Experimental and simulation investigation of pulsed heat pipes in gas compressors

Araz Alizadeh; MohammadBehshad Shafii; Alireza hajiseyed Mirzahosseini; Abtin Ataei; Araz Alizadeh; MohammadBehshad Shafii; Alireza hajiseyed Mirzahosseini; Abtin Ataei

doi:10.3934/energy.2020.3.438

AIMS Energy

2020, Volume 8, Issue 3: 438-454. doi: 10.3934/energy.2020.3.438

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Research article Topical Sections

Experimental and simulation investigation of pulsed heat pipes in gas compressors

1.
Department of Energy Engineering, Faculty of Natural Resources and Environment, Science and Research Branch, Islamic Azad University, Tehran, Iran
2.
Department of Mechanical Engineering, Sharif University of Technology, Tehran, Iran
3.
Department of Environmental Engineering, Faculty of Natural Resources and Environment, Science and Research Branch, Islamic Azad University, Tehran, Iran

Received: 27 February 2020 Accepted: 25 May 2020 Published: 03 June 2020

In natural gas pressure boosting stations, air coolers are used to reduce the gas temperature. Pressure drop as an essential factor in determining the energy performance of any pressure boosting station has a significant impact on the overall performance of the gas transmission. In this paper, a laboratory pilot is designed to investigate the effect of pressure drop reduction on the use of heating pipes at the air coolers. In addition, as a case for a gas pressure boosting station, its impact over energy performance index and pressure drop parameter has been calculated through simulating. The results show, implemented PHP tubes in an air cooler, lead to reduce tube length and improve pressure drop, 44.59, 40.4, 36.78, 23.34% in four gas flow rate. Also, this approach decreased fuel gas consumption more than 1,114,000 Sm3 and 3,889,440 kWh electrical consumption in air coolers, annually. Beside, investigation of energy performance indicators reveals that this approach might improve the total energy performance, thermal performance and electrical energy performance indices up to 3, 2.3 and 79%, respectively.

Keywords:

Citation: Araz Alizadeh, MohammadBehshad Shafii, Alireza hajiseyed Mirzahosseini, Abtin Ataei. Experimental and simulation investigation of pulsed heat pipes in gas compressors[J]. AIMS Energy, 2020, 8(3): 438-454. doi: 10.3934/energy.2020.3.438

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Abstract

1. Introduction

Fractional calculus is a main branch of mathematics that can be considered as the generalisation of integration and differentiation to arbitrary orders. This hypothesis begins with the assumptions of L. Euler (1730) and G. W. Leibniz (1695). Fractional differential equations (FDEs) have lately gained attention and publicity due to their realistic and accurate computations ^{[1,2,3,4,5,6,7]}. There are various types of fractional derivatives, including Riemann–Liouville, Caputo, Grü nwald–Letnikov, Weyl, Marchaud, and Atangana. This topic's history can be found in ^[8,9,10,11]. Undoubtedly, fractional calculus applies to mathematical models of different phenomena, sometimes more effectively than ordinary calculus ^[12,13]. As a result, it can illustrate a wide range of dynamical and engineering models with greater precision. Applications have been developed and investigated in a variety of scientific and engineering fields over the last few decades, including bioengineering ^[14], mechanics ^[15], optics ^[16], physics ^[17], mathematical biology, electrical power systems ^[18,19,20] and signal processing ^[21,22,23].

One of the definitions of fractional derivatives is Caputo-Fabrizo, which adds a new dimension in the study of FDEs. The new derivative's feature is that it has a nonsingular kernel, which is made from a combination of an ordinary derivative with an exponential function, but it has the same supplementary motivating properties with various scales as in the Riemann-Liouville fractional derivatives and Caputo. The Caputo-Fabrizio fractional derivative has been used to solve real-world problems in numerous areas of mathematical modelling for example, numerical solutions for groundwater pollution, the movement of waves on the surface of shallow water modelling ^[24], RLC circuit modelling ^[25], and heat transfer modelling ^[26,27] were discussed.

Rach (1987), Bellomo and Sarafyan (1987) first compared the Adomian Decomposition method (ADM) ^{[28,29,30,31,32]} to the Picard method on a variety of examples. These methods have many benefits: they effectively work with various types of linear and nonlinear equations and also provide an analytic solution for all of these equations with no linearization or discretization. These methods are more realistic compared with other numerical methods as each technique is used to solve a specific type of equations, on the other hand ADM and Picard are useful for many types of equations. In the numerical examples provided, we compare ADM and Picard solutions of multidimentional fractional order equations with Caputo-Fabrizio.

The fractional derivative of Caputo-Fabrizio for the function $x\left(t\right)$ is defined as ^[33]

$\begin{equation} ^{CF}D_{0}^{\alpha }x\left( t\right) = \frac{B\left( \alpha \right) }{ 1-\alpha }\int_{0}^{t}\frac{d}{ds}\left( x\left( s\right) \right) \text{ } e^{-\frac{\alpha }{1-\alpha }(t-s)}ds, \end{equation}$

(1.1)

and its corresponding fractional integral is

$\begin{equation} ^{CF}I^{\alpha }x\left( t\right) = \frac{1-\alpha }{B\left( \alpha \right) } x\left( t\right) +\frac{\alpha }{B\left( \alpha \right) }\int_{0}^{t}x^{ \text{ }}\left( s\right) ds,{ \ \ \ \ }0 < \alpha < 1, \end{equation}$

(1.2)

where $x\left(t\right)$ be continuous and differentiable on [0, T]. Also, in the above definition, the function $B\left(\alpha \right) > 0$ is a normalized function which satisfy the condition $B\left(0\right) = B\left(1\right) = 0.$ The relation between the Caputo–Fabrizio fractional derivate and its corresponding integral is given by

