TH66845B - Multi-stage cyclonic fluid separator - Google Patents

Abstract

------ 12/07/2018 ------ (OCR) page 1 of the number 1 page invention summary. The invention involves a chyclonic fluid separator, consisting of a neck section (4), which is provided between the convergent fluid inlet part and the path part. Out of separate fluid A cyclonic fluid separator will be provided to support the Cyclonic flow through the confluence of the fluid inlet and the neck towards the Trajectories of separate fluid in the direction at the end of the stream Part of the path of the fluid exit Separately, it is assembled with a pipe of the inner circumferential path (7) for the components. A condensated softening fluid and an outer second (6) outlet path pipe for fluid components rich in condensation. Fluid-type separator The cyclonic is composed of an additional outer secondary pipe (16) an outlet pipe. Out in the second bowl, the outer (6) is positioned on the first position along the axis (I) of the separator. The chyclonic fluid and the outer secondary outlet pipe (16) are positioned. On the second position along the core (I) of the cyclonic fluid separator ------------ the invention involves a cyclonic fluid separator consisting of a neck section. (4) which is provided between the porting part of the converging fluid and the passage part. Out of separate fluid A cyclonic fluid separator will be provided to support the Cyclonic flow through the confluence of the fluid inlet and the neck to the part of the Fluid exit paths that are separated in the current direction Part of the path of the fluid exit The separate outlet pipe is initially assembled with the inner circumference (7) for the components of the Condensable reduced flow and outer secondary exit path pipe (6) for fluid components rich in condensation. Cyclonic fluid separator The outer second stage outlet pipe (6) is placed on the first position along the core (I) of the fluid separator. The cyclonic type and the outlet pipe in the second stage.Additional periphery (16) is positioned on The second position along the core (I) of the cyclonic fluid separator.

Claims (9)

Claims (all) which will not appear on the classifieds page. :------12/07/2018------(OCR) Page 1 of 6 pages Articles of Rights 1. Chiclonic Fluid Separator, which consists of neck part. which was prepared Between the converging fluid inlet path sections and the separated fluid exit path sections, a cyclonic fluid separator is provided to support cyclonic flow through. The part of the fluid inlet path converges and the neck towards the part of the fluid path exit. separate in the direction at the end of the stream, the separate fluid exit path sections comprising the exit path tubes. in the inner bowl for the reduced fluid components that can be condensed and Secondary exit path tubes on the periphery for condensable rich fluid components, where the chyclonic fluid separator incorporates the exit path tubes in the second bowl. An additional periphery, by the tube of the exit path in the second periphery that is positioned on the first position. along the axis of the chyclonic fluid separator and the periphery of the secondary exit path. The additional is positioned on the second position along the central axis of the cyclonic fluid separator, where the first position of the exit path in the second periphery is in the part of the separate fluid exit path, and the The second is in the converging inlet path section of the fluid and by the tube of the second stage exit path the periphery of the cyclonic fluid separator is obtained. Connection to an additional fluid separator which is positioned towards the flow end of the separator. Cyclonic Flow 2. Cyclonic Fluid Separator according to Claim 1, where using the primary flow are obtained from the first position of the exit path in the second bowl. in which the mach number of the prime axis is equal to or more than one and the second flow is obtained from the second position where the mach number of the prime axis is lower than one, with the second position being upstream relative to the first position. Nick according to claim 2, where a large flow blocking area The maximum of the chyclonic fluid separator is /^a.c, and the transverse flow area of the separator Cyclonic fluid separator at the position of the tube of the periphery of the secondary exit path is A17, so then at the second position: page 2 of number 6 (Chemical formula). Claim 2, where a large flow cross-sectional area The best of the cyclonic fluid separators is Avm^v1, and the flow cross-sectional area of the cyclonic fluid separator is Cyclonic fluid separator at the position of the duct of the exit path in the second additional periphery is A26, then at the second position: (Chemical formula) 5. The cyclonic fluid separator according to one of the above preceding hold, where the tubes of the periphery exit paths are formed by providing an annular channel in The chyclonic separator housing 6. The chyclonic fluid separator pursuant to one of the preceding claims, which is further incorporated - the central body supplied is present. The upstream of the neck section of the fluid inlet path, with the central body arranged essentially coaxially with the axis of the fluid separator, to form an annular flow path between the bodies. In the center and housing of the separator, a cyclonic fluid separator is provided to support the cyclonic primary flow. Slice the part of the fluid inlet path that meets the rod and neck towards the part of the fluid inlet path. The fluid that separates the rod, where the central body consists of an exit path, directed towards the duct and ventral neck. Provided to fill the middle flow towards the neck, where at least part of at least one of the tubes of the second exit path. The periphery is connected tight to the exit path, in use, to provide a central flow. of the middle body is greater than the minimum diameter of the tubular neck. The center aligns significantly with the core and is bounded by the main flow, page 3 of number 6. 