JP2017137852A - Heat exchange machine body - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat exchange machine body configured to perform power generation, cooling, heating and the like while performing heat exchange by a thermoacoustic machine body including a device operating with a thermoacoustic effect utilizing waste heat from a combustor, a power generator and the like.SOLUTION: A thermoacoustic machine body includes, in a body of a receptacle provided with intake means and discharge means and configured to store a medium generation source for heat exchange or be filled with a medium for heat exchange, a resonance tube storing one or more heat accumulators and filled with an actuation medium, and a device acting with a thermoacoustic effect at one end of the resonance tube, wherein the other end of the resonance tube penetrates so as to enable heat exchange at one end of the heat accumulator, and a part of the resonance tube is provided with heat insulation means so as to increase a temperature gradient of the heat accumulator.SELECTED DRAWING: Figure 1

Description

      The present invention relates to a technology for generating and cooling a heat exchanger body using a thermoacoustic effect by heat generated by a combustion device, a power generation device, and the like.

      There is an action of exchanging energy between heat and sound waves, which is called a thermoacoustic effect. In recent years, power generation and cooling technologies that make use of this effect have made significant progress.

JP2010-276216 JP2015-55438 PR

      Provided is a heat exchanger body that performs power generation, cooling, heating and the like while performing heat exchange with a thermoacoustic body provided with a device that operates by a thermoacoustic effect using exhaust heat such as a combustion device and a power generation device.

      A resonance tube filled with a working medium containing one or more heat accumulators in a main body of a container provided with intake means and discharge means and containing a heat exchange medium generation source or filled with a heat exchange medium, and the resonance A thermoacoustic machine body equipped with a device that works with a thermoacoustic effect at one end of the tube is provided so as to penetrate the other end of the resonance tube so that heat exchange is possible at one end of the heat accumulator, thereby increasing the temperature gradient of the heat accumulator. Thus, a heat exchanger body in which a part of the resonance tube is provided with a heat insulating means.

      As a heat exchange method, new exhaust heat utilization can be proposed by using a thermoacoustic machine body.

It is a figure which shows the structure of an example of the heat exchanger body concerning this Embodiment. It is a figure which shows the structure of an example of the heat exchanger body concerning this Embodiment. It is a figure which shows the structure of an example of the heat exchanger body concerning this Embodiment. It is a figure which shows the structure of an example of the heat exchange system concerning this Embodiment.

The heat exchanger body of the present invention includes a main body, a thermoacoustic body, and heat insulating means. The main body is filled with a heat exchange medium for producing a thermoacoustic effect, and the thermoacoustic body is a unit that includes a resonance tube, a heat accumulator, and a device that works with the thermoacoustic effect. Have the ability to work with. The resonance tube contains one or more heat accumulators, is filled with a working gas, has a function of amplifying the vibration of the working medium caused by the thermoacoustic effect, and communicates with a device that works by the thermoacoustic effect at one end. . The heat accumulator is provided with a large number of fine passages through which the working medium can flow in the axial direction, and a thermoacoustic effect is generated by providing temperature gradients at both ends. Devices that work with the thermoacoustic effect are power generators, cooling devices, and the like. The heat insulating means is appropriately applied to a part of the main body or the resonance tube in order to provide a temperature gradient at both ends of the heat accumulator.
Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
With reference to FIG. 1, the structure of the heat exchanger body 1 which concerns on 1st Embodiment is demonstrated. A heat exchanger body 1 having a heat exchange medium flow path provided with intake means 2 and discharge means 3 as a main body accommodates a heat accumulator 5 that heats one end and a heat accumulator 5 that acts on a cooling device 7, and a working medium. Of the resonance tube 4 so that one end of the heat accumulator 5 can be heat exchanged with a thermoacoustic body 9 provided with the resonance tube 4 filled with the above and a cooling device 7 that works on one end of the resonance tube 4 by a thermoacoustic effect. A thermoacoustic machine body 10 having a resonance tube 4 which is provided so as to penetrate the other end, accommodates one or more heat accumulators 5 and is filled with a working medium, and a power generation device 8 which works at one end of the resonance tube 4 by a thermoacoustic effect. The heat exchanger body 1 is provided with the resonance tube 4 and the main body so as to increase the temperature gradient of the heat storage device 5 by penetrating the other end of the resonance tube 4 so that one end of the heat storage device 5 can be heated. The power generation device 8 is cooled by the cooling device 7 by applying heat insulating means 6 to a part of the power generation device 8.

