Alpha-stream convertor

Abstract

A thermo-acoustic engine and/or cooler is provided and includes an elongated tubular body, multiple regenerators disposed within the body, multiple heat exchangers disposed within the body, where at least one heat exchanger is disposed adjacent to each of the multiple regenerators, multiple transducers axially disposed at each end of the body, and an acoustic wave source generating acoustic waves. At least one of the acoustic waves is amplified by one of the regenerators and at least another acoustic wave is amplified by a second one of regenerators.

Claims

1. A method of operating a thermo-acoustic engine comprising: establishing a first temperature gradient in a first regenerator and a second temperature gradient in a second regenerator; creating a first acoustic wave in the first regenerator that propagates along a propagation path; creating a second acoustic wave in the second regenerator that propagates along the propagation path, wherein there are no electrical acoustical signal generators disposed along the propagation path between the first and second regenerators; superimposing the first acoustic wave and the second acoustic wave to form a combined acoustic wave having an amplitude higher than the first and second acoustic waves; converting the combined acoustic wave to an electrical signal; and outputting a portion of the electrical signal to drive a first transducer.

2. The method of claim 1 further comprising outputting another portion of the electrical signal to a device external to the thermo-acoustic engine.

3. The method of claim 2 further comprising tuning the portion of the electrical signal to a resonant frequency.

4. The method of claim 1, wherein the first temperature gradient and the second temperature gradient are established by a plurality of heat exchangers.

5. The method of claim 4, wherein the plurality of heat exchangers includes a first heat exchanger disposed adjacent to a side of the first regenerator, a second heat exchanger disposed adjacent to an opposite side of the first regenerator and adjacent to a side of the second regenerator, and a third heat exchanger disposed adjacent to an opposite side of the second regenerator, and wherein the first heat exchanger heats or cools the side of the first regenerator to a temperature greater than a temperature that the second heat exchanger heats or cools the opposite side of the first regenerator and the second heat exchanger heats or cools the side of the second regenerator to a temperature greater than a temperature that the third heat exchanger heats or cools the opposite side of the second regenerator.

6. The method of claim 4, wherein the plurality of heat exchangers includes a first heat exchanger disposed adjacent to a side of the first regenerator, a second heat exchanger disposed adjacent to an opposite side of the first regenerator and adjacent to a side of the second regenerator, and a third heat exchanger disposed adjacent to an opposite side of the second regenerator, and wherein the first heat exchanger and the third heat exchanger are hot heat exchangers and the second heat exchanger is a cold heat exchanger.

7. The method of claim 1, further comprising, prior to outputting the portion of the electrical signal to drive the first transducer, applying a phase delay to the portion of the electrical signal.

8. The method of claim 7, further comprising, prior to outputting the portion of the electrical signal to drive the first transducer, combining the portion of the electrical signal with the phase delay with an incoming electrical signal to generate a combined electrical signal.

9. The method of claim 8, further comprising feeding the combined electrical signal to the first transducer.

10. The method of claim 9, wherein the conversion of the combined acoustic wave to the electrical signal is performed via a second transducer.

11. The method of claim 1, wherein the first and second regenerators are each disposed within a body having a central axis, wherein the first and second regenerators are disposed on the central axis at different points along the central axis such that the first and second acoustic waves are at different axial locations within the body.

12. The method of claim 11, wherein the combined acoustic wave is a standing wave within the body.

13. The method of claim 11, wherein the first transducer is disposed proximate to an end of the body.

14. The method of claim 13, wherein, in the first temperature gradient, a temperature in the first generator increases with proximity to the end of body, wherein, in the second temperature gradient, a temperature in the second generator increases with proximity to the end of the body.

15. The method of claim 13, wherein, in the first temperature gradient, a temperature in the first generator decreases with proximity to the end of body, wherein, in the second temperature gradient, a temperature in the second generator decreases with proximity to the end of the body.

16. The method of claim 13, wherein, in the first temperature gradient, a temperature in the first generator increases with proximity to the end of body, wherein, in the second temperature gradient, a temperature in the second generator decreases with proximity to the end of the body.

17. The method of claim 13, wherein, in the first temperature gradient, a temperature in the first generator decreases with proximity to the end of body, wherein, in the second temperature gradient, a temperature in the second generator increases with proximity to the end of the body.

