OIL, WATER, GAS AND SOLID PARTICLE SEPARATION IN OIL AND/OR GAS PRODUCTION

Abstract

An apparatus for, and a method of, separating oil, water, gas and solid particles (usually sand) from a hydrocarbon-containing fluid produced from an oil and/or gas production facility. In particular, this invention relates to an apparatus and method for the separation of oil, water, gas and solid particles from a well or group of wells using an integrated apparatus which significantly reduces the space required on the production platform or rig and recycles produced gas to improve process efficiency while reducing cost.

Claims

1.-48. (canceled)

49. An apparatus for separating oil, water and gas from a hydrocarbon-containing fluid produced from an oil and/or gas production facility, the apparatus comprising: a. a separation tank for separating a multiphase hydrocarbon-containing fluid comprising oil, water and gas into its constituent oil, water and gas phases, the separation tank including a first inlet for the hydrocarbon-containing fluid, a second inlet for gas and, connected to the second inlet, a gas fluffer for passing gas bubbles through an oil/water mixture in a reservoir of the separation tank to collect droplets of oil entrained within the water; b. a first separator provided upstream of the separation tank, the first separator comprising an inflow conduit for the hydrocarbon-containing fluid, a first outlet of the first separator communicating an upper part of the first separator with the second inlet to convey gas separated from the hydrocarbon-containing fluid to the gas fluffer provided inside the separation tank, and a second outlet communicating a lower part of the first separator with the first inlet of the separation tank to convey liquid phases of the hydrocarbon-containing fluid to the separation tank.

50. An apparatus according to claim 49 wherein the first separator further includes a liquid level sensor and a first control module coupled thereto for controlling the liquid level within the first separator to be within a predetermined range.

51. An apparatus according to claim 49 wherein the first separator further includes an internal gas pressure sensor and a second control module coupled thereto for controlling a gas pressure within the first separator to be within a predetermined range.

52. An apparatus according to claim 49 wherein the first separator further comprises a third outlet of the first separator, located lower on the first separator than the first outlet, communicating the upper part of the first separator with the first inlet to convey gas separated from the hydrocarbon-containing fluid to the separation tank.

53. An apparatus according to claim 52 wherein the first outlet, the second outlet and the third outlet are each provided with a respective independently controllable valve selectively to open or close the respective outlet and control a flow rate through the respective outlet.

54. An apparatus according to claim 53 further comprising a controller comprising respective valve controlling modules for the respective valves.

55. An apparatus according to claim 49 wherein the separation tank further comprises a solids separator for separating solid particles from the multiphase hydrocarbon-containing fluid.

56. An apparatus according to claim 49 further comprising a coarse solid particle separator upstream of the first inlet and downstream of the first separator for separating coarse particles from the multiphase hydrocarbon-containing fluid.

57. An apparatus according to claim 49 further comprising a coarse solid particle separator upstream of the first inflow conduit for separating coarse particles from the multiphase hydrocarbon-containing fluid.

58. An apparatus according to claim 49 which is adapted continuously to separate oil, water, gas and solid particles from a continuous flow of a hydrocarbon-containing fluid produced from an oil and/or gas production facility.

59. An oil or gas facility incorporating the apparatus of claim 49.

60. A method of separating oil, water and gas from a hydrocarbon-containing fluid produced from an oil and/or gas production facility, the method comprising the steps of: (i) passing a multiphase hydrocarbon-containing fluid flow comprising oil, water and gas into a first separator through an inflow conduit of the first separator; (ii) separating gas from the hydrocarbon-containing fluid in the first separator to form a separate gas; (iii) conveying liquid phases of the hydrocarbon-containing fluid from an outlet of the first separator to an inlet of the separation tank, the separation tank being adapted for separating the multiphase hydrocarbon-containing fluid comprising oil, water and gas into its constituent oil, water and gas phases; (iv) conveying at least a first portion of the separated gas from the first separator through a first gas outlet of the first separator to a gas fluffer located in the separation tank; and (v) bubbling gas from the gas fluffer through an oil/water mixture in the separation tank to collect droplets of oil entrained within the water.