      In the process of taking in the heating gas generated by the combustion device or the like inside the thermoacoustic body 1 from the heating gas intake means 2 and discharging it from the heating gas discharge means 3, the heat accumulator 5 is used by the heating gas. One end of the heat accumulator 5 is heated, and the other end of the heat accumulator 5 is insulated from the heating gas by the heat insulating means 6, thereby generating a temperature gradient in the heat accumulator 5. The actuator 7 operates by a thermoacoustic effect using a temperature gradient. For example, the heat exchanger body 1 having the heat exchange medium flow path as the main body is used as the flue of the combustion device, and the thermoacoustic body 9 is arranged in parallel so that one end of the heat accumulator 5 can be heated through the resonance tube 4. Insulation means 6 such as glass wool is provided so that one end of the regenerator 5 can be heated to the flue as the resonance tube 4 and the main body so as to increase the temperature gradient of the regenerator 5, and the temperature gradient of the regenerator 5 The cooling device 7 that works by amplifying the vibration of the working gas in the resonance tube by the resonance tube cools the power generation device 8 that similarly works by the thermoacoustic effect, and uses the exhaust heat of the same origin to increase the power generation efficiency. Aircraft 1.

(Second Embodiment)
With reference to FIG. 2, the structure of the heat exchanger body 1 which concerns on 2nd Embodiment is demonstrated. The heat exchanger body 1 having a heat exchange medium flow path as a main body has a cylindrical container, and the heat exchange medium flow path in which one or both of the intake means 2 and the discharge means 3 are provided in a tangential direction is the main body. The thermoacoustic machine body 10 includes a resonance tube 4 that contains a heat accumulator 5 that heats one end and is filled with a working medium, and a power generation device 8 that works on the one end of the resonance tube 4 by a thermoacoustic effect. Is provided so as to penetrate the other end of the resonance tube 4 so that one end of the heat storage device 5 can be heated, and heat insulation means 6 is applied to a part of the resonance tube 4 so as to increase the temperature gradient of the heat storage device 5. Configure as follows.

      The difference from the first embodiment is that in the first embodiment, the thermoacoustic machine bodies are arranged in parallel, and the heat insulating means is applied to the outside of the main body filled with the heat conversion medium. In the second embodiment, the inner side of the main body is provided. In addition, heat insulation is applied to a part of the thermoacoustic machine. Further, the main body is formed in a cylindrical shape, and the intake means and the discharge means are provided in the tangential direction, so that the heat exchange medium is rotated to increase the residence time and increase the heat exchange efficiency.

(Third embodiment)
With reference to FIG. 3, the structure of the heat exchanger body 1 which concerns on 3rd Embodiment is demonstrated. The heat exchanger body 1 having a heat exchange medium flow path as a main body has a cylindrical container, and the heat exchange medium flow path in which one or both of the intake means 2 and the discharge means 3 are provided in a tangential direction is the main body. A heat accumulator 5 that heats a plurality of one ends of the heat exchanger body 1 and a resonance tube 4 filled with a working medium accommodated at appropriate intervals, and a power generator 8 that works on one end of the resonance tube 4 with a thermoacoustic effect Is provided so as to penetrate the other end of the resonance tube 4 so that one end of the heat storage device 5 can be heated, so that the temperature gradient of the heat storage device 5 is increased. The heat insulating means 6 is appropriately applied to the part.

      The difference from the second embodiment is that a plurality of heat accumulators are accommodated in a column in the resonance tube, and heat insulation means are alternately provided in addition to the heat exchange portion to enhance the thermoacoustic effect.

(Fourth embodiment)
With reference to FIG. 4, the structure of the heat exchange system which concerns on 4th Embodiment is demonstrated. A heat exchanger body 100 having a combustion apparatus 110 on which a steam generator 160 is mounted as a main body, a heat exchanger body 200 having a flue 210 of the combustion apparatus 110 as a main body, and a turbine 380 connected to the steam generator 160 are accommodated. The heat exchanger body 300 including the turbine apparatus 310 as a main body, the heat exchanger body 400 including a condenser connected to the turbine apparatus 310 as a main body, and the power generator 500 including the generator 580 connected to the turbine 380.

