• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A separation vessel to separate an impurity from a contaminated liquid. A series of adjacent interconnected chambers, a series of baffles therein, provide a revolving flow of fluid in each chamber to maximize distance for the impurities to separate object from the liquid. The interconnected chambers may be juxtaposed in an end-to-end relationship or in a side-by-side configuration.
    公开号:AT517984A2
    申请号:T9529/2014
    申请日:2014-08-11
    公开日:2017-06-15
    发明作者:
    申请人:Exterran Water Solutions Ulc;
    IPC主号:
    专利说明:

    FIELD OF THE INVENTION
    The present invention relates to ships / tanks for contaminants or unwanted phases of liquids such as water generated while well separating drilling operations.
    BACKGROUND OF THE INVENTION
    Secondary Phase Separation Vessels / tanks are used to separate unwanted minor phases or impurities, such as hydrocarbons made from water, and usually work by facilitating them or the rise of unwanted phase (s) or impurities on the surface of the generated water. The undesirable phases or contaminants can then be removed by skimming off the surface of the generated water.
    Examples of Secondary Phase Separation Vessels / tanks include: -API separators employing gravity-based separation techniques; -induced gas flotation (IGF) devices that inject gas bubbles into separation phases and contaminants to aid in use; and -induced static flotation (ISF), which also gas bubbles to help separate into phases and impurities.
    One of the problems with the latter two types of secondary phase separation vessels / tanks is that they do not allow sufficient time to self-secure the time for effective distribution of gas bubbles within the contaminated liquid and time for such gas bubbles natural agglomeration to impurities or unwanted phases then cause or bring such impurities or unwanted phases to the surface for subsequent removal by skimming by flotation.
    In particular, in the case of the latter two types of secondary phase separation vessels / tanks, gas bubbles in the center of a chamber are typically introduced via a pipe (referred to as a gasification stirrer pipe and a gasification stirrer process), or generated mechanically via motor driven paddles. Such methods of introducing gas bubbles into the center of the chamber reduce the likelihood of contact of gas bubbles with contaminants that may be placed in the center of the chamber.
    In addition, existing prior art tanks typically are designed to allow contaminants to float through the surface of the tank due to different specific gravity between, for example, oil and water, and / or to allow agglomeration of gas bubbles to become impurities that cause such impurities to the surface to ascend the tank. Both techniques then allow skimming off the surface of the tank of contaminants and resulting cleaning of the remaining liquids (leaving the cleanest liquid in the bottom of the tank / container). However, both technologies transmit more fluid from the bottom of the chamber (ie, the cleanest fluid in the chamber is in the bottom of the chamber) when such fluid is transferred to another subsequent chamber to repeat the process and for subsequent successive purification transfer into one process which can be called "bottom-to-bottom" flow. Problematic with bottom flow, if such a liquid is then transferred to a bottom of a subsequent chamber (namely, an area where the cleanest fluid should be in such subsequent chamber), then such "water" may be used to "short-circuit" such water again from the subsequent chamber to allow yet another subsequent chamber (ie down to the lower flow) without sufficient residence time in each chamber from it by gas flotation or specific gravity separation removal of impurities.
    Also problematic in such "down to the bottom flow is the so-called" dilution effect ", namely that upon injection of fluid (ie the cleanest fluid) from a first chamber into a second consecutive treatment chamber (where such cleanest fluid cleaned from such a first chamber effectively the contaminated fluid in the second chamber) such liquid is injected into the bottom of the second chamber, where the cleanest fluid is typically located. This 'dilution' effect is thereby undone, to some extent, phase separation already achieved, and adds required residence time to promote effect separation. US 5,766,584 teaches a tank has an inlet baffle, and the provision in FIG. 1 thereof includes skimming means 30 and weir to scoop and collect contaminants from the surface, or alternatively simply collect a weir contaminant from the surface. However, US 5,766,584 fails to teach apparatus and a method that can be easily adapted for sequential treatment across a series of chambers, that it merely teaches a treatment tank from the same side of the tank to both introduce and remove fluid, which is problematic is to provide for use in a compact juxtaposed series of chambers for the sequential treatment of fluids.
    Accordingly, improved separation vessels / tanks that avoid the shorting problem and the associated "dilution" problem, which facilitate better pollutant gas bubble contact during a liquid treatment, and which allow it to continue for a compact arrangement of the chambers for successive Treatment of fluids are required accordingly.
    SUMMARY OF THE INVENTION
    The present invention seeks to provide a separation vessel for removal of a contaminant from a fluid, or for a phase of a multi-phase fluid that enters into the tank, which avoids or reduces the aforementioned "short circuits" and dilution problems and better gas contamination Facilitated contact and agglomeration.
