Cavitation reactor comprising pulse valve and resonance chamber
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B01F-011/00
F16K-011/085
B01F-005/00
B01D-017/04
B01J-019/00
B01J-019/18
B01D-021/28
출원번호
US-0033439
(2014-10-31)
등록번호
US-9631732
(2017-04-25)
국제출원번호
PCT/CA2014/000783
(2014-10-31)
국제공개번호
WO2015/061888
(2015-05-07)
발명자
/ 주소
Mitton, Michael Jon
출원인 / 주소
MITTON VALVE TECHNOLOGY INC.
대리인 / 주소
Kagan Binder, PLLC
인용정보
피인용 횟수 :
1인용 특허 :
16
초록▼
A cavitation reactor having a pulse valve for receiving an input fluid flow and generating a pulsed output flow that is provided to the input of a resonance chamber, such as a tube. The pulse valve uses a shaft with a number of regularly spaced lands to form fluid conduits between an input port and
A cavitation reactor having a pulse valve for receiving an input fluid flow and generating a pulsed output flow that is provided to the input of a resonance chamber, such as a tube. The pulse valve uses a shaft with a number of regularly spaced lands to form fluid conduits between an input port and the output port connected to the resonance tube to cause fluid communication between the input and output ports to be regularly opened and closed, thereby producing a pulsed output that drives the formation of resonance waves in the resonance chamber. The shaft is rotated at a suitable frequency to produce cavitation bubbles that collapse in the resonance chamber without damaging the valve shaft.
대표청구항▼
1. A cavitation reactor comprising: (a) a pulse valve comprising: (i) a housing having a cylindrical bore extending laterally along the axis of the bore, the cylindrical bore being defined by an inner cylindrical surface of the housing, the housing having an input port and a pulse valve output port,
1. A cavitation reactor comprising: (a) a pulse valve comprising: (i) a housing having a cylindrical bore extending laterally along the axis of the bore, the cylindrical bore being defined by an inner cylindrical surface of the housing, the housing having an input port and a pulse valve output port, each port providing a separate fluid communication path between an outer surface of the housing and the bore; and(ii) a valve shaft coaxially positioned in the bore and having a central portion and at least two lands extending radially therefrom, each land having a surface and having an end proximate to the cylindrical inner surface of the housing, the central portion having a surface, the valve shaft being rotatable inside the bore around the bore axis,wherein the lands extend laterally, along the bore axis, so that the surfaces of the valve shaft, in combination with the housing, define one or more fluid conduits, each fluid conduit having a bottom portion defined by the surfaces of two adjacent lands and the central portion therebetween,wherein the valve shaft is continuously rotatable so that each fluid conduit repeatedly moves between a position in which the input port and the pulse valve output port are not in fluid communication with each other, so that the fluid communication path is closed, to an open position in which the input port and the pulse valve output port are in fluid communication with each other, so that the fluid communication path is open and fluid flows from the input port, through the conduit and out the pulse valve output port; and(b) a resonance chamber having a fundamental frequency, the resonance chamber being in fluid communication with the pulse valve output port, the resonance chamber having a resonance chamber output port, wherein continuously rotating the valve shaft results in repeated opening and closing of the fluid communication path so that when fluid is injected into the input port, a pulsed fluid flow is produced at the pulse valve output port, which drives a resonant wave in the resonance chamber, and the fluid moves through the resonance chamber from the pulse valve output port to the resonance chamber output port. 2. The cavitation reactor of claim 1, wherein the valve shaft further comprises a rear disk-shaped plate perpendicular to the bore axis, and having a cylindrical outer surface and being sized so the outer surface of the rear plate is proximate to the cylindrical inner surface of the housing so that fluid cannot pass between the rear plate and the inner surface of the housing, the rear plate partly defining some or all of the fluid conduits. 3. The cavitation reactor of claim 2, wherein, when fluid is injected through the input port, the fundamental frequency of the resonance tube can be adjusted to create a resonance wave in the resonance chamber with a frequency of over 20 KHz. 4. The cavitation reactor of claim 1, wherein the valve shaft further comprises a front disk-shaped plate perpendicular to the bore axis, and having a cylindrical outer surface and being sized so the outer surface of the front plate is proximate to the cylindrical inner surface of the housing so that fluid cannot pass between the front plate and the inner surface of the housing, the front plate partly defining some or all of the fluid conduits. 5. The cavitation reactor of claim 1, wherein the valve shaft further comprises one or more disk-shaped separators perpendicular to the bore axis, each separator having a cylindrical outer surface and being sized so the outer surface of the separator is proximate to the cylindrical inner surface of the housing so that fluid cannot pass between the separator and the inner surface of the housing, the separator partly defining some or all of the fluid conduits. 6. The cavitation reactor of claim 1, wherein the fundamental frequency of the resonance chamber is adjustable. 7. The cavitation reactor of claim 6, wherein, when fluid is injected through the input port, the fundamental frequency of the resonance chamber can be adjusted to create a resonance wave in the resonance chamber sufficient to cause cavitation bubbles to form in each of the conduits when the conduit has rotated so that the fluid communication path moves from being open to being closed, and while the conduit remains in fluid communication with the pulse valve output port, some of the cavitation bubbles move into resonance chamber where they collapse. 8. The cavitation reactor of claim 1, wherein the valve shaft has exactly three regularly spaced lands and exactly three similarly configured fluid conduits. 9. The cavitation reactor of claim 1, wherein the resonance chamber is an open tube having proximal and distal ends with the proximal end adjacent to and in fluid communication with the pulse valve output port, and wherein the open distal end of the tube is the resonance chamber output port. 10. The cavitation reactor of claim 1, wherein the valve shaft has three lands so that the fluid communication path between the input port and the pulse valve output port is opened and closed at a frequency of between 270 Hz and 600 Hz. 11. The cavitation reactor of claim 1, wherein the bottom portion of each conduit, which bottom has first and second laterally extending ends at the ends of the two adjacent lands, is bounded by a first land on one side and a second land on the other side, and is smoothly shaped.
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