thermoacoustic refrigeration full report



Conventional Refrigeration And Its Drawback
Thermoacoustic Refrigerator
Unpressurised System
Air as Gas Medium
Loudspeaker as Acoustic Driver


Uses sound to create cooling
No moving parts inside device
Tremendous Opportunities
Saves energy
Economic potential
Good for the environment


Heat Powered TAR
beer cooler
Electrically powered TAR
spacecraft applications
Cooling of computer chips


Thermoacoustic effects occur in everyday life are too small

low cost is more important than efficiency

Considerable study requires to reach acoustic devices to their full potential

Thermo acoustic have been known for over years but the use of this phenomenon to develop engines and pumps is fairly recent. Thermo acoustic refrigeration is one such phenomenon that uses high intensity sound waves in a pressurized gas tube to pump heat from one place to other to produce refrigeration effect. In this type of refrigeration all sorts of conventional refrigerants are eliminated and sound waves take their place. All we need is a loud speaker and an acoustically insulated tube. Also this system completely eliminates the need for lubricants and results in 40% less energy consumption. Thermo acoustic heat engines have the advantage of operating with inert gases and with little or no moving parts, making them highly efficient ideal candidate for environmentally-safe refrigeration with almost zero maintenance cost. Now we will look into a thermo acoustic refrigerator, its principle and functions.
Over the past two decades, physicists and engineers have been working on a class of heat engines and compression-driven refrigerators that use no oscillating pistons, oil seals or lubricants. These so called thermo acoustic devices take advantage of sound waves reverberating within them to convert a temperature differential into mechanical energy or mechanical energy into a temperature differential. Such materials thus can be used, for example, to generate electricity or to provide refrigeration and air conditioning. Because thermo acoustic devices perform best with inert gases as the working fluid, they do not produce the harmful environmental effects such as global warming or stratospheric ozone depletion that have been associated with the engineered refrigerants such as CFCs and HFCs. Recent advances have boosted efficiencies to levels that rival what can be obtained from internal combustion engines, suggesting that commercial thermo acoustic devices may soon be a common place.
The entire features mentioned above is possible only because sound waves in thermo acoustic engines and refrigerators can replace the piston and cranks that are typically built into any machinery. These thermo acoustic devices produce or absorb sound power, rather than the shaft power characteristic of rotating machinery making it mechanically simple.
In a nut shell, a thermo acoustic engine converts heat from a high-temperature source into acoustic power while rejecting waste heat to a low temperature sink. A thermo acoustic refrigerator does the opposite, using acoustic power to pump heat from a cool source to a hot sink. These devices perform best when they employ noble gases as their thermodynamic working fluids. Unlike the chemicals used in refrigeration over the years, such gases are both nontoxic and environmentally benign. Another appealing feature of thermo acoustics is that one can easily flange an engine onto a refrigerator, creating a heat powered cooler with no moving parts at all.
The principle can be imagined as a loud speaker creating high amplitude sound waves that can compress refrigerant allowing heat absorption. The researches have exploited the fact that sound waves travel by compressing and expanding the gas they are generated in.
Suppose that the above said wave is traveling through a tube. Now, a temperature gradient can be generated by putting a stack of plates in the right place in the tube, in which sound waves are bouncing around. Some plates in the stack will get hotter while the others get colder. All it takes to make a refrigerator out of this is to attach heat exchangers to the end of these stacks.
It is interesting to note that humans feel pain when they hear sound above 120 decibels, while in this system sound may reach amplitudes of 173 decibels. But even if the fridge is to crack open, the sound will not be escaping to outside environment, since this intense noise can only be generated inside the pressurized gas locked inside the cooling system. It is worth noting that, prototypes of the technology has been built and one has even flown inside a space shuttle.
Acoustic or sound waves can be utilized to produce cooling. The pressure variations in the acoustic wave are accompanied by temperature variations due to compressions and expansions of the gas. For a single medium, the average temperature at a certain location does not change. When a second medium is present in the form of a solid wall, heat is exchanged with the wall. An expanded gas parcel will take heat from the wall, while a compressed parcel will reject heat to the wall.
As expansion and compression in an acoustic wave are inherently associated with a displacement, a net transport of heat results. To fix the direction of heat flow, a standing wave pattern is generated in an acoustic resonator. The reverse effect also exists: when a large enough temperature gradient is imposed to the wall, net heat is absorbed and an acoustic wave is generated, so that heat is converted to work.
The principle may find applications in practical refrigerators, providing cooling, heat engines providing heat or power generators providing work. A great advantage of the technique is that there are no or only one moving part, in the cold area, which results in high reliability and low vibration levels. Also the use of inert gases make them environmentally safe and hence more in demand.
Thermo acoustic refrigerators now under development use sound waves strong enough to make your hair catch fire, says inventor Steven L Garrett. But this noise is safely contained in a pressurized tube. If the tube gets shattered, the noise would instantly dissipate to harmless levels. Because it conducts heat, such intense acoustic power is a clean, dependable replacement for cooling systems that use ozone destroying chlorofluorocarbons (CFCs). Now a scientist Hofler is also developing super cold cryocoolers capable of temperatures as low as -135°F (180°K). he hopes to achieve -243°F (120°K) because such cryogenic temperatures would keep electronic components cool in space or speed the function of new microprocessors.
The interaction between heat and sound has been underestimated even by Sir Isaac Newton. This became clear, when Laplace corrected Newtonâ„¢s earlier calculation of the speed of sound in air. Newton had assumed the expansions and compressions of a sound wave in a gas happen without affecting the temperature. Laplace accounted for slight variations in temperature that in fact take place, and by doing so he derived the correct speed of sound in air, a value that is 18% faster than Newtonâ„¢s estimate.
A thermo acoustic refrigerator functions as follows. First, customized loudspeakers are attached to cylindrical chambers filled with inert, pressurized gases such as xenon and helium. At the opposite end of the tubes are tightly wound "jelly rolls" made of plastic film glued to ordinary fishing line. When the loudspeakers blast sound at 180 decibels, an acoustic wave resonates in the chambers. As gas molecules begin dancing frantically in response to the sound, they are compressed and heated, with temperatures reaching a peak at the thickest point of the acoustic wave. That's where the super hot gas molecules crash into the plastic rolls. After transferring their heat to the stack, the sound wave causes the molecules to expand and cool. "Each one of these oscillating molecules acts as a member of a 'bucket brigade,' carrying heat toward the source of the sound," says Garrett. Cold temperatures can then be tapped for chilling refrigerators, bedrooms, cars, or electronic
components on satellites and inside computers, according to Garrett. Someday, he says, turning up the air-conditioner could be accomplished by adjusting a volume-control knob.
Fig 1 Functioning of a TA Refrigerator
The Space Thermo Acoustic Refrigerator was the first electrically-driven thermo acoustic chiller designed to operate autonomously outside a laboratory. It was launched on the Space Shuttle Discovery (STS-42) on January 22, 1992. The design was an extension of the first thermo acoustic refrigerator built at Los Alamos National Laboratory as the Ph.D. thesis project of Thomas J. Hofler. Dr. Hofler is currently a member of the physics faculty at the Naval Postgraduate School in Monterey, CA.

