Interferometric Study of the Heat Transfer Phenomena Induced by Rapid Heating of Nickel Sheet
Interferometric Study of the Heat Transfer Phenomena Induced by Rapid Heating of Nickel Sheet
Seo, Hyeon-Seok;Hwang, In-Ju;Kim, Youn-Jea
2020-07-06 00:00:00
applied sciences Article Interferometric Study of the Heat Transfer Phenomena Induced by Rapid Heating of Nickel Sheet 1 2 3 , Hyeon-Seok Seo , In-Ju Hwang and Youn-Jea Kim * Chassis & Trim Analysis Engineering Team, Hyundai Mobis, Yongin 16891, Korea; bbashya00@gmail.com Extreme Engineering Research Center, Korea Institute of Civil Engineering and Building Technology, Goyang 10223, Korea; ijhwang@kict.re.kr School of Mechanical Engineering, SungKyunKwan University, 2066 Seobu-ro, Suwon 16419, Korea * Correspondence: yjkim@skku.edu; Tel.: +82-31-290-7448 Received: 28 May 2020; Accepted: 2 July 2020; Published: 6 July 2020 Abstract: Visualization of the heat transfer phenomena induced by the rapid heating of nickel sheets was carried out using a Mach–Zehnder interferometer (MZI) and a high-speed camera. This phenomenon may be an important factor in heat transfer phenomena when the working fluids reach the thermodynamic critical point. The eect of heat transfer on the heating conditions of a nickel sheet was quantified by finite fringe analysis. The results show that isotherms near the heating surface with rapid heating are generated, and the induced isotherms are moved upward with similar patterns for dierent heating conditions. In addition, it is confirmed that the local Nusselt number decreases to the relationship of a secondary function if the thickness of the metal specimen is very thin and the time to reach the highest temperature is very short. Moreover, it decreased according to the increase of heating energy because the heat transfer mainly occurred by conduction and radiation rather than by convection, because the expansive force and compressive force between the fluid layers on the wall increased due to an increase in the heating energy in the beginning. Keywords: rapid heating; compressible fluid; thermo-acoustic phenomena; Mach–Zehnder interferometer 1. Introduction When the boundaries or the interiors of compressible mediums are exposed to a rapid temperature change, a rapid expansion of the adjacent medium will occur and generate a pressure or stress wave, just as when a piston is suddenly pushed into a gas-filled tube. In terms of heat transfer, the waves from these thermal phenomena in the boundary of a compressible fluid are called thermo-acoustic convection. The case of compressible fluids and thermal dynamic processes are closely related to each other because of local heat exchange. Rayleigh [1] found the idea that a micro-dierence in temperature can generate a mechanical reaction in the form of an acoustic wave in the rest of the fluid. Ozoe et al. investigated the characteristics of fluid flow from this rapid heating, so called thermos-acoustic convection [2,3], using numerical methods. They applied temperature-independent thermo-physical properties to finite dierence solutions of the compressible Navier–Stokes equations for the gas dynamics. From the matched asymptotic expansions and multiple-time-scale methodology, Kassoy [4] and Radhwan and Kassoy [5] investigated the thermo-acoustic phenomena in an enclosed ideal gas with slow and rapid boundary heating. They found that the dominant process has two physical regimes, thermo-dynamic convection on the acoustic timescale and strong conductive–convective coupling on the typical timescale for thermal diusion, respectively. Huang and Bau [6,7] established their theoretical modeling of the thermo-acoustic eect in gases, which specified that the thermo-mechanical waves, linear or nonlinear, should have an asymmetrical waveform, including a sharp front and a long Appl. Sci. 2020, 10, 4658; doi:10.3390/app10134658 www.mdpi.com/journal/applsci Appl. Sci. 2020, 10, 4658 2 of 13 tail. These are completely opposite configurations compared to previous predictions, such as those for a rounded symmetric configuration. Fusegi et al. [8] investigated the characteristics of thermo-acoustic waves under a nitrogen-filled two-dimensional cavity in order to study how these can be developed to enhance the eective heat removal mechanism. Lin and Farouk [9], Aktas and Farouk [10], Farouk et al. [11], and Škerget and Ravnik [12] investigated the strong thermo-acoustic waves according to impulsive heating applied to boundary element methods (BEM). Moreover, they found that the horizontal velocity component reverses sign after reflection from the side walls, such as one-dimensional flow fields. Interferometric studies using the principle of interference of consistent light beams due to a phase dierence are useful methodologies for the experimental study of thermal fluid phenomena. Goldstein and Eckert [13] checked the heat transfer coecients on a uniformly heated vertical plate using Mach–Zehnder interferometry. Polymeropoulos and Gebhart [14] investigated the thermal boundary layer of a vertical flat plate using an interferometric apparatus. Shakher and Nirala [15] explained their interferometric study using laser beams for the measurement of the refractive index and the thermal phenomena of burners. Herman et al. [16] experimentally investigated the incompressible flow of air over heated obstacles in a two-dimensional and horizontal channel using holographic interferometry and high-speed cinematography. Jarosinski [17] studied the convection phenomena from the heated wall of a duct using various interferometric methods like interferometry, Schlieren, and PIV (particle image velocimetry) methods with a high-speed camera. Binoy and Sobhan [18] performed finite dierence methods to check the forced convection phenomena in a compact mini-channel with rectangular obstacles and compared these results to the experimental results using Michelson interferometry. These technologies can be applied to various fields where temperatures are not very high. Interferometry can be an eective means for measuring three-dimensional unsteady thermal flow fields accurately. They also checked the forced convection characteristics in a meso-scale channel with