18. The method of claim 5, wherein the first regenerator directly contacts the first and second heat exchangers.

19. The method of claim 18, wherein the second regenerator directly contacts the second and third heat exchangers such that the first heat exchanger, the first regenerator, the second heat exchanger, the second regenerator, and the third heat exchanger form a continuous body.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1A is a perspective illustration of an alpha-STREAM or thermo-acoustic device that can operate as an engine or a cooler (refrigerator) in accordance with aspects of the innovation.

(2) FIG. 1B is a close-up perspective view of one end of the device of FIG. 1 that contains an impedance matching aerogel in accordance with an aspect of the innovation.

(3) FIG. 2 is a schematic illustration of an example embodiment of a thermo-acoustic device that operates as an engine in accordance with aspects of the innovation.

(4) FIG. 3 is an example flow chart illustrating a method of operating the thermo-acoustic device of FIG. 2 in accordance with an aspect of the innovation.

(5) FIG. 4 is a graphical representation of two opposing traveling acoustic waves forming a higher amplitude acoustic wave in accordance with an aspect of the innovation.

(6) FIG. 5 is another schematic illustration of another example embodiment thermo-acoustic device that operates as an engine in accordance with aspects of the innovation.

(7) FIG. 6 is another schematic illustration of another example embodiment of a thermo-acoustic device that operates as an engine in accordance with aspects of the innovation.

(8) FIGS. 7-13 are schematic illustrations of example embodiments of a thermo-acoustic device that operates as a cooler in accordance with an aspect of the innovation.

DETAILED DESCRIPTION

(9) The innovation is now described with reference to the drawings, wherein like reference numerals are used to refer to like elements throughout. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the subject innovation. It may be evident, however, that the innovation can be practiced without these specific details. In other instances, well-known structures and devices are shown in block diagram form in order to facilitate describing the innovation.

(10) While specific characteristics are described herein (e.g., thickness), it is to be understood that the features, functions and benefits of the innovation can employ characteristics that vary from those described herein. These alternatives are to be included within the scope of the innovation and claims appended hereto.

(11) While, for purposes of simplicity of explanation, the one or more methodologies shown herein, e.g., in the form of a flow chart, are shown and described as a series of acts, it is to be understood and appreciated that the subject innovation is not limited by the order of acts, as some acts may, in accordance with the innovation, occur in a different order and/or concurrently with other acts from that shown and described herein. For example, those skilled in the art will understand and appreciate that a methodology could alternatively be represented as a series of interrelated states or events, such as in a state diagram. Moreover, not all illustrated acts may be required to implement a methodology in accordance with the innovation.

(12) Referring now to the figures, FIG. 1A is a perspective illustration of an alpha-STREAM or thermo-acoustic device 100 (hereinafter device) that incorporates a Stirling cycle and can operate as an engine or a cooler (refrigerator) in accordance with aspects of the innovation. Although, Stirling engines are known for their efficiency, they are expensive to manufacture and require moving parts, which compromises the reliability of the engine. The innovation disclosed herein utilizes the Stirling cycle to provide a low cost, highly reliable, highly efficient device that requires no moving parts. The innovation also eliminates streaming losses and through specialized acoustical wave tuning allows for wide manufacturing tolerances. Still yet another benefit is that the innovation is small in size due to combining the advantages of thermo-electro-acoustics and cascaded heat exchangers with multiple wave power generation. The innovation can be used in many applications, such as but not limited to, converting heat to electrical energy, refrigeration, etc.

(13) Still referring to FIG. 1A, the example device 100 includes an elongated tubular body 102, regenerators (or stacks) 104, heat exchangers (hot and cold) 106, transducers 108, and a tunable electrical circuit (electro-acoustic modulator) 110 that allows modulated acoustical waves to travel with periodicity from one end of the buffer tube 102 to an opposite end (or vice versa) of the buffer tube 102. The acoustical waves are converted to electrical signals and modulated appropriately while providing both external electrical energy and returning the modulated signal back to the diametrically opposing transducer. Multiple acoustic pressure waves are generated from the multiple heat exchanger/regenerator pairs. The acoustic pressure waves are phased and oriented such that they superposition either a standing or traveling wave of higher amplitude than is possible in conventional single wave engines.

(14) A portion of the electrical energy signal is used to drive the opposing transducer with the incident acoustical wave such that the acoustical wave propagates on the side opposite as though it traversed a toroidal wave guide of proper length and phasing. This allows long wavelength signals to be carried in a short device. One key difference with the innovation disclosed herein is that the waves can travel in both directions and at any frequency without adjusting the physical length of the device. In addition, the performance of the device can be tuned electrically to maximize wave amplification at regions of interest.

