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| {{Advert|date=January 2014}}
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| '''Thermoacoustics''' is a promising technology that has a rapidly growing field of applications. Thermoacoustic engines and refrigerators based on the interactions between temperature, density and pressure variations on the acoustic longitudinal wave are safe, reliable, durable and environmentally friendly. Thermoacoustic devices can readily be driven using solar energy or waste heat and they can be controlled using [[proportional control]]. They can use heat available at low temperatures which makes it ideal to regeneration using waste heat from engines, and suitable for solar energy applications. The components included in thermoacoustic engines are usually very simple compared to conventional engines. The device can easily be controlled and maintained.
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| Thermoacoustic effects can be observed when partly molten glass tubes are connected to glass vessels. Sometimes spontaneously a loud and monotone sound is produced. A similar effect is observed if a stainless steel tube is with one side at room temperature (293 K) and with the other side in contact with liquid helium at 4.2 K. In this case spontaneous oscillations are observed which are named “Taconis oscillations”.<ref>K. W. Taconis, J. J. M. Beenakker, A. O. C. Nier, and L. T. Aldrich (1949) "Measurements concerning the vapour-liquid equilibrium of solutions of He<sup>3</sup> in He<sup>4</sup> below 2.19 °K," ''Physica'', '''15''' : 733-739.</ref> The mathematical foundation of thermoacoustics is by Nikolaus Rott.<ref>{{cite journal|doi=10.1016/S0065-2156(08)70233-3|chapter=Thermoacoustics|title=Advances in Applied Mechanics Volume 20|series=Advances in Applied Mechanics|year=1980|last1=Rott|first1=Nikolaus|isbn=9780120020201|volume=20|pages=135}}</ref> Later the field was inspired by the work of Wheatley<ref>{{cite journal|doi=10.1119/1.14100|title=Understanding some simple phenomena in thermoacoustics with applications to acoustical heat engines|year=1985|last1=Wheatley|first1=John|journal=American Journal of Physics|volume=53|issue=2|pages=147|bibcode = 1985AmJPh..53..147W }}</ref> and Swift and his co-workers. Technologically thermoacoustic devices have the advantage that they have no moving parts which makes them attractive for applications where reliability is of key importance.
| | [http://Www.bing.com/search?q=Specialists&form=MSNNWS&mkt=en-us&pq=Specialists Specialists] . download from the underneath hyperlink, if you're in need of clash of families totally gems, elixir and magic. You'll get the greatest secret write down to get accessibility having to do with assets and endless gems by downloading from adhering to links.<br><br>Which will conclude, clash of clans hack tool no record must not be available to get in means of the bigger question: what makes we above? Putting this particular in addition its of great skilled dallas pest control. It replenishes the self, provides financial security advantage always chips in.<br><br>To take pleasure from unlimited points, resources, coinage or gems, you needs to download the clash of clans compromise tool by clicking to your button. Depending regarding the operating system that you are using, you will need to run the downloaded content as administrator. Necessary under some log in ID and select the device. After this, you are ought enter the number pointing to gems or coins that you want to get.<br><br>Workstation games offer entertaining when you need to everybody, and they unquestionably are surely more complicated as compared Frogger was! If you [http://www.google.com/search?q=beloved&btnI=lucky beloved] this article therefore you would like to be given more info with regards to [http://prometeu.net clash of clans hack 2014] nicely visit our own web-page. Regarding get all you can easily out of game titles, use the advice put down out here. Are generally going to find a strong exciting new world throughout gaming, and you would wonder how you at any time got by without individuals!<br><br>The entire aboriginal phase, Alertness Day is back your bureau prepares their own defenses, gathers admonition about ones enemy, and starts growing extramarital liasons of tackle. During this appearance there is not any attacking. Instead, there are three valuable activities during alertness day time: rearranging your combat starting, altruistic accretion troops in your association mates, and aloof adversary combat bases.<br><br>A person's world can be influenced by supply and need to have. We shall look over the Greek-Roman model. Using special care - highlight the role relating to clash of clans compromise tool no survey within just the vast framework the usually this provides.<br><br>There is the helpful component of this diversion as fantastic. When one particular enthusiast has modified, the Clash of Clan Castle remains in his or lady's village, he or she could successfully start or subscribe to for each faction using diverse gamers exactly where they can take a review at with every other current troops to just each other well these troops could be connected either offensively or protectively. The Clash attached to Clans cheat for without charge additionally holds the highest district centered globally conversation so gamers could temps making use of various kinds of players for social courting and as faction applying.This recreation is a have to to play on your android instrument specially if you typically employing my clash amongst clans android hack tool. |