    Accordingly, in a first broad aspect of the present invention comprising removing a contaminant from a liquid or separating a phase from a multiphase fluid, the input to the tank, the tank comprises: a bottom, a bottom, the defined tank and each wall defining the sides of the container; a plurality of interconnected chambers within the tank to successively treat the treatment liquid; an inlet in fluid communication with a first chamber of the plurality of chambers for fluid input to comprise one or a plurality of phases, the first chamber; and an outlet in fluid communication with a last chamber of the plurality of adjacent chambers, for dispensing reduced contaminant liquid or substantially only a single phase, the outlet proximate a bottom of the last chamber of the plurality of adjacent chambers; an inclined weir in an upper region of each of the chambers said to induce for a rotational flow of the fluid within each of the chambers; the skimming weir in an upper portion of each ply of the chambers substantially opposite the location of the inclined weir-a-skim sump in communication with a plurality of interconnected chambers and separated from an interior of said plurality of chambers by a skimming weir, wherein the plurality of chambers in that, along an upper surface of the chamber, the rotational flow of the fluid causes movement of the fluid from the inclined weir toward the lean sump; and a communication passage such that fluid flow from substantially a bottom of at least one chamber in an upper region of an adjacent chamber and in the direction of the sloped weir in the adjacent chamber, wherein communication passage within the at least one chamber such that fluid flow of wherein the at least one chamber with the connection passage is not in the direction of the rotational flow of the fluid into the at least one chamber.
    In preferred embodiments, the communication passage from the at least one chamber is fitted into an upper region of an adjacent chamber of output liquid, thereby avoiding "bottom to bottom" flow and thus the above-mentioned "shorting" problems.
    A gas inlet in fluid communication with the connection passage of the at least one chamber is preferably provided to introduce a gas into the liquid from which a chamber is transferred to the adjacent (juxtaposed) chamber via the connection passage. In a further preferred embodiment, where there are a plurality of communication channels between pairs of adjacent (juxtaposed) chambers, the tank will continue to communicate with a gas inlet communicating with each of the connection channels of the gas chambers into the fluid which causes the introduction of a chamber in the adjacent chamber via the connection passage transfer.
    In a further preferred embodiment, the communication passage is narrower in cross-section than the chambers for providing a higher gas to liquid ratio in the communication chamber than if the gas were introduced directly into one of the series of adjacent chambers.
    In a further preferred embodiment, an inlet end of each (or) the connecting passage is disposed substantially below the inclined weir of a corresponding chamber, and a lower side thereof is adjacent. Alternatively or additionally, the inlet end of the communication passage between at least one chamber and an adjacent chamber may be disposed in the at least one chamber on a wall thereof, the wall having an opposite side thereof adjacent to the inclined weir in a successively contained adjacent fluid-flow chamber Connecting passage does not exercise in one direction of rotation in the at least one chamber flow.
    In order to avoid fluid flow to the communication passage not being imparted in the at least one chamber in a direction of rotational flow (thereby avoiding or reducing "shorting" problems), scarfing is preferably provided to partially block the inlet end of the communication passage, fluid to cause it to flow in a direction transverse to or at least different from that of the rotational flow.
    Each chamber, except possibly the last chamber from which the treated water is removed, is provided with a lean oil sump in communication with the chamber.
    In a preferred embodiment, the lean sump is a common lean sump associated with a plurality or all of the chambers.
    In another preferred embodiment of the separation vessel of the present invention, to provide transportability and ease of transportation, the tank is contained within a transport container.
    In one embodiment, the plurality of interconnected chambers are arranged in mutual juxtapositional configuration, and wherein an inlet end of the communication passage is positioned substantially below the inclined one of the one chamber near a bottom of each of the series adjacent chambers.
    In another embodiment, the plurality of interconnected chambers are disposed in end-to-end mutual configuration, which further includes a shield below the positioned one of chambers in the plurality of skimming portions to partially block the inlet end of the communication passage with the communication passage at a location below the shield and a fluid flow from substantially one floor at least one chamber at said location to an upper portion of an adjacent chamber and in the direction of the inclined weir into adjacent chamber.
    In another embodiment, the plurality of interconnected chambers are arranged in a mutual end-to-end configuration, and are further in side-by-side juxtaposition configuration. In this way, successive chambers aligned in an end-to-end manner, one fluid can treat one after the other, with further chambers arranged in juxtaposed position, to similarly treat successively further inlet streams.
    Finally, in another embodiment, the phase separation vessel may contain, in a lower region of at least one of the chambers, a filter medium which, in a preferred embodiment, the filter medium is treated to provide a non-solid granular material, such as granular pellets or walnut shells, filtration of the fluid ,
    A variety of radial nozzles are located within the filter bed. The radial nozzles may disperse a gas or liquid to cause the filter media during a backwash cycle to provide sufficient turbulence and movement of the filter media granules to rid the trapped contaminants without the need for high fluid flow rates. The number of nozzles and their placement within the filter bed will depend on factors such as the size and shape of the filter container and the type of filter media, similar to the configuration and positioning of the radial nozzles as taught and disclosed in Canadian Patent 2,689,487.
    BRIEF DESCRIPTION OF THE DRAWINGS
    The accompanying drawings illustrate one or more embodiments of the present invention and are not to be construed as limiting the invention to these illustrated embodiments. The drawings are not necessarily to scale and are readily illustrated in the concepts of the present invention.