inconstant cross-sections using finite dierence solution and validated these results with the experimental results from Mach–Zehnder interferometry [19]. Ahadi and Saghir [20] performed experimental studies to measure the heat transfer phenomena under thermo-diusion experiments, using Mach–Zehnder interferometry at reduced gravity. They explained the deviations reflected in the measured results between the temperature dierences at the hot and cold sides of a cell using optical techniques and Peltier elements. Takahashi et al. [21] confirmed the availability of the bumped channel for the micro heat sink which is to measure the density distributions of supersonic flow in the microchannel using a phase-shifting interferometer. The results were validated by the results from a numerical study of basic density field and heat transfer simulations. Yousefi-Asli, et al. [22] performed an experimental study to determine the temperature field and Nusselt number for a methane/air slot flame impinging into a cylindrical surface. In order to determine the temperature, Mach–Zehnder interferometry was used. The eects of the operating conditions, Reynolds number, equivalence ratio, distance between the burner and impingement surface, and the surface diameter were considered in order to analyze the thermal fluid flow phenomena. Additionally, there were a few experimental studies focused on obtaining results for the thermo-acoustic wave phenomena using interferometric apparatuses. Blanc-Benon et al. [23] measured the flow characteristics from a stack of parallel plates at relatively low drive ratios between 1.0% and 1.5% using PIV, and they validated these results using the results of numerical analysis. Berson et al. [24] investigated the flow phenomena in the stack of a thermo-acoustic refrigerator using the PIV method. They found that vortex flow fields are generated during the half period of the acoustic cycle when the working fluid flows out of the stack, and they showed the flow phenomena using eight vortices according to eight dierent phases within an acoustic cycle. Mao et al. [25] performed various experimental studies using PIV to find the vortex generation processes under higher drive ratios (by 2%), using two stacks with 1 and 5-mm thick plates, with fixed spacing between the plates of 5 and 10 mm, respectively. They utilized nine figures of vortices out of 20 phases to describe an acoustic cycle, and they found that the most significant vortex structures turned up in the ejection stage (when the Appl. Sci. 2020, 10, x FOR PEER REVIEW 3 of 14 2%), using two stacks with 1 and 5-mm thick plates, with fixed spacing between the plates of 5 and 10 mm, respectively. They utilized nine figures of vortices out of 20 phases to describe an acoustic Appl. Sci. 2020, 10, 4658 3 of 13 cycle, and they found that the most significant vortex structures turned up in the ejection stage (when the fluid flows out of the stack). Aben et al. [26] judged that the ratio between Strouhal and Reynolds num fluid bers flows is anout imp of ort the antstack). factor in Aben decid etial. ng t [26 he] v judged ortex sh that apes the beratio hind t between he stack Str plat ouhal es, and and thReynolds ey also investig numbers ated t ish an e porous e important ffects and the e factor in deci nding d shape o the vortex f the plshapes ate. Shi e behind t al. [27 the –30 stack ] found t plates, hat t and he vthey ariou also s painvestigated rameters and R the e por ynol ous ds numbers were a eects and the endrshape ound 500 of the 0. They al plate. Shi so tri et al. ed to prove the rel [27–30] found thatathe tionshi various p between the parameters Reyno and Reynolds lds number and numbers the wer Strouh e around al nu 5000. mber acco They also rdintried g to the vortex to prove the sheddin relationship g frequency between anthe d the evoluti Reynoldsonumber n of the v and ortex wa the Strke p ouhal atterns. The fl number accor uctuating ding to fie thelds vortex were c shedding lassified fr as the equency ejection and the stage evolution and the of suct theion vortex stage wake . The t patterns. wo-dimThe ension fluctuating al temperat fields ure f wer ields w e classified ere also as ob the serv ejection ed viastage planar and laser-induced fluorescence and combined with the velocity fields. the suction stage. The two-dimensional temperature fields were also observed via planar laser-induced fluor The i escence ntensi and ve studi combined es on the thermo-a with the velocity cousti fields. c phenomena created by thermal effects were being investigated numerically and experimentally at the end of the twentieth century. However, there The intensive studies on the thermo-acoustic phenomena created by thermal eects were being were investigated a lot of problems, like vario numerically and experimentally us errors ofat nthe ume end rical ofschemes, in the twentieth acc century uracy .of the expe However, ther rimental e were a methodologies, and the difficulty of visualization in thermal flow fields with various parameters. In lot of problems, like various errors of numerical schemes, inaccuracy of the experimental methodologies, the present study, the he and the diculty of visuali at transfer phen zation in thermal omena ind flow fields uced by t with he rap various id he parameters. ating of a met In the al sheet present in a study ir , are experimentally studied. A resistance–capacitance (R–C) heating device and measurement systems the heat transfer phenomena induced by the rapid heating of a metal sheet in air are experimentally incl studied. uding a hA igh-spee resistance–capacitance d imaging system were (R–C)de heating signed, device and measurement proce and measurement sses were systems dev including eloped. a The focus was centered on the temperature profile of the metal surface and the visualization of high-speed imaging system were designed, and measurement processes were developed. The focus isotherms ne was centerar the n ed on the icke temperatur l sheet in open e profile space. In of the ad metal dition, the surface eff and ect of the hea visualization t transmission wi of isotherms th respect near to the heating conditions of a nickel sheet was quantified by finite fringe analysis with a Mach– the nickel sheet in open space. In addition, the eect of heat transmission with respect to the heating Zehnder inter conditions of ferometer. a nickel sheet was quantified by finite fringe analysis with a Mach–Zehnder interferometer. 