<?xml version="1.0" encoding="UTF-8"?><!DOCTYPE article  PUBLIC "-//NLM//DTD Journal Publishing DTD v3.0 20080202//EN" "http://dtd.nlm.nih.gov/publishing/3.0/journalpublishing3.dtd"><article xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink" dtd-version="3.0" xml:lang="en" article-type="research article"><front><journal-meta><journal-id journal-id-type="publisher-id">EPE</journal-id><journal-title-group><journal-title>Energy and Power Engineering</journal-title></journal-title-group><issn pub-type="epub">1949-243X</issn><publisher><publisher-name>Scientific Research Publishing</publisher-name></publisher></journal-meta><article-meta><article-id pub-id-type="doi">10.4236/epe.2016.84016</article-id><article-id pub-id-type="publisher-id">EPE-65366</article-id><article-categories><subj-group subj-group-type="heading"><subject>Articles</subject></subj-group><subj-group subj-group-type="Discipline-v2"><subject>Engineering</subject></subj-group></article-categories><title-group><article-title>
 
 
  Experimental and Numerical Investigation on the Flow Characteristics around a Cross-Flow Wind Turbine
 
</article-title></title-group><contrib-group><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>akaaki</surname><given-names>Kono</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Akira</surname><given-names>Yamagishi</given-names></name><xref ref-type="aff" rid="aff2"><sup>2</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Takahiro</surname><given-names>Kiwata</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Shigeo</surname><given-names>Kimura</given-names></name><xref ref-type="aff" rid="aff2"><sup>2</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Nobuyoshi</surname><given-names>Komatsu</given-names></name><xref ref-type="aff" rid="aff2"><sup>2</sup></xref></contrib></contrib-group><aff id="aff2"><addr-line>Division of Mechanical Science and Engineering, Kanazawa University, Kanazawa, Japan</addr-line></aff><aff id="aff1"><addr-line>Research Center for Sustainable Energy &amp;amp; Technology, Kanazawa University, Kanazawa, Japan</addr-line></aff><pub-date pub-type="epub"><day>08</day><month>04</month><year>2016</year></pub-date><volume>08</volume><issue>04</issue><fpage>173</fpage><lpage>182</lpage><history><date date-type="received"><day>18</day>	<month>February</month>	<year>2016</year></date><date date-type="rev-recd"><day>accepted</day>	<month>5</month>	<year>April</year>	</date><date date-type="accepted"><day>8</day>	<month>April</month>	<year>2016</year></date></history><permissions><copyright-statement>&#169; Copyright  2014 by authors and Scientific Research Publishing Inc. </copyright-statement><copyright-year>2014</copyright-year><license><license-p>This work is licensed under the Creative Commons Attribution International License (CC BY). http://creativecommons.org/licenses/by/4.0/</license-p></license></permissions><abstract><p>
 
 
  This study investigated the flow characteristics around a cross-flow wind turbine. A wind tunnel experiment (WTE) was performed to measure the flow characteristics past the wind turbine when operating at the optimal tip-speed ratio of 
  <em>λ</em> = 0.4. In addition, computational fluid dynamics (CFD) simulations were performed for the flow field around the wind turbine that was operating at tip-speed ratios of 
  <em>λ</em> = 0.1, 0.4, and 0.7. The CFD approach was validated against the WTE measurements. CFD results confirmed that with an increase in 
  <em>λ</em>, the velocity deficit was generally increased in the leeward of the return side of the wind turbine, while it was generally decreased in the leeward of the drive side of the wind turbine. It was also confirmed that with an increase in 
  <em>λ</em>, the turbulence kinetic energy was generally increased in the leeward of the return side of the wind turbine, while it generally decreased in the leeward of the drive side of the wind turbine.