      The heat exchanger body 100 contains the combustion device 110 provided with the air supply means 120 and the smoke exhaust means 130 as a main body, and houses the heat storage device 150 that heats one end and the heat storage device 151 that acts on the cooling device 170 as a working medium. A thermoacoustic body 190 having the filled resonance tube 140 and the cooling device 170 acting on one end of the resonance tube 140 by a thermoacoustic effect is arranged so that one end of the heat accumulator 150 can exchange heat. A thermoacoustic machine body 191 provided with the other end penetrating, containing a resonance tube 140 containing one or more heat accumulators 150 and filled with a working medium, and a power generation device 180 acting on one end of the resonance tube 140 by a thermoacoustic effect. Is provided so that one end of the heat accumulator 150 can be heated, and the other end of the resonance tube 140 is penetrated so that the temperature gradient of the heat accumulator 150 is increased. And performing the steam generator 160 and the heat insulating means 161 as a means configured to cool the power-generating device 180 in the cooling device 170.

      The heat exchanger body 200 is composed of a cylindrical flue of the combustion device 110 in which one or both of the intake means 220 and the discharge means 230 are provided in a tangential direction, and a heat accumulator 250 for cooling a plurality of ends and a cooling device. A thermoacoustic machine body 290 including a resonance tube 240 containing a heat accumulator 251 acting on the device 270 and filled with a working medium and the cooling device 270 acting on one end of the resonance tube 240 with a thermoacoustic effect is provided in the heat accumulator 250. Of the resonance tube 240 filled with a working medium in which a plurality of heat accumulators 250 are accommodated at appropriate intervals. A thermoacoustic machine body 291 provided with a power generation device 280 that works by a thermoacoustic effect at one end is provided so as to penetrate the other end of the resonance tube 240 so that one end of the heat accumulator 250 can be heated. Subjected to heat insulation means 260 to a portion of the resonance pipe 240 so as Kojiru distribution suitably configured to cool the power-generating device 280 in the cooling device 270.

      The main body of the heat exchanger body 300 having the turbine device as the main body is the turbine device 310 connected to the steam generator 160 by the intake means 320 and the heat exchanger body 400 having the condenser as the main body by the discharge means 330. A resonance tube 340 that contains a heat storage device 351 that heats one end and a heat storage device 350 that acts on the cooling device 370 and is filled with a working medium, and the cooling device 370 that acts on one end of the resonance tube 340 by a thermoacoustic effect. The thermoacoustic body 390 is provided so as to penetrate the other end of the resonance tube 340 so that one end of the heat storage device 350 can be heated, and is attached to a part of the resonance tube 340 so as to increase the temperature gradient of the heat storage device 350. A heat insulating means 360 is applied, and the generator 580 configured in the power generation apparatus 500 including the generator connected to the turbine is cooled.

      The heat exchanger body 400 including the condenser as a main body includes a heat accumulator 450 and a cooling device that heats one end of the condenser 410 that is connected to the turbine apparatus 310 by an intake means 420 and that has a discharge means 430 and that has one end. A thermoacoustic machine body 490 including a resonance tube 440 that contains a heat storage unit 450 acting on 470 and filled with a working medium, and a cooling device 470 that acts on one end of the resonance tube 440 by a thermoacoustic effect is provided on the heat storage unit 450. The other end of the resonance tube 440 is passed through so that one end can be heated, and a heat insulating means 460 is applied to a part of the resonance tube 440 so as to increase the temperature gradient of the heat accumulator 450. The generator 580 configured is configured to be cooled.

      The heat exchange system of the present application uses various exhaust heat from a combustion device, a nuclear reactor, etc., which is a heat generation source in a power generation device using a turbine and a generator connected to the turbine, and performs cooling, power generation, etc. System.

      In the fourth embodiment, steam is generated by a steam generator using a combustion device, and a thermoacoustic effect is obtained by a temperature difference between the combustion device and the steam generator using the steam generator as a heat insulating means. Further, a heat exchanger body is arranged in the flue of the combustion device, and a thermoacoustic effect is obtained by using exhaust heat of the combustion device. Furthermore, the thermoacoustic effect is obtained also in the turbine apparatus and the condenser which are the flow paths of the steam by using the exhaust heat.

      Further power generation is possible by the energy obtained by the thermoacoustic effect, and the generator and the like can be cooled by the cooling function.