9. The cyclonic fluid separator according to one of the preceding claims, which comprises A number of additional secondary exit paths are positioned on the position. Each additional position along the axis of the cyclonic fluid separator 1 0. System for separating the liquid from the feed at the inlet path. which consists of the flow of Compressible fluid, a system consisting of a claim 1 cyclonic fluid separator and a fractional distillation column, in which - the periphery of the second stage exit path positioned on the first position is welded. connect to the first level within that fractional distillation column; and - the exit path in the second stage, an additional periphery that is positioned on the second position is connected. to the second level within that fractional distillation column, where the first position is upstream relative to the second and the first level is higher. The inlet is a compressible fluid flow, a system which is composed of a cooling system, a cyclonic-based fluid separator. Claim 1 and column of separation, where - the cooling system is provided to receive the feed at the 'inlet path and the feed output is made. Pre-cooling through the cyclonic fluid separator, - The cyclonic fluid separator is prepared to receive the pre-cooled feed. and produces a first-order output at the tube of the periphery of the second-stage exit path and an output feed. Second, where the pipeline of the second stage exit path further periphery towards the separation column, - the separation column is provided to produce the upper feeding of the separation column, where the system is provided for. Navigate at least part of the upper part of the Column of separation to the cooling system to cool the feed at the inlet path 1 2. Claims-based system 11, where the column of segregation is composed by the exit path. side and additional refrigeration unit, where the side exit path is connected to the refrigeration unit. additional to provide side draw to the refrigeration unit, refrigeration unit An additional refrigeration unit is provided to produce a cooled feed, page 4 of 6 pages, where an additional refrigeration unit is provided to receive at least one side suction. that is taken from during the cooling system and the column of separation, where the additional refrigeration unit is provided to use at least one of these side suctions to make the side suction taken from the cooled separation column, and where the cooled feed is introduced into another separation column 1 3. Method of liquid separation from compressible fluid flow This includes: - Arrangement of cyclonic fluid flow to cyclonic fluid separator. It consists of the converging fluid inlet path part, the throat part and the exit path part. sequentially separated fluids, - acquisition of the first flow from the periphery of the second exit path at the position the first along the axis of the chyclonic fluid separator, and - the acquisition of the third flow from the tubes of the inner exit path, where - the acquisition of the secondary flow Two from the exit path in the second periphery further. at the second position along the axis of the chyclonic fluid separator, where the first position is in The separate fluid exit path sections and the second position are located in the inlet trajectory section of the converging fluids and - feeding the first flow to the additional fluid separator which was positioned on the Flow end of the cyclonic fluid separator and get connected to the splitter Cyclonic fluids by the tubes of the periphery of the second exit path 1. 4. Method according to claim 13, where the primary flow is obtained from the first position where The specific axis mac number is equal to or lower than one and the second flow is obtained from the second position. where the mach number of the specific axis is lower than one, where the first position is upstream compared to the second position 1. 5. Claims 13 method, where the transverse area of the machine is the greatest flow separate The cyclonic flow is \R, and the transverse flow area of the cyclonic fluid separator is The location of the duct of the exit path in the second additional periphery is An, thus, at the second position: p. 5 of p. 6 (chemical formula) 1. 6. Claim method 13, where the cross-sectional area of The flow of the chyclonic fluid separator is A^1f, and the cross-sectional area of the chyclonic fluid separator at the position of the duct of the periphery of the secondary exit trajectory is then A26, then, at position two: (chemical formula) 1 7. Method pursuant to one of claims 13 to 16, where the trajectory tube The second exit The periphery is to be formed by providing an annular cavity in the housing of the cyclonic fluid separator 1. 