Fig 2 A Space Thermo Acoustic Refrigerator
The refrigerator is driven by a modified compression driver that is coupled to a quarter-wavelength resonator using a single-convolution electroformed metal bellow. The resonator contains the heat exchangers and the stack. The stack is 3.8 cm in diameter and 7.9 cm in length. It was constructed by rolling up polyester film (Mylar„¢) using fishing line as spaces placed every 5 mm. The device was filled with a 97.2% Helium and 2.7% Xenon gas mixture at a pressure of 10.
The major parts of a thermo acoustic refrigerator are loud speakers and resonators. Pictorical representations of both are given below.
In contrast, inside conventional refrigerators and air conditioners, CFC gas is compressed and heated by an electrically driven pump, then cooled and condensed by a heat exchanger in a process known as a "Rankine cycle." When the liquefied gas is depressurized, it evaporates and drops to a much cooler temperature. Moving through the freezer coils of a food compartment, the cold fluid picks up heat, starting the cycle all over again.
Before World War II, ammonia and sulfur dioxide were commonly used in refrigerators, explains Gregory W. Swift, a thermo acoustics expert at Los Alamos National Laboratory in New Mexico. But these substances were soon replaced with CFCs, which are noncorrosive, nonflammable, and relatively nontoxic, Swift says. Unfortunately, he adds, CFCs leak from cooling systems, destroying the atmospheric ozone that protects the earth's surface from ultraviolet radiation. Damage to the ozone shield may result in adverse human health effects including cancers, cataracts, immune system deficits, and respiratory effects, as well as diminish food supplies and promote increases in vector borne diseases.

