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Shooting method analysis in wire coating withdrawing from a bath of Oldroyd 8-constant fluid with temperature dependent viscosity

  • Zeeshan Khan , Haroon Ur Rasheed , Murad Ullah , Ilyas Khan EMAIL logo , Tawfeeq Abdullah Alkanhal and Iskander Tlili
Published/Copyright: December 31, 2018
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Open Physics
From the journal Open Physics Volume 16 Issue 1

Abstract

The most important plastic resins used in wire coating are high/low density polyethylene (LDPE/HDPE), plasticized polyvinyl chloride (PVC), nylon and polysulfone. To provide insulation and mechanical strength, coating is necessary for wires. Simulation of polymer flow during wire coating dragged froma bath of Oldroyd 8-constant fluid incompresible and laminar fluid inside pressure type die is carried out numerically. In wire coating the flow depends on the velocity of the wire, geometry of the die and viscosity of the fluid.The non-dimensional resulting flow and heat transfer differential equations are solved numerically by Ruge-Kutta 4th-order method with shooting technique. Reynolds model and Vogel’s models are encountered for temperature dependent viscosity. The numerical solutions are obtained for velocity field and temperature distribution. The solutions are computed for different physical parameters.It is observed that the non-Newtonian propertis of fluid were favourable, enhancing the velocity in combination with temperature dependent variable. The Brinkman number contributes to increase the temperature for both Reynolds and Vogel’smodels. With the increasing of pressure gradient parameter of both Reynolds and Vogel’s models, the velocity and temperature profile increases significantly in the presence of non-Newtonian parameter. Furthermore, the present result is also compared with published results as a particular case.

Keywords: Ruge-Kuta 4th-order method; heat transfer; temperature dependent viscosity; wire coating; viscoelastic Oldroyd 8-constant fluid
PACS: 57.85.-g; 47.50.-d

1 Introduction

The understanding and analysis of non-Newtonian fluids is of great interest from fundamental as well as applied perspective [1, 2]. The knowledge of physics and material science associated with the flows of non-Newtonian fluids may have direct effects on numerous fields such as polymer preparation, covering and coating, ink-jet printing, smaller scale fluidics, homodynamics, the flow of turbulent shear, colloidal and additive suspensions, animal blood etc. For this reason, research has been concentrated on these flows and subsequently the literature presents extensive work on numerical, analytical, and asymptotic solutions on the subject [3, 4]. Furthermore, flow of these fluids presents great challenges equally to the experts from diverse research fields such as numerical simulations, engineering, mathematics, physics. Indeed, the equations proposed and created for non-Newtonian models are considerably more complicated, compared to those for Newtonian fluids. The modeled equations of non-Newtonian fluid are highly nonlinear and it is very difficult to obtain the exact solutions of such equations [5, 6, 7, 8]. Due to the non-linear and inapplicable nature in terms of superposition principle, it is hard to obtain highly accurate solutions for viscous fluids [5, 6, 7, 8]. For this purpose, many researchers developed analytical and numerical techniques to obtain the solutionstothese non-linear equations.

Wire-coating (an extrusion procedure) is generally utilized as a part of the polymer industry for insulation and it protects the wire from mechanical damage. In this procedure an exposed preheated fiber or wire is dipped and dragged through the melted polymer. This procedure can also be accomplished by extruding the melted polymer over a moving wire. A typical wire coating equipment is composed of five distinct units: pay-off tool, wire preheating tool, an extruder, a cooling and a take-off tool. The most common dies used for coatings are tubing-type dies and pressure type dies. The latter is normally used for wire-coating and is shaped like an annulus. Flows through such die are therefore similar to the flows through an annular area formed by two coaxial cylinders. One of the two cylinders (inner cylinder) moves in the axial direction while the second (external cylinder) is fixed. Preliminary efforts by several researchers [9, 10, 11, 12, 13, 14] used power-law and Newtonian models to reveal the rheology of the polymer melt flow. In references [15, 16], authors provide the wire coating analysis using pressure type die. Afterwards, more research regarding this matter was conveyed in references [17, 18, 19, 20]. In addition, a very detailed survey regarding heat transfer and fluid flow in wire-coating is given in references [21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40]. Akter and Hashmi [42], analyzed the wire coating using pressurized die. Later on, Akter and Hashmi performed simulations on polymer flow during the wire-coating process by means of a conical unit as in references [43, 44].

Wire coating or covering is a modern industrial procedure to coat a wire for insulation and environmental safety. Wire coating can be classified in three types: dipping process, coaxial process, and electrostatic deposition process. The dipping process provides considerably stronger bond among the continuums however this process is relatively slow when compared to the other two processes. The problems related to the coating extrusion based on the pressure-die were reviewed by Han and Rao [45]. Generally, the extrusion process requires three components: the feeding unit, the barrel and a head with a die. Detailed discussions regarding these three distinct elements are reported by Kozan in reference [46]. In addition, Sajid et al. [47] addressed and solved the wire-coating process of Oldroyd (8-constant fluid) by utilizing HAM method. Similarly, Shah et al. [48] utilized the perturbation approach and analytically analyzed the wire-coating of a third-grade fluid.

At present, the Phan-Thien Tanner (PTT) model, a third-grade visco-elastic fluid model, is the most commonly used model for wire-coating. The high-speed wire-coating process for polymer melts in elastic constitutive model was analyzed by Binding in [49]. It also discussed the shortcomings of the realistic modeling approach. Multu et al. in [50] provided the wire-coating analysis based on the tube-tooling die. Kasajima and Ito in [51] analyzed the wire-coating process and examined the post treatment of polymer extruded. They also discussed the impacts of heat transfer on cooling coating. Afterward, Winter [52, 53] investigated the thermal effect on die both from Internal and external perspective. Recently, wire-coating in view of linear variations of temperature in the post-treatment analysis was investigated by Baag and Mishra [54].

Wet-on-dry (WOD) and wet-on-wet (WOW) are the most common coating process used for double-layer coating. In WOD processthe fiber is dragged into the primary layer and then curved by ultraviolet lamp. Then,primary coated layeris passed through the secondary coating-layer and again curved by ultraviolet lamp. But in the WOW process the fiber is passedfrom the primary and secondary-coating die and then curved by ultraviolet lamp. Recently WOW process gained significant importance production industry. Herein, WOWcoating-process is applied for fiber optics. Kim et al. [55] used WOW process for the analysis of two-layers coating on optical fiber. Zeeshan et al. [56, 57] used pressure coating die for the two-layer coating in optical coating analysis using PTT fluid model. The same author discussed viscoelastic fluid for two-layer coating in fiber coating [58]. The Sisko fluid model was used for fiber coating by adopting WOW process by Zeeshan et al. [59] in the presence of pressure type coating die.