    Fig. 1A is a schematic illustration of an isometric front view of a secondary phase separation tank of the present invention, namely the so-called "VSL" embodiment in which the outer wall has been removed to allow viewing of the inner chambers;
    Fig. 1B is a schematic illustration of the embodiment of the secondary phase separation tank of Fig. 1A with the outer wall being present;
    Fig. 2 is a schematic illustration of the embodiment of the secondary phase separation tank of Figs. 1A, 1B, wherein the components of the tank are translucent to allow view of the various components;
    Fig. 3 is a schematic illustration of the embodiment of the secondary phase separation tank of Figs. 1A, 1B of the rear view of the container;
    Fig. 4 is a flowchart of fluid flow through the secondary phase separation tank of Figs. 1A, 1B;
    Fig. 5A is a schematic illustrative of a secondary phase separation vessel such as that shown in Figs. 1A, 1B in a portable sea container;
    Fig. 5B is a schematic cut-away illustration of a secondary phase separation vessel, such as that in Figs. 1A, 1B, in a portable shipping container;
    Fig. 6 is a schematic illustration of an isometric front view of another embodiment of a secondary phase separation tank of the present invention, namely the so-called "VS" embodiment in which the outer wall has been removed to allow viewing of the inner chambers;
    Fig. 7 is a schematic illustrative rear left side isometric view of the embodiment of a secondary phase separation tank in Fig. 6 with the outer wall removed to allow viewing of the inner chambers;
    FIG. 8 is a schematic illustrative rear right side isometric view of the embodiment of a secondary phase separation tank of FIG. 6 with the outer wall removed to allow viewing of the inner chambers; FIG.
    Fig. 9 is a schematic illustration of a left side of the embodiment of a secondary phase separation tank in Fig. 6 with the outer wall removed to allow viewing of the inner chambers;
    Fig. 10 is a schematic illustrative right side of the embodiment of a secondary phase separation tank in Fig. 6 with the outer wall removed to allow viewing of the inner chambers;
    Figure 11 is a schematic illustrative of a right side of another embodiment of the invention, similar to the embodiment of Figure 10, with the outer wall removed to allow viewing of the inner chambers;
    Figs. 12 and 13 are flowcharts showing fluid flow through the secondary phase separation tank of Figs. 6 and 11;
    Figures 14 and 15 are schematic illustrative of a secondary phase separation vessel, such as that shown in Figures 6 and 11, within a portable sea container;
    Fig. 16 is a perspective view of yet another embodiment of the secondary phase separation vessels of the present invention wherein successive chambers are aligned in an end-to-end manner for successively handling a fiddle with further chambers disposed in juxtaposed relation thereto successively treating a plurality of inlet streams (hereinafter called the successive plural version or "SPV" version);
    Fig. 17 is a sectional view along the plane R "- 'R' of Fig. 16 taken along a longitudinal plane 'R' - R '' through a series of longitudinally aligned successive chambers;
    Fig. 18 is a cross-sectional view of another embodiment of a secondary phase separation tank and the method of the present invention further comprising filter means which may comprise and include in the embodiment a non-solid media filter bed; and
    FIG. 19 is a similar cross-sectional view of a slightly modified form of the invention in FIG. 18. FIG.
    DETAILED DESCRIPTION OF SOME PREFERRED EMBODIMENTS OF THE INVENTION
    In a non-limiting embodiment, a secondary phase separation tank 10 is provided for removing impurities including an undesirable phase from an input fluid, for example, water. The separation vessel 10 has a bottom and walls that generally define the container. Inside the tank, a series of chambers is divided by dividing walls. In communication with each chamber is a lean oil sump into which contaminant or unwanted phase is skimmed off. The lean oil pan is separated from the chamber by an oil skirin weir over which the contaminants or unwanted phase passages where it is then trapped in the lean oil pan. Fluid input into the tank passes from chamber adjacent chamber as contamination is gradually removed. In each chamber, a sloped weir creates a longitudinal three-way flow which generally increases the path (and thus the residence time) of the fluid in each chamber before the fluid passes into the adjacent chamber. The stream also promotes any lighter than liquid impurities to rise to the surface, being skimmed off over the oil skimming weir and away. As fluid is passed from chamber to adjacent chamber, it is removed from a bottom portion of the first chamber and directed into an upper portion of the adjacent (sequential) chamber.
    In various embodiments of the separation vessels, the chamber and inclined weir are of suitable orientation and spacing to produce a three-phase flow within the chamber which comprises a longer horizontal component then prior designs or a longer horizontal component comprising a vertical component, the horizontal movement of the liquid and Particles by increasing and providing a longer path for the particles to increase unwanted particles, resulting in a longer time to remove the surface for removal and the unwanted impurities will thereby rise when skimmed, more effectively removed from the fluid. In particular, the longer path around the particles gives longer actual residence in a chamber, as well as an increased likelihood (over the longer path and being brought to the surfaces) to adhere to a bubble, thereby separating the horizontal component of the rotational flow Increase, for example, can be achieved by changing the ratio of the length of the chamber and the height of the inclined weir. In addition, injecting the purified water from the bottom of the chamber, and avoiding it in the upper area of the adjacent successive chamber, or at least greatly reducing the "shorting" problem to inject.
