 ∗2 ∗ 2 2 ∗ ∗ e e e e e e e e L1 L4 − L3 L2 α −β β −α L2 L3 + L1 L4 − sinh (α − β) y + sinh (α + β ∗ ) y 2 2 ∗ (β − α) (β + α)      ∗2 2 e1 L e∗ − L e2 L e∗ e3 L e∗ + L e∗ L e4 β ∗2 − α2 L L β − β 4 3 4 3 + sinh (α − β ∗ ) y + sinh (β + β ∗ ) y ∗ 2 ∗ 2 (α − β ) (β + β )     e3 L e∗4 − L e∗3 L e4  β ∗2 − β 2 L ∗ sinh (β − β ) y , +  (β − β ∗ )2 c1 = c2 = c3 =

1 (D3 − s) , 2    2 −Fe (1) + D1 − 2 −Fe (−h) + D2 + 2e g (−h) − 2e g (1) − (−h2 + 1) (−s + D3 )

2 (h + 1)     e e 2 −F (1) + D1 h + 2 D2 − F (−h) − 2e g (−h) − 2he g (1) − h (h + 1) (−s + D3 ) 2 (h + 1)

, ,

Journal Pre-proof

α2  (L1 + L∗1 ) sinh α + α2 (L2 + L∗2 ) cosh α + β 2 L3 sinh β 2  +β ∗2 L∗3 sinh β ∗ + β 2 L4 cosh β + β ∗2 L∗4 cosh β ∗ ,

D1 = −

  1 L1 e−iθ + L∗1 eiθ α2 sinh αh − α2 L2 e−iθ + L∗2 eiθ cosh hα + β 2 L3 e−iθ sinh hβ 2  +L∗3 eiθ β ∗2 sinh β ∗ h − L4 e−iθ β 2 cosh βh − L∗4 eiθ β ∗2 cosh β ∗ h ,

of

D2 = −

  iαR  2 α − β 2 (L∗1 L3 sinh α sinh β + L∗1 L4 sinh α cosh β) + α2 − β 2 (L∗2 L3 cosh α sinh β 4  L∗2 L4 cosh α cosh β) + β ∗2 − α2 (L1 L∗3 sinh α sinh β ∗ + L1 L∗4 sinh α cosh β ∗ )

p ro

D3 = −

  + β ∗2 − α2 (L2 L∗3 cosh α sinh β ∗ + L2 L∗4 cosh α cosh β ∗ ) + β ∗2 − β 2 (L3 L∗3 sinh β sinh β ∗

Pr e-

  +L3 L∗4 sinh β cosh β ∗ ) + β ∗2 − β 2 (L∗3 L4 cosh β sinh β ∗ + L4 L∗4 cosh β cosh β ∗ )

 1 4 α (L1 + L∗1 ) − α3 (α − iR) L1 − α3 (α + iR) L∗1 sinh α + α4 (L2 + L∗2 ) − α3 (α − iR) L2 2    −α3 (α + iR) L∗2 cosh α + β 4 − αβ 2 (α − iR) L3 sinh β + β ∗4 − αβ ∗2 (α + iR) L∗3 sinh β ∗



   + β 4 − αβ 2 (α − iR) L4 cosh β + β ∗4 − αβ ∗2 (α + iR) L∗4 cosh β ∗ ,

  iαR  2 α − β 2 (L∗1 L3 + L∗2 L4 ) cosh (α + β) − α2 − β 2 (L∗1 L3 − L∗2 L4 ) cosh (α − β) 4   + β ∗2 − α2 (L1 L∗3 + L2 L∗4 ) cosh (α + β ∗ ) − β ∗2 − α2 (L1 L∗3 − L2 L∗4 ) cosh (α − β ∗ )

urn

al

s = −

  + β ∗2 − β 2 (L3 L∗3 + L4 L∗4 ) cosh (β + β ∗ ) − β ∗2 − β 2 (L3 L∗3 − L4 L∗4 ) cosh (β − β ∗ )   + α2 − β 2 (L∗1 L4 + L∗2 L3 ) sinh (α + β) − α2 − β 2 (L∗1 L4 − L∗2 L3 ) sinh (α − β)

Jo

  + β ∗2 − α2 (L1 L∗4 + L2 L∗3 ) sinh (α + β ∗ ) + β ∗2 − α2 (L1 L∗4 − L2 L∗3 ) sinh (α − β ∗ )

  + β ∗2 − β 2 (L3 L∗4 + L∗3 L4 ) sinh (β + β ∗ ) + β ∗2 − β 2 (L3 L∗4 − L∗3 L4 ) sinh (β − β ∗ )