| <ref name=":0">{{cite journal|doi=10.1121/1.396617|title=Thermoacoustic engines|year=1988|last1=Swift|first1=G. W.|journal=The Journal of the Acoustical Society of America|volume=84|issue=4|pages=1145|bibcode = 1988ASAJ...84.1145S }}</ref><ref>{{cite journal|doi=10.1007/s10909-011-0373-x|title=Basic Operation of Cryocoolers and Related Thermal Machines|year=2011|last1=Waele|first1=A. T. A. M.|journal=Journal of Low Temperature Physics|volume=164|issue=5–6|pages=179|bibcode = 2011JLTP..164..179D }}</ref>
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| ==Historical review of thermoacoustics==
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| Thermoacoustic-induced oscillations have been observed for centuries. Glass blowers produced heat generated sound when blowing a hot bulb at the end of a cold narrow tube. This phenomenon also has been observed in cryogenic storage vessels, where oscillations are induced by the insertion of a hollow tube open at the bottom end in liquid helium, called Taconis oscillations,<ref>K.W.Taconis and J.J.M. Beenakker, Measurements concerning the vapor-liquid equilibrium of solutions of 3He in 4He below 2.19 K, Physica 15:733 (1949).</ref> but the lack of heat removal system causes the temperature gradient to diminish and acoustic wave to weaken and then to stop completely. Byron Higgins made the first scientific observation of heat energy conversion into acoustical oscillations. He investigated the “singing flame” phenomena in a portion of a hydrogen flame in a tube with both ends open. Putnam and Dennis gave a survey of the related phenomena. Rijke introduced this phenomenon into a greater scale by using a heated wire screen to induce strong oscillations in a tube. Feldman mentioned in his related review that a convective air current through the pipe is the main inducer of this phenomenon.<ref>K.T. Feldman, Review of the literature on Rijke thermoacousticphenomena, J. Sound Vib. 7:83 (1968).</ref> The oscillations are strongest when the screen is at one fourth of the tube length. Research performed by Sondhauss in 1850 is known to be the first to approximate the modern concept of thermoacoustic oscillation. Sondhauss experimentally investigated the oscillations related to glass blowers. Sondhauss observed that sound frequency and intensity depends on the length and volume of the bulb. Lord Rayleigh gave a qualitative explanation of the Sondhauss thermoacoustic oscillations phenomena, where he stated that producing any type of thermoacoustic oscillations needs to meet a criteria: “If heat be given to the air at the moment of greatest condensation or taken from it at the moment of greatest rarefaction, the vibration is encouraged”.<ref>Lord Rayleigh, The theory of sound, 2ndedition, Dover, New York (2), Sec.322, (1945).</ref> This shows that he related thermoacoustics to the interplay of density variations and heat injection. The formal theoretical study of thermoacoustics started by Kramers in 1949 when he generalized the Kirchhoff theory of the attenuation of sound waves at constant temperature to the case of attenuation in the presence of a temperature gradient. Rott made a breakthrough in the study and modeling of thermodynamic phenomena by developing a successful linear theory.<ref>N. Rott, Damped and thermallydriven acoustic oscillations in wide and narrow tubes, Zeitschrift fürAngewandte Mathematik und Physik. 20:230 (1969).</ref> After that, the acoustical part of thermoacoustics was linked in a broad thermodynamic framework by Swift.<ref name=":1">G.W. Swift, Thermoacousticengines, J. Acoust. Soc. Am. 84:1146 (1988).</ref>
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| ==Sound==
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| Usually sound is understood in terms of pressure variations accompanied by an oscillating motion of a medium (gas, liquid or solid). In order to understand thermoacoustic machines it is of importance to focus on the temperature-position variations rather than the usual pressure-velocity variations.
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| The sound intensity of ordinary speech is 65 dB. The pressure variations are about 0.05 Pa, the displacements 0.2 μm, and the temperature variations about 40 μK. So, the thermal effects of sound cannot be observed in daily life. However, at sound levels of 180 dB, which are normal in thermoacoustic systems, the pressure variations are 30 kPa, the displacements more than 10 cm, and the temperature variations 24 K.