2. Experiments 2. Experiments 2.1. Experimental Apparatus 2.1. Experimental Apparatus Figure 1a shows the schematic of an experimental chamber and circuit to obtain the pressure wave Figure 1a shows the schematic of an experimental chamber and circuit to obtain the pressure and the temperature in open space [31]. The experimental setup for an open space is composed of bus wave and the temperature in open space [31]. The experimental setup for an open space is composed bars, connecting bolts, and a nickel sheet. For minimizing thermal loss, insulating materials are added of bus bars, connecting bolts, and a nickel sheet. For minimizing thermal loss, insulating materials under the nickel sheet. This is fixed on the bus bars to connect the heating circuit. The temperature are added under the nickel sheet. This is fixed on the bus bars to connect the heating circuit. The of an experimental specimen (nickel sheet) with resistance can be increased suddenly according to temperature of an experimental specimen (nickel sheet) with resistance can be increased suddenly the capacitor ’s characteristics, which allows the quick release of electric power. The designed R–C according to the capacitor’s characteristics, which allows the quick release of electric power. The heating system of this study has charging and discharging circuits, an electric switch, and a trigger designed R–C heating system of this study has charging and discharging circuits, an electric switch, part near the capacitor (see Figure 1b). The charging circuit has a capacitor which has the ability and a trigger part near the capacitor (see Figure 1b). The charging circuit has a capacitor which has to charge electric power, a power supplier to handle the direct current, a resistor to protect over the ability to charge electric power, a power supplier to handle the direct current, a resistor to protect current, and a power button. The discharging circuit contains a capacitor, a metal sheet which will over current, and a power button. The discharging circuit contains a capacitor, a metal sheet which be heated by the discharging electric power, and the power button for immediate opening of the will be heated by the discharging electric power, and the power button for immediate opening of the circuit. Tables 1 and 2 show the details of the capacitor and the physical properties of the experimental circuit. Tables 1 and 2 show the details of the capacitor and the physical properties of the experimental specimen, respectively. specimen, respectively. (a) (b) Figure 1. The experimental chamber and circuit diagram [31]. (a) Modeled chamber, (b) Circuit Figure 1. The experimental chamber and circuit diagram [31]. (a) Modeled chamber, (b) Circuit diagram of resistance–capacitance (R–C) heating. diagram of resistance–capacitance (R–C) heating. Appl. Sci. 2020, 10, x FOR PEER REVIEW 4 of 14 Appl. Sci. 2020, 10, 4658 4 of 13 Table 1. Specification of capacitor applied. Table 1. Specification of capacitor applied. Capacitor 68,000 µF Diameter (mm) 76.0 Capacitor 68,000 F Diameter (mm) 76.0 Length (mm) 105.0 Length (mm) 105.0 Surging voltage (V) 50 Surging voltage (V) 50 Operating temperature (°C) −40–85 Operating temperature ( C) 40–85 Max. equivalent series r Max. equivalent esistance series resistance () 0. (W) 0.012012 Max. ripple (RMS Amps) 16.0 Max. ripple (RMS Amps) 16.0 Max. DC leakage current (A) I = 0.006 C V Working voltage (V) 50 Max. DC leakage current (A) I=⋅ 0.006 CV Working voltage (V) 50 Table 2. Physical and mechanical properties of the tested metal sheets. Table 2. Physical and me Property chanical properties of the tested Nickel metal sheets. Specific weight (kgf/m ) Property Nickel Electrical resistance (W cm) 6.84 Specific weight (kgf/m) 8900 Physical Specific heat (J/kg K) 445.9 Electrical resistance (µΩ cm) 6.84 Thermal conductivity (W/mK) 83 Physical Specific heat (J/kg K) 445.9 Thickness, (mm) 0.0125, 0.01, 0.0075 Thermal conductivity (W/m·K) 83 Thickness, δ (mm) 0.0125, 0.01, 0.0075 Yield strength (kg/mm ) 15 Yield strength (kg/mm2) 15 Mechanical Tensile strength (kg/mm ) 47 Mechanical Tensile strength (kg/mm) 47 Elongation length (%) 50 Elongation length (%) 50 The interference phenomenon of thermo-acoustic waves due to the variation of density is The interference phenomenon of thermo-acoustic waves due to the variation of density is visualized by a Mach–Zehnder interferometer. The interferometer is equipped with a He-Ne laser with visualized by a Mach–Zehnder interferometer. The interferometer is equipped with a He-Ne laser about 10-mW output, a beam expander, a beam splitter, a reflection mirror, and concave and convex with about 10-mW output, a beam expander, a beam splitter, a reflection mirror, and concave and lenses, as shown in Figure 2. This device measures the distribution of the density or temperature. convex lenses, as shown in Figure 2. This device measures the distribution of the density or The fundamental principle relies on the distinction between the refractive indices from the result of the temperature. The fundamental principle relies on the distinction between the refractive indices from interference between two laser beams separated by a half-silvered mirror, one passing to the test space the result of the interference between two laser beams separated by a half-silvered mirror, one and the other acting as a reference beam. The fringe shift between them is utilized to determine the passing to the test space and the other acting as a reference beam. The fringe shift between them is density or temperature distributions. utilized to determine the density or temperature distributions. Figure 2. Schematic diagram and real image of Mach–Zehnder interferometer in this study. Figure 2. Schematic diagram and real image of Mach–Zehnder interferometer in this study. The operating sequence of the apparatus is as follows. First, the beam emitted from a He-Ne laser is diffused after passing through