$\begin{equation} \left( ^{CF}I_{0}^{\alpha }\right) \left( ^{CF}D_{0}^{\alpha }f\left( t\right) \right) = f\left( t\right) -f\left( a\right) . \end{equation}$

(1.3)

2. Construction of the algorithm

In this section, we will introduce a multidimentional FDE subject to the initial condition. Let $\alpha \in \; (0, 1]$ , $0 < \alpha _{1} < \alpha _{2} < ..., \alpha _{m} < 1,$ and $m$ is integer real number,

$\begin{eqnarray} ^{CF}Dx & = &f(t,x,^{CF}D^{\alpha _{1}}x,^{CF}D^{\alpha _{2}}x,...,^{CF}D^{\alpha _{m}}x,)\text{ }, \\ x\left( 0\right) & = &c_{0}, \end{eqnarray}$

(2.1)

where $x = x\left(t\right), t\in J = \left[ 0, T\right], T\in R^{+}, x\in C\left(J\right)$ .

To facilitate the equation and make it easy for the calculation, we let $x\left(t\right) = c_{0}+X\left(t\right)$ so Eq (2.1) can be witten as

$\begin{eqnarray} ^{CF}D^{\alpha }X & = &f(t,c_{0}+X,^{CF}D^{\alpha _{1}}X,^{CF}D^{\alpha _{2}}X,...,^{CF}D^{\alpha _{m}}X), \\ \text{ }X\left( 0\right) & = &0. \end{eqnarray}$

(2.2)

the algorithm depends on converting the initial condition from a constant $c_{0}$ to 0.

Let $^{CF}D^{\alpha }X = y\left(t\right)$ then $X = \; ^{CF}I^{\alpha }y,$ so we have

$\begin{equation} ^{CF}D^{\alpha i}X = \text{ }^{CF}I^{\alpha -\alpha i{ \ }CF}D^{\alpha }X = \text{ }^{CF}I^{\alpha -\alpha i}y,{ \ \ }i = 1,2,...,m. \end{equation}$

(2.3)

Substituting in Eq (2.2) we obtain

$\begin{equation} y = f(t,c_{0}+\text{ }^{CF}I^{\alpha }y,\text{ }^{CF}I^{\alpha -\alpha _{1}}y,...,\text{ }^{CF}I^{\alpha -\alpha _{m}}y). \end{equation}$

(2.4)

Assume $f$ satisfies Lipschtiz condition with Lipschtiz constant $\ L$ given by,

$\begin{equation} \left\vert f(t,y_{0},y_{1},...,y_{m})\right\vert -\left\vert f(t,z_{0},z_{1},...,z_{m})\right\vert \leq L\sum\limits_{i = 0}^{m}\left\vert y_{i}-z_{i}\right\vert , \end{equation}$

(2.5)

which implies

$\begin{eqnarray} && \begin{array}{c} \left\vert f(t,c_{0}+^{CF}I^{\alpha }y,^{CF}I^{\alpha -\alpha _{1}}y,..,^{CF}I^{\alpha -\alpha _{m}}y)\right. \\ \left. -f(t,c_{0}+^{CF}I^{\alpha }z,^{CF}I^{\alpha -\alpha _{1}}z,..,^{CF}I^{\alpha -\alpha _{m}}z)\right\vert \end{array} \\ &\leq &L\sum\limits_{i = 0}^{m}\left\vert \text{ }^{CF}I^{\alpha -\alpha _{i}}y-\text{ }^{CF}I^{\alpha -\alpha _{i}}z\right\vert . \end{eqnarray}$

(2.6)

The solution algorithm of Eq (2.4) using ADM is,

$\begin{eqnarray} y_{0}\left( t\right) & = &a\left( t\right) \\ y_{n+1}\left( t\right) & = &A_{n}\left( t\right) ,{ \ }j\geqslant 0. \end{eqnarray}$

(2.7)

where $a\left(t\right)$ pocesses all free terms in Eq (2.4) and $A_{n}$ are the Adomian polynomials of the nonlinear term which takes the form ^[34]

$\begin{equation} A_{n} = f\left( S_{n}\right) -\sum\limits_{i = 0}^{n-1}A_{i}, \end{equation}$

(2.8)

where $f\left(S_{n}\right) = \sum_{i = 0}^{n}A_{i}$ . Later, this accelerated formula of Adomian polynomial will be used in convergence analysis and error estimation. The solution of Eq (2.4) can be written in the form,

$\begin{equation} y\left( t\right) = \sum\limits_{i = 0}^{\infty }y_{i}\left( t\right) . \end{equation}$

(2.9)

lastly, the solution of the Eq (2.4) takes the form

$\begin{equation} x\left( t\right) = c_{0}+X\left( t\right) = c_{0}+\text{ }^{CF}I^{\alpha }y\left( t\right) . \end{equation}$

(2.10)

At which we convert the parameter to the initial form $y$ to $x$ in Eq (2.10), so we have the solution of the original Eq (2.1).

3. Convergence analysis

3.1. Existence and uniqueness

Define a mapping $F:E\rightarrow E$ where $E = \left(C\left[ J\right], \left\Vert \cdot \right\Vert \right)$ is a Banach space of all continuous functions on $J$ with the norm $\left\Vert x\right\Vert = \underset{t\epsilon J}{\text{ }\max\limits } \; x\left(t\right)$ .

Theorem 3.1. Equation (2.4) has a unique solution whenever $0 < \phi < 1$ where $\phi = L\left(\sum_{i = 0}^{m}\frac{\left[ \left(\alpha-\alpha _{i}\right) \left(T-1\right) \right] +1}{B\left(\alpha -\alpha_{i}\right) }\right)$ .