61. A method according to claim 60 further comprising the step of conveying a second portion of the separated gas from the gas separator through a second gas outlet of the first separator into the inlet of the separation tank.

62. A method according to claim 60 or claim 61 further comprising the step of controlling the flow rate of gas through the first gas outlet and the second gas outlet and controlling the flow rate of liquid phases flow through the outlet of the first separator in order to prevent the level of the liquid phases rising to the level of the first or second gas outlets.

63. A method according to claim 60 wherein the hydrocarbon-containing fluid further comprises solid particles.

64. A method according to claim 63 further comprising the step of separating, in the separation tank, solid particles from the oil, water and gas of the hydrocarbon-containing fluid.

65. A method according to claim 63 further comprising the step of separating coarse solid particles from the hydrocarbon-containing fluid at a location upstream of the inlet of the separation tank and downstream of the outlet of the first separator.

66. A method according to claim 63 further comprising the step of separating coarse solid particles from the hydrocarbon-containing fluid at a location upstream of the inflow conduit of the first separator.

67. A method according to claim 60 which continuously separates oil, water and gas from a continuous flow of a hydrocarbon-containing fluid produced from an oil and/or gas production facility.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0044] Embodiments of the present invention will now be described in more detail by way of example only with reference to the accompanying drawings, in which:

[0045] FIG. 1 schematically illustrates a side view of a solid particle, water, oil and gas separation system in accordance with an embodiment of the present invention; and

[0046] FIG. 2 schematically illustrates in enlarged detail the solids bucket and flushing unit of the separation system of FIG. 1.

DETAILED DESCRIPTION

[0047] Referring to FIG. 1 there is shown a schematic illustration of an oil, water, gas and solids separation system, designated generally as 100, which constitutes an apparatus for separating oil, water, gas and solid particles from a hydrocarbon-containing fluid produced from an oil and/or gas production facility in accordance with an embodiment of the present invention. The separation system 100 comprises an inlet separator tank 101 and a larger separation tank 102 downstream thereof. Oil, water, gas and solids (usually sand) enter the inlet separator tank 101 via inflow conduit 103. This inflow conduit 103 contains production flow from a production manifold, not shown, that has come from an oil well or group of oil wells. This manifold may also choke the flow so that the pressure of the mixture entering the inlet separator tank 101 is regulated.

[0048] In accordance with the first and second aspects of the present invention as identified above, the separation tank 102 is configured to separate the hydrocarbon-containing fluid, which comprises four phases, that is oil, water, gas and solid particles, into its constituent four phases. A single separation tank separates the hydrocarbon-containing fluid inti the individual four phases, each of which can provide a respective output from the separation tank. In accordance with the third and fourth aspects of the present invention as identified above, the inlet separator tank 101 can separate gas from the hydrocarbon-containing fluid, which may comprises three phases, that is oil, water, gas, which is fed to the inlet separator tank 101. The oil and water phases are fed from the inlet separator tank 101 to the separation tank 102, downstream of the inlet separator tank 101, in which the oil and water phases are separated. The gas is fed from the inlet separator tank 101 to a gas fluffer 119 in the separation tank 102, the gas fluffer 119 being used to assist separation of the water and oil phases in the separation tank 102. This avoids the need for additional gas, such as nitrogen, to be provided to the gas fluffer. The hydrocarbon-containing fluid which is fed to the inlet separator tank 101 may only comprises three phases, namely oil, water and gas, and any solid phase, in the form of particles, may have been removed from the hydrocarbon-containing fluid by a solids separator upstream of the inlet separator tank 101. Alternatively, the hydrocarbon-containing fluid which is fed to the inlet separator tank 101 may comprise four phases, that is oil, water, gas and a solid phase, in the form of particles, and the liquid and solid phases are separated from the gas phase in the inlet separator tank 101 and then the separated liquid and solid phases are fed to the separation tank 102, downstream of the inlet separator tank 101, in which the oil, water and solid phases are separated.