an objective lens and a space filter of 10-µm depth. The beam is separated into two parallel beams by a beam splitter. The two beams are recombined after they Appl. Sci. 2020, 10, 4658 5 of 13 The operating sequence of the apparatus is as follows. First, the beam emitted from a He-Ne laser is diused after passing through an objective lens and a space filter of 10-m depth. The beam is separated into two parallel beams by a beam splitter. The two beams are recombined after they pass through dierent paths, which have dierent densities. At this time, the interference phenomenon, which occurs due to the dierence in wavelength, can show an interference fringe in the wall. This fringe is used to analyze the flow field. A high-speed camera (HG 2000, Kodak) which is capable of operating at 2000 frames per second is used to visualize the test section. For simultaneous operation with a rapid heating switch and a data measuring instrument, a pulse generator and trigger system are made using a J-K flip-flop chip. A part of the saved image is selected to evaluate and analyze the fringes. 2.2. Experimental Methodologies The experimental setup for this study had various devices to check the interference. Thus, controlling the sensitivity of these devices is very important to secure the reliability of the results. The measuring process of the thermo-acoustic wave is established to the preliminary experimental study, the main aim of which is to evaluate the data reproduction and processing. Before the main experiment, charging and discharging devices, trigger systems, the measuring device, and the high-speed camera needed to be calibrated to ensure their reliability. Then, the test specimen of this experiment, the nickel sheet, was produced in various sizes. A thermocouple (0.127 mm, K-type, Omega) was fixed on the surface to measure the temperature of the specimen via the electric arc welding method. The left and right sides of the specimen were compressed by bus bars, which were connected to the circuit for rapid heating. The capacitor was charged to a set voltage, and the various values of the charging voltage, such as 16 V, 19 V, and 21 V, etc., were measured using the multi-meter. The reliability of the capacitor under continuous charging and discharging was estimated in a sample test according to the various temperature values from 300 to 500 C [31]. A Mach–Zehnder interferometer and high-speed camera were prepared for measurements. The pulse generator acts as a trigger which allows each device to operate simultaneously. The temperature distribution and visualization image data were automatically measured for about 0.3 s. After one experiment, performed in an open or closed space with the specimen, the conditions of the experiment were reset, and the experiment was repeatedly carried out in order to check the reproducibility of these experiments. Actually, there were some uncertainties about these experiments. The uncertainty in this study could be divided into operational aspects of the experimental equipment and errors in data processing. In terms of the operation of the experimental equipment, there were the dimensions of production of the specimens, the precision of the charging voltage, etc., the misalignment of the experimental equipment, and the inherent error of the measurement equipment. In addition, the errors in data processing occur mainly in the process of measuring the deformation distance of the finite pattern line to calculate the Nusselt number. 3. Results and Discussion Experiments were performed to confirm the generation and propagation of the thermo-acoustic waves from a nickel sheet in an R–C rapid heating circuit. Figure 3 shows the trial process to find the testing sheet temperature and thickness of it, generating the Mach number (Ma) with various charging voltages. This confirmed that the Mach number had the value of 0.99, which comes close to the value of 1, as in the case of E = 19 V [31]. We performed the experimental works to confirm the eects of charging voltages based on the value of charging voltage at 19 V. Figure 3a shows the thickness eects of the specimen with various values of temperature, as in the case of continuously discharging energy by a 68,000 F capacitor with a charging voltage of E = 21 V. For the specimen thicknesses of = 0.0125 mm and = 0.01 mm, the maximum temperature values were obtained as 142 C and 185 C, with acquisition times of 0.35 s and 0.065 s, respectively. The eects of the discharging energy Appl. Sci. 2020, 10, 4658 6 of 13 on the temperature distribution of the specimen with = 0.0075 mm thickness are shown in Figure 3b. The maximum temperature values were found to be about 257 C, 362 C, and 475 C when the discharging voltages of the capacitor were E = 16 V, 19 V, and 21 V, respectively [31]. Appl. Sci. 2020, 10, x FOR PEER REVIEW 6 of 14 δ = 0.0075mm δ = 0.0100mm δ = 0.0125mm 0.0 0.2 0.4 0.6 0.8 1.0 1.2 Time, t (s) (a) 21V 19V 16V 0.0 0.2 0.4 0.6 0.8 1.0 1.2 Time, t (s) (b) Figure 3. Temperature variation of nickel sheet with C = 68,000 F [31]. (a) Thickness eect with 21 V, Figure 3. Temperature variation of nickel sheet with C = 68,000 µF [31]. (a) Thickness effect with 21 V, (b) Voltage eect with = 0.0075 mm. (b) Voltage effect with δ = 0.0075 mm. Infinite fringes of the interference phenomena in the upper part of a heating surface of the nickel Infinite fringes of the interference phenomena in the upper part of a heating surface of the nickel sheet are shown in Figure 4. A Mach–Zehnder interferometer and high-speed digital camera were sheet are shown in Figure 4. A Mach–Zehnder interferometer and high-speed digital camera were used to visualize the interference phenomena. In order to elucidate the eects of charging energies, used to visualize the interference phenomena. In order to elucidate the effects of charging energies, the charging voltages of the capacity were set to E = 17 V, 19 V, and 21 V, in order to check the the charging voltages of the capacity were set to Ec = 17 V, 19 V, and 21 V, in order to check the interference phenomena with various charging energies based on the value of Ma = 1. The maximum interference phenomena with various charging energies based on