Proof. First, we define the mapping $F:E\rightarrow E$ as

$\begin{equation*} Fy = f(t,c_{0}+\text{ }^{CF}I^{\alpha }y,\text{ }^{CF}I^{\alpha -\alpha _{1}}y,...,\text{ }^{CF}I^{\alpha -\alpha _{m}}y). \end{equation*}$

Let $y$ and $z\in E$ are two different solutions of Eq (2.4). Then

$\begin{equation*} Fy-Fz = f(t,c_{0}+^{CF}I^{\alpha }y,^{CF}I^{\alpha -\alpha _{1}}y,..,^{CF}I^{\alpha -\alpha _{m}}y)-f(t,c_{0}+^{CF}I^{\alpha }z,^{CF}I^{\alpha -\alpha _{1}}z,...,^{CF}I^{\alpha -\alpha _{m}}z) \end{equation*}$

which implies that

$\begin{eqnarray*} \left\vert Fy-Fz\right\vert & = &\left\vert f(t,c_{0}+\text{ }^{CF}I^{\alpha }y,\text{ }^{CF}I^{\alpha -\alpha _{1}}y,...,\text{ }^{CF}I^{\alpha -\alpha _{m}}y)\right. \\ &&-\left. f(t,c_{0}+\text{ }^{CF}I^{\alpha }z,\text{ }^{CF}I^{\alpha -\alpha _{1}}z,...,\text{ }^{CF}I^{\alpha -\alpha _{m}}z)\right\vert \\ &\leq &L\sum\limits_{i = 0}^{m}\left\vert \text{ }^{CF}I^{\alpha -\alpha _{i}}y-\text{ }^{CF}I^{\alpha -\alpha _{i}}z\right\vert \\ &\leq &L\sum\limits_{i = 0}^{m}\left\vert \frac{1-\left( \alpha -\alpha _{i}\right) }{ B\left( \alpha -\alpha _{i}\right) }\left( y-z\right) +\frac{\alpha -\alpha _{i}}{B\left( \alpha -\alpha _{i}\right) }\int_{0}^{t}\left( y-z\right) ds\right\vert \\ \left\Vert Fy-Fz\right\Vert &\leq &L\sum\limits_{i = 0}^{m}\frac{1-\left( \alpha -\alpha _{i}\right) }{B\left( \alpha -\alpha _{i}\right) }\underset{ t\epsilon J}{\max }\left\vert y-z\right\vert +\frac{\alpha -\alpha _{i}}{ B\left( \alpha -\alpha _{i}\right) }\underset{t\epsilon J}{\max }\left\vert y-z\right\vert \int_{0}^{t}ds \\ &\leq &L\sum\limits_{i = 0}^{m}\frac{1-\left( \alpha -\alpha _{i}\right) }{B\left( \alpha -\alpha _{i}\right) }\left\Vert y-z\right\Vert +\frac{\alpha -\alpha _{i}}{B\left( \alpha -\alpha _{i}\right) }\left\Vert y-z\right\Vert T \\ &\leq &L\left\Vert y-z\right\Vert \left( \sum\limits_{i = 0}^{m}\frac{1-\left( \alpha -\alpha _{i}\right) }{B\left( \alpha -\alpha _{i}\right) }+\frac{\alpha -\alpha _{i}}{B\left( \alpha -\alpha _{i}\right) }T\right) \\ &\leq &L\left\Vert y-z\right\Vert \left( \sum\limits_{i = 0}^{m}\frac{\left[ \left( \alpha -\alpha _{i}\right) \left( T-1\right) \right] +1}{B\left( \alpha -\alpha _{i}\right) }\right) \\ &\leq &\phi \left\Vert y-z\right\Vert . \end{eqnarray*}$

under the condition $0 < \phi < 1,$ the mapping $F$ is contraction and hence there exists a unique solution $y\in C\left[ J\right]$ for the problem Eq (2.4) and this completes the proof.

3.2. Proof of convergence

Theorem 3.2. The series solution of the problem Eq (2.4)converges if $\left\vert y_{1}\left(t\right) \right\vert < c$ and $c$ isfinite.

Proof. Define a sequence $\left\{ S_{p}\right\}$ such that $S_{p} = \sum_{i = 0}^{p}y_{i}\left(t\right)$ is the sequence of partial sums from the series solution $\sum_{i = 0}^{\infty }y_{i}\left(t\right),$ we have

$\begin{equation*} f(t,c_{0}+\text{ }^{CF}I^{\alpha }y,\text{ }^{CF}I^{\alpha -\alpha _{1}}y,...,\text{ }^{CF}I^{\alpha -\alpha _{m}}y) = \sum\limits_{i = 0}^{\infty }A_{i}, \end{equation*}$

$\begin{equation*} f(t,c_{0}+\text{ }^{CF}I^{\alpha }S_{p},\text{ }^{CF}I^{\alpha -\alpha _{1}}S_{p},...,\text{ }^{CF}I^{\alpha -\alpha _{m}}S_{p}) = \sum\limits_{i = 0}^{p}A_{i}, \end{equation*}$

From Eq (2.7) we have

$\begin{equation*} \sum\limits_{i = 0}^{\infty }y_{i}\left( t\right) = a\left( t\right) +\sum\limits_{i = 0}^{\infty }A_{i-1} \end{equation*}$

let $S_{p}, S_{q}$ be two arbitrary sums with $p\geqslant q$ . Now, we are going to prove that $\left\{ S_{p}\right\}$ is a Caushy sequence in this Banach space. We have