    To further promote the undesirable phases rising or impurities on the surface, gas can be introduced into the chambers. As is typically seen, the gas, such as methane, air or nitrogen, is dispersed in the liquid and forms bubbles or microbubbles which adhere to the contaminant so that it is easier than the liquid to convey to the surface. The gas, which is lighter than the liquid, rises toward the surface of the liquid adhering to the contaminant. Again, as the horizontal component of the rotational flow increases, the bubbles or microbubbles are promoted into effective contaminants on the surface of the liquid for removal as the residence time is increased. Further, due to induced within each chamber the induced rotational flow, such as a hydraulic pressure that may possibly help in skimming, the need for mechanical skimming means avoiding such skimming, thus avoiding increased costs of mechanical skimming, avoiding maintenance and possibly mechanical Failure thereof in contamination or secondary phase entails re-entrainment.
    All chambers, perhaps the last chamber in the sequence of chambers store, which only remove an outlet of the treated fluid, are connected via a connecting channel between each chamber. Fluid from a chamber passes to an adjacent chamber via the communication passage. To further promote cleaner or less contaminated liquid to the next adjacent chamber, the connection passages have their inlet near the bottom of the chamber where the cleaning liquid tends to become, thereby increasing fluid acquisition with less contaminants than the contamination in the chamber on the surface , The fluid is then directed into the adjacent chamber for further decontamination / phase separation. When the fluid is transferred to the adjacent chamber, generally more contaminant than the fluid in the adjacent chamber is the communication chamber entrance the fluid in an upper region of the adjacent chamber where impurity concentration is higher on a lower or bottom region of the adjacent chamber ,
    To promote further attachment of the gas to the contaminant or minor phase to cause it to separate from the liquid (typically water), control over the directional flow and location of injection of the gas is important. In particular, the gas is liable to adhere to the contaminant when the velocity and direction of the inlet flow of the gas are similar to the velocity and flow direction of the fluid. In this way, prior devices and methods that do not attempt to align with the gas injection flow of the fluid and merely introduce, for example, the gas in the central region of the chamber are inferior. Accordingly, to promote adherence of the gas to the contaminant or minor phase, and to influence the flow path of the gas, to be the liquid in the present invention, and more particularly in the VSL embodiment described herein, the gas is between two adjacent parallel chambers placed in a connecting passage in the first chamber is low, when such gas and gas bubbles can then rise when traveling into the second chamber with the fluid flow therein to the surface and adhere to impurities and / or secondary phase at the surface, and prevent she skimming with the continuous circuit in the second chamber of the journey, which would then be traveling downwards, thus skimming on the surface. The orientation of the gas flow into the fluid is injected, and the fluid and impurities and / or minor phase therein cause greater ability of the gas bubbles to adhere to such particles, impurities or secondary phase within and retain the surface. It is desirable to flow the gas parallel to the fluid flow at such location, promoting adhesion to contaminants and / or minor phase.
    As will become apparent, the gas may be introduced into all or some of the connecting passageways. It is within the scope of the invention that the communication passages are smaller in cross-section and in cross-section than the chambers themselves, and further, the communication passages of various sizes, shapes or orientations can be chamber to chamber. Further, in each chamber with the connection channels used can be a variety of gas injection sites. Further, out of the connecting channel, which exits the outlet of the connecting channels in appropriate proximity to the inclined weir of the adjacent chamber, can impart a rotational flow in the liquid.
    Example 1 - First Embodiment ("VSL")
    In one embodiment best shown in FIGS. 1A, 1B, 2, 3, hereinafter: "VSL" embodiment is a secondary phase separation tank 10 for removing impurities, such as hydrocarbons, drilling fluids and / or fracking fluids, and those on them Way may include liquids of different specific gravity, viscosity and miscibility as compared to water. Separating tank 10 has a bottom 50 and floating walls 40 defining a series of chambers 100, each chamber 100 being separated from an adjacent chamber by a dividing wall 105. It will be appreciated that although the tank 10 in Figures 1A-5B includes four chambers 100, the tank 10 is less or more
    Chambers 100 and the separation vessel may contain 10 should not be limited to only four chambers 100.
    In conjunction with each chamber is a lean oil weir 70, which additionally serves as a weir continues to serve a lean oil sump 60 to separate from each chamber 100. Surface contamination in each chamber 100 is removed by skimming over the lean oil weir 70 into the skim oil sump 60, which may then be detected, and / or removed as desired using conventional methods and means. The lean oil weir 70 in the embodiments of FIGS. 1A to 5B is a municipal lean oil sump 82 that has a single lean sump adjacent all the chambers of the vessel 10.