the value of Ma = 1. The maximum temperatures of 296 C, 378 C, and 480 C, corresponding to each discharging voltage, respectively, temperatures of 296 °C, 378 °C, and 480 °C, corresponding to each discharging voltage, respectively, were reached in about 0.05 s. were reached in about 0.05 s. At the beginning of heating, conduction or radiation heat transfer were expected from the rapid heating and cooling of fluid, which makes contact with the heated wall. It was verified from the results that the distance between the isothermal line and the nickel sheet was shorter than 0.5 mm. Then, the distance between them gradually increased because of the expansion of the fluid. The cutting line of the infinite fringes appeared at 0.01 s and then disappeared after about 0.001 s. This is because the thermo-acoustic wave generated by the fluid heating source dissipated. Therefore, the heating energy and time required to reach the maximum temperature are important factors in the generation of thermally powerful acoustic waves. For generating the thermo-acoustic waves, rapid Temperature, T ( C) Temperature, T ( C) Appl. Sci. 2020, 10, 4658 7 of 13 Appl. Sci. 2020, 10, x FOR PEER REVIEW 8 of 14 t = 0.000 s t = 0.001 s t = 0.002 s t = 0.003 s t = 0.004 s (a) (b) (c) Figure 4. Temporal variations of interferogram with nickel sheet (infinite fringe, = 0.0075 mm). Figure 4. Temporal variations of interferogram with nickel sheet (infinite fringe, δ = 0.0075 mm). (a) (a) 17 V, (b) 19 V, (c) 21 V. 17 V, (b) 19 V, (c) 21 V. At the beginning of heating, conduction or radiation heat transfer were expected from the rapid heating and cooling of fluid, which makes contact with the heated wall. It was verified from the results that the distance between the isothermal line and the nickel sheet was shorter than 0.5 mm. Then, the distance between them gradually increased because of the expansion of the fluid. The cutting line of the infinite fringes appeared at 0.01 s and then disappeared after about 0.001 s. This is because the thermo-acoustic wave generated by the fluid heating source dissipated. Therefore, the heating energy and time required to reach the maximum temperature are important factors in the generation of thermally powerful acoustic waves. For generating the thermo-acoustic waves, rapid heating Appl. Sci. 2020, 10, 4658 8 of 13 should be supplied within 0.01–0.03 s, and sucient energy is needed to grow and propagate the thermo-acoustic waves. The isothermal lines that occurred at the beginning of heating are disturbed at a certain time. Figure 4c shows that the largest heating energy occurs at about 0.008 s. In Figure 4a,b, the largest heating energy occurs at about 0.12–0.14 s and 0.1 s, respectively. The occurrence of these disturbance phenomena is considered a critical point from which the natural convection originates. The critical point of the nickel sheet is shortened by about two times relative to that of a stainless steel sheet, despite having a five to eight times lower heating energy. However, in order to observe visual outputs such as shock waves, it is necessary that the maximum temperature be reached within 0.015–0.023 s. The displacements of finite fringes are shown in Figure 5. Finite fringes were set perpendicularly on the upper part of the = 0.0075 mm thick nickel sheet. The heating conditions were the same as in Figure 4. The heating phenomena were observed before 0.001–0.002 s for the heating conditions. At about 0.01 s, a cutting line that interrupted the finite fringes could be observed near the upper part of the nickel sheet, but it was extinguished immediately. This displacement was dependent on the surface temperature of the sheet, and it plays a leading part in understanding the characteristics of the heat transfer of the fluid near the metal sheet. Before 0.015 s, it was dicult to distinguish the critical point of the displacements. As time proceeded, however, the critical point could be observed. It could be distinguished with the naked eye that these local displacements varied according to the discharging energy. The displacement lines formed at the beginning of heating were disturbed at a certain time. The occurrence of these disturbance phenomena is considered as a critical point from which the natural convection originates, like in Figure 4. The local Nusselt number can be obtained in order to estimate the heat transfer characteristics in the heating wall by measuring local values of the interval between the order of interference (S ) and the finite pattern, using the following equations: H 1 @Dx Nu = (1) dn/dT l @y (T T ) w 1 z dn S = (2) dT l (T T ) z w 1 where H is the local height, and T and T are the wall temperature and the surround temperature, w 1 respectively. denotes the wavelength of the He-Ne laser source, which is 632.8 nm, and l is the measured specimen length along the direction of light. The modified position and spacing of the patterns can be determined by measuring the pixel coordinates, as shown in Figure 6. The relevant values can be converted into actual dimensions or positions using Equation (3): h = h (3) The variations of the local Nusselt numbers for dierent nickel sheet thicknesses and heating energies are shown in Figures 7–9. As the thickness of the testing sheet increased, the total heat capacity increased accordingly. Therefore, a high charging voltage must be applied to ensure the temperature of the shock wave on the plate. The local Nusselt number distributions for the case of rapidly heated = 0.0125 mm nickel sheet are shown in Figure 7. It was dicult to distinguish the exact deformed location in the finite patterns obtained until 0.015 s. This diculty was caused by the natural convection generated due to buoyancy eects, which resulted from the relatively long time of 0.35 s to reach the maximum temperature, unlike with the initial expansion and compression and heat transfer by conduction. The local Nusselt number was decreased by increasing the charging voltage, indicating a dependence on the discharge energy. Appl. Sci. 2020, 10, 4658 9 of 13 Appl. Sci. 2020, 10, x FOR PEER REVIEW 9 of 14 t = 0.000 s t = 0.001 s t = 0.002 s Appl. Sci. 2020, 10, x FOR PEER REVIEW 10 of 14 where H is the