$\begin{eqnarray*} S_{p} & = &\sum\limits_{i = 0}^{p}y_{i}\left( t\right) = a\left( t\right) +\sum\limits_{i = 0}^{p}A_{i-1,} \\ S_{q} & = &\sum\limits_{i = 0}^{q}y_{i}\left( t\right) = a\left( t\right) +\sum\limits_{i = 0}^{q}A_{i-1.} \end{eqnarray*}$

$\begin{eqnarray*} S_{p}-S_{q} & = &\sum\limits_{i = 0}^{p}A_{i-1}-\sum\limits_{i = 0}^{q}A_{i-1} = \sum\limits_{i = q+1}^{p}A_{i-1} = \sum\limits_{i = q}^{p-1}A_{i-1} \\ & = &f(t,c_{0}+\text{ }^{CF}I^{\alpha }S_{p-1},\text{ }^{CF}I^{\alpha -\alpha _{1}}S_{p-1},...,\text{ }^{CF}I^{\alpha -\alpha _{m}}S_{p-1})- \\ &&f(t,c_{0}+\text{ }^{CF}I^{\alpha }S_{q-1},\text{ }^{CF}I^{\alpha -\alpha _{1}}S_{q-1},...,\text{ }^{CF}I^{\alpha -\alpha _{m}}S_{q-1}) \end{eqnarray*}$

$\begin{eqnarray*} \left\vert S_{p}-S_{q}\right\vert & = &\left\vert f(t,c_{0}+\text{ } ^{CF}I^{\alpha }S_{p-1},\text{ }^{CF}I^{\alpha -\alpha _{1}}S_{p-1},..., \text{ }^{CF}I^{\alpha -\alpha _{m}}S_{p-1})-\right. \\ &&\left. f(t,c_{0}+\text{ }^{CF}I^{\alpha }S_{q-1},\text{ }^{CF}I^{\alpha -\alpha _{1}}S_{q-1},...,\text{ }^{CF}I^{\alpha -\alpha _{m}}S_{q-1})\right\vert \\ &\leq &L\sum\limits_{i = 0}^{m}\left\vert \text{ }^{CF}I^{\alpha -\alpha _{i}}S_{p-1}- \text{ }^{CF}I^{\alpha -\alpha _{i}}S_{q-1}\right\vert \\ &\leq &L\sum\limits_{i = 0}^{m}\left\vert \frac{1-\left( \alpha -\alpha _{i}\right) }{ B\left( \alpha -\alpha _{i}\right) }\left( S_{p-1}-S_{q-1}\right) +\frac{ \alpha -\alpha _{i}}{B\left( \alpha -\alpha _{i}\right) }\int_{0}^{t}\left( S_{p-1}-S_{q-1}\right) ds\right\vert \\ &\leq &L\sum\limits_{i = 0}^{m}\frac{1-\left( \alpha -\alpha _{i}\right) }{B\left( \alpha -\alpha _{i}\right) }\left\vert S_{p-1}-S_{q-1}\right\vert +\frac{ \alpha -\alpha _{i}}{B\left( \alpha -\alpha _{i}\right) }\int_{0}^{t}\left \vert S_{p-1}-S_{q-1}\right\vert ds \end{eqnarray*}$

$\begin{eqnarray*} \left\Vert S_{p}-S_{q}\right\Vert &\leq &L\sum\limits_{i = 0}^{m}\frac{1-\left( \alpha -\alpha _{i}\right) }{B\left( \alpha -\alpha _{i}\right) }\underset{ t\epsilon J}{\max }\left\vert S_{p-1}-S_{q-1}\right\vert +\frac{\alpha -\alpha _{i}}{B\left( \alpha -\alpha _{i}\right) }\underset{t\epsilon J}{ \max }\left\vert S_{p-1}-S_{q-1}\right\vert \int_{0}^{t}ds \\ &\leq &L\left\Vert S_{p}-S_{q}\right\Vert \sum\limits_{i = 0}^{m}\left( \frac{ 1-\left( \alpha -\alpha _{i}\right) }{B\left( \alpha -\alpha _{i}\right) }+ \frac{\alpha -\alpha _{i}}{B\left( \alpha -\alpha _{i}\right) }T\right) \\ &\leq &L\left\Vert S_{p}-S_{q}\right\Vert \left( \sum\limits_{i = 0}^{m}\frac{\left[ \left( \alpha -\alpha _{i}\right) \left( T-1\right) \right] +1}{B\left( \alpha -\alpha _{i}\right) }\right) \\ &\leq &\phi \left\Vert S_{p}-S_{q}\right\Vert \end{eqnarray*}$

let $p = q+1$ then,

$\begin{equation*} \left\Vert S_{q+1}-S_{q}\right\Vert \leq \phi \left\Vert S_{q}-S_{q-1}\right\Vert \leq \phi ^{2}\left\Vert S_{q-1}-S_{q-2}\right\Vert \leq ...\leq \phi ^{q}\left\Vert S_{1}-S_{0}\right\Vert \end{equation*}$

From the triangle inequality we have

$\begin{eqnarray*} \left\Vert S_{p}-S_{q}\right\Vert &\leq &\left\Vert S_{q+1}-S_{q}\right\Vert +\left\Vert S_{q+2}-S_{q+1}\right\Vert +...\left\Vert S_{p}-S_{p-1}\right\Vert \\ &\leq &\left[ \phi ^{q}+\phi ^{q+1}+...+\phi ^{p-1}\right] \left\Vert S_{1}-S_{0}\right\Vert \\ &\leq &\phi ^{q}\left[ 1+\phi +...+\phi ^{p-q+1}\right] \left\Vert S_{1}-S_{0}\right\Vert \\ &\leq &\phi ^{q}\left[ \frac{1-\phi ^{p-q}}{1-\phi }\right] \left\Vert y_{1}\left( t\right) \right\Vert \end{eqnarray*}$

Since $0 < \phi < 1, p\geqslant q$ then $\left(1-\phi ^{p-q}\right) \leq 1$ . Consequently

$\begin{equation} \left\Vert S_{p}-S_{q}\right\Vert \leq \frac{\phi ^{q}}{1-\phi }\left\Vert y_{1}\left( t\right) \right\Vert \leq \frac{\phi ^{q}}{1-\phi }\underset{ \forall t\epsilon J}{\max }\left\vert y_{1}\left( t\right) \right\vert \end{equation}$

(3.1)

but $\left\vert y_{1}\left(t\right) \right\vert < \infty$ and as $q\rightarrow \infty$ then, $\left\Vert S_{p}-S_{q}\right\Vert \rightarrow 0$ and hence, $\left\{ S_{p}\right\}$ is a Caushy sequence in this Banach space then the proof is complete.