      In order to fully utilize various exhaust heat, the heat exchanger body can be configured in multiple stages.

      Various heat insulation means can be used to enhance the thermoacoustic effect. For example, it is also preferable to use a heat exchange medium flow path connected with a cooling device using the cooling function of the thermoacoustic machine body as the heat insulating means.

      In order to enhance the thermoacoustic effect, it is also preferable to change the material depending on the part of the resonance tube. It is also suitable to use various carbon fiber composite materials as the material.

      In order to enhance the thermoacoustic effect, it is also preferable that a part of the resonance tube has various shapes. In order to enhance the acoustic effect, it is also preferable to connect a buffer, a loop tube or the like to the resonance tube. It is also preferable to provide a squeezing or pressure regulating valve in the resonance tube.

      In addition to the above, various configurations and embodiments are possible without departing from the spirit of the present invention.

      Housing a part including the heating part of a thermoacoustic engine in a chimney, muffler, etc., which is a flow path of exhaust gas generated by a combustion device, etc. effectively uses exhaust heat and progresses in practical use Let

DESCRIPTION OF SYMBOLS 1 Heat exchange machine body 2 Intake means 3 Ejection means 4 Resonance tube 5 Heat accumulator 6 Heat insulation means 7 Cooling device 8 Power generation device 9 Thermoacoustic body body provided with cooling device 10 Thermoacoustic body body provided with power generation device 100 Combustion device and main body Heat exchanger body 110 Combustion device 120 Air supply means 130 Smoke exhaust means 140 Resonant tube 150 Heat accumulator heating one end 151 Heat accumulator acting on cooling device 160 Steam generator 161 Heat insulation means 170 Cooling device 190 Heat provided with cooling device Acoustic body 191 Thermoacoustic body 200 equipped with a power generation device that works by a thermoacoustic effect 200 Heat exchanger body having a flue as a main body 210 Flue 220 Intake means 230 Discharge means 240 Resonance tube 250 A heat accumulator 251 that heats one end Regenerative heat exchanger 260 Heat insulation means 270 Cooling device 280 Power generation device working with thermoacoustic effect 290 Cooling device Thermoacoustic machine body 291 Thermoacoustic machine body equipped with a power generation device that works by a thermoacoustic effect 300 Heat exchanger body having a turbine device as a main body 310 Turbine device 320 Intake means 330 Discharge means 340 Resonance tube 350 Heat accumulator 351 Cooling one end Heat accumulator 360 acting on the apparatus 360 Heat insulation means 370 Cooling device 380 Turbine 390 Thermoacoustic machine body 400 equipped with a cooling device 400 Heat exchanger body having a condenser as a main body 410 Condenser 420 Intake means 430 Discharge means 440 Resonance tube 450 One end A heat accumulator 451 A heat accumulator acting on a cooling device 460 A heat insulating means 470 A cooling device 490 A thermoacoustic machine body provided with a cooling device acting by a thermoacoustic effect 500 A power generator including a generator connected to a turbine 580 A generator connected to a turbine

Claims (32)