local height, and Tw and T∞ are the wall temperature and the surround temperature, respectively. λ denotes the wavelength of the He-Ne laser source, which is 632.8 nm, and lz is the measured specimen length along the direction of light. The modified position and spacing of the t = 0.003 s patterns can be determined by measuring the pixel coordinates, as shown in Figure 6. The relevant values can be converted into actual dimensions or positions using Equation (3): y ' hh ' = (3) The variations of the local Nusselt numbers for different nickel sheet thicknesses and heating energies are shown in Figures 7–9. As the thickness of the testing sheet increased, the total heat t = 0.010 s capacity increased accordingly. Therefore, a high charging voltage must be applied to ensure the temperature of the shock wave on the plate. The local Nusselt number distributions for the case of rapidly heated δ = 0.0125 mm nickel sheet are shown in Figure 7. It was difficult to distinguish the exact deformed location in the finite patterns obtained until 0.015 s. This difficulty was caused by the (a) (b) (c) natural convection generated due to buoyancy effects, which resulted from the relatively long time of 0.35 s to reach the maximum temperature, unlike with the initial expansion and compression and Figure 5. Temporal variations of interferogram with nickel sheet (finite fringe, = 0.0075 mm). (a) 17 V, heat transfer Figure 5. by conductio Temporal varia n. The loc tions of interferogra al Nusselt n m with ni umber was decr ckel sheet (finiease te fringe, d by δ =incr 0.0075 easing the ch mm). (a) 17 arging (b) 19 V, (c) 21 V. V, (b) 19 V, (c) 21 V. voltage, indicating a dependence on the discharge energy. The local Nusselt number can be obtained in order to estimate the heat transfer characteristics in the heating wall by measuring local values of the interval between the order of interference (Sw) and the finite pattern, using the following equations: H 1 λ ∂Δx Nu =− (1) H () TT−∂ dn/dTl y wz ∞ dn λ S (2) =− ⋅ dT l () T −T zw ∞ (a) (b) Figure 6. Figure 6.The Themethodology for the ca methodology for the calculation lculation of lo of local cal posi position tion of fr of fringe. inge. (( aa ) Reference, ( ) Reference, ( b b) Real state ) Real state. . E = 21.25W E = 28.59W E = 37.02W 0.00 0.04 0.08 0.12 0.16 0.20 Time, t (s) Figure 7. Variations in local Nusselt numbers for different heating energies with nickel sheet (δ = 0.0125 mm). Nusselt number, Nu Appl. Sci. 2020, 10, x FOR PEER REVIEW 10 of 14 where H is the local height, and Tw and T∞ are the wall temperature and the surround temperature, respectively. λ denotes the wavelength of the He-Ne laser source, which is 632.8 nm, and lz is the measured specimen length along the direction of light. The modified position and spacing of the patterns can be determined by measuring the pixel coordinates, as shown in Figure 6. The relevant values can be converted into actual dimensions or positions using Equation (3): y ' hh ' = (3) The variations of the local Nusselt numbers for different nickel sheet thicknesses and heating energies are shown in Figures 7–9. As the thickness of the testing sheet increased, the total heat capacity increased accordingly. Therefore, a high charging voltage must be applied to ensure the temperature of the shock wave on the plate. The local Nusselt number distributions for the case of rapidly heated δ = 0.0125 mm nickel sheet are shown in Figure 7. It was difficult to distinguish the exact deformed location in the finite patterns obtained until 0.015 s. This difficulty was caused by the natural convection generated due to buoyancy effects, which resulted from the relatively long time of 0.35 s to reach the maximum temperature, unlike with the initial expansion and compression and heat transfer by conduction. The local Nusselt number was decreased by increasing the charging voltage, indicating a dependence on the discharge energy. (a) (b) Appl. Sci. 2020, 10, 4658 10 of 13 Figure 6. The methodology for the calculation of local position of fringe. (a) Reference, (b) Real state. E = 21.25W E = 28.59W E = 37.02W 0.00 0.04 0.08 0.12 0.16 0.20 Time, t (s) Figure Appl. 7. Sci. Variations 2020, 10, x FO in local R PEER Nusselt REVIEW numbers for dierent heating energies with nickel sheet ( = 0.0125 11 of 14 mm). Figure 7. Variations in local Nusselt numbers for different heating energies with nickel sheet (δ = Appl. Sci. 2020, 10, x FOR PEER REVIEW 11 of 14 0.0125 mm). E = 21.25W E = 21.25W E = 26.65W E = 26.65W E = 32.67W E = 32.67W 0 0.00 0.02 0.04 0.06 0.08 0.10 0.12 0.14 0.00 0.02 0.04 0.06 0.08 0.10 0.12 0.14 Time, t (s) Time, t (s) Figure 8. Variation in local Nusselt numbers for different heating energies with nickel sheet (δ = 0.0100 Figure 8. Variation in local Nusselt numbers for dierent heating energies with nickel sheet ( = 0.0100 mm). Figure 8. Variation in local Nusselt numbers for different heating energies with nickel sheet (δ = 0.0100 mm). mm). E = 6.66W E = 6.66W E = 9.82W E = 9.82W E = 12.27W E = 12.27W 40 E = 14.99W E = 14.99W 0.00 0.02 0.04 0.06 0.08 0.10 0.12 0.14 0.00 0.02 0.04 0.06 0.08 0.10 0.12 0.14 Time, t (s) Time, t (s) Figure 9. Variation in local Nusselt numbers for dierent heating energies with nickel sheet ( = 0.0075 mm). Figure 9. Variation in local Nusselt numbers for different heating energies with nickel sheet (δ = 0.0075 Figure 9. Variation in local Nusselt numbers for different heating energies with nickel sheet (δ = 0.0075 mm). mm). For heating energies of E = 21.25 W, 28.59 W, and 37.02 W, equivalent to the charging voltage For heating energies of E = 21.25 W, 28.59 W, and 37.02 W, equivalent to the charging voltage values of 25 V, 29 V, and 33 V, respectively, the maximum temperatures reached 137 °C, 280 °C, and values of 25 V, 29 V, and 33 V, respectively, the maximum temperatures reached 137 °C, 280 °C, and 520 °C. The results also showed that at around 0.2 s, the local Nusselt number tended to increase and 520 °C. The results also showed that at around 0.2 s, the local Nusselt number tended to increase and converge. This might have resulted from the increase in convective heat transfer due to buoyancy, converge. This might have resulted