3.3. Error estimate

Theorem 3.3. The maximum absolute truncated error Eq (2.4)is estimated to be $\underset{t\epsilon J}{\max }\left\vert y\left(t\right)-\sum_{i = 0}^{q}y_{i}\left(t\right) \right\vert \leq \frac{\phi ^{q}}{1-\phi }\underset{t\epsilon J}{\max }\left\vert y_{1}\left(t\right) \right\vert$

Proof. From the convergence theorm inequality (Eq 3.1) we have

$\begin{equation*} \left\Vert S_{p}-S_{q}\right\Vert \leq \frac{\phi ^{q}}{1-\phi }\underset{ t\epsilon J}{\max }\left\vert y_{1}\left( t\right) \right\vert \end{equation*}$

but, $S_{p} = \sum_{i = 0}^{p}y_{i}\left(t\right)$ as $p\rightarrow \infty$ then, $S_{p}\rightarrow y\left(t\right)$ so,

$\begin{equation*} \left\Vert y\left( t\right) -S_{q}\right\Vert \leq \frac{\phi ^{q}}{1-\phi } \underset{t\epsilon J}{\max }\left\vert y_{1}\left( t\right) \right\vert \end{equation*}$

so, the maximum absolute truncated error in the interval $J$ is,

$\begin{equation} \underset{t\epsilon J}{\max }\left\vert y\left( t\right) -\sum\limits_{i = 0}^{q}y_{i}\left( t\right) \right\vert \leq \frac{\phi ^{q}}{1-\phi }\underset{t\epsilon J}{\max }\left\vert y_{1}\left( t\right) \right\vert \end{equation}$

(3.2)

and this completes the proof.

4. Numerical examples

In this part, we introduce several numerical examples with unkown exact solution and we will use inequality (Eq 3.2) to estimate the maximum absolute truncated error.

Example 4.1. Application of linear FDE

$\begin{equation} ^{CF}Dx\left( t\right) +2a^{CF}D^{1/2}x\left( t\right) +bx\left( t\right) = 0, { \ \ \ \ \ \ \ }x\left( 0\right) = 1. \end{equation}$

(4.1)

A Basset problem in fluid dynamics is a classical problem which is used to study the unsteady movement of an accelerating particle in a viscous fluid under the action of the gravity ^[36]

Set

$\begin{equation*} X\left( t\right) = x\left( t\right) -1 \end{equation*}$

Equation (4.1) will be

$\begin{equation} ^{CF}DX\left( t\right) +2a^{CF}D^{1/2}X\left( t\right) +bX\left( t\right) = 0, { \ \ \ \ \ \ \ }X\left( 0\right) = 0. \end{equation}$

(4.2)

Appling Eq (2.3) to Eq (4.2), and using initial condition, also we take a = 1, b = 1/2,

$\begin{equation} y = -\frac{1}{2}-2I^{1/2}y-\frac{1}{2}I\text{ }y \end{equation}$

(4.3)

Appling ADM to Eq (4.3), we find the solution algorithm become

$\begin{eqnarray} y_{0}\left( t\right) & = &-\frac{1}{2}, \\ y_{i}\left( t\right) & = &-2\text{ }^{CF}I^{1/2}y_{i-1}-\frac{1}{2}\text{ } ^{CF}I\text{ }y_{i-1},\ \ \ \ \ i\geq 1. \end{eqnarray}$

(4.4)

Appling Picard solution to Eq (4.2), we find the solution algorithm become

$\begin{eqnarray} y_{0}\left( t\right) & = &-\frac{1}{2}, \\ y_{i}\left( t\right) & = &-\frac{1}{2}-2\text{ }^{CF}I^{1/2}y_{i-1}-\frac{1}{2} \text{ }^{CF}I\text{ }y_{i-1},\ \ \ \ \ i\geq 1. \end{eqnarray}$

(4.5)

From Eq (4.4), the solution using ADM is given by $y\left(t\right) = \underset{q\rightarrow \infty }{Lim}{_{i = 0}^{q} y_{i}} \left(t\right)$ while from Eq (4.5), the solution using Picard technique is given by $y\left(t\right) = \; \underset{i\rightarrow \infty }{ Lim} \; y_{i}\left(t\right)$ . Lately, the solution of the original problem Eq (4.2), is

$\begin{equation*} x\left( t\right) = 1+\text{ }^{CF}I\text{ }y\left( t\right) . \end{equation*}$

One the same processor (q = 20), the time consumed using ADM is 0.037 seconds, while the time consumed using Picard is 7.955 seconds.

Figure 1 gives a comparison between ADM and Picard solution of Ex. 4.1.

Figure 1. ADM and Picard solution of Ex. 4.1.