4

Graphical analysis

This section discusses the quantitative analysis of the sundry parameters. For this purpose the mean velocity and mean axial velocity distribution are calculated for K0 = 0. Computer codes were developed for the numerical evaluations of the analytical results and some important

Journal Pre-proof

results are displayed graphically in Figs. 2 − 3. The constant D1 , which initially arose from the non-slip condition of the axial-velocity on the wall, is due to the value of Φ′20

u¯ (1) =

ǫ2 ′ Φ 2 20

(1) =

ǫ2 D1 . 2

of

at the boundary and is related to the mean velocity at the boundaries of the channel by In Fig. 2a the effects of a on the mean velocity at the boundaries

p ro

D1 with wave number α are observed. It is noted that D1 increases by increasing a. Fig. 2b indicates the influence of D1 with d for different values of the channel width h. One can see that there is an increase in D1 with an increase in h. We have found that D1 decreases with

Pr e-

an increase in d, goes zero for some value of d and then remains negative until d reaches 1 which indicates that the damping causes the mean flow reversal. Fig. 2c depicts the effect of D1 with the elastance of the wall for different values of phase difference θ. It is found that D1 increases for 0 ≤ θ ≤ π/2 and decreases for π/2 < θ ≤ π. Fig. 2d shows the variation of D1 with R for different values of the wall tension T . Fig. 2d depicts an increase in the

al

mean velocity at the boundaries with increasing wall tension. Fig. 2e shows the effect of the relaxation time λ1 on D1 for different values of the α. One observes that D1 decreases with

urn

an increasing λ1 . The effect of λ2 on D1 is opposite to the effect of λ1 on D1 as is clear from Fig. 2f. Fig. 3a explains the effects of a on u¯. The possibility of flow reversal increases in the narrow part of the channel whereas an increase is observed in the wider part of the channel.

Jo

Fig. 3b provides the effect of the channel width h on the mean velocity. From this figure it is observed that maximum reverse in the flow occurs in the channel’s lower part when compared with the channel’s upper part. Fig. 3c elucidates the effect of the phase difference θ on u¯. Obviously, the flow reversal decreases in the channel’s narrow part while it increases in the channel’s wider part. A similar behavior is observed in Fig. 3d which displays the effect of T on u¯, while the reverse situation is seen in Fig. 3g displaying the effect of the wall damping on u¯(y). Figs. 3e and 3f indicate the opposite behavior of the relaxation and the

Journal Pre-proof

retardation time on u¯(y) respectively. From Fig. 3e it is seen that flow reversal decreases near the channel’s lower wall. However it increases in the remaining parts of channel. Note

Final remarks

p ro

5

of

that the situation is reversed in Fig. 3f.

In the present analysis, the effects of elastic walls are examined on the peristaltic flow of a realistic fluid in an asymmetric channel. Governing equations are first modeled and then

Pr e-

solved analytically for the case of free pumping. The effects of various parameters on D1 and mean velocity distribution u¯(y) are analyzed. The main findings are listed below. • The variations of a, h, T and λ1 on D1 are quite opposite to λ2 . • The flow reversal occurs close to the boundaries.

al

• The flow reversal close to the lower wall is much greater than that close to the lower

urn

wall.

• Results for viscous fluid can be deduced when λ1 = λ2 = 0. • The solution formally coincides with that of Fung and Yih [2] by choosing θ = λ1 =

Jo

λ2 = 0 and a = h = 1; however, the results differ in many respects • The results of hydrodynamic viscous fluid [16] can be computed as the limiting cases of present study by choosing θ = λ1 = λ2 = 0 and a = h = 1. • The last solution (32) (when wall tension T and wall elastance K → 0 (thin plate); wall rigidity B and wall elastance K → 0 (membrane)) and by choosing θ = λ1 = λ2 = 0 and a = h = 1 agree with the work of Mitra and Prasad [3].

Journal Pre-proof

Acknowledgment: The authors are grateful to the financial support of Higher Edu-

of

cation Commission (HEC) of Pakistan (5854/Federal/NRPU/R&D/HEC/2016).

References

of Technology, Cambridge, AMA (1966).

p ro

[1] T. W. Latham, Fluid motion in a peristaltic pump, MS thesis, Massachusetts Institute

Pr e-

[2] Y. C. Fung and C. S. Yih, Peristaltic transport. J. Appl. Mech. 35 (1968) 669 − 75. [3] T. K. Mitra and S. N. Prasad, On the influence of wall properties and Poiseuille flow in peristalsis, J. Biomech. 6 (1973) 681 − 93.