In the main body of the container that is provided with intake means and discharge means and accommodates the heat exchange medium generation source or is filled with the heat exchange medium,
A thermoacoustic machine body including a resonance tube containing one or more regenerators and filled with a working medium, and a device that works on a thermoacoustic effect at one end of the resonance tube;
A heat exchanger body provided so as to pass through the other end of the resonance tube so that one end of the heat accumulator can exchange heat.     The heat exchanger body according to claim 1, wherein a heat insulating means is provided in a part of the resonance tube so as to increase a temperature gradient of the heat accumulator.     The heat exchanger body according to claim 1 or claim 2, wherein a plurality of the thermoacoustic bodies are provided.     The heat exchanger body according to claim 1, wherein a plurality of the heat accumulators are accommodated in the resonance tube, and a plurality of heat insulating means are provided in addition to the heating unit so as to provide a temperature gradient.     5. The heat exchanger body according to claim 1, wherein at least one of the thermoacoustic bodies has a cooling function, and cools the generator.     The one or more of the thermoacoustic airframes have a cooling function, and one or more of the devices of the thermoacoustic airframe are generators, and the power generator is cooled by the cooling function. The heat exchanger body according to claim 2, claim 3, claim 4 or claim 5.     The heat exchange according to claim 1, 2, 3, 4, 5 or 6, wherein the main body is a cylindrical container, and the intake means is provided in a tangential direction. Aircraft.     The said main body is made into a cylindrical container, The said discharge means is provided in a tangent direction, The claim 1, Claim 3, Claim 4, Claim 6, Claim 7 characterized by the above-mentioned. Heat exchanger body.     The heat generating medium generating source accommodated in the main body is a combustion engine, and the combustion engine is used. 5. The claim 1, the claim 4, the claim 5, the claim 7, the claim 7, or the claim Item 9. The heat exchanger body according to Item 8.     The heat generating medium generation source housed in the main body is a power generation device. Claims 1, 2, 3, 4, 5, 6, 7 or Item 9. The heat exchanger body according to Item 8.     The heat exchange medium generation source accommodated in the main body is an electric computer, wherein the electric computer is used. The claim 1, the claim 2, the claim 3, the claim 4, the claim 6, the claim 7, or the claim Item 9. The heat exchanger body according to Item 8.     The medium generating source for heat exchange accommodated in the main body is derived from a chemical reaction, claim 1, claim 3, claim 4, claim 5, claim 7, claim 7 or The heat exchanger body according to claim 8.     The medium generating source for heat exchange accommodated in the main body is derived from a physical reaction, claim 1, claim 3, claim 4, claim 5, claim 7, claim 7 or The heat exchanger body according to claim 8.     The medium for heat exchange contained in the main body is derived from a biological reaction, wherein claim 1, claim 2, claim 3, claim 4, claim 6, claim 7 or The heat exchanger body according to claim 8.     The heat-generating medium generating source housed in the main body is derived from geothermal heat, wherein claim 1, claim 2, claim 3, claim 4, claim 5, claim 7, or claim 7 is provided. Item 9. The heat exchanger body according to Item 8.     The heat exchange medium generating source housed in the main body is derived from sunlight, wherein claim 1, claim 2, claim 3, claim 4, claim 6, claim 7 or claim 7 The heat exchanger body according to claim 8.     The heat exchanger body according to claim 16, wherein the heat exchange medium generating source housed in the main body is derived from the light collecting means.     The heat according to claim 1, claim 2, claim 3, claim 5, claim 7, claim 7, or claim 8, wherein the main body is an exhaust passage of a combustion engine. Switch body.     The heat according to claim 1, claim 2, claim 3, claim 4, claim 5, claim 6, claim 7, or claim 8, wherein the main body is a condenser of a power generator. Switch body.     The said main body is made into the exhaust means of an electric computer accommodation facility, Claim 1, Claim 2, Claim 3, Claim 4, Claim 5, Claim 7 or Claim 8 characterized by the above-mentioned. Heat exchanger body.     The heat exchanger body according to claim 9 or claim 18, wherein the combustion engine is an internal combustion engine.     The heat exchanger body according to claim 9 or 18, wherein the combustion engine is a combustion device.     The heat exchanger body according to claim 22, wherein the combustion device is a rotary combustion device.     The heat exchanger body according to claim 22, wherein the combustion device is a naturally aspirated combustion device.     The heat exchanger body according to claim 10 or 19, wherein the power generation device is a nuclear power generation device. The main body of the container containing the heat exchange medium generation source or filled with the heat exchange medium contains one or more heat accumulators, filled with the working medium, and one end of the resonance pipe with a thermoacoustic effect. One or more thermoacoustic bodies equipped with a device with a working power generation function,
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
A heat exchange system for generating electricity by exhaust heat of the generator. In the main body of the container that contains the generator in the heat exchange medium generation source or is filled with the heat exchange medium,
One or more thermoacoustic airframes having a resonance tube containing one or more heat accumulators and filled with a working medium, and a device having a power generation function working on a thermoacoustic effect at one end of the resonance tube,
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
27. The heat exchange system according to claim 26, wherein power is generated by exhaust heat of the generator. In the main body of the container filled with the heat exchange medium that contains the generator in the heat exchange medium generation source,
One or more thermoacoustic airframes having a resonance tube containing one or more regenerators and filled with a working medium, and a device having a cooling function that works by a thermoacoustic effect at one end of the resonance tube,