DownLoad: Full-Size Img PowerPoint

Example 4.2. Consider the following nonlinear FDE ^[35]

$\begin{eqnarray} ^{CF}D^{1/2}x & = &\frac{8t^{3/2}}{3\sqrt{\pi }}-\frac{t^{7/4}}{4\Gamma \left( \frac{11}{4}\right) }-\frac{t^{4}}{4}+\frac{1}{8}\text{ }^{CF}D^{1/4}x+\frac{ 1}{4}x^{2},\text{ } \\ x\left( 0\right) & = &0. \end{eqnarray}$

(4.6)

Appling Eq (2.3) to Eq (4.6), and using initial condition,

$\begin{equation} y = \frac{8t^{3/2}}{3\sqrt{\pi }}-\frac{t^{7/4}}{4\Gamma \left( \frac{11}{4} \right) }-\frac{t^{4}}{4}+\frac{1}{8}\text{ }^{CF}I^{1/4}y+\frac{1}{4}\left( ^{CF}I^{1/2}y\right) ^{2}. \end{equation}$

(4.7)

Appling ADM to Eq (4.7), we find the solution algorithm will be become

$\begin{eqnarray} y_{0}\left( t\right) & = &\frac{8t^{3/2}}{3\sqrt{\pi }}-\frac{t^{7/4}}{4\Gamma \left( \frac{11}{4}\right) }-\frac{t^{4}}{4}, \\ y_{i}\left( t\right) & = &\frac{1}{8}\text{ }^{CF}I^{1/4}y_{i-1}+\frac{1}{4} \left( A_{i-1}\right) ,\ \ \ \ \ i\geq 1. \end{eqnarray}$

(4.8)

at which A $_{\text{i}}$ are Adomian polynomial of the nonliner term $\left(^{CF}I^{1/2}y\right) ^{2}.$

Appling Picard solution to Eq (4.7), we find the the solution algorithm become

$\begin{eqnarray} y_{0}\left( t\right) & = &\frac{8t^{3/2}}{3\sqrt{\pi }}-\frac{t^{7/4}}{4\Gamma \left( \frac{11}{4}\right) }-\frac{t^{4}}{4}, \\ y_{i}\left( t\right) & = &y_{0}\left( t\right) +\frac{1}{8}\text{ } ^{CF}I^{1/4}y_{i-1}+\frac{1}{4}\left( ^{CF}I^{1/2}y_{i-1}\right) ^{2},\ \ \ \ \ i\geq 1. \end{eqnarray}$

(4.9)

From Eq (4.8), the solution using ADM is given by $y\left(t\right) = \underset{q\rightarrow \infty }{Lim}{_{i = 0}^{q}y_{i}} \left(t\right)$ while from Eq (4.9), the solution using Picard technique is given by $y\left(t\right) = \underset{i\rightarrow \infty }{Lim} y_{i}\left(t\right)$ . Finally, the solution of the original problem Eq (4.7), is.

$\begin{equation*} x\left( t\right) = \text{ }^{CF}I^{1/2}y. \end{equation*}$

One the same processor (q = 2), the time consumed using ADM is 65.13 seconds, while the time consumed using Picard is 544.787 seconds.

Table 1 showed the maximum absolute truncated error of of ADM solution (using Theorem 3.3) at different values of m (when t = 0:5; N = 2):

Table 1. Max. absolute error.

q	max. absolute error
2	0.114548
5	0.099186
10	0.004363

| Show Table

DownLoad: CSV

Figure 2 gives a comparison between ADM and Picard solution of Ex. 4.2.

Figure 2. ADM and Picard solution of Ex. 4.2.

DownLoad: Full-Size Img PowerPoint

Example 4.3. Consider the following nonlinear FDE ^[35]

$\begin{eqnarray} ^{CF}D^{\alpha }x & = &3t^{2}-\frac{128}{125\pi }t^{5}+\frac{1}{10}\left( ^{CF}D^{1/2}x\right) ^{2}, \\ x\left( 0\right) & = &0. \end{eqnarray}$

(4.10)

Appling Eq (2.3) to Eq (4.10), and using initial condition,

$\begin{equation} y = 3t^{2}-\frac{128}{125\pi }t^{5}+\frac{1}{10}\left( ^{CF}I^{1/2}y\right) ^{2} \end{equation}$

(4.11)

Appling ADM to Eq (4.11), we find the solution algorithm become

$\begin{eqnarray} y_{0}\left( t\right) & = &3t^{2}-\frac{128}{125\pi }t^{5}, \\ y_{i}\left( t\right) & = &\frac{1}{10}\left( A_{i-1}\right) ,\ \ \ \ \ i\geq 1 \end{eqnarray}$

(4.12)

at which A $_{\text{i}}$ are Adomian polynomial of the nonliner term $\left(^{CF}I^{1/2}y\right) ^{2}.$

Then appling Picard solution to Eq (4.11), we find the solution algorithm become

$\begin{eqnarray} y_{0}\left( t\right) & = &3t^{2}-\frac{128}{125\pi }t^{5}, \\ y_{i}\left( t\right) & = &y_{0}\left( t\right) +\frac{1}{10}\left( ^{CF}I^{1/2}y_{i-1}\right) ^{2},\ \ \ \ \ i\geq 1. \end{eqnarray}$

(4.13)

From Eq (4.12), the solution using ADM is given by $y\left(t\right) = \underset{q\rightarrow \infty }{Lim}{_{i = 0}^{q}y_{i}} \left(t\right)$ while from Eq (4.13), the solution is $y\left(t\right) = \underset{i\rightarrow \infty }{Lim}y_{i}\left(t\right)$ . Finally, the solution of the original problem Eq (4.11), is

$\begin{equation*} x\left( t\right) = ^{CF}Iy\left( t\right) . \end{equation*}$

One the same processor (q = 4), the time consumed using ADM is 2.09 seconds, while the time consumed using Picard is 44.725 seconds.