8. Method pursuant to one of Claims 13 to 17, where it has been established. equip the body In the middle of the upstream of the neck section of the fluid inlet path, the central body is prepared. Essentially coaxial to the core of the fluid separator, forming a flow path. An annular shape between the center body and the separator housing, the assembly method includes: - The use of the cyclonic fluid separator to support the cyclonic main flow. through the converging fluid inlet trajectory section and the cervical towards the fluid exit trajectory section. separate flows, where the central body consists of an exit path, directed towards the cervical and tubular that is provided to fill the central flow towards the neck, where at least part of at least one of the tubes of the outer second stage exit path is connected to the exit path, in use, To provide center flow 1 9. Method according to claim 18, where, in use, the center flow is essentially synonymous with the core and is surrounded by main flow 2 0. a method pursuant to one of Claims 13 to 19, which comprises a number of of the exit path in the second stage, the additional periphery is positioned on each of the corresponding additional positions. Along the axis of the cyclonic fluid separator 2 1. Methods for separating the liquid from the feed at the inlet path consisting of the flow. Compressible Fluids, Method Using Claim 1 Cyclonic Fluid Separator and Fractional Distillation Column, Combination Method Page 6 of 6 - Determination via Solution Path In the second periphery the periphery is positioned on the first position where the flow is fed to the first level within the fractional distillation column, and - is obtained via an additional periphery second exit path. that was positioned on second position where the flow is fed to the second level within the fractional distillation column, where the first is upstream relative to the second and the first is high. Over the second level 2 2. Methods for separating the liquid from the deposit at the inlet path is a compressible fluid flow, a system incorporating a refrigeration system, a cyclonic fluid separator according to Claim 1 and the column of separation, where - the cooling system is provided to receive the feed at the inlet path and the feed output is made. cool down first To the cyclonic fluid separator, - The cyclonic fluid separator is provided to receive the pre-cooled feed. and produces the first output input and the second output input at the exit path pipe in Second, the outer periphery towards the separation column, - the separation column is provided to produce the upper feeding of the separation column, where the system is provided to navigate at least part of the separation. Entering the top of The column of separation to the cooling system to cool the feed at the inlet path 2 3. Method according to claim 22, where the column of separation consists of the exit path. Lateral and additional refrigeration units, where the method of assembly includes: - directing lateral suction from the column of separation via side outlet paths, - providing lateral suction to the refrigeration unit. additionally to produce cooled feed, - bringing at least one of the suction on the cooling side from during the system making Cooling and separation columns, - providing at least one suction on the cooling side to the refrigeration unit. to cool the side suction taken from the separation column, and - re-introduction of the cooled feed into the separation column ------------ 1. A cyclonic fluid separator consisting of a neck section (4), which is provided between the converging fluid inlet path section and the fluid outlet path section. A separate, cyclonic fluid separator is provided to support cyclonic flow through. The part of the fluid inlet path converges and the neck towards the part of the fluid path exit. Separated in the flow direction, a separate fluid exit path segment consisting of an internal exit path tube (7) for a condensed reduced fluid component and a condensed down flow tube. of the outer secondary exit pathway (6) for the condensed rich fluid component, characterized in which The cyclonic fluid separator consists of a tube of Additional periphery secondary exit path (16), periphery secondary exit path (6) positioned on the first position along the axis (I) of the cyclonic fluid separator and pipe of An additional peripheral secondary exit path (16) is positioned on the second axis along the axis (I) of the cyclonic fluid separator. 1, which is a large diameter The maximum diameter of the middle body (1) is greater than the minimum diameter of the tubular neck section (4). The second position lies in the separate fluid exit path sections. 4. The cyclonic fluid separator pursuant to one of the preceding claims, in which the periphery of the secondary path exit tube is additional. (36) shall be positioned in the periphery of the exit path tube in the second stage (6) The periphery of the secondary exit path (6) lies in the part of the exit path of the fluid at seperately and the second position lies in the confluence of the inlet paths of the fluid. The first is obtained from the first position of the exit path in the second (6), where the Mach number of the specific axis is equal to or greater than one, and the second flow is obtained from the second position where the Mach number of the specific axis will be lower than one, the second position may be countercurrent because Position one 7. Cyclonic fluid separator according to claim 6, in which the flow cross-sectional area The max. of