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
28. The heat exchange system according to claim 26 or claim 27, wherein the generator is cooled by exhaust heat of the generator. In the main body of the container containing the combustion device in the heat exchange medium generating source or filled with the heat exchange medium,
One or more thermoacoustic airframes having a resonance tube containing one or more heat accumulators and filled with a working medium, and a device having a power generation function working on a thermoacoustic effect at one end of the resonance tube,
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
A heat exchanger body that generates electricity by exhaust heat of the combustion device;
The exhaust passage of the combustion device is a main body of a container filled with a heat exchange medium,
One or more thermoacoustic airframes having a resonance tube containing one or more heat accumulators and filled with a working medium, and a device having a power generation function working on a thermoacoustic effect at one end of the resonance tube,
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
A heat exchanger body that generates electricity by exhaust heat of the combustion device;
The heat exchange system according to claim 26, having a power generation function. In the main body of the container containing the combustion device in the heat exchange medium generating source or filled with the heat exchange medium,
One or more thermoacoustic airframes having a resonance tube containing one or more heat accumulators and filled with a working medium, and a device having a power generation function working on a thermoacoustic effect at one end of the resonance tube,
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
A heat exchanger body that generates electricity by exhaust heat of the combustion device;
The exhaust passage of the combustion device,
The main body of the container filled with heat exchange medium provided with intake means and discharge means,
One or more thermoacoustic airframes having a resonance tube containing one or more regenerators and filled with a working medium, and a device having a cooling function that works by a thermoacoustic effect at one end of the resonance tube,
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
A heat exchanger body that cools the power generation device by exhaust heat of the combustion device;
30. A heat exchange system according to claim 26 or claim 29 having a power generation function. In the main body of the container containing the combustion device in the heat exchange medium generating source or filled with the heat exchange medium,
One or more thermoacoustic airframes having a resonance tube containing one or more heat accumulators and filled with a working medium, and a device having a power generation function working on a thermoacoustic effect at one end of the resonance tube,
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
A heat exchanger body that generates electricity by exhaust heat of the combustion device;
The exhaust passage of the combustion device,
The main body of the container filled with heat exchange medium provided with intake means and discharge means,
A thermoacoustic machine body including a resonance tube containing one or more regenerators and filled with a working medium, and a device having a cooling function that works by a thermoacoustic effect at one end of the resonance tube,
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
A heat exchanger body that cools the power generation device by exhaust heat of the combustion device;
The heat exchange system according to claim 26, claim 29, or claim 30, having a power generation function. In the main body of the container filled with the heat exchange medium by accommodating the combustion device in the heat exchange medium generation source,
A thermoacoustic machine body including a resonance tube containing one or more regenerators and filled with a working medium, and a device that works on a thermoacoustic effect at one end of the resonance tube;
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
As one of the heat insulating means, a water vapor generating device having a water supply port and a discharge port connected to a condenser, a turbine, and a generator operating on the turbine,
The thermoacoustic body utilizing exhaust heat;
In the main body of the container filled with the heat exchange medium by accommodating the turbine in the heat exchange medium generation source,
A thermoacoustic machine body including a resonance tube containing one or more regenerators and filled with a working medium, and a device that works on a thermoacoustic effect at one end of the resonance tube;
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
The thermoacoustic body utilizing exhaust heat;
The condenser,
The main body of the container filled with heat exchange medium provided with intake means and discharge means,
A thermoacoustic machine body including a resonance tube containing one or more regenerators and filled with a working medium, and a device that works on a thermoacoustic effect at one end of the resonance tube;
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was applied to a part of the resonance tube so as to increase the temperature gradient of the regenerator,
The heat exchanger body utilizing exhaust heat;
The exhaust passage of the combustion device,
The main body of the container filled with heat exchange medium provided with intake means and discharge means,
A thermoacoustic machine body including a resonance tube containing one or more regenerators and filled with a working medium, and a device that works on a thermoacoustic effect at one end of the resonance tube;
Provide one end of the heat accumulator so as to penetrate the other end of the resonance tube so that heat exchange is possible,
Insulating means was placed on a part of the resonance tube so as to increase the temperature gradient of the regenerator 30.
The heat exchanger body utilizing the exhaust heat of the combustion device;
The heat exchange system according to claim 26, claim 29, claim 30, or claim 31, wherein the heat exchange system has a power generation function, wherein power generation and cooling are performed by exhaust heat, and a generator operated by the turbine is cooled.

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