IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0794434
(2005-12-29)
|
등록번호 |
US-8800599
(2014-08-12)
|
우선권정보 |
EP-04107064 (2004-12-30) |
국제출원번호 |
PCT/EP2005/057219
(2005-12-29)
|
§371/§102 date |
20071001
(20071001)
|
국제공개번호 |
WO2006/070020
(2006-07-06)
|
발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
2 인용 특허 :
10 |
초록
▼
A Joule-Thompson or other throttling valve comprises an outlet channel (7) in which swirl imparting means (10) impose a swirling motion to the cooled fluid stream discharged by the valve, thereby inducing liquid droplets to swirl towards the outer periphery (7A) of the fluid outlet channel (7) and t
A Joule-Thompson or other throttling valve comprises an outlet channel (7) in which swirl imparting means (10) impose a swirling motion to the cooled fluid stream discharged by the valve, thereby inducing liquid droplets to swirl towards the outer periphery (7A) of the fluid outlet channel (7) and to coalesce into enlarged liquid droplets (17) which can be separated easily from a gaseous or other carrier fluid.
대표청구항
▼
1. A throttling valve comprising: a housing;a valve body which is arranged in the housing;a perforated sleeve via which the valve body permits the multiphase fluid to flow from a fluid inlet channel into a fluid outlet channel, wherein the multiphase fluid stream is in a straight flow upstream of th
1. A throttling valve comprising: a housing;a valve body which is arranged in the housing;a perforated sleeve via which the valve body permits the multiphase fluid to flow from a fluid inlet channel into a fluid outlet channel, wherein the multiphase fluid stream is in a straight flow upstream of the perforated sleeve;wherein the valve body and the perforated sleeve are slidably arranged in the housing such that the valve body controls multiphase fluid flow from a fluid inlet channel into the fluid outlet channel of the valve; andwherein at least some perforations of the sleeve have an at least partially tangential orientation relative to a longitudinal axis of the sleeve, such that the multiphase fluid is expanded and converted into a multiphase fluid stream, which is induced to swirl within the fluid outlet channel and liquid droplets are induced to swirl towards the outer periphery of the fluid outlet channel and to coalesce into enlarged liquid droplets, wherein the valve is such that the multiphase fluid stream is non-swirling until it is induced to swirl. 2. The throttling valve of claim 1, wherein a gas-liquid separation assembly is connected to the outlet channel of the choke valve, in which assembly liquid and gaseous phases of the multiphase fluid stream discharged by the valve are at least partly separated. 3. The throttling valve of claim 1, wherein the multiphase fluid stream comprises hydrocarbon and aqueous fluids and wherein at least a fraction of the aqueous fluids is converted into liquid water droplets which are induced to swirl towards the outer periphery of the fluid outlet channel and to coalesce into enlarged water droplets and/or an annular water film at the outer periphery of the fluid outlet channel. 4. The throttling valve of claim 1, wherein the multiphase fluid stream comprises a gaseous carrier fluid and the fluid inlet and/or fluid outlet channel and/or other parts of the interior of the throttling valve provides a fluid channel in which the fluid stream is accelerated and is thereby induced to be expanded and cooled by means of the Joule Thomson effect. 5. A throttling valve comprising: a housing;a valve body which is arranged in the housing; anda swirl imparter which imposes a swirling motion to a fluid stream flowing through a fluid outlet channel,wherein the valve body and the swirl imparter are slidably arranged in the housing such that they can be moved into the fluid outlet channel to control the flux of a fluid stream flowing from a fluid inlet channel into a fluid outlet channel of the valve such that the fluid stream is expanded and cooled,wherein the swirl imparter is provided by longitudinally evenly-spaced perforations and circumferentially evenly-spaced perforations of a perforated sleeve, via which the valve body permits the fluid stream to flow from the fluid inlet channel into the fluid outlet channel, andwherein the swirl imparter is oriented such that the fluid stream swirls about a longitudinal axis of the fluid outlet channel, thereby inducing liquid droplets that are formed during the expansion along the flow path of the valve to swirl towards the outer periphery of the fluid outlet channel and to coalesce, wherein the valve is such that the fluid stream is non-swirling until it reaches the swirl imparter. 6. The throttling valve of claim 5, wherein a substantially conical central body is arranged in the fluid outlet channel, which body is substantially co-axial to a central axis of the fluid outlet channel and which generates an outlet channel having a gradually increasing cross-sectional area in downstream direction, thereby generating a vortex with a swirl factor that promotes growth and coalescence of condensed fluid droplets. 