In the recent study MHD flow of viscoelastic Oldroyd 8-constant fluid is investigated for wireinside pressurized coating die. The modeled equations describing the polymer flow inside the die are solved numerically by Runge-Kutta Fehlberg algorithm with shooting technique [60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83]. The result is validated via a comparison with published results by Shah et al. [83].

2 Modeling of the problem

Thegeometry of the flow problem isshown in Figure 1 in which thewire of radius Rw is dragged with velocity V inside the coating die filled with viscoelastic fluid. The fluidis electrically conducted in the presence ofapplied magneticfield B0 normal to the flow. Due to small magnetic Reynold number the inducedmagnetic field is negligible, which is also a valid assumption on a laboratory scale.

Figure 1 Geometry of wire coating process
Figure 1

Geometry of wire coating process

The velocity and temperature profiles for one-dimensional flow are

(1)u=0,0,wr,S=Sr,Θ=Θ(r).

Here Rd is the radius of the die, θw temperature of the wire and θd is the temperature of the die.

For viscoelastic fluid, the stres tensor is:

(2)S+γ1DSDt+γ32A1S+SA1+γ52trSA1+γ62trSA1I=ηA1+γ2DA1Dt+γ4A12+γ72trA12I,

In above equation A1 and γi (i = 1 − 7) are the Rivlin-Ericksen tensor and material constants, respectively.

(3)A1=LT+L,
(4)An=An1LT+LAn1+DAn1Dt,n=2,3,

The basic governing equations for incompressible flow are the continuity, momentum and energy equations, given by:

(5).u=0,
(6)ρDuDt=.T+J×B,
(7)ρcpDθDt=k2θ+T.L,

In Eq. (6) the body force is defined as:

(8)J×B=(0,0,σB02w).

In view of Eqs. (1)-(7), we have:

(9)pr=1rddr(rSrz),
(10)pθ=0,
(11)pz=1rddr(rSrz)σB02wνkpw,
(12)pz=1rddrrη1+αdwdr21+βdwdr2,
(13)kd2θdr2+1rdθdrrη1+αdwdr21+βdwdr2=0,

where

α=γ1γ4+γ7γ3+γ5γ4+γ7γ2γ5γ72,β=γ1γ3+γ6γ3+γ5γ1γ3+γ6γ1γ5γ62.

2.1 Constant viscosity

Introducing the dimensionless parameters:

(14)r=rRw,w=wV,α=αV2Rw2,β=βV2Rw2,M=σB02η/Rw2,p=pηV/Rw2,kp=Rw2Vkp,θ=θθwθdθw,Br=ηV2k(θdθw),pr=Ω

In view of Eq. (14), the system of Eqs. (12) and (13) becomes:

(15)rΩ=dwdr+α+βdwdr3+αβdwdr51+βdwdr23+rd2wdr2+3αβdwdr2d2wdr2+αβdwdr4d2wdr21+βdwdr23+1ηdηdrrdwdr+αdwdr31+βdwdr21ηMwr+1Kpwr,
(16)d2θdr2+1rdθdr+ηβrdwdr21+βdwdr21+βdwdr2=0

Corresponding to the boundary-conditions

(17)w1=1
(18)θ1=0,θδ=1.

The constant viscosity case is discussed by Shah et al. [46] in detail. Here we discuss the variable viscosity case.

2.2 Reynolds model

In this case η is a function of temperature. Introducing the dimensionless parameters:

(19)r=rRw,w=wV,α=αV2Rw2,RdRw=δ>1,β=βV2Rw2,M=σB02η/Rw2,p=pRwηV,kp=Rw2Vkp,θ=θθwθdθw,Br=ηV2k(θdθw),pr=Ω.

In Reynolds model, the dimensionless temperature dependent viscosity can be expressed as η = e(−β0) ≈ 1 −β0. Therefore, Eqs. (15)-(18) in view of Eq. (19) become:

(20)d2wdr2=r1+βdwdr2Ar1+3αβdwdr2+αβdwdr4dwdr+α+βdwdr3+αβdwdr5r1+3αβdwdr2+αβdwdr4,

where

A=[Ω+11β0mθM+1Kpw+11β0mθβ0mdθdrdwdr+αdwdr31+βdwdr2
(21)d2θdr2=1rdθdr1B0mθBrdwdr2+αdwdr41+βdwdr2,
(22)w1=1,wδ=0,θ0=0,θδ=1.

2.3 Vogel’s model

Temperature dependent viscosity can be expressed as η=η0expDB+θθw,by expanding

(23)η=Ω11DB2θ,

where Ω1=η0expDBθwand D, B' denotes the temperature dependent viscosity parameters of the Vogel’s model. Therefore, Eqs. (15)-(18) in view of Eqs. (19) and (23) become:

(24)d2wdr2=r1+βdwdr2Br1+3αβdwdr2+αβdwdr4dwdr+(α+β)dwdr3+αβdwdr3r1+(3αβ)dwdr2+αβdwdr4

where

B=[Ω+1Ω11DB2θM+1Kpw+DB2dθdrdwdr+αdwdr31+βdwdr2
(25)d2θdr2=1rdθdrΩ11DB12θBrdwdr2+αdwdr41+βdwdr2,
(26)w1=1,wδ=0,θ0=0,θδ=1.

3 Numerical solution

The above system of equations is solved numerically by using fourth order Runge-Kutta method along with shooting technique. For this purpose the Eqs. (20-22) and (24-26) are transformed in to first order due to the higher order equation at r = δ (boundary-layer thickness) being unavailable. Then, the boundary value problem is solved by shooting method.

3.1 Numerical solution of Reynolds model

Eqs. (20) and (21) are solved numerically by Ruge-Kutta method corresponding to the boundary conditions (22) by considering:

(27)z1=w,z2=dwdrandz3=θ,z4=dθdr.