from the increase in convective heat transfer due to buoyancy, according to the long time required to reach the highest temperature and the lack of cooling rate according to the long time required to reach the highest temperature and the lack of cooling rate caused by the heat capacity of the material. caused by the heat capacity of the material. Figure 8 shows the case of the δ = 0.01-mm-thick nickel sheet. As the heating energy was varied Figure 8 shows the case of the δ = 0.01-mm-thick nickel sheet. As the heating energy was varied to E = 21.25 W, 26.65 W, and 32.67 W, corresponding to charging voltage values of 25 V, 28 V, and 31 to E = 21.25 W, 26.65 W, and 32.67 W, corresponding to charging voltage values of 25 V, 28 V, and 31 V, respectively, the maximum temperatures reached 290 °C, 390 °C, and 490 °C. The local Nusselt V, respectively, the maximum temperatures reached 290 °C, 390 °C, and 490 °C. The local Nusselt number tended to decrease initially and then increase slightly after 0.12 s, since the time to reach the number tended to decrease initially and then increase slightly after 0.12 s, since the time to reach the peak temperature and cooling characteristics still affected the partial increase in the convective heat peak temperature and cooling characteristics still affected the partial increase in the convective heat transfer, as is shown in the numerical results in Figure 3a. transfer, as is shown in the numerical results in Figure 3a. Figure 9 presents the local Nusselt number variations for the case of δ = 0.0075-mm-thick nickel Figure 9 presents the local Nusselt number variations for the case of δ = 0.0075-mm-thick nickel sheet. The maximum temperature reached 204 °C, 296 °C, 378 °C, and 480 °C for the heating energies sheet. The maximum temperature reached 204 °C, 296 °C, 378 °C, and 480 °C for the heating energies Nusselt number, Nu Nu Nu ssss elt elt num num ber, ber, N u Nu Nusselt Nusselt num num ber ber , N , u Nu Appl. Sci. 2020, 10, 4658 11 of 13 For heating energies of E = 21.25 W, 28.59 W, and 37.02 W, equivalent to the charging voltage values of 25 V, 29 V, and 33 V, respectively, the maximum temperatures reached 137 C, 280 C, and 520 C. The results also showed that at around 0.2 s, the local Nusselt number tended to increase and converge. This might have resulted from the increase in convective heat transfer due to buoyancy, according to the long time required to reach the highest temperature and the lack of cooling rate caused by the heat capacity of the material. Figure 8 shows the case of the = 0.01-mm-thick nickel sheet. As the heating energy was varied to E = 21.25 W, 26.65 W, and 32.67 W, corresponding to charging voltage values of 25 V, 28 V, and 31 V, respectively, the maximum temperatures reached 290 C, 390 C, and 490 C. The local Nusselt number tended to decrease initially and then increase slightly after 0.12 s, since the time to reach the peak temperature and cooling characteristics still aected the partial increase in the convective heat transfer, as is shown in the numerical results in Figure 3a. Figure 9 presents the local Nusselt number variations for the case of = 0.0075-mm-thick nickel sheet. The maximum temperature reached 204 C, 296 C, 378 C, and 480 C for the heating energies of E = 6.66 W, 9.82 W, 12.27 W, and 14.99 W, which are equivalent to the charging voltage values of 14 V, 17 V, 19 V, and 33 V, respectively. As time passed, the local Nusselt number tended to vary as a quadratic function. In addition, it tended to decrease due to increases in the heating energy in the same way as in the prior cases of Figures 7 and 8, compared to the relatively large values of the local Nusselt numbers that were found in the case of Figure 9. This is because of the dierent heating energy per unit volume, caused by dierences in the thickness of the nickel sheet and the temperature rise. The local Nusselt number can be expressed as a quadratic Equation (4) with respect to time, as follows: Nu = At + Bt + C (4) The coecients A, B, and C are described in Table 3. Table 3. Coecients of Nusselt number in Equation (4). Conditions A B C 25 V 1201.6 353.06 41.70 = 0.0125 mm 29 V 1288.2 337.38 33.30 33 V 1349.5 327.83 29.46 25 V 1533.6 349.9 28.95 = 0.0100 mm 28 V 2100.9 400.4 27.32 31 V 2114.3 392.2 23.57 14 V 687.7 336.7 46.71 17 V 672.7 263.1 34.28 = 0.0075 mm 19 V 1164.1 320.1 30.61 21 V 1189.9 300.6 25.49 4. Conclusions The visualization of thermo-acoustic phenomena induced by the rapid heating of compressible fluid near a nickel sheet has been studied experimentally. The following conclusions were obtained: (1) Dierent discharging rates and heating characteristics could occur with the same energy supplied according to the material properties and the size of the metal sheet. These dierences cause variations in the maximum temperature and the required time to reach the peak of the nickel sheet. (2) At the beginning of heating (before 0.008 s), several interference fringes were observed near the nickel sheet. The number of isothermal lines and the strain rate increased with the heating energy. The critical time denoted as the onset of disturbance was shortened as the heating energy Appl. Sci. 2020, 10, 4658 12 of 13 increased and the heating time decreased. The critical time was measured to be about 0.06–0.16 s after heating. (3) The heat transfer decreases as a second-order function with time. As the heating energy increased, the local Nusselt number decreased. It is concluded that the heat transfer mainly occurred by conduction and radiation rather than by convection, because the expansive force and compressive force between fluid layers on the wall increased due to an increase in the heating energy in the beginning. Author Contributions: H.-S.S. supported the theory background, developed experiments, analyzed the data, and wrote the paper. I.-J.H. and Y.