IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0675900
(2012-11-13)
|
등록번호 |
US-8552284
(2013-10-08)
|
우선권정보 |
JP-2010-171629 (2010-07-30); JP-2010-171631 (2010-07-30); JP-2010-171634 (2010-07-30); JP-2011-105964 (2011-05-11) |
발명자
/ 주소 |
- Kanno, Tsutomu
- Sakai, Akihiro
- Takahashi, Kohei
- Yamada, Yuka
- Omote, Atsushi
- Ueda, Daisuke
|
출원인 / 주소 |
|
대리인 / 주소 |
McDermott Will & Emery LLP
|
인용정보 |
피인용 횟수 :
2 인용 특허 :
4 |
초록
▼
A pipe-shaped thermoelectric power generating device includes an internal through-hole along the axis direction of the pipe-shaped thermoelectric power generation device; a plurality of first cup-shaped components each made of metal; a plurality of second cup-shaped components each made of thermoele
A pipe-shaped thermoelectric power generating device includes an internal through-hole along the axis direction of the pipe-shaped thermoelectric power generation device; a plurality of first cup-shaped components each made of metal; a plurality of second cup-shaped components each made of thermoelectric material; a first electrode; a second electrode. The plurality of first cup-shaped components and the plurality of second cup-shaped components are arranged alternately and repeatedly along the axis direction. The first electrode and the second electrode are provided respectively at one end and at the other end of the pipe-shaped thermoelectric power generation device.
대표청구항
▼
1. A pipe-shaped thermoelectric power generation device having two ends apart from each other along an axis direction, comprising: an internal through-hole along the axis direction of the pipe-shaped thermoelectric power generation device;a plurality of first cup-shaped components each made of metal
1. A pipe-shaped thermoelectric power generation device having two ends apart from each other along an axis direction, comprising: an internal through-hole along the axis direction of the pipe-shaped thermoelectric power generation device;a plurality of first cup-shaped components each made of metal;a plurality of second cup-shaped components each made of thermoelectric material;a first electrode; anda second electrode; wherein:the plurality of the first cup-shaped components and the plurality of second cup-shaped components are arranged alternately and repeatedly along the axis direction of the pipe-shaped thermoelectric power generation device,the first electrode and the second electrode are provided respectively at one end and at another end of the pipe-shaped thermoelectric power generation device,each of the first cup-shaped components has a shape of a circular truncated cone, a shape of an elliptical truncated cone, or a shape of a truncated pyramid,each of the first cup-shaped components has a first internal surface and a first external surface,the first internal surface has a shape of a periphery of a circular truncated cone, a shape of a periphery of an elliptical truncated cone, or a shape of a periphery of a truncated pyramid,the first external surface has a shape of a periphery of a circular truncated cone, a shape of a periphery of an elliptical truncated cone, or a shape of a periphery of a truncated pyramid,each of the first cup-shaped components comprises a first through-hole at a bottom end thereof,a cross-sectional area of each of the first cup-shaped components decreases in the direction toward the bottom end thereof,each of the second cup-shaped components has a shape of a circular truncated cone, a shape of an elliptical truncated cone, or a shape of a truncated pyramid,each of the second cup-shaped components has a second internal surface and a second external surface,the second internal surface has a shape of a periphery of a circular truncated cone, a shape of a periphery of an elliptical truncated cone, or a shape of a periphery of a truncated pyramid,the second external surface has a shape of a periphery of a circular truncated cone, a shape of a periphery of an elliptical truncated cone, or a shape of a periphery of a truncated pyramid,each of the second cup-shaped components comprises a second through-hole at a bottom end thereof,a cross-sectional area of each of the second cup-shaped components decreases in the direction toward the bottom end thereof,the internal through-hole along the axis direction of the pipe-shaped thermoelectric power generation device is composed of the plurality of the first through-holes and the plurality of the second through-holes,each of the first cup-shaped components is inserted in one of adjacent second cup-shaped components of the plurality of second cup-shaped components in such a manner that the first external surface of the each of the first cup-shaped components is adhered to the second internal surface of the one of adjacent second cup-shaped components,another one of adjacent second cup-shaped components of the plurality of second cup-shaped