Fig 3 Graphs of temperature ratio and coefficient of performance against heat load
In a thermo acoustic refrigerator there are two major factors for heat transfer. They are mentioned below:
1. Temp gradient(T/x)
The temperature gradient is measured as

T/x = P / Cp
Where p is the acoustic pressure,
is the displacement amplitude,
is the density and Cp is the specific heat/unit mass.
2. Thermal penetration length ( )
The thermal penetration length is the distance heat can diffuse through a gas in a time t seconds.
= k t / Cp.
Where k is the thermal conductivity, is the density and Cp is the specific heat/unit mass.
Depending on the thermal penetration depth the distance between the stack plates is varied. If the distance is very large heat transfer will be minimum or if the distance is too small the gas will be unable to pass through the stack plates and moreover transfer of heat to plates will be difficult. So the stack of plates should be kept at proper distances apart. Moreover the acoustic pressure determines the temperature gradient setup. So a resonator is a must in a thermo acoustic refrigerator.
Even though thermo acoustic devices uses low cost components and require only one moving part, making them inexpensive and maintenance free systems they have certain challenges before them. But with time researches must overcome them.
One of the main challenges faced is regarding the efficiency. The efficiency of thermo acoustic refrigerators and engines is very low. Thermo acoustic refrigerators gives only one-fourth the efficiency compared to conventional refrigerators. The coefficient of performance of the most advanced thermo acoustic refrigerator is only around 1 compared to 3 to 4 of conventional refrigerators.
Since, they use electricity to drive a pump that moves working gas, conventional refrigerants represent 6% of the nationâ„¢s annual electricity consumption. Similarly, the loud speakers inside a thermo acoustic refrigerator also must be activated by electric power. The best thermo acoustic coolers built thus far use twice as much electricity as conventional refrigerants. Though much greater efficiency is theoretically possible, the claim that the thermo acoustic refrigerators will ever catch up with traditional Rankine cycle designs is in doubt.
Complex physical factors such as the friction generated by gas molecules churning back and forth inside a chamber place fundamental limits on the efficiency of thermo acoustic refrigerators. Losses also occur because of acoustic distortions generated at levels above 155 decibels.
Another major problem is that a thermo acoustic refrigerator is either fully on or off. That is it gets too cold when thermostat is turned on and too hot when it is off.
In order to improve the efficiency, regenerators are used. The function of a regenerator is to store thermal energy during part of the cycle and return it later. This component can increase the thermodynamic efficiency to impressive levels, but its mechanical complexity is greater. In a regenerator used some thermal energy was converted to acoustic energy, though not enough to make up for the accompanying losses.
The extra stress given in using standing waves also paved to be fruitful. Amplification became much easier while using standing waves. This increased the level of temperature gradient setup thereby providing more refrigeration effect.
An increased voltage and reduced current gave better performances than usual. Moreover intense working is going on in developing sound by piezoelectric effect which would considerably reduce electricity hazards.
With these workings it was found that the efficiency of the engine improved markedly. At best it ran at 42% of the maximum theoretical efficiency, which is about 40% better than earlier thermo acoustic devices had achieved and rivals what modern engines have.
Although the working principle of thermo acoustic technology is quite complex, the practical implementation is relatively simple. This offers great advantages with respect to the economic feasibility of this technology. Other advantages are
1. No moving parts for the process, so very reliable and a long life span.
2. Environmentally friendly working medium (air, noble gas)
3. The use of air or noble gas as working medium offers a large window of applications because there are no phase transitions.
4. Use of simple materials with no special requirements, which are commercially available in large quantities and therefore relatively cheap.