In view of Eq. (27), Eqs. (20) and (21) become:

(28)z2=C1+βz222z2+α+βz23+αβz25r1+3αβz22+αβz24,z4=1rz41B0mθBrz22+αz241+βz22,

where

C=[rΩ+11β0mθM+1Kpz1+11β0mθβ0mz4z2+αz231+βz22]

with boundary conditions:

(29)za1=1,zb1=0,za2=0,zb2=1.

3.2 Numerical solution of Vogel’s model

The numerical solution of Eqs. (24) and (25) with boundary conditions given in Eq. (26) can be obtained by considering D = β0b. The expression for the velocity and temperature profiles are:

(30)z2=D1+βz222z2+α+βz23+αβz25r1+3αβz22+αβz24,

where

D=rΩ+1Ω11DB12θM+1Kpz1+DB12z4Ω11DB12θz2+αz231+βz22
(31)z4=1rz4Ω11DB12θBrz22+αz241+βz22,

with the specific boundary conditions

(32)za1=1,zb1=0,za2=0,zb2=1.

4 Analysis of the results

In this section the results are discussed derived on the theoretical basis. In the following subsection the figures illustrate how the fluid velocity and the temperature distribution vary in the pressure unit of the conical geometry for different physical parameter values such as dilatant constant (α), pseudoplastic constant (β), viscosity parameter of Reynolds model (m), Vogel’s parameter (Ω1), Brinkman number (Br), magnetic parameter (M) and porosity parameter (kp). The numerical solutions have been calcultaed by fourth order Ruge-Kutta method along with shooting technique.

(a) Reynolds model

Figure 2 displays the velocity profile in the presence of 2 porous matrix (kp) by variation of magnetic parameter (M) 22and dilatant constant (α). The effect of dilatant constant on the velocity profile is significant. It is noticed that the velocity profile retards with the increasing values of dilatant constant but reverse effect is observed in the presence of kp and M = 0. For M = 2, the situation becomes adverse. It is interesting to note that for α = 0.4 the present result made significant agreement with the reported results [45] when M = 0,kp = 0.2. The impact of β on velocity varaition is depicted in Figure 3 in the absence of M and for fixed values of kp. It is observed that the pseudoplastic constant (β), accelerates the velocity of the coating polymer by taking M = 0. But converse effect is detected in the presence of kp. It is also evident that for M = 3, the velocity profile retards as increases in the presence/absence of kp.

Figure 2 Impact of α on velocity (Reynolds model)
Figure 2

Impact of α on velocity (Reynolds model)

Figure 3 Impact of β on velocity (Reynolds model)
Figure 3

Impact of β on velocity (Reynolds model)

Figure 4 displays the influence of viscosity parameter (Reynolds model parameter) m on the velocity profile. It is observed that for both presence of kp and M the velocity profile increases all points. Due to high magnetic field, the electromagnetic force may add to nonlinearity of velocity distribution. It is also found that for high values of viscosity and magnetic parameter i.e., kp = 50 and M = 2, accelerates/decelerates the velocity profile. Figure 5 delineates the impact of M on velocity profile for two different values of kp. It is perceived that the velocity profile decreases with magnetic parameter. This deceleration in velocity field is due to the Lorenz forces. In the presence and absence of M, Figure 6 depicts the velocity profile for various values of porous matrix. This shows that the porous matrix has accelerating effect of velocity profile both in the presence and absence of M. The impact of Br and M in the temperature profile is revealed in Figure 7. It follows that the Br i.e., the relation between viscous heating andthe heat conductor, enhances the temperature distribution. It is also remarkable to note that two-layer variation is noted with the increasing values of magnetic parameter. Temperature distribution increases sharply within the region r ≤ 1.4, and retards significantly. For kp = 0.2 and 50, the impact of M and β on the temperature distribution is displayed in Figure 8. The Reynolds model viscosity parameter is taken to be fixed at m = 15. It is seen that the temperature decreases with increasing β in the presence/absence of M. Figure 9 shows the effect of porous matrix on temperature distribution. It is noticed that the temperature profile gets a higher gradient as kpincrease in both ceases. Also is remarkable to note that for large values of magnetic parameter and Brinkman number i.e., M = 3 and Br = 15, the temperature is maximum at the middle of the annular die.

Figure 4 Impact of m on velocity (Reynolds model)
Figure 4

Impact of m on velocity (Reynolds model)

Figure 5 Impact of on velocity (Reynolds model)
Figure 5

Impact of on velocity (Reynolds model)

Figure 6 Impact of kp on velocity (Reynolds model)
Figure 6

Impact of kp on velocity (Reynolds model)

Figure 7 Impact of Br on temperature (Reynolds model)
Figure 7

Impact of Br on temperature (Reynolds model)

Figure 8 Impact of β on temperature (Reynolds model)
Figure 8

Impact of β on temperature (Reynolds model)

Figure 9 Impact of kp on temperature (Reynolds model)
Figure 9

Impact of kp on temperature (Reynolds model)

(b) Vogel’s model

The effect of physical parameter involves in the Vogel’s model on the solutions are revealed in Figures 10-16. Figure 10 shows the effect of the dilatant constant α as well as the pseudoplastic constant β in the presence/absence of M for fixed values of kp = 0.2 and 50, on the velocity. From this simulation it is pointed out that the velocity decreases as the dilatant constant increases while the effect of β is opposite to that of α. Also the results of Shah et al. [45] can be easily recovered by taking M = 0, kp = 0, α = 0.4. The variation of the velocity of the coating liquid is displayed in Figure 11. It is seen that the velocity decreases with increasing M. This due the Lorenz forces, which act as a resistive force and resist the motion of the fluid. The variation of the velocity is significant for porous matrix. Figure 12 depicts the effect of M and Ω1 (pressure gradient parameter of Vegel’s model) on the velocity profile. Due the existence of non-Newtonian characteristics the pressure gradient parameter accelerates the velocity profile significantly in the domain r ≤ 1.3 and then decreases sharply. In the presence/absence of magnetic parameter M, the effect of pseudoplastic constanton temperature is displayed in Figure 13. With increasing β, the temperature distribution within the die increases. It is interesting to note that for M = 3 and kp = 0.2, the temperature profile increases significantly inthe region r ≤ 1.5 and afterwards, it decreases. Figure 14 reveals the effect of pressure gradient parameter of Vogel’s model on the temperature profile with the contribution of constant porous matrix in the presence/absence of M. From this simulation it is observed that for M = 0 and kp = 0.2, the temperature profile increases as Ω increases. A retarding effect was observed after the region r ≥ 1.5 and in the presence of and kp the reverse effect was encountered near the plate. An interesting observation is given in Figure 15. It is significant that the temperature distribution gets accelerated due to the increase of M in the presence. The impact of on the temperature is depicted in Figure 16. It is observed that for large value of Brinkman number i.e., Br = 20, the peak in temperature distribution is encountered within the layer 1 ≤ r ≤ 1.7 and afterwards, it decreased sharply in the presence of kp. Finally, the present result is also validated by comparing with reported results [45] and good agreement is found as presented in Table 1.