 
</p></abstract><kwd-group><kwd>Cross-Flow Wind Turbine</kwd><kwd> Wind Tunnel Experiment</kwd><kwd> CFD</kwd></kwd-group></article-meta></front><body><sec id="s1"><title>1. Introduction</title><p>A small wind turbine with a cross-flow runner (hereafter referred to as “cross-flow wind turbine”) has a high starting torque and is quiet. Thus, it is suitable for it to be introduced in urban areas where wind speed is generally low and careful attention to noise reduction is required. However, it has a drawback in that its maximum power coefficient is extremely low (about 10%) when compared with that of other small wind turbines. To date, several studies have addressed ways to improve the efficiency of cross-flow wind turbines [<xref ref-type="bibr" rid="scirp.65366-ref1">1</xref>] - [<xref ref-type="bibr" rid="scirp.65366-ref4">4</xref>] . However, knowledge of flow characteristics around a cross-flow wind turbine is extremely limited. Therefore, there is great potential to improve cross-flow wind turbine’s efficiency by taking flow characteristics into account.</p><p>In this study, we conduct computational fluid dynamics (CFD) simulations and a wind tunnel experiment (WTE) to clarify the flow characteristics around a cross-flow wind turbine.</p></sec><sec id="s2"><title>2. Experimental Method</title><p><xref ref-type="fig" rid="fig1">Figure 1</xref> shows the schematic of the experimental setup. The experiment was conducted using a closed circuit wind tunnel with an open test section. The size of the cross section of the wind tunnel outlet was 1250 mm &#215; 1250 mm.</p><p>The cross-flow wind turbine being tested, which is shown in <xref ref-type="fig" rid="fig2">Figure 2</xref>, had an outer diameter of D = 80 mm, an inner diameter of d = 65 mm, and a lateral length of L = 400 mm. The shape of the blades was an arc of a circle with radius of r = 11. 5 mm, angle of θ = 114˚, and chord length of l<sub>c</sub> = 10.5 mm. The inlet angle of the blades was β = 40˚, and the number of the blades was N = 15.</p><p>The wind turbine was placed at 800 mm downwind from the wind tunnel outlet and 525 mm above the floor. The wind turbine then was connected to a torque meter and a direct current motor that controls the wind turbine’s number of rotations.</p><p>The free stream velocity was set to U = 7 m/s, and the turbulence intensity was less than 0.5%. Assuming that the origin lay at the center of the wind turbine, wind velocity distribution was measured using an X-array hot- wire probe (KANOMAX, 0252R-T5) at z/D = 0 in the lateral direction, at the range of x/D = −0.5 to 2.0 in the streamwise direction, and at the range of y/D = −1.5 to 1.5 in the vertical direction, as shown in <xref ref-type="fig" rid="fig3">Figure 3</xref>. The spacing of the measurement points was 5 mm in both the x and y directions.</p></sec><sec id="s3"><title>3. Numerical Analysis Method</title><sec id="s3_1"><title>3.1. Abbreviations and Acronyms</title><p>Two-dimensional CFD simulation was performed for the flow field around the wind turbine on the x-y plane at z/D = 0. The governing equations are the Reynolds-averaged continuity equation</p><fig id="fig1"  position="float"><label><xref ref-type="fig" rid="fig1">Figure 1</xref></label><caption><title> Experimental setup</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x7.png"/></fig><fig id="fig2"  position="float"><label><xref ref-type="fig" rid="fig2">Figure 2</xref></label><caption><title> Cross-flow wind turbine</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x8.png"/></fig><disp-formula id="scirp.65366-formula131"><label>(1)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/1-6201928x9.png"  xlink:type="simple"/></disp-formula><p>and the Reynolds-averaged Navier-Stokes (RANS) equations</p><disp-formula id="scirp.65366-formula132"><label>(2)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/1-6201928x10.png"  xlink:type="simple"/></disp-formula><p>where u<sub>i</sub> is the velocity component in the x<sub>i</sub> direction, t is the time, ρ is the density of air, p is the pressure, ν is the kinetic viscosity, and <inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x11.png" xlink:type="simple"/></inline-formula> is the Reynolds-average of a flow variable ϕ. The Reynolds stresses <inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x12.png" xlink:type="simple"/></inline-formula> were computed using the k-ω shear-stress transport (SST) turbulence model [<xref ref-type="bibr" rid="scirp.65366-ref5">5</xref>] . The advection term was discretized by the second-order upwind scheme. Other spatial derivatives were discretized via the second-order central difference scheme. The Pressure-Implicit with Splitting of Operators (PISO) algorithm was used for velocity- pressure coupling.