5. On the same technology base a large variety of applications can be covered.
Out of these, the two distinct advantages of thermo acoustic refrigeration are that the harmful refrigerant gases are removed. The second advantage is that the number of moving parts is decreased dramatically by removing the compressor. It also has fewer moving parts than its competitors, and so is less likely to break down.
Also sonic compression or Ëœsound wave refrigerationâ„¢ uses sound to compress refrigerants which replace the traditional compressor and need for lubricants. The technology could represent a major breakthrough using a variety of refrigerants, and save up to 40% in energy. The system is also an energy saving drop in current compressors, and projected mass production cost is very low.
The planned system uses sound waves to compress inert Helium gas and extract heat. The system is potentially much more energy efficient in all applications, as well as non-ozone depleting and having no global warming potential.
Thermo acoustic refrigeration works best with inert gases such as helium and argon, which are harmless, non flammable, non toxic, non ozone depleting or global warming and is judged inexpensive to manufacture.
Speaking of its practical applicability, prototype of thermo acoustic refrigerators have operated on the Space Shuttle and abroad a Navy warship. And a powerful thermo acoustic engine has recently demonstrated its ability to liquefy natural gas on a commercial scale.
In practice there is a large variety of applications possible for both thermo acoustic engines and refrigerators and combination of these. Below, some concrete examples are given of possible applications:
a. Liquefaction of natural gas:
Burning natural gas in a thermo acoustic engine generates acoustic energy. This acoustic energy is used in a thermo acoustic heat pump to liquefy natural gas.
b. Chip cooling:
In this case a piezoelectric element generates the sound wave. A thermo acoustic heat pump cools the chip.
c. Electronic equipment cooling on naval ships:
In this application, a speaker generates sound waves. Again a thermo acoustic pump is used to provide the cooling.
d. Electricity from sunlight:
Concentrated thermal solar energy generates an acoustic wave in a heated thermo acoustic engine. A linear motor generates electricity from this.
e. Cogeneration (combined heat and power):
A burner heats a thermo acoustic engine, therewith generating acoustic energy. A linear motor converts this energy to electricity. Waste heat of burner (flue gases) can be used to supply heat.
f. Upgrading industrial waste heat:
Acoustic energy is created by means of industrial waste heat in a thermo acoustic engine. In a thermo acoustic heat pump this acoustic energy is used to upgrade the same waste heat to a useful temperature level.
Though it probably wonâ„¢t be useful for car air conditioning systems any time soon since they are too bulky and heavy, it may prove useful for niche applications, such as cooling satellite sensors or super fast computers. In addition to being useful on shipboard, this technology could be adapted for soft drink machines, medicine storage, computer chips and food transport companies.
Chilled water from the refrigerator circulated through racks of radar electronics on the USS Deyo, a Navy destroyer. Although we can improve the performance substantially with some modest changes, thermo acoustic refrigerators of this type will always have an intrinsic limit to their efficiency.
Thermo acoustic engines and refrigerators were already being considered a few years ago for specialized applications, where their simplicity, lack of lubrication and sliding seals, and their use of environmentally harmless working fluids were adequate compensation for their lower efficiencies. This latest breakthrough, coupled with other developments in the design of high power, single frequency loud speakers and reciprocating electric generators suggests that thermo acoustics may soon emerge as an environmentally attractive way to power hybrid electric vehicles, capture solar energy, refrigerate food, air condition buildings, liquefy industrial gases and serve in other capacities that are yet to be imagined.
In future let us hope these thermo acoustic devices which promise to improve everyoneâ„¢s standard of living while helping to protect the planet might soon take over other costly, less durable and polluting engines and pumps. The latest achievements of the former are certainly encouraging, but there are still much left to be done.