the cyclonic fluid separator is A max. and the flow cross-sectional area of the machine. The cyclonic fluid separator is placed at the pipe position of the periphery of the secondary exit path in addition 17, A17, then, at the second position: A maximally < 2. A17 8. The cyclonic fluid separator follows the Claim 6, where the flow cross-sectional area The max. of the cyclonic fluid separator is A max. and the flow cross-sectional area of the machine. Separator cyclonic fluid at the pipe position of the exit path in the second periphery of the additional 26 is A26, then at the second position: A max < 2 and A neck < 1. A26 A26 9. Fluid separator. Cyclonic type pursuant to one of the preceding claims, in which the periphery of the secondary exit path tube is constructed by providing an annular channel in the presence of It is contained in the cyclonic fluid separator 1 0. The cyclonic fluid separator pursuant to one of the preceding claims, which is further incorporated - the center body (10) is supplied. A countercurrent occurs with the neck (4) section of the fluid inlet path, the central body (10) that is substantially provided in the axis together with the I-axis of the fluid separator, to form the path of the fluid separator. Flow in the ring (3) between the central body (10) and the existing separator (20), the cyclonic fluid separator is provided to support the cyclonic primary flow. through the converging fluid inlet trajectory section and the cervical towards the fluid exit trajectory section. A separate flow, in which the central body (10) is composed of an exit path (13), directed towards the cervical tube (4) and is provided to fill the middle flow towards the cervix. (4), which is at least part of at least One of the tubes of the periphery exit path (6,16) is connected to the exit path (13), in use, to supply the center flow 1. 1. Cyclo Fluid Separator Nick according to claim 10, in which, in use, the center flow is substantially synonymous with core I and is bounded. by primary flow 1 2. The cyclonic fluid separator pursuant to one of the preceding claims, which consists of a certain number of additional secondary exit pathways is positioned on the following. respectively along the axis (I) of the cyclonic fluid separator 1 3. The system for separating the liquid from the feed at the inlet path (S-1), which consists of Compressible fluid flow, a system consisting of a cyclonic fluid separator. According to claim 3 and fractional distillation column (COL-1), to which - the outer second stage exit path (6) that is positioned on the first position will be connected. to the first level inside the fractional distillation column (COL-1) and - the additional outer second-stage exit path (16) that is positioned on the second position will be Connected to the second level within the fractional distillation column (COL-1), the first position is countercurrent because the second and the first are lower than the second level 1. 4. System for liquid separation. Enter at the inlet path (S-1) that is the flow of Compressible Fluid, System including Cooling System (CS-1), Fluid Separator Claim 3 cyclonic and column of separation (COL), where - the refrigeration system (CS) is prepared to receive the feed at the inlet path (S-1) and yield it as a medium. The pre-cooled feed (S-4) goes through the cyclonic separator, - The cyclonic fluid separator is prepared to receive the pre-cooled feed (S-4). ) and will produce a condensable-rich first-order feedstock S-7 and a condensable-rich secondary feed S-8 towards the separation column, - column of Separation (COL) is provided to produce the separation column upper feeder (S-22), for which the system is provided to guide. at least part from the upper feeder of Column of separation (S-22) to the cooling system (CS) to cool the feed at the inlet path (S-1) 1. 5. System according to claim 14, where the column of separation (COL ) will consist of The exit path and an additional refrigeration unit (E-3), where the exit path side is connected to the refrigeration unit. Additional refrigeration (E-3) to supply side draw (S-18) to refrigeration unit (E-3), additional refrigeration unit (E-3) will be provided to produce refrigerant. The cooled feed (S-19) where an additional refrigeration unit (E-3) will be provided to receive At least one side refrigeration draw (S-12, S-13; S-15, S-16) taken from during the cooling system (CS) and column of separation (COL). , where an additional refrigeration unit (E-3) will be provided for this use. At least one side draw refrigerant (S-12, S-13; S-15, S-16) to cool the side draw (S-18) taken from Column of separation (COL), and where the cooled feed (S-19) is reintroduced into the column of separation (COL) 1. 