7. The throttling valve of claim 5, wherein the valve is a Joule Thompson valve having a substantially tubular fluid outlet channel and a valve body comprising a piston which is movable in a substantially longitudinal direction through the fluid outlet channel and wherein the perforated sleeve is secured to the piston such that a substantially annular downstream end of the fluid inlet channel at least partially surrounds the perforated sleeve and at least some fluid is induced to flow from the fluid inlet channel via non-radial perforations in the perforated sleeve into the fluid outlet channel when the valve body is in a fully open position. 8. System for separating a liquid and gaseous phase in a fluid separation assembly, comprising a throttling valve according to claim 5, and a fluid separation assembly that is arranged downstream of the throttling valve. 9. The throttling valve of claim 5, wherein the valve further comprises: a substantially conical central body that is arranged downstream of the perforated sleeve in the fluid outlet channel, which body is substantially co-axial to a central axis of the fluid outlet channel and which generates an outlet channel having a gradually increasing cross-sectional area in downstream direction, thereby generating a vortex with a swirl factor that promotes growth and coalescence of condensed fluid droplets. 10. The throttling valve of claim 5, wherein the valve further comprises: a valve shaft, wherein by rotation of a gear wheel at the valve shaft a teethed piston rod pushes the valve body up and down into the fluid outlet channel to control the flow of the fluid stream from the fluid inlet channel into the fluid outlet channel. 11. The throttling valve of claim 5, wherein: the flow inlet channel and the flow outlet channel are aligned along a same central axis line. 12. The throttling valve of claim 5, wherein the fluid inlet channel operates to accelerate the fluid stream and thereby induces the fluid stream to be expanded and cooled by means of the Joule Thomson effect. 13. The throttling valve of claim 5, wherein: the fluid stream is comprised of gaseous fluid that can be expanded and cooled. 14. The throttling valve of claim 5, wherein evenly-spaced perforations of the perforated sleeve have an at least partially tangential orientation relative to a longitudinal axis of the sleeve, such that the fluid stream is induced to swirl about the longitudinal axis of the fluid outlet channel. 15. The throttling valve of claim 14, wherein at least some perforations have a central axis, which positions relatively to a longitudinal axis of the sleeve at a selected distance D and at a selected acute angle along the flow direction. 16. The throttling valve of claim 15, wherein the inner surface of the perforated sleeve is located at a radius R from the longitudinal axis of the sleeve and the ratio between the distance D and the radius R is between 0.2 and 1. 17. The throttling valve of claim 16, wherein the ratio between the distance D and the radius R is between 0.5 and 0.99. 18. A method for enlarging droplet sizes in a multiphase fluid stream comprising the steps of: flowing liquid droplets and a carrier fluid in the multiphase fluid stream through a perforated sleeve into an outlet section of a throttling valve which comprises a housing, a valve body and the perforated sleeve with the valve body and the perforated sleeve being slidably arranged in the housing, wherein the multiphase fluid stream is in a straight flow upstream of the perforated sleeve;using available free pressure in the throttling valve for isenthalpic expansion; andcreating a swirling flow in the fluid stream flowing through the outlet channel of the valve thereby inducing liquid droplets to swirl towards the outer periphery of the fluid outlet channel and to coalesce, wherein a swirl imparter is provided by longitudinally evenly-spaced perforations and circumferentially evenly-spaced perforations of the perforated sleeve, wherein the swirl imparter is oriented such that the fluid stream swirls about a longitudinal axis of the fluid outlet channel. 19. The method of claim 18, wherein a gas-liquid separation assembly is connected to the outlet channel of the choke valve, in which assembly liquid and gaseous phases of the multiphase fluid stream discharged by the valve are at least partly separated. 20. The method of claim 18, wherein the multiphase fluid stream comprises hydrocarbon and aqueous fluids and wherein at least a fraction of the aqueous fluids is converted into liquid water droplets which are induced to swirl towards the outer periphery of the fluid outlet channel and to coalesce into enlarged water droplets and/or an annular water film at the outer periphery of the fluid outlet channel. 21. The method of claim 18, wherein the multiphase fluid stream comprises a gaseous carrier fluid and the fluid inlet and/or fluid outlet channel and/or other parts of the interior of the throttling valve provides a fluid channel in which the fluid stream is accelerated and is thereby induced to be expanded and cooled by means of the Joule Thomson effect. 22. The method of claim 21, wherein the multiphase fluid stream is expanded to a transonic or supersonic velocity. 23. Method for separating a liquid and gaseous phase in a fluid separation assembly, comprising: performing the method for enlarging droplet sizes in accordance with claim 18, using a throttling valve; andperforming separation using a fluid separation assembly arranged downstream of the throttling valve.
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