please read http://p2paysref/22/21165.pdf

The thermoacoustic heat pumping cycle is the youngest technology that will be presented at this workshop. Although the reverse process - the generation of sound by an imposed temperature gradient - had been observed for several centuries by glassblowersl~al nd for decades by cryogenic researchersP1; the recognition that useful amounts of heat could be pumped against a substantial temperature gradient with a coefficient-of-performance which is a significant fraction of the Camot limit was only made ten years agoU1, with the first demonstration, including efficiency measurements, being made in 1986141. This discovery was made even more significant by the recognition that the thermoacoustic heat pumping cycle was intrinsically irreversible. Traditional heat engine cycles, such as the Camot Cycle typically studied in elementary thermodynamics courses, assume that the individual steps in the cycle are reversible. In thermoacoustic engines, the irreversibility due to the imperfect (diffusive) thermal contact between the acoustically oscillating working fluid and a stationary second thermodynamic medium (the "stack") provides the required phasing. This "natural phasing"[41 has produced heat engines which require no moving parts other than the selfmaintained oscillations of the working fluid. During this relatively short period, several refrigerators and prime movers have been fabricated and tested at Los Alamos National Laboratories[3-5] and two refrigerators for spacecraft applications were built at the Naval Postgraduate School.

An Introduction to Thermoacoustic Refrigeration

Presented By:
Mark McCarty
School of Mechanical and Aerospace Engineering

I. Thermoacoustics
II. Thermodynamics of Cooling
III. Thermoacoustic Components
IV. Thermoacoustic Theory
V. Applications and Research
VI. Environmental Benefits
VII. Summary

A. Background
1. Uses sound to create cooling
2. No moving parts inside device
B. Tremendous Opportunities
1. Saves energy
2. Economic potential
3. Good for the environment

II. Thermodynamics of Cooling
A. Power Cycles versus Heat Pump Cycles
1. Power generation
2. Cooling
B. Energy balance equation
W l = Q t - Q
cycle ^ out ^ in

(a) Power cycle (b) Refrigeration and heat pump cycle
Figure 1. Thermodynamics (Adapted from Moran and Shapiro, 2000, p. 70)

A. Resonance Tube
1. Length related to sound
2. Fundamental frequency
L = n”, n = 1,2,3,... 2
where L is the length of the resonance tube n is the number of the harmonic ” is the wavelength

B. Regenerator Stack
1. Heart of thermoacoustic device
2. Ceramic material
a. Low thermal conductivity
b. Refrigeration

C. Acoustic Loudspeaker
1. Least efficient component
2. Gas spring system
- Improves efficiency
D. Heat Exchangers
- Least understood component
E. Working Gases
- Air versus noble gases

Hot Heat Exchanger
Regenerator Stack
Resonato r Tube

Working Gas (inside tube)

Cold Heat Exchanger
Figure 2. Simple thermoacoustic device (Adapted from Garrett and Backhaus, 2000, p. 517)

A. Acoustic Wave
1. Standing wave
2. Fundamental - Sinusoidal
B. Pressure
C. Temperature
1. Stack gradient
2. Heat exchange

A. Los Alamos National Laboratory
1. Energy industry
- Cryogenics
- Liquifaction of natural gas
2. Spacecraft power (deep space)

(IV. Applications and Research, continued)

B. Penn State University
1. Ben and Jerry's
2. Defense industry refrigeration

(, 2005)

(IV. Applications and Research, continued)
C. Interesting Patents
1. Production of potable water from humid air
2. Cooling dock for laptop computers
3. Baby formula/breast-milk cooler/warmer
4. Automatic ice maker
5. Acoustic cooling of automotive electronics
6. Energy recovery system

A. Reduce Greenhouse Gas Emissions
1. Carbon dioxide
2. Refrigerant gases
B. Lower Energy Consumption

A. Simple Device
1. No moving parts
2. Inexpensive to make
B. Applications in Many Areas
1. Food industry
2. Energy sector
3. Consumer products
C. Environmentally Friendly

please read
presented by:
Trevor Bourgeois
Mike Horne
Peter Smith
Erin MacNeil

ThermoAcoustic Refrigeration
Design Description

 Thermoacoustic Refrigerator
– Unpressurized System
– Air as Gas Medium
– Loudspeaker as Acoustic Driver
– Variable design (stacks)
 Advantages of Thermoacoustic Refrigeration
– No Environmentally-Harmful Refrigerants
– Mechanically Simple
Summary of Fall Term
 Work to understand Theory
 Development of Mathematical Model
 Construction of two Prototypes
– Standing wave created
– No DT
 Identification of Stack as most important component
Main Prototype Components
 Speaker
 Gas
 Tube
 Stack
 Heat Exchangers
 Considerations
– Power Capacity
– Frequency Response
 Choice
– 10 inch
– Operates At Low Frequencies (100 Hz)
– 400 W Maximum Power
Gas Medium
 Considerations
– Physical Properties
– Sealing
– Cost
 Choice
– Air
– Atmospheric Pressure
 Considerations
– Length
– Diameter
– Sound Reflection
– Low Acoustic Losses
– Sound Transmission
 Choice
– 1.5” PVC Tube
– Flat End
 Considerations
– Gap Size
– Material properties
– Material thickness
– Location
– Length
– Does not impede wave
 Choice
– Paper
– Aluminum Screen
Heat Exchangers
 Considerations
– Material
– Type
 Choice
– Aluminum
– Water Circulated
 Solid Porous Material
 Give And Takes Heat From Gas
 Heat Transfer
 DT Across
Design Considerations
 Gap Size
 Solid Thickness
 Position
 Length
 Ability Of Sound To Pass Through
 Physical Properties
Stack Designs
 Foil
 Paper
 Foam
 Lexan
 Screen
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i need a ful report along with ppt. kindly forward me.
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please send me details about this project, any document, pdf and ppt....
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