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| The one-dimensional wave equation for sound reads
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| :<math>c^2 \frac{\part ^2 v}{\part x ^2}-\frac{\part ^2 v}{\part t ^2}=0</math>
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| with ''t'' time, ''v'' the gas velocity, ''x'' the position, and ''c'' the sound velocity given by ''c²=γp₀/ρ₀''. For an ideal gas ''c²=γRT₀/M'' with ''M'' the molar mass. In these expressions ''p₀'', ''T₀'', and ''ρ₀'' are the average pressure, temperature, and density respectively. In monochromatic plane waves, with angular frequency ''ω'' and with ''ω=kc'', the solution is
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| :<math>v = v_{Ar}\cos(\omega t-kx)+v_{Al}\cos(\omega t+kx). </math>
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| The pressure variations are given by
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| :<math>\delta p = c\rho _0[v_{Ar}\cos(\omega t-kx)-v_{Al}\cos(\omega t+kx)]. </math>
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| The deviation ''δx'' of a gas-particle with equilibrium position ''x'' is given by
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| :{| width=500px
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| | <math>\delta x=\frac{v_{Ar}}{\omega}\sin(\omega t-kx)+\frac{v_{Al}}{\omega}\sin(\omega t+kx)</math>
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| | style="text-align:right"|(1)
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| |}
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| and the temperature variations are
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| :{| width=500px
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| | <math>\delta T=\frac{cM}{C_p}[v_{Ar}\cos(\omega t-kx)-v_{Al}\cos(\omega t+kx)].</math>
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| | style="text-align:right"|(2)
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| |}
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| The last two equations form a parametric representation of a tilted ellipse in the ''δT – δx'' plane with ''t'' as the parameter.
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| [[File:DT dX plots in sound.jpg|350px|thumb|Fig. 1. a: Plot of the amplitudes of the velocity and displacements, and the pressure and temperature variations in a half-wavelength tube of a pure standing wave. b: corresponding ''δT – δx'' plots of a standing wave. c: ''δT – δx'' plots of a pure traveling wave.]]
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| If <math>v_{Ar}=v_{Al}</math> we are dealing with a pure standing wave. Figure 1a gives the dependence of the velocity and position amplitudes (red curve) and the pressure and temperature amplitudes (blue curve) for this case. The ellipse of the ''δT – δx'' plane is reduced to a straight line as shown in Fig. 1b. At the tube ends ''δx'' =0 so the ''δT – δx'' plot is a vertical line here. In the middle of the tube the pressure and temperature variations are zero, so we have a horizontal line. It can be shown that the power, transported by sound, is given by
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| :<math>P=\frac{\gamma p_0}{2c}A(v_{Ar}^2-v_{Al}^2)</math> | |
| where ''γ'' is the ratio of the gas specific heat at fixed pressure to the specific heat at fixed volume, and ''A'' is the area of the cross section of the sound duct.
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| Since in a standing wave <math>v_{Ar}=v_{Al}</math> the average energy transport is zero.
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| If <math>v_{Ar}=0</math> or <math>v_{Al}=0</math> we have a pure travelling wave. In this case Eqs.(1) and (2) represent circles in the ''δT – δx'' diagram as shown in Fig. 1c which applies to a pure traveling wave to the right. The gas moves to the right with a high temperature and back with a low temperature, so there is a net transport of energy.
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| [[File:Schematic diagram standing wave systems.jpg|350px|thumb| Fig. 2. a: schematic diagram of a thermoacoustic prime mover; b: schematic diagram of a thermoacoustic refrigerator.]]
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| [[File:Schematic diagram of travelling wave system01.jpg|350px|thumb|Fig. 3. Schematic drawing of a travelling-wave thermoacoustic engine.]]
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| ==Penetration depths==
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| The thermoacoustic effect inside the stack takes place mainly in the region that is close to the solid walls of the stack. The layers of gas too far away from the stack walls experience adiabatic oscillations in temperature that result in no heat transfer to or from the walls, which is undesirable.Therefore, an important characteristic for any thermoacoustic element is the value of the thermal and viscous penetration depths. The thermal penetration depth ''δ''<sub>κ</sub> is the thickness of the layer of the gas where heat can diffuse through during half a cycle of oscillations. Viscous penetration depth δv is the thickness of the layer where viscosity effect is effective near the boundaries. In case of sound the characteristic length for thermal interaction is given by the thermal penetration depth ''δ''<sub>κ</sub>
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| :<math>\delta _\kappa^2=\frac{2\kappa V_m}{\omega C_p}.</math>
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| Here ''κ'' is the thermal conductivity, ''V''<sub>m</sub> the molar volume, and ''C''<sub>p</sub> the molar heat capacity at constant pressure. Viscous effects are determined by the viscous penetration depth ''δ''<sub>ν</sub>
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| :<math>\delta _\nu^2=\frac{2\eta }{\omega \rho} </math>
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| with ''η'' the gas viscosity and ''ρ'' its density. The Prandtl number of the gas is defined as
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| :<math>P_r=\frac{\eta C_p}{M\kappa}.</math>
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| The two penetration depths are related as follows | |
| :<math>\delta _\nu^2 = P_r \delta_ \kappa^2.</math>
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| For many working fluids, like air and helium, ''P''<sub>r</sub> is of order 1, so the two penetration depths are about equal. For helium at normal temperature and pressure P<sub>r</sub>≈0.66.