(15) The acoustical signals are converted into their electrical voltage analog and can be both phase and impedance adjusted to compensate for any transducer used. Multiple cascaded regenerators/stacks can serve to further amplify the acoustical signal and to increase the effective heat transfer area without increasing pressure vessel diameter. This technology can be operated in its thermodynamically reversed cycle as a cooler. Moreover, this device can be directly combined with a cooler either pneumatically, mechanically, or electrically to provide both power and cooling from the same device with no moving parts and small diameter.

(16) Referring to FIG. 1B, one end of the device 100 includes an impedance layer support 112 with a protective diaphragm 114 to protect the impedance layer. Specifically, the impedance layer support 112 includes an aerogel that impedance matches a gas, such as but not limited to helium, inside the buffer tube 102 to a coil wrapped magnetostrictive stack 116, which includes permanent magnets 118.

(17) FIGS. 2, 5, and 6 are example embodiments where the device acts as an engine. Specifically, FIG. 2 schematically illustrates one example embodiment of a device (engine) 200 having a standing or traveling wave configuration in accordance with aspects of the innovation. The device 200 includes an elongated tubular body 202, regenerators 204, heat exchangers 206, transducers 208, a phase delay circuit (), and impedance circuits Z.sub.1-Z.sub.4.

(18) The body 202 may be constructed from material that is generally thermally and acoustically insulative and capable of withstanding pressurization up to several atmospheres. For example, the body may be constructed from a metal, such as but not limited to, stainless steel or iron-nickel-chromium alloy.

(19) As shown in FIG. 2, the regenerators 204 are disposed within the body 202 and include a first regenerator 204A and a second regenerator 204B. As will become evident from other example embodiments described further below, it is to be appreciated, that the number of regenerators 204 may vary depending on the application. Thus, the example embodiment shown in FIG. 2 is for illustrative purposes only and is not intended to limit the scope of the innovation. The regenerators 204 may be structured having a relatively high thermal mass but low acoustic attenuation. For example, the regenerators 204 may be constructed of a material having a structure, such as but not limited to, a wire mesh, random fiber mesh, open cell, etc. Further, the density of the material may be constant throughout the regenerator 204 or may vary for optimum efficiency.

(20) The heat exchangers 206 are also disposed within the body 202 adjacent on each side of each regenerator 204. Thus, in the example illustrated in FIG. 2, the heat exchangers 206 include a first heat exchanger 206A, second heat exchanger 206B, and a third heat exchanger 206C. As will become evident from other example embodiments described further below, it is to be appreciated, that the number of heat exchangers 206 may vary depending on the application. The additional heat exchangers allow for more heat energy to enter without increasing the diameter of the device. This reduces hoop stresses and allows for high pressure operation.

(21) As shown in FIG. 2, the regenerators 204 and heat exchangers 206 are disposed in the body 202 in a cascade arrangement. As mentioned above, the cascade arrangement of the regenerators 204 and heat exchangers 206 facilitate amplification of the acoustic wave and increases heat transfer without increasing the diameter of the body 202. Further, although, FIG. 2 illustrates the regenerators 204 and the heat exchangers 206 centrally located in an axial direction within the body 202, the regenerators 204 and heat exchangers 206 may be disposed at different axial locations to tailor the acoustical wave for maximum effect through the modulation of the acoustical waves.

(22) In the example embodiment shown in FIG. 2, the transducers 208 include a first transducer 208A and a second transducer 208B. As the acoustic wave travels through the device 200, the second transducer 208B converts the acoustic wave into an electrical signal. The electrical signal travels into and out of impedance circuit Z.sub.2 to a splitter 212. The splitter 212 splits the electrical signal and outputs a portion of the electrical signal, via output O.sub.1 to a device external to the device 200. Another portion of the electrical signal is output, via output O.sub.2, to impedance circuit Z.sub.3. The electrical signal is output from impedance circuit Z.sub.3 to the phase delay circuit (), which provides the desired phasing to the electrical signal. The electrical signal is output from the phase delay circuit () to impedance circuit Z.sub.4. The electrical signal is output from impedance circuit Z.sub.4 and input, via I.sub.1, to a combiner 214, where it is combined with an incoming signal via I.sub.2. The combined signal is fed to impedance circuit Z.sub.1 where it is ultimately fed to the first transducer 208A to thereby drive the first transducer 208A.