    To impart a longitudinal rotational flow in each chamber 100, wherein each chamber 100 includes a beveled weir 90. The nature of the inclined weir 90 exerts a rotational flow to the fluid within each chamber 100. The rotational flow of the fluid in the chambers 100 can be seen in the flow chart in FIG. 4th
    Each chamber port 100 is a connection channel 80. The connection channel 80 has an inlet portion in fluid communication with a lower portion of a chamber 100 and an outlet portion in fluid communication with the adjacent chamber. In the illustrated embodiment 80, the passageway communicating the outlet with an upper portion of the adjacent chamber is adjacent to the inclined weir 90 of the adjacent chamber imparting a three-phase flow to the fluid inlet into the adjacent chamber 100. Further, the communication passage has the outlet portion in the upper portion of the adjacent chamber, as generally in each chamber, the liquid has a higher concentration of impurities in the direction of the surface and less contaminated down. By removing the chamber fluid mold 100 at or near the bottom of the chamber 100 and the fluid in an upper area of the adjacent chamber entering liquid of a lower concentration of impurities on the adjacent chamber in the area of highest contamination existed for the chamber. This reduces or eliminates so-called "shorting" and also facilitates removal of contaminants or by-pass over the lean oil weir 70.
    The separation vessel 10 also includes a fluid inlet 20 in communication with the first chamber of the series of interconnected untreated fluid chambers 100 in the tank 10, such as water prepared for input, which typically contains hydrocarbons as an impurity. To remove decontaminated liquid from the tank 10, an outlet 30 in communication with a lower portion of the last chamber of the tank 10 is used. If the fluid from each chamber to the bottom 100 is closer in general to contain a lower concentration of impurities, it is suggested that the output be positioned in a lower portion of the last chamber.
    As shown in Figs. 1B, 2 and 10, the separation vessel includes gas inlets 120 80, a gas into the connection channels for introduction. In the first chamber 100 with the input 20 or next to the input gas 20 are introduced. In later injection sites, the gas can be injected into the connection channels 80. By injecting gas, such as air or nitrogen, into the communication passages 80, the gas tends to adhere to impurities in the liquid. This is presumably because the volume of the liquid passing through the communication passages 80 is smaller than the volume in the chamber 100 and thus the volume ratio of gas to liquid in the communication passage 80 is much higher than when the gas is injected directly into each one Chamber 100. Also, the flow of fluid through the communication passageway is typically in a uniform direction, and thus the gas flow will pass a flow pattern similar to that of fluid passing through communication passageway 80. The gas is more likely to adhere to the contaminants in the liquid when the flow patterns of the gas and the liquid are similar. In addition, by introducing the gas into the communication passageways 80, dense packing of bubbles rather than distribution of the bubbles would be observed as if gas introduction steering into the chamber creates a higher likelihood of contamination or spurious contact with a gas bubble. All of the fluid exits each chamber 100 past the next chamber 100 passes through this packed zone of gas bubbles while, if otherwise centrally introduced into the chamber 100 the gas over a larger fluid volume, particles scatter a lower probability of adhesion to a gas bubble.
    As shown in FIG. 1A, the separation vessel 10 also includes a drain hole 110 in the bottom of the partitions 105 to facilitate emptying of the tank 10 when required.
    The residence time in the separation vessel 10 may be adjusted as needed based on the amount of contaminants in the influent, the degree of decontamination desired, the number of chambers, the flow rate of the fluid, etc.
    The tank 10 may be placed in a portable sea container, such as in Figs. 5 A and 5B, to facilitate the transport of the separation tank 10. As shown in. 5B, the associated pumps, piping and ancillaries of the tank are necessary for the input and output of fluid, entering gas, for example, can also be detected within the portable sea container, as shown at 140.
    Example 2 - Second Embodiment ("VS")
    An alternative embodiment of a phase separation vessel will be shown with reference to Figs. 6-15 and is shown generally at 200. As opposed to the VSL layout of the tank 10 with reference to FIG. 5B separation shown in FIG. 1A, the VS tank 200 210 is placed in end-to-end relationship of a series of chambers. Again, the tank 200 is defined by a floor 320 and walls 310 pending. Each chamber 210 is separated by a partition wall 220. Likewise, each chamber 210 has an inclined weir 230 to induce the flow of rotational fluid in each chamber. The flow pattern of the input fluid can be seen in Figures 11 and 12.
    Further, each chamber 210 205 is connected via a communication passage to the adjacent chamber. However, the communication passage 205 is defined by a gap at the base of each partition 220 and the bottom 320 through which fluid can pass. A partition plate 290 separates the chamber 210 from the dividing wall and serves to define an inlet into the connecting chamber. Fluid flows over the divider plate 290 and enters through the gap at the base of the divider wall in front of the adjacent chamber via the rear side and then on top of the inclined weir 230 of the adjacent chamber.