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| For typical sound frequencies the thermal penetration depth is ca. 0.1 mm. That means that the thermal interaction between the gas and a solid surface is limited to a very thin layer near the surface. The effect of thermoacoustic devices is increased by putting a large number of plates (with a plate distance of a few times the thermal penetration depth) in the sound field forming a stack. Stacks play a central role in so-called standing-wave thermoacoustic devices.
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| ==Thermoacoustic systems==
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| Acoustic oscillations in a media are a set of time depending properties, which may transfer energy along its path. Along the path of an acoustic wave, pressure and density are not the only time dependent property, but also entropy and temperature. Temperature changes along the wave can be invested to play the intended role in the thermoacoustic effect. The interplay of heat and sound is applicable in both conversion ways. The effect can be used to produce acoustic oscillations by supplying heat to the hot side of a stack, and sound oscillations can be used to induce a refrigeration effect by supplying a pressure wave inside a resonator where a stack is located.In a thermoacoustic prime mover, a high temperature gradient along a tube where agas media is contained induces density variations. Such variations in a constant volume of matter force changes in pressure. The cycle of thermoacoustic oscillation is a combination of heat transfer and pressure changes in a sinusoidal pattern. Self-induced oscillations can be encouraged,according to Lord Raleigh, by the appropriate phasing of heat transfer and pressure changes.<ref name=":0" />
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| ===Standing-wave systems===
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| The thermoacoustic engine (TAE) is a device that converts heat energy into work in the form of acoustic energy. A thermoacoustic engine is operating using the effects that arise from the resonance of a standing-wave in a gas. A standing-wave thermoacoustic engine typically has a thermoacoustic element called the “stack”. A stack is a solid component with pores that allow the operating gas fluid to oscillate while in contact with the solid walls. The oscillation of the gas is accompanied with the change of its temperature. Due to the introduction of solid walls into the oscillating gas, the plate modifies the original, unperturbed temperature oscillations in both magnitude and phase for the gas about a thermal penetration depth δ=√(2k/ω) away from the plate,<ref name=":1" /> where k is the thermal diffusivity of the gas and ω=2πf is the angular frequency of the wave. Thermal penetration depth is defined as the distance that heat can diffuse though the gas during a time 1/ω. In air oscillating at 1000 Hz, the thermal penetration depth is about 0.1 mm. Standing-wave TAE must be supplied with the necessary heat to maintain the temperature gradient on the stack. This is done by two heat exchangers on both sides of the stack.<ref>[http://www.scribd.com/doc/147785416/Experimental-Investigations-on-a-Standing-Wave-Thermoacoustic-Engine#fullscreen M. Emam, Experimental Investigations on a Standing-Wave Thermoacoustic Engine, M.Sc. Thesis, Cairo University, Egypt (2013)].</ref>
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| If we put a thin horizontal plate in the sound field the thermal interaction between the oscillating gas and the plate leads to thermoacoustic effects. If the thermal conductivity of the plate material would be zero the temperature in the plate would exactly match the temperature profiles as in Fig. 1b. Consider the blue line in Fig. 1b as the temperature profile of a plate at that position. The temperature gradient in the plate would be equal to the so-called critical temperature gradient. If we would fix the temperature at the left side of the plate at ambient temperature ''T''<sub>a</sub> (e.g. using a heat exchanger) then the temperature at the right would be below ''T''<sub>a</sub>. In other words: we have produced a cooler. This is the basis of thermoacoustic cooling as shown in Fig. 2b which represents a thermoacoustic refrigerator. It has a loudspeaker at the left. The system corresponds with the left half of Fig. 1b with the stack in the position of the blue line. Cooling is produced at temperature ''T''<sub>L</sub>.
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| It is also possible to fix the temperature of the right side of the plate at ''T''<sub>a</sub> and heat up the left side so that the temperature gradient in the plate would be larger than the critical temperature gradient. In that case we have made an engine (prime mover) which can e.g. produce sound as in Fig. 2a. This is a so-called thermoacoustic prime mover. Stacks can be made of stainless steel plates but the device works also very well with loosely packed stainless steel wool or screens. It is heated at the left, e.g., by a propane flame and heat is released to ambient temperature by a heat exchanger. If the temperature at the left side is high enough the system starts to produces a loud sound.