(23) Referring to FIG. 3, with reference to FIG. 2, the operation of the device 200 will now be described. At 302, temperature gradients are established within the body 202. Specifically, the first, second, and third heat exchangers 206A, 206B, 206C provide a temperature T.sub.1, T.sub.2, and T.sub.3 within the tube respectively, where T.sub.1>T.sub.2>T.sub.3 or vice versa. Thus, a decreasing (or increasing) temperature gradient is established from T.sub.1 to T.sub.3. In another embodiment, both the first and third heat exchangers 206A, 206C can be established as hot (or cold) heat exchangers and the second heat exchanger 206B can be established as a cold (or hot) heat exchanger. Thus, a decreasing (or increasing) temperature gradient would be established from T.sub.1 to T.sub.2 and from T.sub.3 to T.sub.2. As a result, a first temperature gradient is established in the first regenerator 204A and a second temperature gradient is established in the second regenerator 204B.

(24) Continuing with the operation of the device 200, at 304, both the established first and second temperature gradients creates a first acoustic pressure wave in the first regenerator 204A and a second acoustic wave in the second regenerator 204B respectively. At 306, the first and second acoustic waves are superimposed to form a higher amplitude acoustic wave. At 308, the higher amplitude acoustic wave is converted into an electrical signal. At 310, a portion of the electrical signal is output to a device external to the device 200. At 312, another portion of the electrical signal is fed back into the device 200 and is used to drive the first transducer. At 314, the electrical signal, as it travels through the impedance circuits Z.sub.1-Z.sub.4, is tuned to a resonant frequency.

(25) Generating multiple acoustical waves traveling in the same direction in varying axial locations within the body 202 enables several benefits through wave superposition. Wave superposition produces a single amplified wave (traveling in this embodiment) having a greater amplitude than is possible with a single acoustic wave source. Further, phasing and frequency of the combined wave may be controlled to cause maximum pressure anti-nodes at one or more places. Utilizing multiple regenerators to create acoustic waves enables a high amplitude traveling wave or standing wave operation, with gains in efficiency and stability over devices with a single acoustic source that produce only

(26) Alternatively, multiple regenerators and heat exchangers may be oriented such that the generated acoustic waves travel in opposed directions. For example, referring to FIG. 4, two right traveling waves 402 and two left traveling waves 404 each having an amplitude of one combine to form a standing wave having an amplitude of four 406. As mentioned above, wave superposition produces a single amplified wave having an amplitude greater than is possible with a single acoustic wave source.

(27) FIG. 5 is a schematic illustration of another example embodiment of a thermo-acoustic device (engine) 500 in accordance with an aspect of the innovation. The device 500 is an example standing wave configuration. The device 500 is similar to the device described above and illustrated in FIG. 2, thus, like elements will not be repeated. As in the device 200 described above, the device 500 includes a body 502, multiple regenerators 504, multiple heat exchangers 506, multiple transducers. In this embodiment, however, the regenerators 504 and heat exchangers 506 are disposed axially apart at opposite ends of the body 502. This arrangement facilitates the entering heat load to be distributed, which allows for a more compact, smaller diameter design since increased surface heat transfer area occurs axially rather than circumferentially.

(28) In addition, the multiple transducers include multiple (i.e., two) axial signal transducers 508 disposed at each axial end of the body 502 as above, and multiple (i.e., two) vertical power transducers 510 disposed in the axial center of the body 502. One benefit to the axial signal transducers 508 is that the axial signal transducer circuit is simpler as it carries only the periodic signal. The vertical power transducers 510 extract power from the device 500.

(29) FIG. 6 is a schematic illustration of another example embodiment of a thermo-acoustic device (engine) 600 in accordance with an aspect of the innovation. Again, like elements in the device 600 in this embodiment to those above will not be repeated. The device 600 includes a body 602, multiple regenerators 604, multiple heat exchangers 606, multiple axial signal transducers 608, and two sets of multiple vertical power transducers 610A, 610B. In this embodiment, each set of the vertical power transducers 610A, 610B are disposed at axially opposite ends of the body 602. Each transducer has a preferred impedance, operating frequency, and displacement amplitude for optimal operation and by adding more transducers the ideal operating conditions may be achieved. This enables higher frequency operation and more flexibility with vibration control. For example, multiple transducers may be used at the same pressure node in order to achieve the required volume change necessary for acoustic resonance and stability. Some transducer types have limited displacements, and would not otherwise be viable. This increases efficiency and allows for a more compact design. An additional benefit of using multiple transducers is enhanced reliability since the system may still operate in limited capacity after failure of one or more transducers.