</p></sec><sec id="s3_2"><title>3.2. Computational Conditions</title><p>The detail of the computational grid is shown in <xref ref-type="fig" rid="fig4">Figure 4</xref>. The computational domain consists of a rotational area, which includes the wind turbine, and a stationary area that surrounds it. A sliding mesh technique was used</p><fig id="fig3"  position="float"><label><xref ref-type="fig" rid="fig3">Figure 3</xref></label><caption><title> Measurement range</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x13.png"/></fig><fig-group id="fig4"><label><xref ref-type="fig" rid="fig4">Figure 4</xref></label><caption><title> Computational grid. (a) Entire domain, (b) enlarged view.</title></caption><fig id ="fig4_1"><label> (b)</label><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x14.png"/></fig></fig-group><p>to couple the rotational grid and stationary grid, as described in literature [<xref ref-type="bibr" rid="scirp.65366-ref6">6</xref>] . The total number of grid points was approximately 250,000.</p><p>On the inflow boundary, a stream-wise wind speed of U = 7 m/s with the turbulent intensity of 0.5% was implemented. On the outlet boundary, the pressure outlet boundary condition was imposed. On the bottom boundary of the computational domain and blade surface, the non-slip boundary condition was set. On the top boundary of the computational domain, the free-slip boundary condition was implemented.</p><p>The tip-speed ratio λ (= Dw/U) of the wind turbine was set with U being constant and w, the turbine’s angular velocity, being changed. The time step Δt (= π/360ω) is the period of time for the wind turbine to rotate by 0.5 degrees. The statics were summed up from 3600Δt to 7200Δt.</p></sec></sec><sec id="s4"><title>4. Results and Discussion</title><sec id="s4_1"><title>4.1. Power Coefficient</title><p><xref ref-type="fig" rid="fig5">Figure 5</xref> shows the dependence of the power coefficient C<sub>P</sub> (= 2Tw/LDrU<sup>3</sup>) on the tip-speed ratio λ, where T is the turbine’s torque. It is observed that the CFD results match well.</p></sec><sec id="s4_2"><title>4.2. Flow Characteristics around Wind Turbine at Optimal Tip-Speed Ratio</title><p>In this section, we focus on the flow characteristics around the wind turbine when operating at λ = 0.4.</p><p><xref ref-type="fig" rid="fig6">Figure 6</xref> shows the time-averaged velocity profiles of the flow past the wind turbine. The profiles of the CFD and WTE results appear to be in good agreement except for the streamwise velocities in the range of y/D = −0.5 to 0.0. The large discrepancies between the CFD and WTE results for the streamwise velocity likely due to the difference in the generation frequency of the strong counter-clockwise vortices, one of which is indicated by the dashed oval in <xref ref-type="fig" rid="fig7">Figure 7</xref>, shed from the return side of the wind turbine. Based on <xref ref-type="fig" rid="fig8">Figure 8</xref>, which shows the</p><fig id="fig5"  position="float"><label><xref ref-type="fig" rid="fig5">Figure 5</xref></label><caption><title> Dependence of the power coefficient C<sub>P</sub> on the tip-speed ratio λ</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x15.png"/></fig><fig-group id="fig6"><label><xref ref-type="fig" rid="fig6">Figure 6</xref></label><caption><title> Time-averaged velocity profiles of the flow past the wind turbine when operating at λ = 0.4. (a) Streamwise velocity, (b) vertical velocity.</title></caption><fig id ="fig6_1"><label> (b)</label><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x16.png"/></fig></fig-group><fig-group id="fig7"><label><xref ref-type="fig" rid="fig7">Figure 7</xref></label><caption><title> Contours of axial vorticity and streamwise velocity around the wind turbine when operating at λ = 0.4. (a) Axial vorticity, (b) streamwise velocity.</title></caption><fig id ="fig7_1"><label> (b)</label><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x17.png"/></fig></fig-group><p>frequency spectra of the streamwise velocity fluctuations at the position indicated by a cross mark in <xref ref-type="fig" rid="fig7">Figure 7</xref>(a), the strong counter-clockwise vortices are periodically shed from the return side of the wind turbine at a frequency of approximately f<sub>b</sub>/4 Hz in CFD and f<sub>b</sub>/3 Hz in WTE. Here, f<sub>b</sub> is the blade passing frequency (the product of the rotor rotation frequency and the number of blades) shown in <xref ref-type="table" rid="table1">Table 1</xref>.</p><p><xref ref-type="fig" rid="fig9">Figure 9</xref> shows the turbulence kinetic energy (TKE) profiles of the flow past the wind turbine. Here, the values of TKE of WTE are calculated by</p><disp-formula id="scirp.65366-formula133"><label>, (3)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/1-6201928x18.png"  xlink:type="simple"/></disp-formula><p>and the values of TKE of CFD are calculated using the following approximate equations, (see Appendix):</p><disp-formula id="scirp.65366-formula134"><label>, (4)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/1-6201928x19.png"  xlink:type="simple"/></disp-formula><p>where <inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x20.png" xlink:type="simple"/></inline-formula> is the time average of a flow variable<inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x21.png" xlink:type="simple"/></inline-formula>, <inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x21.