6. Methods of liquid separation from compressed fluid flow. can This includes: - Procurement of cyclonic fluid flow to the cyclonic fluid separator. A cyclonic consisting of a converging fluid inlet path segment, a cervical part (4) and a separate fluid exit path segment respectively, - acquisition of the primary flow from an exit path. in the second periphery (6) at the first position along the axis (I) of the cyclonic fluid separator, and - the acquisition of the third flow from the tube of the primary exit path around the (7), characterized by - acquisition of a secondary flow from an additional peripheral secondary exit path (16) at the second position along the axis (I) of the cyclonic fluid separator. C1 7. Claim 16 method, in which the first and second positions are part of Separate Fluid Exit Paths 1 8. Methods for one of Claims 16 to 17, in which the tubes of the second stage exit routes An additional periphery (36) is positioned in the exit path tube in the second outer periphery (6) 1 9. Claim 16 method, in which the first trajectory is located in the exit path section of the periphery. The separate and second flows are located in the converging fluid inlet path section 2 0. Claims 16 method, in which the first flow is obtained from the first position where the Mach number of the dedicated axis is lower than one and the second flow is derived from the second position where the Mach number of the particular axis is equal or more than one, the first position may be countercurrent. because of the second position 2 1. Method according to claim 19, in which the largest flow cross-sectional area of the separator The cyclonic type flow is the most, and the cross-sectional area of the flow of the cyclonic type fluid separator. At the position of the tube of the exit path in the second stage, the additional hoist 17 is A17, then at the second position: (chemical formula) 2. 2. Method according to claim 19, in which the flow cross-sectional area of the cyclonic separator is A is the most and the cyclonic separator flow cross-sectional area at the position of the tube of the exit path in the second stage, the periphery of the additional 26 is A26, then at the second position: (chemical formula) 2. 3. Methods pursuant to one of Claim 16-22, in which the pipeline of the second stage exit route The periphery is formed by providing an annular cavity to be present in the cyclonic type 2 fluid separator. 4. A method pursuant to one of Claims 16-23, which is provided to form a counter-current (10) central body with a neck (4) in the part of the fluid inlet path, straight body. The center (10) is provided substantially in conjunction with the I-axis of the fluid separator, to form a flow path in the ring (3) between the central body (10) and the existing separator (20). ), the method will consist of: - the use of a cyclonic fluid separator to support the cyclonic primary flow through The part of the fluid inlet path converges and the neck towards the part of the fluid path exit. separate, in which the central body (10) is composed of an exit path (13), directed towards the cervical duct (4) and is provided to fill the middle flow towards the cervical ( 4), which is at least part of at least One of the pipes of the outer second stage exit path (6, 16) is connected to the exit path (13), in use, to provide center flow 2. 5. The method of claim 24, in which, in use, the middle flow may be synonymous with Significant to core I and may be surrounded by core flow 2. 6. Methods pursuant to any of Claims 16-25, which comprise a number of of the secondary exit path, the additional periphery is positioned on the following in order of position along the axis (I) of the cyclonic fluid separator 2. 7. Methods for separating liquids from feeds at the inlet path (S-1), which consist of Compressible fluid flow, method using Claim 16 cyclonic fluid separator and fractional distillation column. (COL-1), the method will consist of - acquisition via the outer second stage exit path (6) that is positioned on the first position. The flow, which is fed to the first level within the fractional distillation column (COL-1), and - is obtained via an additional outer secondary secondary exit path (16) that is positioned on the second position The flow, which is fed to the second level within the fractional distillation column (COL-1), position one is countercurrent because position two and level one are lower than second level 2. 8. A method may be provided for separating the liquid from the feed at the inlet path (S-1) as a compressible fluid flow, a system incorporating a cooling system (CS), a psycho-fluid separator. According to claim 1 and column of separation (COL), where - the cooling system (CS) is prepared to receive the feed at the inlet path (S-1) and yield as the feed at the inlet path (S-1) is pre-cooled (S-4) towards the cyclonic fluid separator, - The cyclonic fluid separator is prepared to receive the pre-cooled feed (S-4) and Remember to produce a condensable-rich primary feedstock (S-7) and a condensable-rich secondary feedstock (S-8) towards the separation column, - The Separation Column (COL) is provided to produce the upper feed of the Separation Column (S-22), which the system is provided to guide. at least part from the upper feeder of Column of separation (S-22) to the cooling system (CS) to cool the feed at the inlet path (S-1) 2. 9. Claim method 28, in which the column of separation (COL) shall consist of The exit path and an additional refrigeration unit (E-3), which the method will consist of: - removal of the side draw (S-18) from the column of separation (COL) through the exit path side, - supply. Generate side draw (S-18) to additional refrigeration unit (E-3) to produce feedstock. refrigerated (S-19), - bringing at least one refrigerant side draw (S-12, S-13; S15, S-16) from between the cooling system (CS) and the column of Isolation (COL), Procurement At least one side draw refrigerant (S-12, S-13, S15, S-16) to the refrigeration unit (E-3) to cool the side draw (S-18). are taken from the column of separation (COL), and - reintroduction of the cooled feed (S-19) in the column of separation (COL).