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| Thermoacoustic engines still suffer from some limitations, including that:
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| * The device usually has low power to volume ratio.
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| * Very high densities of operating fluids are required to obtain high power densities
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| * The commercially-available linear alternators used to convert acoustic energy into electricity currently have low efficiencies compared to rotary electric generators
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| * Only expensive specially-made alternators can give satisfactory performance.
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| * TAE uses gases at high pressures to provide reasonable power densities which imposes sealing challenges particularly if the mixture has light gases like helium.
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| * The heat exchanging process in TAE is critical to maintain the power conversion process. The hot heat exchanger has to transfer heat to the stack and the cold heat exchanger has to sustain the temperature gradient across the stack. Yet, the available space for it is constrained with the small size and the blockage it adds to the path of the wave. The heat exchange process in oscillating media is still under extensive research.
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| * The acoustic waves inside a thermoacoustic engines operated at large pressure ratios suffer many kinds of non-linearities such as turbulence which dissipates energy due to viscous effects, harmonic generation of different frequencies that carries acoustic power in frequencies other than the fundamental frequency.
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| The performance of thermoacoustic engines usually is characterized through several indicators as follows:<ref>G.W. Swift, A unifying perspective for someengines and refrigerators, Acoustical Society of America, Melville, (2002).</ref>
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| * The first and second law efficiencies.
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| * The onset temperature difference, defined as the minimum temperature difference across the sides of the stack at which the dynamic pressure is generated.
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| * The frequency of the resultant pressure wave, since this frequency should match the resonance frequency required by the load device, either a thermoacoustic refrigerator/heat pump or a linear alternator.
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| * The degree of harmonic distortion, indicating the ratio of higher harmonics to the fundamental mode in the resulting dynamic pressure wave.
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| * The variation of the resultant wave frequency with the TAE [[operating temperature]]
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| ===Travelling-wave systems===
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| Figure 3 is a schematic drawing of a travelling-wave thermoacoustic engine. It consists of a resonator tube and a loop which contains a regenerator, three heat exchangers, and a bypass loop. A regenerator is a porous medium with a high heat capacity. As the gas flows back and forth through the regenerator it periodically stores and takes up heat from the regenerator material. In contrast to the stack, the pores in the regenerator are much smaller than the thermal penetration depth, so the thermal contact between gas and material is very good. Ideally the energy flow in the regenerator is zero, so the main energy flow in the loop is from the hot heat exchanger via the pulse tube and the bypass loop to the heat exchanger at the other side of the regenerator (main heat exchanger). The energy in the loop is transported via a travelling wave as in Fig. 1c, hence the name travelling-wave systems. The ratio of the volume flows at the ends of the regenerator is ''T''<sub>H</sub>/''T''<sub>a</sub>, so the regenerator acts as a volume-flow amplifier.
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| Just like in the case of the standing-wave system the machine “spontaneously” produces sound if the temperature ''T''<sub>H</sub> is high enough. The resulting pressure oscillations can be used in a variety of ways such as in producing electricity, cooling, and heat pumping.
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| ==See also==
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| *[[Cryocooler]]
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| *[[Rijke tube]]
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| *[[Photoacoustic effect]]
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| ==References==
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| {{reflist}}[http://www.coolsound.us/technology.html The Technology] Cool Sound Industries, Inc.
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| ==External links==
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| *[http://www.lanl.gov/thermoacoustics/ Thermoacoustic research at Los Alamos National Laboratory]
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| *[http://www.scribd.com/doc/147785416/Experimental-Investigations-on-a-Standing-Wave-Thermoacoustic-Engine M. Emam, Experimental Investigations on a Standing-Wave Thermoacoustic Engine, M.Sc. Thesis, Cairo University, Egypt (2013)]
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| *[http://alexandria.tue.nl/extra2/200112997.pdf M.E.H. Tijani, Loudspeaker-driven thermo-acoustic refrigeration, Ph.D. Thesis, Technische Universiteit Eindhoven, (2001)]
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| *[http://www.lanl.gov/thermoacoustics/DeltaEC.html Design Environment for Low-amplitude ThermoAcoustic Energy Conversion]
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| *[http://www.coolsound.us/technology.html The Technology] Cool Sound Industries, Inc.
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| [[Category:Acoustics]]
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| [[fr:Thermoacoustique]]
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| [[nl:Thermo-akoestiek]]
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| [[pt:Refrigeração termoacústica]]
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| [[th:อุณหสวนศาสตร์]]
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