Figure 10 Impact of α and β on velocity (Vogel’s model)
Figure 10

Impact of α and β on velocity (Vogel’s model)

Figure 11 Impact of M and kp on velocity (Vogel’s model)
Figure 11

Impact of M and kp on velocity (Vogel’s model)

Figure 12 Impact of Ω on velocity profile (Vogel’s model)
Figure 12

Impact of Ω on velocity profile (Vogel’s model)

Figure 13 Impact of β on temperature (Vogel’s model)
Figure 13

Impact of β on temperature (Vogel’s model)

Figure 14 Impact of Ω on temperature (Vogel’s model)
Figure 14

Impact of Ω on temperature (Vogel’s model)

Figure 15 Impact of M on temperature (Vogel’s model)
Figure 15

Impact of M on temperature (Vogel’s model)

Figure 16 Impact of Br on temperature (Vogel’s model)
Figure 16

Impact of Br on temperature (Vogel’s model)

Table 1

Comparison of present work with Rehan et al. [45]

rPresent workRehan et al. [45]
111
1.20.7344250.73451
1.40.5252220.525203
1.60.3485010.348552
1.80.1804760.180466
201

5 Conclusion

The magnetic field and heat transfer effect on wire coating analysis is investigated numerically while with drawing the wire from the center of he die filled with viscoelastic Oldroyd 8-constant fluid. The velocity and temperature profiles have been obtained numerically by applying Runge-Kutta 4th-order method along with shooting technique. The effect of variable viscosity is also investigated. Reynolds and Vogel’s models are used for the variable viscosity. The effect of physical parameters such as values such as dilatant constant pseudoplastic constant (β), viscosity parameter of Reynolds model (m), and viscosity parameter of Vogel’s model (Ω1), Brinkman number magneticpparameter (M) and porosity parameter (kp). It is seen that the non-Newtonian parameter of viscoelastic Oldroyd 8-constant fluid accelerates the velcity profile in the presence of porous matrix and M = 0. For large value of magnetic parameter the reverse effect is observed. It is observed that the temperature profiles decreases with increasing psedoplastic parameter in the presence and absence of magnetic parameter. The Brinkman number contributes to increase the temperature for both Reynolds and Vogel’smmodels. With increasing pressure gradient parameter with both Reynolds and Vogel’s models, the velocity and temperature profile increases significantly in the presence of non-Newtonian parameter.

References

[1] Rajagopal., K.R. On the boundary conditions for fluids of the differential type, in: A. Sequira (Ed.), Navier-Stokes Equation and Related Non-Linear Problems, Plenum press, New York, 1995, 273-278.10.1007/978-1-4899-1415-6_22Search in Google Scholar

[2] Rajagopal K.R., Kaloni. P.N., Some remarks on the boundary conditions for fluids of the differential type, in: G.A. Gram, S.K. Malik (Eds.), Continuum Mechanics and its Applications, Hemisphere, Washington DC, 1980, 935-941.Search in Google Scholar

[3] Szeri A.Z., Rajagopal. K.R, Flow of a non-Newtonian fluid between heated parallel plates, Int. J. Non-Lin. Mech., 1985, 20, 91-101.10.1016/0020-7462(85)90003-4Search in Google Scholar

[4] Makinde O.D., Irreversibility analysis for gravitry driven non-Newtonian liquid film along an inclined isothermal plate, Phys. Scripta, 2006, 74, 642-645..10.1088/0031-8949/74/6/007Search in Google Scholar

[5] Makinde O.D, Thermal criticality for a reactive gravity driven thin film flow of a third-grade fluid with adiabatic free surface down an inclined plane, Appl. Math. Mech. Ed., 2009, 30, 373-380.10.1007/s10483-009-0311-6Search in Google Scholar

[6] Massoudi M., Christie I., Effects of variable viscosity and viscous dissipation on the flow of a third-grade fluid in a pipe, Int. J. Non-Lin. Mech., 1995, 30, 687-699.10.1016/0020-7462(95)00031-ISearch in Google Scholar

[7] Damirel Y., Kahraman R., Thermodynamics Analysis of Convective Heat Transfer in an Annular Packed Bed, Int. J. Heat Fluid Flow, 2000, 21, 442-448.10.1016/S0142-727X(00)00032-1Search in Google Scholar

[8] Postelnicu A., Grosan T., Pop I., Free convection boundary-layer over a vertical permeable flat plate in a porous medium with internal heat generation, Int. Comm. Heat and Mass Trans., 2000, 27, 729-738.10.1016/S0735-1933(00)00153-6Search in Google Scholar

[9] Bernhardt E.C., Processing of Thermoplastic Materials, Reinhold Publishing, New York, 1962, 263-269.Search in Google Scholar

[10] McKelvey J.M., Polymer Processing, 1962, John Wiley and Sons, New York.Search in Google Scholar

[11] Bagley E.B., Storey S.H., Processing of thermoplastic materials, WireWire Prod., 1963, 38, 1104-1122.Search in Google Scholar

[12] Han C.D., Rao D., The rheology of wire coating extrusion, Polym. Eng. Sci.,1978, 18, 1019-1029.10.1002/pen.760181309Search in Google Scholar

[13] Carley J.F., Endo T., Krantz W., Realistic analysis of flow in wire coating dies,Polym. Eng. Sci.,1979, 19, 1178-1187.10.1002/pen.760191609Search in Google Scholar

[14] Han C.D., Rheology and Processing of Polymeric Materials Volume 2 Polymer Processing, Oxford University Press, 2007, 2, 235-256.10.1093/oso/9780195187823.001.0001Search in Google Scholar

[15] Middleman S., Fundamentals of Polymer Processing, McGraw-Hill, New York,1977.Search in Google Scholar