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x22.png" xlink:type="simple"/></inline-formula>is<inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x21.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x22.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x23.png" xlink:type="simple"/></inline-formula>, <inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x21.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x22.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x23.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x24.png" xlink:type="simple"/></inline-formula>is<inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x21.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x22.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x23.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x24.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x25.png" xlink:type="simple"/></inline-formula>, and k is the TKE of the SST k-ω turbulence model. <xref ref-type="fig" rid="fig9">Figure 9</xref> confirms that the profiles of the WTE and CFD results match qualitatively well, having two peaks around y/D ≈ −0.5 and y/D ≈ 0.5 to 0.9. It is considered that these two peaks were generated by the vortices released from the wind turbine, as shown in <xref ref-type="fig" rid="fig7">Figure 7</xref>(a).</p><fig-group id="fig8"><label><xref ref-type="fig" rid="fig8">Figure 8</xref></label><caption><title> Frequency spectra of the streamwise velocity fluctuations at the position indicated by a cross mark in <xref ref-type="fig" rid="fig7">Figure 7</xref>(b). (a) CFD, (b) WTE.</title></caption><fig id ="fig8_1"><label> (b)</label><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x26.png"/></fig></fig-group><table-wrap id="table1" ><label><xref ref-type="table" rid="table1">Table 1</xref></label><caption><title> Blade passing frequency</title></caption><table><tbody><thead><tr><th align="center" valign="middle" >Tip speed ratio, λ</th><th align="center" valign="middle" >0.1</th><th align="center" valign="middle" >0.4</th><th align="center" valign="middle" >0.7</th></tr></thead><tr><td align="center" valign="middle" >Blade pasing frequency, f<sub>b</sub> (Hz)</td><td align="center" valign="middle" >41.5</td><td align="center" valign="middle" >167.25</td><td align="center" valign="middle" >291.75</td></tr></tbody></table></table-wrap><fig id="fig9"  position="float"><label><xref ref-type="fig" rid="fig9">Figure 9</xref></label><caption><title> Turbulence kinetic energy profiles of the flow past the wind turbine when operating at λ = 0.4</title></caption><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x27.png"/></fig></sec><sec id="s4_3"><title>4.3. Dependency of Flow Characteristics on the Tip-Speed Ratio of the Wind Turbine</title><p>In this section, based on the CFD results, we discuss the dependency of the flow characteristics on the tip-speed ratio of the wind turbine.</p><p><xref ref-type="fig" rid="fig1">Figure 1</xref>0(a) compares the time-averaged streamwise velocity profiles of the flow past the wind turbine when operating at various tip-speed ratios. With an increase in λ, the velocity deficit is generally increased in the leeward of the return side of the wind turbine (y/D &lt; 0), and in the leeward of the drive side of the wind turbine (y/D &gt; 0), the velocity deficit is generally decreased.</p><p><xref ref-type="fig" rid="fig1">Figure 1</xref>0(b) compares the TKE profiles of the flow past the wind turbine when operating at various tip-speed ratios. With an increase in λ, the values of TKE are generally increased in the leeward of the return side of the wind turbine, and in the leeward of the drive side of the wind turbine, the values of TKE are generally decreased.</p><p>With regard to the causes of the dependencies of the velocity deficit and TKE on λ, the characteristics of the vortices shed from the drive side and from the return side of the wind turbine vary depending on λ. <xref ref-type="fig" rid="fig1">Figure 1</xref>1 shows the contours of the axial vorticity around the wind turbine at λ = 0.1 and 0.7, respectively. According to <xref ref-type="fig" rid="fig7">Figure 7</xref>(a) and <xref ref-type="fig" rid="fig1">Figure 1</xref>1, the vortices shed from the return side of the wind turbine become larger and stronger as λ increases. As a result, the velocity deficit and TKE in the leeward of the return side increases with an increase in λ. The formation of larger and stronger vortices with an increase in λ is considered to stem from the fact that the shear stress near the blades on the return side of the wind turbine increases due to an increase in the speed of the blades that move in the opposite direction of the flow around the wind turbine. Moreover, based on <xref ref-type="fig" rid="fig7">Figure 7</xref>(a) and <xref ref-type="fig" rid="fig1">Figure 1</xref>1, the vortices shed from the drive side of the wind turbine become smaller and weaker as λ increases. As a result, the velocity deficit and TKE in the leeward of the drive side decreases with an increase in λ. The formation of smaller and weaker vortices with an increase in λ is considered to occur because the interaction between the opposite sign of the vortices from the edges of a blade becomes less frequent due to an increase in the frequency of the reattachment of the vortices from the inner edge of a blade.