components is inserted in the each of the first cup-shaped components in such a manner that the first internal surface of the each of the first cup-shaped components is adhered to the second external surface of the another one of adjacent second cup-shaped components,the metal is nickel, cobalt, copper, aluminum, silver, gold, or alloy thereof,the thermoelectric material is Bi, Bi2Te3, PbTe, or Bi2Te3 containing Sb or Se, andthe following mathematical formulas are satisfied: 5 degrees≦θ1≦45 degrees5 degrees≦θ2≦45 degrees, andθ1=θ2,where θ1 represents an angle formed by a part of the first cup-shaped component in which the cross-sectional area is decreased and an axis direction of the first cup-shaped component, andθ2 represents an angle formed by a part of the second cup-shaped component in which the cross-sectional area is decreased and an axis direction of the second cup-shaped component. 2. The pipe-shaped thermoelectric power generation device according to claim 1, wherein the metal is nickel, cobalt, copper, or aluminum. 3. The pipe-shaped thermoelectric power generation device according to claim 1, wherein: the first external surface of the each of the first cup-shaped components is in contact with the second internal surface of the one of adjacent second cup-shaped components, andthe first internal surface of the each of the first cup-shaped components is in contact with the second external surface of the another one of adjacent second cup-shaped components. 4. The pipe-shaped thermoelectric power generation device according to claim 1, wherein: solder is supplied between the first external surface of the each of the first cup-shaped components and the second internal surface of the one of adjacent second cup-shaped components, andsolder is supplied between the first internal surface of the each of the first cup-shaped components and the second external surface of the another one of adjacent second cup-shaped components. 5. The pipe-shaped thermoelectric power generation device according to claim 1, further comprising a tubular jacket, wherein the pipe-shaped thermoelectric power generation device is inserted in the tubular jacket. 6. The pipe-shaped thermoelectric power generation device according to claim 1, wherein an insulated internal wall is arranged around the internal through-hole. 7. The pipe-shaped thermoelectric power generation device according to claim 1, wherein an insulated external wall is arranged around pipe-shaped thermoelectric power generation device. 8. A thermoelectric power generator comprising n pipe-shaped thermoelectric power generation devices, the n pipe-shaped thermoelectric power generation devices including a first pipe-shaped thermoelectric power generation device disposed within an nth pipe-shaped thermoelectric power generation device with one or more pipe-shaped thermoelectric power generation devices disposed therebetween wherein: n is a natural number of three or more,each of the n pipe-shaped thermoelectric power generation devices is the pipe-shaped thermoelectric power generation device according to claim 1,a cross-sectional area of the first pipe-shaped thermoelectric power generation device is smallest,a cross-sectional area of the nth pipe-shaped thermoelectric power generation device is largest, anda cross-sectional area of each of the one or more pipe-shaped thermoelectric power generation devices disposed between the first pipe-shaped thermoelectric power generation device and the nth pipe-shaped thermoelectric power generation devices increases in size from the first pipe-shaped thermoelectric power generation device to the nth pipe-shaped thermoelectric power generation device,wherein an external surface of the first pipe-shaped thermoelectric power generation device is adhered to an internal surface of the one or more pipe-shaped thermoelectric power generation devices that is closest to the first pipe-shaped thermoelectric power generation device through an insulation layer, the internal surface of the nth pipe-shaped thermoelectric power generation device is connected to an external surface of the one or more pipe-shaped thermoelectric power generation devices that is closest to the nth pipe-shaped thermoelectric power generation device through an insulation layer and internal and external surfaces of the one or more pipe-shaped thermoelectric power generation devices are adhered to one another through an insulation layer in order of increasing cross-sectional area from the first pipe-shaped thermoelectric power generation device to the nth pipe-shaped thermoelectric power generation device. 9. The thermoelectric power generator according to claim 8, wherein: each first electrode is connected to one another,each second electrode is connected to one another, andthe n pipe-shaped thermoelectric power generation devices are electrically connected in parallel. 