[16] Tadmor Z., Gogos C.G., Principle of Polymer Processing, 1978, John Wiley and Sons, New York.Search in Google Scholar

[17] Kasajima M., Ito K., Post-treatment of polymer extrudate in wire coating, Appl.Polym. Symp., 1973, 221, 221-235.Search in Google Scholar

[18] Tadmor Z., Bird R.B., Rheological analysis of stabilizing forces in wire-coating dies, Polym. Eng. Sci., 1974, 14,124-136.10.1002/pen.760140208Search in Google Scholar

[19] Caswell B., Tanner R.J., Wire coating die using finite element methods, Polym.Eng. Sci., 1985, 18, 417-421.10.1002/pen.760180514Search in Google Scholar

[20] Wagner R., Mitsoulis E., Effect of die design on the analysis of wire coating,Adv.Polym. Technol., 1985, 5, 305-325.10.1002/adv.1985.060050404Search in Google Scholar

[21] Tlili I., Timoumi Y., Ben Nasrallah S., Numerical simulation and losses analysis in a Stirling engine, Int. J. Heat & Techn., 2006, 24, 1.Search in Google Scholar

[22] Tlili I., Timoumi Y., Ben Nasrallah S., Thermodynamic analysis of Stirling heat engine with regenerative losses and internal irreversibilities, Int. J. Engine Res., 2007, 9, 45-56.10.1243/14680874JER01707Search in Google Scholar

[23] Tlili I., Timoumi Y., Ben Nasrallah S., Performance optimization of Stirling engines’, Renew. Ener., 2008, 33, 2134-2144.10.1016/j.renene.2007.12.012Search in Google Scholar

[24] Ahmadi M.H., Ahmadi M.A., Pourfayaz F., Hosseinzade H., Acıkkalp E., Tlili I., Feidt M., Designing a powered combined Otto and Stirling cycle power plant through multi-objective optimization approach, Renew. Sust. Ener. Rev, May 2016.10.1016/j.rser.2016.05.034Search in Google Scholar

[25] Tlili I., Renewable energy in Saudi Arabia: current status and future potentials, Environment, development and sustainability, 2015, 17, 4, 859-886.10.1007/s10668-014-9579-9Search in Google Scholar

[26] Sa’ed A., Tlili I., Numerical Investigation of Working Fluid Effect on Stirling Engine Performance, Int. J. Therm. Envir. Eng., 2015, 10, 1, 31-36.10.5383/ijtee.10.01.005Search in Google Scholar

[27] Tlili I., Finite time thermodynamic evaluation of endoreversible Stirling heat engine at maximum power conditions, Renew. Sust. Ener. Rev., May 2012.10.1016/j.rser.2012.01.022Search in Google Scholar

[28] Tlili I., Thermodynamic Study On Optimal Solar Stirling Engine Cycle Taking Into Account The Irreversibilities Effects, Ener. Procedia, March 2012.10.1016/j.egypro.2011.12.979Search in Google Scholar

[29] Tlili I., A numerical investigation of an alpha Stirling engine, Int. J. Heat & Techn., July 2012.Search in Google Scholar

[30] Tlili I., Musmar S.A., Thermodynamic evaluation of a second order simulation for Yoke Ross Stirling engine, Ener. Conv. Manag., April 2013.10.1016/j.enconman.2013.01.005Search in Google Scholar

[31] Tlili I., Timoumi Y., Nasrallah S.B., Analysis and design consideration of mean temperature differential Stirling engine for solar application, Renew. Ener., 2008, 33, 1911-1921.10.1016/j.renene.2007.09.024Search in Google Scholar

[32] Timoumi Y., Tlili I., Nasrallah S.B., Design and performance optimization of GPU-3 Stirling engines, Energy, 2008, 33, 1100-1114.10.1016/j.energy.2008.02.005Search in Google Scholar

[33] Timoumi Y., Tlili I., Nasrallah S.B., Reduction of energy losses in a Stirling engine” Heat Techn. 2007, 25(1), 84-93.Search in Google Scholar

[34] Al-Qawasmi A.-R., Tlili I., Energy Efficiency Audit Based on Wireless Sensor and Actor Networks: Air-Conditioning Investigation, J. Eng., 2018, 3640821.10.1155/2018/3640821Search in Google Scholar

[35] Al-Qawasmi A.-R., Tlili I., Energy efficiency and economic impact investigations for air-conditioners using wireless sensing and actuator networks, Ener. Rep., 2018, 4, 478-485.10.1016/j.egyr.2018.08.001Search in Google Scholar

[36] MN Khan, WA Khan, Tlili I., Forced Convection of Nanofluid Flow Across Horizontal Elliptical Cylinder with Constant Heat Flux Boundary Condition, J. Nanofluids, 2019, 8(2), 386-393.10.1166/jon.2019.1583Search in Google Scholar

[37] Tlili I., Khan W.A., Ramadan K., MHD Flow of Nanofluid Flow Across Horizontal Circular Cylinder: Steady Forced Convection, J. Nanofluids, 2019, 8(1), 179-186.10.1166/jon.2019.1574Search in Google Scholar

[38] Afridi M.I., Tlili I., Qasim M., Khan I., Nonlinear Rosseland thermal radiation and energy dissipation effects on entropy generation in CNTs suspended nanofluids flow over a thin needle, Bound. Value Probl., 2018, 148.10.1186/s13661-018-1062-3Search in Google Scholar

[39] Almutairi M.M., Osman M., Tlili I., Thermal Behavior of Auxetic Honeycomb Structure: An Experimental and Modeling Investigation, ASME. J. Ener. Res. Technol., 2018, 140(12), 122904-122904.10.1115/1.4041091Search in Google Scholar

[40] Li Z., Khan I., Shafee A., Tlili I., Asifa T., Energy transfer of Jeffery-Hamel nanofluid flow between non-parallel walls using Maxwell-Garnetts (MG) and Brinkman models, Ener. Rep., 2018, 4, 393-399.10.1016/j.egyr.2018.05.003Search in Google Scholar

[41] Khan M.N., Tlili I., Innovative thermodynamic parametric investigation of gas and steam bottoming cycles with heat exchanger and heat recovery steam generator: Energy and exergy analysis, Ener. Rep., 2018, 4, 497-506.10.1016/j.egyr.2018.07.007Search in Google Scholar