</p></sec></sec><sec id="s5"><title>5. Conclusions</title><p>To clarify the flow characteristics around a cross-flow wind turbine, a wind tunnel experiment (WTE) and computational fluid dynamics (CFD) simulations were conducted. The CFD simulations were performed for the cases in which the wind turbine was operating at tip-speed ratios of λ = 0.1, 0.4, and 0.7. The validity of the CFD approach was confirmed through the comparison with the WTE results for the optimal tip-speed ratio of λ = 0.4. The main findings are summarized as follows.</p><p>1) With an increase in λ, the velocity deficit is generally increased in the leeward of the return side of the wind turbine, while it is generally decreased in the leeward of the drive side of the wind turbine.</p><p>2) With an increase in λ, the turbulence kinetic energy is generally increased in the leeward of the return side of the wind turbine, while it is generally decreased in the leeward of the drive side of the wind turbine.</p><fig-group id="fig10"><label><xref ref-type="fig" rid="fig1">Figure 1</xref>0</label><caption><title> Time-averaged streamwise velocity and turbulence kinetic energy profiles of the flow past the wind turbine. (a) Streamwise velocity, (b) turbulence kinetic energy.</title></caption><fig id ="fig10_1"><label> (b)</label><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x28.png"/></fig></fig-group><fig-group id="fig11"><label><xref ref-type="fig" rid="fig1">Figure 1</xref>1</label><caption><title> Contours of axial vorticity around the wind turbine when operating at λ = 0.1 and 0.7. (a) λ = 0.1, (b) λ = 0.7.</title></caption><fig id ="fig11_1"><label> (b)</label><graphic mimetype="image"   position="float"  xlink:type="simple"  xlink:href="http://html.scirp.org/file/1-6201928x29.png"/></fig></fig-group><p>3) With an increase in λ, the vortices shed from the return side of the wind turbine tend to be larger and stronger.</p><p>4) With an increase in λ, the vortices shed from the drive side of the wind turbine tend to be smaller and weaker.</p></sec><sec id="s6"><title>Cite this paper</title><p>Takaaki Kono,Akira Yamagishi,Takahiro Kiwata,Shigeo Kimura,Nobuyoshi Komatsu, (2016) Experimental and Numerical Investigation on the Flow Characteristics around a Cross-Flow Wind Turbine. Energy and Power Engineering,08,173-182. doi: 10.4236/epe.2016.84016</p></sec><sec id="s7"><title>Appendix</title><p>The approximate Equation (4) is derived as follows.</p><p>With time averaging and Reynolds averaging, an instantaneous velocity is decomposed as</p><disp-formula id="scirp.65366-formula135"><label>, (A.1)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/1-6201928x30.png"  xlink:type="simple"/></disp-formula><disp-formula id="scirp.65366-formula136"><label>, (A.2)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/1-6201928x31.png"  xlink:type="simple"/></disp-formula><p>The turbulence kinetic energy based on time-averaging operation is defined as</p><disp-formula id="scirp.65366-formula137"><label>, (A.3)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/1-6201928x32.png"  xlink:type="simple"/></disp-formula><p>Using the relationship in Equation (A.2), Equation (A.3) is expressed as</p><disp-formula id="scirp.65366-formula138"><label>, (A.4)</label><graphic position="anchor" xlink:href="http://html.scirp.org/file/1-6201928x33.png"  xlink:type="simple"/></disp-formula><p>Because using the present CFD approach is not possible for computing the values of <inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x34.png" xlink:type="simple"/></inline-formula> and <inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x34.png" xlink:type="simple"/></inline-formula><inline-formula><inline-graphic xlink:href="http://html.scirp.org/file/1-6201928x35.png" xlink:type="simple"/></inline-formula> in Equation (A.4), the present study assumes these values to be zero. As a result, Equation (4) is obtained.</p></sec><sec id="s8"><title>NOTES</title></sec></body><back><ref-list><title>References</title><ref id="scirp.65366-ref1"><label>1</label><mixed-citation publication-type="other" xlink:type="simple">Al-Maaitah, A.A. (1993) The Design of the Banki Wind Turbine and Its Testing in Real Wind Conditions. Renewable Energy, 3, 781-786. http://dx.doi.org/10.1016/0960-1481(93)90085-U</mixed-citation></ref><ref id="scirp.65366-ref2"><label>2</label><mixed-citation publication-type="other" xlink:type="simple">Tanino, T. and Nakao, S. (2005) Improving Ambient Wind Environments of a Cross-Flow Wind Turbine near a Structure by Using an Inlet Guide Structure and a Flow Deflector. Journal of Thermal Science, 14, 242-248.  
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