(30) The resonant frequency of the device and the frequency of the output can be controlled electronically and is not limited solely by the physical length of the device body. The ability to choose the locations of maximum pressure amplitude through the generation of multiple acoustical waves enables the use of varied transducer materials and designs at varying locations. This flexibility combined with a tunable electro-acoustic circuit enables the use of many kinds of transducers including traditional linear alternator, piezo-electric, electro-active polymers, and magneto-restrictive materials.

(31) The ability to eliminate the traditional toroidal path and to convert the wave into an electrical signal allows for significant advantages. First, only the acoustical wave will travel around the loop and this eliminates the need for a jet pump and eliminates Gedeon streaming losses. Second, the ability to convert the acoustic wave into an electrical signal enables modulation of the wave using electrical components instead of physical components as is currently required. Specifically, the thermal buffer, compliance, and inertance tubes are no longer required resulting in a smaller and more efficient device. Third, the entire device now has no moving parts and the frequency of the device can be significantly increased to produce a higher efficiency device than current Stirling engines. Fourth, since the wave is now electronically tunable, manufacturing deficiencies can be tuned out and fabrication costs are significantly reduced. Fifth, the flow will only travel in a straight line through the heat exchangers reducing pressure drop while increasing overall engine efficiency. Finally, the device has a simple design that simply looks like a pipe that contains only heat exchangers. Thus, all of the complex physical components normally required for heat engines are eliminated by modulating the acoustical waves through electrical transduction and tuning.

(32) FIGS. 7-13 are additional example embodiments where the alpha-STREAM concept operates in a reverse cycle and, thus, can be applied to act as a cooler (i.e., provide refrigeration). Specifically, FIG. 7, schematically illustrates one example embodiment of a device (cooler) 700 that includes an elongated tubular body 702, regenerators 704, heat exchangers 706, transducers 708, a phase delay circuit (), and impedance circuits Z.sub.1-Z.sub.3. The arrangement and operation of elements that are similar to the device described above and will not be repeated.

(33) In the example illustrated in FIG. 7, the acoustic waves are produced by one or more of the plurality of transducers 708. The transducers can be linear alternators, piezoelectric, or magnetostrictive. The high amplitude acoustic waves, due to wave superposition described above, travel through the regenerators 704 and heat exchangers 706 in such a way as to lift heat to thereby provide cooling to an external system. The other manifestations of the design are simply the device being operated in reverse with electrical power being used to create the sound waves that travel through the heat exchangers and regenerators. As above, by using multiple waves it is possible to cascade the heat exchangers for additional heat transfer area while maintaining a smaller diameter device. In addition, the construction of the cooler does not include moving parts while still maintaining high efficiency.

(34) FIGS. 8 and 9 are other example embodiments of a device (cooler) 800, 900 that include multiple source/converters and multiple acoustic wave generators.

(35) FIGS. 10 and 11 are other example embodiments of a combination device (engine/refrigerator duplex) 1000, 1100 that includes multiple sources/convertors and multiple acoustic wave generators.

(36) FIGS. 12 and 13 are other embodiments of an electrically combined engine/refrigerator and a mechanically combined engine/refrigerator respectively that includes multiple sources/convertors and multiple acoustic wave generators.

(37) Key benefits to the example embodiments illustrated in FIGS. 7-13 are that all wave phasing and impedance are modulated with electronic components and not mechanical components. This eliminates the jet pump, compliance tube, thermal buffer tube, and inertance tube. In addition, multiple waves can be employed that superimpose constructively to multiply performance while maintaining a narrow tube.

(38) What has been described above includes examples of the innovation. It is, of course, not possible to describe every conceivable combination of components or methodologies for purposes of describing the subject innovation, but one of ordinary skill in the art may recognize that many further combinations and permutations of the innovation are possible. Accordingly, the innovation is intended to embrace all such alterations, modifications and variations that fall within the spirit and scope of the appended claims. Furthermore, to the extent that the term includes is used in either the detailed description or the claims, such term is intended to be inclusive in a manner similar to the term comprising as comprising is interpreted when employed as a transitional word in a claim.