-J.K. supported the theory background, analyzed the data, and reviewed the paper. All authors have read and agree to the published version of the manuscript. Funding: This research was supported by a grant (19IFIP-B089072-06#) from Plant Research Program funded by Ministry of Land, Infrastructure and Transport of Korean government. Conflicts of Interest: The authors declare no conflict of interest. References 1. Rayleigh, L., XXV. On the conduction of heat in a spherical mass of air confined by walls at a constant temperature. Lond. Edinb. Dublin Philos. Mag. J. Sci. 1899, 47, 314–325. [CrossRef] 2. Ozoe, H.; Sato, N.; Churchill, S.W. The eect of various parameters on thermoacoustic convection. Chem. Eng. Commun. 1980, 5, 203–221. [CrossRef] 3. Ozoe, H.; Sato, N.; Churchill, S.W. Numerical analyses of two-and three-dimensional thermo-acoustic convection generated by a transient step in the temperature of one wall. Numer. Heat Transf. A 1990, 18, 1–15. [CrossRef] 4. Kassoy, D.R. The response of a confined gas to a thermal disturbance: Slow transients. Siam J. Appl. Math. 1979, 36, 624–634. [CrossRef] 5. Radhwan, A.M.; Kassoy, D.R. The response of a confined gas to a thermal disturbance: Rapid boundary heating. J. Eng. Math. 1984, 18, 133–156. [CrossRef] 6. Huang, Y.; Bau, H.H. Thermoacoustic waves in a semi-infinite medium. Int. J. Heat Mass. Transf. 1995, 38, 1329–1345. [CrossRef] 7. Huang, Y.; Bau, H.H. Thermoacoustic waves in a confined medium. Int. J. Heat Mass. Transf. 1997, 40, 407–419. [CrossRef] 8. Fusegi, T.; Farouk, B.; Oran, E.S. Numerical study of thermo-acoustic convection in a cavity. In National Heat Transfer Conference; American Society of Mechanical Engineers: New York, NY USA, 1995; HTD-Volume 305. 9. Lin, Y.; Farouk, B. Flows induced by thermoacoustic waves in an enclosure: Eect of gravity. J. Thermophys. Heat Trans. 2006, 20, 376–383. [CrossRef] 10. Aktas, M.; Farouk, B. Numerical simulation of developing natural convection in an enclosure due to rapid heating. Int. J. Heat Mass Transf. 2003, 46, 2253–2261. [CrossRef] 11. Farouk, B.; Oran, E.S.; Brown, M.A. Numerical study of thermoacoustic waves in an enclosure. Phys. Fluids 2000, 12, 1052–1061. [CrossRef] 12. Škerget, L.; Ravnik, J. Numerical simulation of compressible fluid flow in an enclosure induced by thermoacoustic waves. In AIP Conference Proceedings, Numerical Analysis and Applied Mathematics; American Institute of Physics: University Park, MD, USA, 2007; Volume 936, pp. 523–526. 13. Goldstein, R.J.; Eckert, E.R.G. The steady and transient free convection boundary layer on a uniformly heated vertical plate. Int. J. Heat Mass Transf. 1960, 1, 208–218. [CrossRef] 14. Polymeropoulos, C.E.; Gebhart, B. Incipient instability in free convection laminar boundary layer. J. Fluid Mech. 1967, 30, 225–239. [CrossRef] 15. Shakher, C.; Nirala, A.K. A review on refractive index and temperature profile measurements using laser-based interferometric techniques. Opt. Lasers Eng. 1999, 31, 455–491. [CrossRef] 16. Herman, C.; Kang, E. Experimental visualization of temperature field and study of heat transfer enhancement in oscillatory flow in a grooved channel. Int. J. Heat Mass Transf. 2001, 37, 87–99. [CrossRef] 17. Jarosinski, W. Various experimental methods to study heat transfer from the heated rib-roughed wall to a steady or pulsating flow. J. Kones Intern. Combust. Engines 2003, 10, 3–4. Appl. Sci. 2020, 10, 4658 13 of 13 18. Binoy, B.; Sobhan, C.B. Investigation on forced convection in compact passage with surface irregularities. Heat Trans. Eng. 2012, 33, 1105–1119. 19. Binoy, B.; Sobhan, C.B. Numerical and experimental investigation on forced convection in meso-channel with irregular geometry of cross-section. Int. J. Heat Mass Transf. 2014, 70, 276–288. 20. Blanc-Benon, P.; Besnoin, E.; Knio, O. Experimental and computational visualization of the flow field in a thermoacoustic stack. Comptes Rendus Mec. 2003, 331, 17–24. [CrossRef] 21. Takahshi, Y.; Chen, L.; Okajima, J.; Iga, Y.; Komiya, A.; Maruyama, S. Interferometric measurement and numerical comparison of supersonic heat transfer flows in microchannel. Appl. Therm. Eng. 2016, 109, 582–590. [CrossRef] 22. Yousefi-Asli, V.; Houshfar, E.; Beygi-Khosroshahi, F.; Ashjaee, M. Experimental investigation on temperature field and heat transfer distribution of a slot burner methane/air flame impinging on a curved surface. Appl. Therm. Eng. 2018, 129, 761–771. [CrossRef] 23. Berson, A.; Michard, M.; Blanc-Benon, P. Measurement of acoustic velocity in the stack of a thermoacoustic refrigerator using particle image velocimetry. Heat Mass Transf. 2007, 44, 1015–1023. [CrossRef] 24. Berson, A.; Poignand, G.; Blanc-Benon, P.; Comte-Bellot, G. Nonlinear temperature field near the stack ends of a standing-wave thermoacoustic refrigerator. Int. J. Heat Mass Transf. 2011, 54, 4730–4735. [CrossRef] 25. Mao, X.; Yu, Z.; Jaworski, A.J.; Marx, D. PIV studies of coherent structures generated at the end of a stack of parallel plates in a standing wave acoustic field. Exp. Fluids 2008, 45, 833–846. [CrossRef] 26. Aben, P.C.H.; Bloemen, P.R.; Zeegers, J.C. 2-D PIV measurements of oscillatory flow around parallel plates. Exp. Fluids 2009, 46, 631–641. [CrossRef] 27. Shi, L.; Yu, Z.B.; Jaworski, A.J. Vortex formation at the end of the parallel-plate stack in the standing-wave thermoacoustic device. In Proceedings of the Sixteenth International Congress on Sound and Vibration, Krakow, Poland, 5–7 July 2009. 28. Shi, L.; Yu, Z.B.; Jaworski, A.J.; Abduljalil, A.S. Vortex shedding at the end of parallel-plate thermoacoustic stack in the oscillatory flow condition. Int. J. Aerosp. Mech. Eng. 2009, 37, 766–773. 29. Shi, L.; Yu, Z.B.; Jaworski, A.J. Vortex shedding flow patterns and their transitions in oscillatory flows past parallel-plate thermoacoustic stacks. Exp. Fluid Sci. 2010, 34, 954–965. [CrossRef] 30. Shi, L.; Yu, Z.B.; Jaworski, A.J. Application of laser-based instrumentation for measurement of time-resolved temperature and velocity fields in the thermoacoustic system. Int. J. Sci. 2010, 49, 1688–1701. [CrossRef] 31. Hwang, I.J.; Kim, Y.J. Measurement of thermo-acoustic waves induced by rapid heating of nickel sheet in open and confined spaces. Int. J. Heat Mass Transf. 2006, 49, 575–581. [CrossRef] © 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png
Applied Sciences
Multidisciplinary Digital Publishing Institute
http://www.deepdyve.com/lp/multidisciplinary-digital-publishing-institute/interferometric-study-of-the-heat-transfer-phenomena-induced-by-rapid-oBi0HPydOg