    In a variant of this embodiment, it is best shown in FIGS. 6-10, with each chamber 210 having an individual skim sump 240 separated from the chamber 250 by a lean oil weir received in the skim oil sump 240. A contaminant outlet tube 300 in fluid communication with each of the lean oil pans 240 allows for retraction of the collected contaminants in each oil pan 240. It is understood that any suitable means of contamination from the lean oil pans may be used to remove 240.
    In another variant of the "VS" configuration in FIG. 11 (FIG. 11 is a schematic illustrative of a right side of the "VS" configuration with the outer wall removed to allow viewing of the inner chambers 210), such a design sets up a common drip pan 252 for collecting contaminants or separate phase from each chamber 210, and overflowing such common collection well 252 in fluid communication with each oil pan 242 for each chamber 210.
    Another distinguishing feature of the tank 10 is that the communication passage 205 collects generally non-aligned with the rotational flow direction of the fluid at an inlet region as fluid enters the bottom of the chamber opposite the inclined weir 230. To prevent liquid from entering from the top and just past the separation plate 290 in their rotational flow patterns, a baffle 330 is used to partially block the opening at the top of the separation plate 290. This increases the residence time of the fluid in each chamber 210 and increases the effectiveness of the gas introduced into the chamber to bring the adhering contaminants and impurities to the surface for removal above the lean oil. Similarly to the tank 10 in FIG. 1A of FIG. 5B, 280, a gas inlet in the communication passage 205 for injecting a gas such as air or nitrogen is positioned in the communication passage 205 for mixing with the liquid as passing through the communication passage 205. As stated above, a better control of the flow of the gas by introducing the gas in the communication passage 205 than the volume of the fluid reached in the communication passage 205 is reduced as compared to the chamber 210. By introducing the gas in the communication passage 205, the Gas has a greater tendency to follow a similar flow pattern than fluid, once it is introduced into the adjacent chamber and hence the effectiveness of the gas to adhere to the contaminants in the liquid is increased. During operation, fluid enters the first chamber in fluid inlet 270 into an upper region of the chamber 100 and is output from a lower portion of the last chamber 100 of the container 10 at an outlet 260.
    As in FIGS. 6-10, each communication passage 205 has an inlet 280 of gas in each of the communication passageways 205 for injection. Gas may be injected into the inlet 270 or adjacent thereto into the first chamber.
    As fluid flows from the chamber adjacent chamber, impurities rise on the surface and above the lean oil weir 250. Fluid to the bottom of each chamber 210 has a lower concentration of contaminants, the liquid toward the top of each chamber 210. As the communication passage 205 fluid from towards the bottom of the chamber 210 fluid from the chamber moves past the adjacent chamber has a lower concentration Impurities as the chamber from which it came. In this way, the fluid is gradually decontaminated as it passes from the chamber to adjacent chamber through the communication passages 205, injecting gas, and adheres to contaminants in the fluid. Fluid flows through the chambers 210 at the front of the container and then enters the rear chamber because the third chamber is shown in the sequence of chambers, where the fluid then comes back towards the front of the container and through the remaining chambers.
    The rear chamber is more apparent in Figs. 8-11, where it can be seen because the liquid changes direction back toward the front of the container 200, the connecting passage 205 does not contain a partition plate 290, but the fluid the rear chamber from the adjacent chamber flows under an intermediate bottom 295 and under the partition to separate, where gas is then injected into the connection passage 205. Further, the rear chamber does not include a deflector 330, which is not required in view of the orientation and inlet shape and position of the connecting passage 205. The fluid flow pattern through the tank 200 with the rear chamber is shown in FIGS. 11 and 12.
    It should be understood that although tank 200, as with five chambers 210 (best seen in FIG.
    As can be seen in Figures 6-8), the tank 200 may contain fewer or more chambers 210 as desired or required.
    In an alternative embodiment to that in FIGS. 6-10, and as shown in FIG. 11 (FIG. 11 is a schematic illustrative right side of the embodiment of a secondary phase separation tank shown in FIG. 6 with the outer wall removed to allow viewing of the inner chambers) a common skim sump 252 may be used and in the center of the tank Contaminant from skimmed oil pans 242 is positioned to the associated adjacent chambers 100. The chamber 100 at the rear end of the container 200, as the third chamber is shown in the illustrated embodiment, generally still requires its own skim sump 242.
    As with the tank outlined above with respect to Example 1, the container 200 may also be stored in a portable transport container 350 as shown in Figs. 15 are placed to facilitate transport of the tank 200. As shown in Fig. 14 of the & 15, the associated pumps, piping and ancillaries of the tank necessary for the input and output of fluid, entering gas, for example, can also be trapped inside the portable transport container.
    It will be understood that although the term "decontaminated" is used herein, use of this term should reflect a reduction in the concentration or amount of impurities in the liquid when liquid is introduced, as compared to when the fluid exit from the container is used and not that all contaminants will be removed to be laid out. Trace amounts or even small amounts of impurities may remain in the fluid. Contaminant reduction based on retention time, the number of chambers in the container, the flow rate, etc.