[4] S. E. Ghasemi, M. Hatami, J. Hatami, S. A. R. Sahebi and D. D. Ganji, An efficient approach to study the pulsatile blood flow in femoral and coronary arteries by Differential

al

Quadrature Method, Physica A: Statistical Mechanics and its Applications 443 (2016)

urn

406 − 414.

[5] S. E. Ghasemi, M. Vatani, M. Hatami and D. D. Ganji, Analytical and numerical investigation of nanoparticle effect on peristaltic fluid flow in drug delivery systems, Journal

Jo

of Molecular Liquids 215 (2016) 88 − 97. [6] A. S. Dogonchi and D. D. Ganji, Impact of Cattaneo–Christov heat flux on MHD nanofluid flow and heat transfer between parallel plates considering thermal radiation effect, Journal of the Taiwan Institute of Chemical Engineers 80 (2017) 52 − 63. [7] M. Gholinia, Kh. Hosseinzadeh, H. Mehrzadi, D. D. Ganji and A. A. Ranjbar, Investigation of MHD Eyring–Powell fluid flow over a rotating disk under effect of homogeneous– heterogeneous reactions, Case Studies in Thermal Engineering 13 (2019) 100356.

Journal Pre-proof

[8] D. Tripathi, Study of transient peristaltic heat flow through a finite porous channel, Math. Comp. Model. 57 (2013) 1270 − 1283.

of

[9] D. Tripathi and, O. Anwar B´eg, Peristaltic propulsion of generalized Burgers’ fluids through a non-uniform porous medium: A study of chyme dynamics through the diseased

p ro

intestine, Mathematical Biosciences 248 (2014) 67 − 77.

[10] J. Prakash, K. Ramesh, D. Tripathi and R. Kumar, Numerical simulation of heat transfer in blood flow altered by electroosmosis through tapered micro-vessels, Microvascular

Pr e-

Research 118 (2018) 162 − 172.

[11] N. K. Ranjit, G. C. Shit and D. Tripathi, Entropy generation and Joule heating of two layered electroosmotic flow in the peristaltically induced micro-channel, International Journal of Mechanical Sciences 153 − 154 (2019) 430 − 444.

al

[12] S. Noreen, Quratulain and D. Tripathi, Heat transfer analysis on electroosmotic flow via peristaltic pumping in non-Darcy porous medium, Thermal Science and Engineering

urn

Progress In press (2019) .

[13] T. Hayat, A. Bibi, H. Yasmin and B. Ahmad, Simultaneous effects of Hall current and homogeneous/heterogeneous reactions on peristalsis, Journal of the Taiwan Institute of

Jo

Chemical Engineers 58 (2016) 28 − 38. [14] M. Rafiq, H. Yasmin, T. Hayat and F. Alsaadi, Effect of Hall and ion-slip on the peristaltic transport of nanofluid: A biomedical application, Chinese Journal of Physics In press (2019) .

Journal Pre-proof

[15] M. Waqas, T. Hayat, S. A. Shehzad and A. Alsaedi, Transport of magnetohydrodynamic nanomaterial in a stratified medium considering gyrotactic microorganisms, Physica B:

of

Condensed Matter 529 (2018) 33 − 40. [16] M. A. Abd Elnaby and M. H. Haroun, A new model for study the effect of wall properties

p ro

on peristaltic transport of a viscous fluid, Comm. Nonlinear Sci. Numer. Simul. 13 (2008) 752 − 762.

[17] M. Hatami, Kh. Hosseinzadeh, G. Domairry and M. T. Behnamfar, Numerical study

Pr e-

of MHD two-phase Couette flow analysis for fluid-particle suspension between moving parallel plates, Journal of the Taiwan Institute of Chemical Engineers 45 (2014) 2238 − 2245.

[18] M. Fakoura, A. Vahabzadeha, D. D. Ganji and M. Hatami, Analytical study of microp-

al

olar fluid flow and heat transfer in a channel with permeable walls, Journal of Molecular Liquids 204 (2015) 198 − 204.

urn

[19] J. Rahimi, D. D. Ganji, M. Khaki and Kh. Hosseinzadeh, Solution of the boundary layer flow of an Eyring-Powell non-Newtonian fluid over a linear stretching sheet by collocation method, Alexandria Engineering Journal 56 (2017) 621 − 627.