10. A method for generating an electric power with use of a pipe-shaped thermoelectric power generator, the method comprising steps of: (a) preparing the thermoelectric power generator according to claim 9; and(b) applying a temperature difference between the internal through-hole of the first pipe-shaped thermoelectric power generation device and an external surface of the thermoelectric power generator, so as to generate a voltage difference between the first electrodes and the second electrodes. 11. The thermoelectric power generator according to claim 8, wherein: second electrodes of the odd number-th pipe-shaped thermoelectric power generation devices from a first to a (2m−1)th are electrically connected to second electrodes of the even number-th pipe-shaped thermoelectric power generation devices from a second to a (2m)th, respectively,n is an odd number of three or more,the value of m is defined by the formula: m=(n−1)/2,first electrodes of the even number-th pipe-shaped thermoelectric power generation devices from a second to a (2m)th are electrically connected to first electrodes of the odd number-th pipe-shaped thermoelectric power generation devices from a third to a (2m+1)th, respectively, andthe n pipe-shaped thermoelectric power generation devices are electrically connected in series. 12. A method for generating an electric power with use of a pipe-shaped thermoelectric power generator, the method comprising steps of: (a) preparing the thermoelectric power generator according to claim 11, and(b) applying a temperature difference between the internal through-hole of the first pipe-shaped thermoelectric power generation device and an external surface of the thermoelectric power generator, so as to generate a voltage difference between the first electrode of the first pipe-shaped thermoelectric power generation device and the second electrode of the nth pipe-shaped thermoelectric power generation device. 13. The thermoelectric power generator according to claim 8, wherein: second electrodes of the odd number-th pipe-shaped thermoelectric power generation devices of the n pipe-shaped thermoelectric power generation devices from a first to a (2m−1)th are electrically connected to second electrodes of the even number-th pipe-shaped thermoelectric power generation devices from a second to a (2m)th, respectively,n is an even number,the value of m is defined by the formula: m=n/2,when n is four or more, first electrodes of the even number-th pipe-shaped thermoelectric power generation devices of the n pipe-shaped thermoelectric power generation devices from a second to a (2m−2)th are electrically connected to first electrodes of the odd number-th pipe-shaped thermoelectric power generation devices from a third to a (2m−1)th, respectively, andthe n pipe-shaped thermoelectric power generation devices are electrically connected in series. 14. A method for generating an electric power with use of a pipe-shaped thermoelectric power generator, the method comprising steps of: (a) preparing the thermoelectric power generator according to claim 13, and(b) applying a temperature difference between the internal through-hole of the first pipe-shaped thermoelectric power generation device and an external surface of the thermoelectric power generator, so as to generate a voltage difference between the first electrode of the first pipe-shaped thermoelectric power generation device and the second electrode of the nth pipe-shaped thermoelectric power generation device. 15. The pipe-shaped thermoelectric power generation device according to claim 1, wherein a groove is provided along the axial direction. 16. A method for generating an electric power with use of a pipe-shaped thermoelectric power generation device, the method comprising steps of: (a) preparing the pipe-shaped thermoelectric power generation device according to claim 1; and(b) applying a temperature difference between the internal through-hole and an external surface of the pipe-shaped thermoelectric power generation device to generate a voltage difference between the first electrode and the second electrode. 17. A thermoelectric power generator comprising first and second pipe-shaped thermoelectric power generation devices, wherein: each of the first and second pipe-shaped thermoelectric power generation devices is the pipe-shaped thermoelectric power generation device according to claim 1,a cross-sectional area of the first pipe-shaped thermoelectric power generation device is smaller than a cross-sectional area of the second pipe-shaped thermoelectric power generation device, andan external surface of the first pipe-shaped thermoelectric power generation device is adhered to an internal surface of the second pipe-shaped thermoelectric power generation device through an insulation layer.
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