    Further, although the inclined weirs 90, 230 of the tanks 10 are shown generally in a similar position within each chamber 100, 210 and the tanks 10, respectively, the inclined weirs 90 may be positioned 230 and 230 at different depths Orientations in each chamber.
    Fig. 16 and the cross-sectional view in Fig. 17 taken along the plane 'R' - 'R' of Fig. 16 shows embodiment of the container 10 of the present invention comprises: - A first plurality of interconnected chambers 210a, 210'a and 210th "a; - - a second plurality of interconnected chambers 210b, 210'b urid 210" b; A third plurality of interconnected chambers 210c, 210'c and 210 "C, - a fourth plurality of interconnected chambers 210d, 210'd, 210 and" d; A fifth plurality of interconnected chambers 210e, 210'e and 210 "e; and - a sixth plurality of interconnected chambers 21of, 210'f and 210" f, each of the three elements of a corresponding plurality of interconnected chambers in FIG mutual end-to-end configuration are arranged. Each 3-member plurality of interconnected chambers is further arranged in mutual side-by-side relationship with an adjacent series of interconnected chambers.
    In this way, a plurality of successive chambers 210, 210 'and 210 "(in this case three), may treat a plurality of inlets sequentially streams a, b, c, d, e and f, the tank 10 via respective input ports 270 af on intake manifold IM ".
    Purified flow, at least one phase separated from this, leaves tank 10 via respective outlet openings 260a-f which are common in 'manifold outlet flow area'. A common trough 277 may be provided along one side of the tank 10 to separately collect secondary phase collected from each skimming trough 240a-f, 240 "a-f and 240" a-f.
    Fig. 17 shows a cross-section along the plane R "- 'R' of Fig. 16, and in particular a longitudinal cross-section through the second plurality of interconnected chambers 210b, 201" b, 210 and "b, shields 290b, 290'b, 290 and "b and 330b, 330'b and 330" b are at the respective locations of the communication passages 205, 205 'as well as at the exit port 260b to ensure fluid flow to each respective communication passage 205, 205' and exit port 260b is in one direction the rotational flow is not imparted in respective chambers 210b, 210'b and 210 "b, to reduce" short circuits "flow as discussed earlier herein.
    FIG. 18 shows a modified separation tank 1000 of the present invention that may include the single chamber 210 in FIG. 18 or a series of such chambers 210 are in fluid communication (sequentially connected to each other) for the successive treatment of a fluid. A filter device, in the form of unfixed media such as pelletized granules or black walnut shells 370, is provided in the lower portion of the chamber 210. Inclined weir 230 mediates a direction of rotation to be treated fluid, shown in the direction of the arrow. Treated water, skimmed off a secondary phase, by weir 240 is withdrawn through the filter means 370 and then removed from the exit port 260 and possibly to another similar modified tank 1000 for subsequent further treatment of such fluids.
    Finally, Fig. 19 shows a similar separation tank 1000 filter device in the bottom of the chamber 201. Filter media 370 in the form of non-fixed media such as pelletized granules or black walnut shells 370. In the embodiment shown, a plurality of radial nozzles 372 are obtained via a purge fluid Pressure line 374, useful during a backwash cycle for such separation vessels, may re-fluidize contaminants that have connected the filter means 370 thereby subjecting them to further skimming such contaminants during a backflush cycle of the vessel 1000. Upon completion of the backwash cycle and the delivery of a cleaning fluid nozzle 372 to radial, the earlier methods impart a rotatioinal flow when the liquid is resumed into the chamber 210 via inlet 230, the treatment process may resume.
    Although not shown in the figures, it will be appreciated that additional water piping, piping, pumps, and accessory operations, the tanks disclosed herein may be required for operation, which are commonly used and would be known. These additional components are contemplated and their use and incorporation are within the scope of the invention. Other medicaments and changes obvious to one skilled in the art can be made to the tanks disclosed herein and such modifications and alterations are disclosed within the scope and spirit of the invention.
    权利要求:
    Claims (15)
    [1]
    claims:
    A separation vessel for removing an impurity from a liquid or separating a phase from a multiphase fluid, the input to the tank, the tank comprising: a bottom defined, the sides of the container defining a bottom of the container and depending on walls; a plurality of interconnected chambers within the tank to successively treat the treatment liquid; an inlet in fluid communication with a first chamber of the plurality of chambers for fluid input to comprise one or a plurality of phases, the first chamber; and an outlet in fluid communication with a last chamber of the plurality of adjacent chambers, for dispensing reduced contaminant liquid or substantially only a single phase, the outlet proximate a bottom of the last chamber of the plurality of adjacent chambers; an inclined weir in an upper region of each of the chambers said to induce for a rotational flow of the fluid within each of the chambers; the skimming weir in an upper portion of each ply of the chambers substantially opposite the location of the inclined weir-a-skim sump in communication with a plurality of interconnected chambers and separated from an interior of said plurality of chambers by a skimming weir, wherein the plurality of chambers in that, along an upper surface of the chamber, the rotational flow of the fluid causes movement of the fluid from the inclined weir toward the lean sump; and a communication passage such that fluid flow from substantially a bottom of at least one chamber in an upper region of an adjacent chamber and in the direction of the sloped weir in the adjacent chamber, wherein communication passage within the at least one chamber such that fluid flow of wherein the at least one chamber with the connection passage is not in the direction of the rotational flow of the fluid into the at least one chamber.
