IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0381500
(2010-03-12)
|
등록번호 |
US-8695356
(2014-04-15)
|
우선권정보 |
CN-2009 1 0100287 (2009-06-29) |
국제출원번호 |
PCT/CN2010/071028
(2010-03-12)
|
§371/§102 date |
20111229
(20111229)
|
국제공개번호 |
WO2011/000228
(2011-01-06)
|
발명자
/ 주소 |
- Gan, Zhihua
- Wang, Bo
- Qiu, Limin
- Wang, Longyi
- Fan, Bingyan
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
2 |
초록
▼
A pulse tube cryocooler modulating phase via an inertance tube and an acoustic amplifier (A1, A2) provided in the pulse tube cryocooler are disclosed. The acoustic power amplifier (A1, A2) is made of a metal pulse tube (PT1, PT2) filled with regenerative materials, which are located at a distance of
A pulse tube cryocooler modulating phase via an inertance tube and an acoustic amplifier (A1, A2) provided in the pulse tube cryocooler are disclosed. The acoustic power amplifier (A1, A2) is made of a metal pulse tube (PT1, PT2) filled with regenerative materials, which are located at a distance of X from the hot end of the pulse tube. The length of the regenerative materials is L which meets the requirement of X−L0. The acoustic power amplifier (A1, A2) can be used not only in a single-stage pulse tube cryocooler, but also in a multi-stage pulse tube cryocooler thermally coupled or gas coupled. The regenerative materials may be any cold storage materials applicable at low temperatures, such as stainless steel wire mesh, lead pellet, lead thread et al. The acoustic power amplifier (A1, A2) can increase the acoustic power at the hot end of the pulse tube (PT1, PT2), which is advantageous to the phase modulation of the inertance tube, thereby the properties of the pulse tube cryocooler can be enhanced.
대표청구항
▼
1. An acoustic power amplifier used in an inertance tube phase modulation, characterized in that a metal tube filled with regenerative materials, is located at a distance of X from a hot end of a pulse tube, or that the regenerative materials is located at an internal part of the pulse tube with a d
1. An acoustic power amplifier used in an inertance tube phase modulation, characterized in that a metal tube filled with regenerative materials, is located at a distance of X from a hot end of a pulse tube, or that the regenerative materials is located at an internal part of the pulse tube with a distance of X from the hot end of the pulse tube, with a length of L, X−L>0. 2. A pulse tube cryocooler with acoustic power amplifier, characterized in that it comprises a first stage compressor (RG1), a first stage pulse tube (PT1), a first stage acoustic power amplifier (A1), an inertance tube (I1), and a reservoir; wherein a first stage compressor (C1) connects with a hot end of the first stage regenerator (RG1); a cold end of the first stage regenerator (RG1) connects with a cold end of the first stage pulse tube (PT1); a hot end of the first stage pulse tube (PT1) connects with a first stage reservoir (R1) through the first stage inertance tube (I1); the first stage acoustic power amplifier (A1) locates inside the first stage pulse tube (PT1), at the position with a distance X from the hot end of the first stage pulse tube (PT1), the length of the first stage acoustic power amplifier is L, X−L>0. 3. A pulse tube cryocooler with an acoustic power amplifier, characterized in that it includes a first stage compressor (C1), a first stage regenerator (RG1), a first stage pulse tube (PT1), a first stage acoustic power amplifier (A1), an inertance tube (I1), a first stage reservoir (R1), a second stage compressor (C2), a precooling section of second stage regenerator (RG21), a second stage regenerator (RG22), a second stage pulse tube (PT1), a second stage acoustic amplifier (A2), a second inertance tube (I2), a second stage reservoir (R2), and a thermal bridge (TB); wherein the first stage compressor (C1) connects with a hot end of the first stage regenerator (RG1); a cold end of the first stage regenerator (RG1) connects with the cold end of the first stage pulse tube (PT1); the hot end of the first stage pulse tube (PT1) connects with the first stage reservoir (R1) through the first stage inertance tube; the first stage acoustic power amplifier (A1) locates inside the first stage pulse tube (PT1); the distance between the first stage acoustic power amplifier and the hot end of the pulse tube is X, the length of the first stage acoustic amplifier is L, X−L>0; the second stage compressor (C2) connects with the hot end of the second stage regenerator (RG21); the cold end of the precooling section of the second stage regenerator (RG21) connects with the hot end of the second stage regenerator (RG22); the cold end of the second stage regenerator (RG22) connects with the cold end of the second stage pulse tube (PT2), the hot end of the second stage pulse tube (PT2) connects with the second stage reservoir (R2) through the second stage inertance tube; the second stage acoustic power amplifier (A2) is inside the second stage pulse tube (PT2), the distance between the hot end of the second stage pulse tube (PT2) and the second stage acoustic power amplifier (A2) is X, the length of the second stage acoustic power amplifier (A1) is L, and X−L>0; the cold end of the precooling section of the second stage regenerator (RG21) connects with the cold end of the first stage through the thermal bridge. 4. A pulse tube cryocooler with an acoustic power amplifier, characterized in that it includes a first stage pulse tube (PT1), a first stage acoustic power amplifier (A1), an inertance tube (I1), a first stage reservoir (R1), a second stage compressor (C2), a precooling section of second stage regenerator (RG21), a second stage regenerator (RG22), a second stage pulse tube (PT1), a second stage acoustic amplifier (A2), a second inertance tube (I2), a second stage reservoir (R2), and a thermal bridge (TB); wherein a cold end of the first stage pulse tube (PT1) connects with a hot end of the precooling section of the second stage regenerator (RG21); a hot end of the first stage pulse tube (PT1) connects with the first stage reservoir (R1) through the first stage inertance tube (I1); the first stage acoustic power amplifier (A1) is inside the first stage pulse tube (PT1); the distance between the first stage acoustic power amplifier (A1) and a hot end of the first stage pulse tube (PT1) is X, the length of the first stage acoustic amplifier (A1) is L, X−L>0; the second stage compressor (C2) connects with the hot end of the precooling section of the second stage regenerator (RG21); a cold end of the precooling section of the second stage regenerator (RG21) connects with the hot end of the second stage regenerator (RG22); a cold end of the second stage regenerator (RG22) connects with a cold end of the second stage pulse tube (PT2); a hot end of the second stage pulse tube (PT2) connects with the second stage reservoir (R2) through the second stage inertance tube (I2); the second stage acoustic power amplifier (A2) is inside the second stage pulse tube (PT2); the distance between the second stage acoustic power amplifier (A2) and the hot end of the second stage pulse tube (PT2) is X, the length of the second stage acoustic power amplifier (A1) is L, X−L>0.
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