Table 2 showed the maximum absolute truncated error of of ADM solution (using Theorem 3.3) at different values of m (when t = 0:5; N = 4):

Table 2. Max. absolute error.

q	max. absolute error
2	0.00222433
5	0.0000326908
10	2.88273*10 $^{-8}$

| Show Table

DownLoad: CSV

gives a comparison between ADM and Picard solution of Ex. 4.3 with $\alpha = 1$ .

Figure 3. ADM and Picard solution where of Ex. 4.3.

DownLoad: Full-Size Img PowerPoint

Example 4.4. Consider the following nonlinear FDE ^[35]

$\begin{eqnarray} ^{CF}D^{\alpha }x & = &t^{2}+\frac{1}{2}\text{ }^{CF}D^{\alpha _{1}}x+\frac{1}{ 4}\text{ }^{CF}D^{\alpha _{2}}x+\frac{1}{6}\text{ }^{CF}D^{\alpha 3}x+\frac{1 }{8}x^{4}, \\ x\left( 0\right) & = &0. \end{eqnarray}$

(4.14)

Appling Eq (2.3) to Eq (4.10), and using initial condition,

$\begin{equation} y = t^{2}+\frac{1}{2}\left( ^{CF}I^{\alpha -\alpha _{1}}y\right) +\frac{1}{4} \left( ^{CF}I^{\alpha -\alpha _{2}}y\right) +\frac{1}{6}\left( ^{CF}I^{\alpha -\alpha 3}y\right) +\frac{1}{8}\left( ^{CF}I^{\alpha }y\right) ^{4}, \end{equation}$

(4.15)

Appling ADM to Eq (4.15), we find the solution algorithm become

$\begin{eqnarray} y_{0}\left( t\right) & = &t^{2}, \\ y_{i}\left( t\right) & = &\frac{1}{2}\left( ^{CF}I^{\alpha -\alpha _{1}}y\right) +\frac{1}{4}\left( ^{CF}I^{\alpha -\alpha _{2}}y\right) +\frac{ 1}{6}\left( ^{CF}I^{\alpha -\alpha 3}y\right) +\frac{1}{8}A_{i-1},{ \ \ }i\geq 1 \end{eqnarray}$

(4.16)

where A $_{\text{i}}$ are Adomian polynomial of the nonliner term $\left(^{CF}I^{\alpha }y\right) ^{4}.$

Then appling Picard solution to Eq (4.15), we find the solution algorithm become

$y_{0}\left( t\right) = t^{2}, \\ y_{i}\left( t\right) = t^{2}+\frac{1}{2}\left( ^{CF}I^{\alpha -\alpha _{1}}y_{i-1}\right) +\frac{1}{4}\left( ^{CF}I^{\alpha -\alpha _{2}}y_{i-1}\right) \\+\frac{1}{6}\left( ^{CF}I^{\alpha -\alpha 3}y_{i-1}\right) +\frac{1}{8}\left( ^{CF}I^{\alpha }y_{i-1}\right) ^{4}\ \ \ \ \ i\geq 1.$

(4.17)

From Eq (4.16), the solution using ADM is given by $y\left(t\right) = \underset{q\rightarrow \infty }{Lim}{_{i = 0}^{q}y_{i}} \left(t\right)$ while from Eq (4.17), the solution using Picard technique is $y\left(t\right) = \underset{i\rightarrow \infty }{Lim} y_{i}\left(t\right)$ . Finally, the solution of the original problem Eq (4.14), is

$\begin{equation*} x\left( t\right) = ^{CF}I^{\alpha }y\left( t\right) . \end{equation*}$

One the same processor (q = 3), the time consumed using ADM is 0.437 seconds, while the time consumed using Picard is (16.816) seconds. shows a comparison between ADM and Picard solution of Ex. 4.4 $at \; \alpha = 0.7, \; \alpha _{1} = 0.1, \alpha _{2} = 0.3, \alpha _{3} = 0.5.$

Figure 4. ADM and Picard solution where of Ex. 4.4.

DownLoad: Full-Size Img PowerPoint

5. Conclusions

The Caputo-Fabrizo fractional deivative has a nonsingular kernel, and consequently, this definition is appropriate in solving nonlinear multidimensional FDE ^[37,38]. Since the selected numerical problems have an unkown exact solution, the formula (3.2) can be used to estimate the maximum absolute truncated error. By comparing the time taken on the same processor (i7-2670QM), it was found that the time consumed by ADM is much smaller compared with the Picard technique. Furthermore Picard gives a more accurate solution than ADM at the same interval with the same number of terms.

Conflict of interest

The authors declare there is no conflict of interest.