    [2]
    The phase separation tank of claim 1, wherein the communication passage from the at least one chamber is adapted to an upper portion of an adjacent Kaminer output fluid.
    [3]
    The phase separation tank according to claim 1 or 2, further comprising a gas inlet in connection with the communication passage of the at least one chamber for a gas to be introduced into the liquid from the at least one chamber into the adjacent chamber via the transferred communication passage.
    [4]
    A phase separation vessel as claimed in claim 3 wherein the connecting passage is narrower in cross-section than the chambers to provide for a higher gas to liquid ratio in the connection chamber than when the gas flows directly into one of the series of adjoining chambers.
    [5]
    The phase separation tank according to any one of claims 1 to 4, wherein an inlet end of the communication passage is positioned substantially below the inclined one of the one chamber, near a lower end of each of the rows of adjacent chambers.
    [6]
    The phase separation tank of claim 6, further comprising a shield for partially blocking the inlet end of the communication passage.
    [7]
    7. A phase separation tank according to any one of claims 1 to 5, wherein an inlet end of the communication passage between the at least one chamber and an adjacent chamber is disposed in the at least one chamber on a wall thereof, the wall having an opposite side thereof, wherein inclined weir in a consecutive adjacent chamber, which further includes a shield near the inlet to the fluid stream to ensure fluid passage communication is not imparted in a direction of rotational flow in the at least one chamber.
    [8]
    8. phase separation container 1 to 7 in any one of claims, wherein each chamber has a skimmed oil pan in communication with the chamber.
    [9]
    The phase separation tank of any one of claims 1 to 8, wherein the skimmed sump is a municipal skim sump in communication with a plurality of or all of the chambers.
    [10]
    10. Phase separation tank according to one of claims 1 to 8, wherein the tank is contained within a transport container.
    [11]
    A phase separation tank according to any one of claims 1, 2 or 3, wherein the plurality of interconnected chambers are in side-by-side juxtaposition with each other and wherein an inlet end of the communication passage is substantially recessed below the positioned inclined weir of the one chamber a bottom of each of the rows of adjacent chambers.
    [12]
    A phase separation tank according to any one of claims 1, 2 or 3, wherein the plurality of interconnected chambers are arranged in end-to-end mutual configuration, further comprising a shield comprising the bottom positioned weir in the plurality of chambers for partial Blocking the inlet end of the connection passage, the connection channel at a location located below the shield and a bottom allowing at least one chamber of substantially fluid flow at said location to an upper portion of an adjacent chamber and towards the inclined weir in the adjacent chamber.
    [13]
    A phase separation tank according to any one of claims 1, 2 or 3, wherein: wherein the plurality of interconnected chambers are arranged in a mutual end-to-end configuration; and wherein the plurality of interconnected chambers are further arranged in mutual juxtaposed configuration.
    [14]
    The phase separation tank according to any one of claims 1, 2 or 3, further comprising, in a lower portion of at least one of the chambers, a filter medium.
    [15]
    A phase separation tank according to any one of claims 1, 2 or 3, wherein the filter medium is a non-solid granular medium.
    类似技术:
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    同族专利:
    公开号 | 公开日
    AT517984A5|2018-07-15|
    BR112017002677A2|2018-07-17|
    RO132756A2|2018-08-30|
    AT517984B1|2018-07-15|
    RO132756B1|2021-01-29|
    WO2016023095A1|2016-02-18|
    MX2017001928A|2017-06-21|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US4132652A|1977-10-11|1979-01-02|Chevron Research Company|Slotted baffle for use in separating oil-water mixtures|
    US4340487A|1980-12-24|1982-07-20|Lyon Michael R|Process for purifying water|
    GB9016020D0|1990-07-20|1990-09-05|Sev Trent Water Ltd|Waste water treatment plant|
    NO303048B1|1994-10-19|1998-05-25|Mastrans As|Process and equipment for cleaning a liquid|
    DE19647512A1|1996-11-16|1998-05-20|Damann Franz Josef|Mobile waste water treatment assembly|
    US6048376A|1998-08-03|2000-04-11|Ingersoll-Rand Company|Combination baffle and filter element system for removing oil from an oil/gas mixture|
    US8080158B2|2005-11-22|2011-12-20|Exterran Water Solutions Ulc|Vessel and method for treating contaminated water|KR101997488B1|2017-12-20|2019-07-08|김인식|Apparatus for separation of waste oil|
    KR101997481B1|2017-12-20|2019-07-08|김인식|Apparatus for separation of waste oil|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    PCT/CA2014/050764|WO2016023095A1|2014-08-11|2014-08-11|Phase separation tank|
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