Jo

[20] S. S. Ghadikolaei, Kh. Hosseinzadeh and D. D. Ganji, Analysis of unsteady MHD EyringPowell squeezing flow in stretching channel with considering thermal radiation and Joule heating effect using AGM, Case Studies in Thermal Engineering 10 (2017) 579 − 594. [21] S. S. Ghadikolaei, Kh. Hosseinzadeh, D. D. Ganji and B. Jafari, Nonlinear thermal radiation effect on magneto Casson nanofluid flow with Joule heating effect over an

Journal Pre-proof

inclined porous stretching sheet, Case Studies in Thermal Engineering 12 (2018) 176 − 187.

of

[22] S. S. Ardahaie, A. J. Amiri, A. Amouei, Kh. Hosseinzadeh and D. D. Ganji, Investigating the effect of adding nanoparticles to the blood flow in presence of magnetic field in a

p ro

porous blood arterial, Informatics in Medicine Unlocked 10 (2018) 71 − 81. [23] K. De Vries, E. A. Lyons, J. Ballard, C. S. Levi and D. J. Lindsay, Contractions of the

Pr e-

inner third of the myometrium, Am. J. Obstetrics Gynecol 162 (1990) 679 − 682. [24] M. Kothandapani and J. Prakash, Effect of radiation and magnetic field on peristaltic transport of nanofluids through a porous space in a tapered asymmetric channel, Journal of Magnetism and Magnetic Materials 378 (2015) 152 − 163. [25] M. Kothandapani, J. Prakash and V. Pushparaj, Nonlinear peristaltic motion of a

al

Johnson–Segalman fluid in a tapered asymmetric channel, Alexandria Engineering Jour-

urn

nal 55 (2016) 1607 − 1618.

[26] M. Kothandapani, V. Pushparaj and J. Prakash, Effect of magnetic field on peristaltic flow of a fourth grade fluid in a tapered asymmetric channel, Journal of King Saud

Jo

University - Engineering Sciences 30 (2018) 86 − 95. [27] T. Hayat, S. Farooq, M. Mustafa and B. Ahmad, Peristaltic transport of Bingham plastic fluid considering magnetic field, Soret and Dufour effects, Results in Physics 7 (2017) 2000 − 2011. [28] G. C. Shit and N. K. Ranjit, Role of slip velocity on peristaltic transport of couple stress fluid through an asymmetric non-uniform channel: Application to digestive system, Journal of Molecular Liquids 221 (2016) 305 − 315.

Journal Pre-proof

[29] K. Vajravelu, S. Sreenadh, K. Rajanikanth and C. Lee, Peristaltic transport of a Williamson fluid in asymmetric channels with permeable walls, Nonlinear Analysis: Real

of

World Applications 13 (2012) 2804 − 2822. [30] A. A. Khan, A. Farooq and K. Vafai, Impact of induced magnetic field on synovial fluid

p ro

with peristaltic flow in an asymmetric channel, Journal of Magnetism and Magnetic Materials 15 (2018) 54 − 67.

Jo

urn

al

Pr e-

a

b

Journal Pre-proof

d

p ro

of

c

f

urn

al

Pr e-

e

Fig. 2: The variation of D1 for different values of amplitude ratio a (panel (a)), channel width h (panel (b)), phase difference θ (panel (c)), wall tension T (panel (d)), relaxation time

Jo

λ1 (panel (e)) and retardation time λ2 (panel (f )).

Journal Pre-proof

b

Pr e-

p ro

of

a

Jo

urn

al

c

d

Journal Pre-proof

f

p ro

of

e

urn

al

Pr e-

g

Fig. 3: The variation of mean-velocity distribution and reversal flow for different values of amplitude ratio a (panel (a)), channel width h (panel (b)), difference θ (panel (c)), wall

Jo

tension T (panel (d)), relaxation time λ1 (panel (e)), retardation time λ2 (panel (f )) and wall damping d (panel (g)).

Journal Pre-proof

Pr e-

p ro

of

Figure 1

Jo

urn

al

Figure 2a

Journal Pre-proof

Pr e-

p ro

of

Figure 2b

Jo

urn

al

Figure 2c

Journal Pre-proof

Pr e-

p ro

of

Figure 2d

Jo

urn

al

Figure 2e

Journal Pre-proof

Pr e-

p ro

of

Figure 2f

Jo

urn

al

Figure 3a

Journal Pre-proof

Pr e-

p ro

of

Figure 3b

Jo

urn

al

Figure 3c

Journal Pre-proof

Pr e-

p ro

of

Figure 3d

Jo

urn

al

Figure 3e

Journal Pre-proof

Pr e-

p ro

of

Figure 3f

Jo

urn

al

Figure 3g

Journal Pre-proof

Declaration of interests ☐ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

of

☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests:

Jo

urn

al

Pr e-

p ro

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.