References

[1]	Man Y, Han Y, Hu Y, et al. (2018) Synthetic natural gas as an alternative to coal for power generation in China: Life cycle analysis of haze pollution, greenhouse gas emission, and resource consumption. J Cleaner Prod 172: 2503-2512. doi: 10.1016/j.jclepro.2017.11.160
[2]	Mohd NS, Francisco MJ, Olav B, et al. (2018) Techno-economic assessment of chemical looping reforming of natural gas for hydrogen production and power generation with integrated CO₂ capture. Int J Greenhouse Gas Control 78: 7-20. doi: 10.1016/j.ijggc.2018.07.022
[3]	Valizadeh K, Farahbakhsh S, Bateni A, et al. (2019) A parametric study to simulate the non‐Newtonian turbulent flow in spiral tubes. J Energy Sci Eng 8: 134-149.
[4]	Borelli D, Devia F, Cascio EL, et al. (2018) Energy recovery from natural gas pressure reduction stations: Integration with low temperature heat sources. J Energy Convers Manage 159: 274-283. doi: 10.1016/j.enconman.2017.12.084
[5]	Vaughn T, Bell C,Yacovitch T, et al. (2017) Comparing facility-level methane emission rate estimates at natural gas gathering and boosting stations. J Elem Sci Anth 5: (NREL/JA-6A20-70688).
[6]	Bac S, Keskin S, Avci AK (2018) Modeling and simulation of water-gas shift in a heat exchange integrated microchannel converter. Int J Hydrogen Energy 43: 1094-1104. doi: 10.1016/j.ijhydene.2017.09.141
[7]	Wang L, Davarpanah A (2020) An experimental investigation to consider thermal methods efficiency on oil recovery enhancement. J Heat Transfer.
[8]	Agwu O, Markson I, Umana M (2016) Minimizing energy consumption in compressor stations along two gas pipelines in Nigeria. J Mech Eng Autom 3: 29-34.
[9]	Demissie A, Zhu W, Belachew C (2017) A multi-objective optimization model for gas pipeline operations. J Comput Chem Eng 100: 94-103. doi: 10.1016/j.compchemeng.2017.02.017
[10]	Davarpanah A, Mirshekari B (2019a) Experimental investigation and mathematical modeling of gas diffusivity by carbon dioxide and methane kinetic adsorption. J Ind Eng Chem Res 58: 12392-12400.
[11]	Zarei M, Davarpanah A, Mokhtarian N, et al. (2020) Integrated feasibility experimental investigation of hydrodynamic, geometrical and, operational characterization of methanol conversion to formaldehyde. J Energy Sources, Part A: Recovery, Util, Environ Eff 42: 89-103.
[12]	Cordova JL, Heshmat H (2018) High effectiveness low pressure drop heat exchanger. Google Patents.
[13]	Wan Mohamed WAN, Talib S, Zakaria I, et al. (2018) Effect of dynamic load on the temperature profiles and cooling response time of a proton exchange membrane fuel cell. J Energy Inst 91: 349-357. doi: 10.1016/j.joei.2017.02.006
[14]	Davarpanah A, Mirshekari B (2019b) Experimental study of CO₂ solubility on the oil recovery enhancement of heavy oil reservoirs. J Therm Anal Calorim.
[15]	Rosli RE, Sulong AB, Daud WRW, et al. (2017) A review of high-temperature proton exchange membrane fuel cell (HT-PEMFC) system. Int J Hydrogen Energy 42: 9293-9314. doi: 10.1016/j.ijhydene.2016.06.211
[16]	Zhao J, Qifei J, Luo L, et al. (2018) Dynamic behavior study on voltage and temperature of proton exchange membrane fuel cells. J Appl Therm Eng 145: 343-351. doi: 10.1016/j.applthermaleng.2018.09.030
[17]	Tao H, Wang C, Zhu C, et al. (2018) Optimization of waste heat recovery power generation system for cement plant by combining pinch and exergy analysis methods. J Appl Therm Eng 140: 334-340. doi: 10.1016/j.applthermaleng.2018.05.039
[18]	Davarpanah A, Mazarei M, Mirshekari B (2019) A simulation study to enhance the gas production rate by nitrogen replacement in the underground gas storage performance. J Energy Rep 5: 431-435. doi: 10.1016/j.egyr.2019.04.004
[19]	Davarpanah A, Zarei M, Valizadeh K, et al. (2019) CFD design and simulation of ethylene dichloride (EDC) thermal cracking reactor. J Energy Sources, Part A: Recovery, Util, Environ Eff 41: 1573-1587.
[20]	Kwon HM, Kim TS, Sohn JL (2018) Performance improvement of gas turbine combined cycle power plant by dual cooling of the inlet air and turbine coolant using an absorption chiller. J Energy 163: 1050-1061. doi: 10.1016/j.energy.2018.08.191
[21]	Rahman AA, Mokheimer EMA (2018) Comparative analysis of different inlet air cooling technologies including solar energy to boost gas turbine combined cycles in hot regions. J Energy Resour Technol 140: 112006. doi: 10.1115/1.4040195
[22]	Vasiliev LL (2005) Heat pipes in modern heat exchangers. J Appl Therm Eng 25: 1-19. doi: 10.1016/j.applthermaleng.2003.12.004
[23]	Delpech B, Axcell B, Jouhara H (2019) Experimental investigation of a radiative heat pipe for waste heat recovery in a ceramics kiln. J Energy 170: 636-651. doi: 10.1016/j.energy.2018.12.133
[24]	Ma H, Yin L, Shen X, et al. (2016) Experimental study on heat pipe assisted heat exchanger used for industrial waste heat recovery. J Appl Energy 169: 177-186. doi: 10.1016/j.apenergy.2016.02.012
[25]	Jafari-Mosleh H, Bijarchi MA, Shafii MB (2019) Experimental and numerical investigation of using pulsating heat pipes instead of fins in air-cooled heat exchangers. J Energy Convers Manage 181: 653-662. doi: 10.1016/j.enconman.2018.11.081
[26]	Sun X, Ling L, Liao S, et al. (2018) A thermoelectric cooler coupled with a gravity-assisted heat pipe: An analysis from heat pipe perspective. J Energy Convers Manage 155: 230-242. doi: 10.1016/j.enconman.2017.10.068
[27]	Burlacu A, Sosoi G, Vizitiu RS, et al. (2018) Energy efficient heat pipe heat exchanger for waste heat recovery in buildings. J Procedia Manuf 22: 714-721. doi: 10.1016/j.promfg.2018.03.103
[28]	Hagens H, Ganzevles FLA, Geld CWM, et al. (2007) Air heat exchangers with long heat pipes: experiments and predictions. J Appl Therm Eng 27: 2426-2434. doi: 10.1016/j.applthermaleng.2007.03.004

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