[42] Akter S., Hashmi M.S.J., Modelling of the pressure distribution within ahydrodynamic pressure unit: effect of the change in viscosity during drawingof wire coating, J. Mater. Process. Technol.,1998, 77, 32-36.10.1016/S0924-0136(97)00389-0Search in Google Scholar

[43] Akter S., Hashmi M.S.J., Analysis of polymer flow in a conical coating unit: apower law approach, Prog. Org. Coat., 1999, 37, 15-22.10.1016/S0300-9440(99)00045-4Search in Google Scholar

[44] Akter S., Hashmi M.S.J., Wire drawing and coating using a combined geometryhydrodynamic unit, J. Mater. Process. Technol. 178 (2006) 98-110.10.1016/j.jmatprotec.2006.02.010Search in Google Scholar

[45] Han C.D., Rao D., The rheology of wire coating extrusion, Polym. Eng. Sci., 1978, 18, 1019-1029.10.1002/pen.760181309Search in Google Scholar

[46] Kozan R., Prediction of the coating thickness of wire coating extrusionprocesses using artificialneural network (ANN), Mod. Appl. Sci., 2009, 3,52.10.5539/mas.v3n7p52Search in Google Scholar

[47] Sajid M., Siddiqui A.M., Hayat T., Wire coating analysis using MHDoldroyd8-constant fluid, Int. J. Eng. Sci., 2007, 45, 381-392.10.1016/j.ijengsci.2007.04.010Search in Google Scholar

[48] Shah R.A., Islam S., Ellahi M., Siddhiqui A.M., Harron T., Analytical solutions forheat transfer flows of a third grade fluid in post treatment of wire coating, Int. J. Phys. Sci., 2011, 6, 4213-4223.Search in Google Scholar

[49] Binding D.M., Blythe A.R., Guster S., Mosquera A.A., Townsend P., Wester M.P., Modelling polymer melt flows in wire coating process, J. Non-Newton. Fluid Mech., 1996, 64, 191-206.10.1016/0377-0257(96)01447-4Search in Google Scholar

[50] Multu I., Twnsend I., Webster M.F., Simulation of cable-coating viscoelasticflow with coupled and de-coupled schemes, J. Non-newton. Fluid Mech., 1998, 74, 1-23.10.1016/S0377-0257(97)00069-4Search in Google Scholar

[51] Kasajima M., Ito K., Post-treatment of polymer extrudate in wire coating, Appl.Polym. Symp., 1873, 20, 221-235.Search in Google Scholar

[52] Winter H.H., SPE 36th ANTEC, Tech. Papers, 1977, 23, 462.10.14789/pjmj.23.462Search in Google Scholar

[53] Symmons G.R., Hasmi M.S.J., Pervinmehr H., Plasto-hydrodynamics die lesswire drawing theoretical treatments and experimental result, in: ProgressReports in Conference in Developments in Drawing of Metals, Met. Soc. London, 1992, 54-62.Search in Google Scholar

[54] Baag S., Mishra S.R., Power law model in post treatment analysis of wirecoating with linearlyvariable temperature, Amer. J. Heat Mass Transf., 2015, 2, 89-107.10.7726/ajhmt.2015.1007Search in Google Scholar

[55] Kim K., Kwak H.H., Park S.H., Theoretical prediction on double-layer coating in wet-on-wet optical fiber coating process, J. Coat. Technol. Res., 2011, 8, 35-44.10.1007/s11998-010-9272-3Search in Google Scholar

[56] Kim K., Kwak H.H., Analytic Study of Non-Newtonian Double Layer Coating Liquid Flows in Optical Fiber Manufacturing, Trans Tech Publ, 2012, 224, 260-263.10.4028/www.scientific.net/AMM.224.260Search in Google Scholar

[57] Zeeshan, Shah R.A., Islam S., SiddiqueA. M., Double-layer Optical Fiber Coating Using Viscoelastic Phan-Thien-Tanner Fluid, New York Sci. J.,2013, 6, 66-73.Search in Google Scholar

[58] Khan Z., Islam S., Shah R.A., Khan I., Gu T., Exact Solution of PTT Fluid in Optical Fiber Coating Analysis using Two-layer Coating Flow, J. Appl. Environ. Biol. Sci., 2015, 596-105.Search in Google Scholar

[59] Khan Z., Islam S., Shah R.A., Flow and heat transfer of two immiscible fluids in double-layer optical fiber coating, J. Coat. Technol. Res., 2016, 13, 1055-1063.10.1007/s11998-016-9817-1Search in Google Scholar

[60] Ali F., Aamina, Khan I., Sheikh N.A., Gohar M., Tlili I., Effects of Different Shaped Nanoparticles on the Performance of Engine-Oil and Kerosene-Oil: A generalized Brinkman-Type Fluid model with Non-Singular Kernel, Sci. Rep., 2018, 8, 15285.10.1038/s41598-018-33547-zSearch in Google Scholar PubMed PubMed Central

[61] Tlili I., Khan W.A., Ramadan K., Entropy Generation Due to MHD Stagnation Point Flow of a Nanofluid on a Stretching Surface in the Presence of Radiation, J. Nanofluids, 2018, 7(5), 879-890.10.1166/jon.2018.1513Search in Google Scholar

[62] Asif M., UlHaq S., Islam S., Khan I., Tlili I., Exact solution of non-Newtonian fluid motion between side walls, Results Phys., 2018, 11, 534-539.10.1016/j.rinp.2018.09.023Search in Google Scholar

[63] Agaie B.G., Khan I., Yacoob Z., Tlili I., A novel technique of reduce order modellingwithout static correction for transient flow of non-isothermal hydrogen-natural gas mixture, Results Phys., 2018, 10, 532-540.10.1016/j.rinp.2018.01.052Search in Google Scholar

[64] Khalid A., Khan I., Khan A., Shafie S., Tlili I., Case study of MHD blood flow in a porous medium with CNTS and thermal analysis, Case Studies Therm. Eng., 2018, 12, 374-380.10.1016/j.csite.2018.04.004Search in Google Scholar

[65] Khan I., Ali Abro K., Mirbhar M.N., Tlili I., Thermal analysis in Stokes’ second problem of nanofluid: Applications in thermal engineering, Case Studies Therm. Eng., 2018, 12, 271-275.10.1016/j.csite.2018.04.005Search in Google Scholar

[66] Afridi M.I., Qasim M., Khan I., Tlili I., Entropy generation in MHD mixed convection stagnation-point flow in the presence of joule and frictional heating, Case Studies in Therm. Eng., 2018, 12, 292-300.10.1016/j.csite.2018.04.002Search in Google Scholar

[67] Khan M.N., Tlili I., New advancement of high performance for a combined cycle power plant: Thermodynamic analysis, Case Studies in Therm. Eng., 2018, 12, 166-175.10.1016/j.csite.2018.04.001Search in Google Scholar

[68] Khan M.N., Tlili I., Performance enhancement of a combined cycle using heat exchanger bypass control: A thermodynamic investigation, J. Clean. Prod., 2018, 192(10), 443-452.10.1016/j.jclepro.2018.04.272Search in Google Scholar

[69] Khan Z.A., Ul Haq S., Khan T.S., Khan I., Tlili I., Unsteady MHD flow of a Brinkman type fluid between two side walls perpendicular to an infinite plate, Results Phys., 2018, 9, 1602-1608.10.1016/j.rinp.2018.04.034Search in Google Scholar

[70] Aman S., Khan I., Ismail Z., Salleh M., Tlili I., A new Caputo time fractional model for heat transfer enhancement of water based graphene nanofluid: An application to solar energy, Results Phys., 2018, 9, 1352-1362.10.1016/j.rinp.2018.04.007Search in Google Scholar

[71] Khan Z., Khan I., Ullah M., Tlili I., Effect of thermal radiation and chemical reaction on non-Newtonian fluid through a vertically stretching porous plate with uniform suction, Results Phys., 2018, 9, 1086-1095.10.1016/j.rinp.2018.03.041Search in Google Scholar

[72] Khan I., Tlili I., Imran M.A., Fizza M., MHD fractional Jeffrey’s fluid flow in the presence of thermo diffusion, thermal radiation effects with first order chemical reaction and uniform heat flux, Results Phys., 2018, 10, 10-17.10.1016/j.rinp.2018.04.008Search in Google Scholar

[73] Tlili I., Khan W.A., Khan I., Multiple slips effects on MHD SA-Al2O3 and SA-Cu non-Newtonian nanofluids flow over a stretching cylinder in porous medium with radiation and chemical reaction, Results Phys., 2018, 8, 213-222.10.1016/j.rinp.2017.12.013Search in Google Scholar

[74] Khan Z., Ur Rasheed H., Tlili I., Khan I., Abbas T., Runge-Kutta 4th-order method analysis for viscoelastic Oldroyd 8-constant fluid used as coating material for wire with temperature dependent viscosity, Sci. Rep., 2018, 8(8), 14504.10.1038/s41598-018-32068-zSearch in Google Scholar PubMed PubMed Central

[75] Tlili I., Hamadneh N.N., Khan W.A., Thermodynamic Analysis of MHD Heat and Mass Transfer of Nanofluids Past a Static Wedge with Navier Slip and Convective Boundary Conditions, Arab. J. Sci. Eng., 2018, 1-13.10.1007/s13369-018-3471-0Search in Google Scholar

[76] Tlili I., Hamadneh N.N., Khan W.A., Atawneh S., Thermodynamic analysis of MHD Couette-Poiseuille flow of water-based nanofluids in a rotating channel with radiation and Hall effects, J. Therm. Anal. Calorim., 2018, 132(3), 1899-1912.10.1007/s10973-018-7066-5Search in Google Scholar

[77] Khan M.N., Tlili I., Khan W.A., Thermodynamic Optimization of New Combined Gas/Steam Power Cycles with HRSG and Heat Exchanger, Arab. J. Sci. Eng., 2017, 42(11), 4547-4558.10.1007/s13369-017-2549-4Search in Google Scholar

[78] Makinde O.D., Iskander T., Mabood F., Khan W.A., Tshehla M.S., MHD Couette-Poiseuille flow of variable viscosity nanofluids in a rotating permeable channel with Hall effects, J. Mol. Liq., 2016, 221, 778-787.10.1016/j.molliq.2016.06.037Search in Google Scholar

[79] Musmar S.A., Al-Halhouli A.T., Tlili I., Büttgenbach S., Performance Analysis of a New Water-based Microcooling System, Exp. Heat Trans., 2018, 29(4), 485-499.10.1080/08916152.2015.1024353Search in Google Scholar

[80] Ramadan K., Tlili I., Shear work, viscous dissipation and axial conduction effects on microchannel heat transfer with a constant wall temperature, Proc. Instit. Mech. Eng., Part C: J. Mech. Eng. Sci., 2015, 230(14), 2496-2507.10.1177/0954406215598799Search in Google Scholar

[81] Ramadan K., Tlili I., A Numerical Study of the Extended Graetz Problem in a Microchannel with Constant Wall Heat Flux: Shear Work Effects on Heat Transfer, J. Mech., 2015, 31(6), 733-743.10.1017/jmech.2015.29Search in Google Scholar

[82] Musmar S.A., Razavinia N., Mucciardi F., Tlili I., Performance analysis of a new Waste Heat Recovery System, Int. J. Therm. Envir. Eng., 2015, 10, 31-36.Search in Google Scholar

[83] Shah R.A., Islam S., Siddiqui A.M., Haroon T.,Wire coating analysis with Oldroy 8-constant fluid by optimal homotopy asymptotic method, Comput. Math. Appl, 2012, 63, 693-707.10.1016/j.camwa.2011.11.033Search in Google Scholar

Received: 2018-03-16
Accepted: 2018-05-17
Published Online: 2018-12-31

© 2018 Z. Khan et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.

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https://doi.org/10.1515/phys-2018-0117
Keywords for this article
Ruge-Kuta 4th-order method; heat transfer; temperature dependent viscosity; wire coating; viscoelastic Oldroyd 8-constant fluid
Creative Commons
BY-NC-ND 4.0

Articles in the same Issue

  1. Regular Articles
  2. A modified Fermi-Walker derivative for inextensible flows of binormal spherical image
  3. Algebraic aspects of evolution partial differential equation arising in the study of constant elasticity of variance model from financial mathematics
  4. Three-dimensional atom localization via probe absorption in a cascade four-level atomic system
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  60. Structure of traveling wave solutions for some nonlinear models via modified mathematical method
  61. Thermo-convective instability in a rotating ferromagnetic fluid layer with temperature modulation
  62. Construction of new solitary wave solutions of generalized Zakharov-Kuznetsov-Benjamin-Bona-Mahony and simplified modified form of Camassa-Holm equations
  63. Effect of magnetic field and heat source on Upper-convected-maxwell fluid in a porous channel
  64. Physical cues of biomaterials guide stem cell fate of differentiation: The effect of elasticity of cell culture biomaterials
  65. Shooting method analysis in wire coating withdrawing from a bath of Oldroyd 8-constant fluid with temperature dependent viscosity
  66. Rank correlation between centrality metrics in complex networks: an empirical study
  67. Special Issue: The 18th International Symposium on Electromagnetic Fields in Mechatronics, Electrical and Electronic Engineering
  68. Modeling of electric and heat processes in spot resistance welding of cross-wire steel bars
  69. Dynamic characteristics of triaxial active control magnetic bearing with asymmetric structure
  70. Design optimization of an axial-field eddy-current magnetic coupling based on magneto-thermal analytical model
  71. Thermal constitutive matrix applied to asynchronous electrical machine using the cell method
  72. Temperature distribution around thin electroconductive layers created on composite textile substrates
  73. Model of the multipolar engine with decreased cogging torque by asymmetrical distribution of the magnets
  74. Analysis of spatial thermal field in a magnetic bearing
  75. Use of the mathematical model of the ignition system to analyze the spark discharge, including the destruction of spark plug electrodes
  76. Assessment of short/long term electric field strength measurements for a pilot district
  77. Simulation study and experimental results for detection and classification of the transient capacitor inrush current using discrete wavelet transform and artificial intelligence
  78. Magnetic transmission gear finite element simulation with iron pole hysteresis
  79. Pulsed excitation terahertz tomography – multiparametric approach
  80. Low and high frequency model of three phase transformer by frequency response analysis measurement
  81. Multivariable polynomial fitting of controlled single-phase nonlinear load of input current total harmonic distortion
  82. Optimal design of a for middle-low-speed maglev trains
  83. Eddy current modeling in linear and nonlinear multifilamentary composite materials
  84. The visual attention saliency map for movie retrospection
  85. AC/DC current ratio in a current superimposition variable flux reluctance machine
  86. Influence of material uncertainties on the RLC parameters of wound inductors modeled using the finite element method
  87. Cogging force reduction in linear tubular flux switching permanent-magnet machines
  88. Modeling hysteresis curves of La(FeCoSi)13 compound near the transition point with the GRUCAD model
  89. Electro-magneto-hydrodynamic lubrication
  90. 3-D Electromagnetic field analysis of wireless power transfer system using K computer
  91. Simplified simulation technique of rotating, induction heated, calender rolls for study of temperature field control
  92. Design, fabrication and testing of electroadhesive interdigital electrodes
  93. A method to reduce partial discharges in motor windings fed by PWM inverter
  94. Reluctance network lumped mechanical & thermal models for the modeling and predesign of concentrated flux synchronous machine
  95. Special Issue Applications of Nonlinear Dynamics
  96. Study on dynamic characteristics of silo-stock-foundation interaction system under seismic load
  97. Microblog topic evolution computing based on LDA algorithm
  98. Modeling the creep damage effect on the creep crack growth behavior of rotor steel
  99. Neighborhood condition for all fractional (g, f, n′, m)-critical deleted graphs
  100. Chinese open information extraction based on DBMCSS in the field of national information resources
  101. 10.1515/phys-2018-0079
  102. CPW-fed circularly-polarized antenna array with high front-to-back ratio and low-profile
  103. Intelligent Monitoring Network Construction based on the utilization of the Internet of things (IoT) in the Metallurgical Coking Process
  104. Temperature detection technology of power equipment based on Fiber Bragg Grating
  105. Research on a rotational speed control strategy of the mandrel in a rotary steering system
  106. Dynamic load balancing algorithm for large data flow in distributed complex networks
  107. Super-structured photonic crystal fiber Bragg grating biosensor image model based on sparse matrix
  108. Fractal-based techniques for physiological time series: An updated approach
  109. Analysis of the Imaging Characteristics of the KB and KBA X-ray Microscopes at Non-coaxial Grazing Incidence
  110. Application of modified culture Kalman filter in bearing fault diagnosis
  111. Exact solutions and conservation laws for the modified equal width-Burgers equation
  112. On topological properties of block shift and hierarchical hypercube networks
  113. Elastic properties and plane acoustic velocity of cubic Sr2CaMoO6 and Sr2CaWO6 from first-principles calculations
  114. A note on the transmission feasibility problem in networks
  115. Ontology learning algorithm using weak functions
  116. Diagnosis of the power frequency vacuum arc shape based on 2D-PIV
  117. Parametric simulation analysis and reliability of escalator truss
  118. A new algorithm for real economy benefit evaluation based on big data analysis
  119. Synergy analysis of agricultural economic cycle fluctuation based on ant colony algorithm
  120. Multi-level encryption algorithm for user-related information across social networks
  121. Multi-target tracking algorithm in intelligent transportation based on wireless sensor network
  122. Fast recognition method of moving video images based on BP neural networks
  123. Compressed sensing image restoration algorithm based on improved SURF operator
  124. Design of load optimal control algorithm for smart grid based on demand response in different scenarios
  125. Face recognition method based on GA-BP neural network algorithm
  126. Optimal path selection algorithm for mobile beacons in sensor network under non-dense distribution
  127. Localization and recognition algorithm for fuzzy anomaly data in big data networks
  128. Urban road traffic flow control under incidental congestion as a function of accident duration
  129. Optimization design of reconfiguration algorithm for high voltage power distribution network based on ant colony algorithm
  130. Feasibility simulation of aseismic structure design for long-span bridges
  131. Construction of renewable energy supply chain model based on LCA
  132. The tribological properties study of carbon fabric/ epoxy composites reinforced by nano-TiO2 and MWNTs
  133. A text-Image feature mapping algorithm based on transfer learning
  134. Fast recognition algorithm for static traffic sign information
  135. Topical Issue: Clean Energy: Materials, Processes and Energy Generation
  136. An investigation of the melting process of RT-35 filled circular thermal energy storage system
  137. Numerical analysis on the dynamic response of a plate-and-frame membrane humidifier for PEMFC vehicles under various operating conditions
  138. Energy converting layers for thin-film flexible photovoltaic structures
  139. Effect of convection heat transfer on thermal energy storage unit
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