[0049] As the production enters into the inlet separator tank 101, the solids and liquids tend to fill the inlet separator tank 101 increasing the level, which is measured using the fluid level sensor 107. In FIG. 1 this sensor is shown as a float type device; however, those skilled in the art will appreciate that there are many other types readily available.

[0050] Gas that enters the inlet separator tank 101 as part of the hydrocarbon-containing fluid will tend to partially separate and fill the void above the liquid level. This gas cap will act as a pressure drive, thereby forcing the oil, water and solids mix within the inlet separator tank 101 out through conduit 106 and into a hydrocyclone 108 located within the separation tank 102. Preferably this hydrocyclone 108 is a dynamic cyclone as described in GB-A-2529729; however, any other suitable hydrocyclone could be used.

[0051] The fluid/particle mixture entering hydrocyclone 108 creates a rotation flow through the hydrocyclone 108 where the heavier particles are thrown outwards by centrifugal forces towards the cyclone wall. Here they will be slowed by frictional forces at the wall and will drop out of the liquid phase into the solids bucket 109, which is within the separation tank 102.

[0052] The solids bucket 109 is pivoted on an axle 110, provided on one side thereof, and rests on a weight sensor 111, provided on an opposite side thereof. This configuration is more clearly shown in FIG. 2. The weight sensor is connected to a display device 112 and can also be connected to a controller, not shown.

[0053] As the amount of solids collected increases in the solids bucket 109, the weight is recorded on display device 112 and also by the controller. Once the quantity of solids reaches some predetermined amount, they are flushed from the solids bucket 109 and out of the separation tank 102 through a solids outlet 226. This is achieved using a water fluidisation and flushing unit. Water is pumped through the conduit 113 and out from the nozzles in the fluidisation head 201, whereby the water fluidises the solids in the vicinity of the head 201. The mixture of water and solids then enters into the central conduit 202 in the head 201, and exits through the conduit 114. Both conduits 113 and 114 pass through to the exterior of the separation tank 102, as shown in FIG. 1. During this operation flow of hydrocarbon fluid into the separation tank 102 may be temporarily stopped. As the solids are flushed from the separation tank 102, the weight in the solids bucket 109 decreases. Once the weight has been reduced below a predefined value, the controller switches off (or it is switched off manually) the flow of water thought conduit 113 and flushing stops. Flushing will start again once sufficiently more solids are collected, at which time another flushing cycle starts.

[0054] Returning to the description of the flow though hydrocyclone 108, the solid particles are removed as described above leaving water, oil and gas as the remaining phases.

[0055] The water and oil are collected in a first reservoir 210 in the separation tank 102 which has at a downstream end thereof with respect to the flow of oil through the separation tank 102 a baffle 124, which functions as a weir, and on the downstream side of the baffle 124 is a second reservoir 212 downstream of the first reservoir 210 which collects oil which has flowed over the top of the weir.

[0056] The gas is released from the liquids by the agitation at the cyclone knocker 115 that disturbs the rotational flow within the hydrocyclone 108, and will exit from the hydrocyclone 108 at the top exit 116. The remaining water and oil liquid mixture exits the cyclone at the bottom thereof and increases the liquid level 117 in the separation tank 102. Above this level 117 is gas and below level 117 is liquid, composed of oil and water. This fluid level 117 is measured using the ultrasonic level sensor (other types of level measurement can be used) 121 which can be connected to the controller (not shown).

[0057] In FIG. 1 it is shown that the inlet separator tank 101 has three exit conduits 104, 105 and 106 that allow flow from the inlet separator tank 101 into the inlet 224 of the main separation tank 102. Each exit conduit 104, 105 and 106 has an associated valve, as shown in FIG. 1. As described above, the water, oil and solids mixture will exit the inlet separator tank 101 through the lower exit 106 driven by the gas pressure in the top of the inlet separator tank 101. If the liquid level in the inlet separator tank 101 drops below a predefined value as measured by level sensor 107 then the controller may close the value of 106 and open 105 so that gas exits the inlet separator tank 101 directly into the hydrocyclone 108. It should be noted that this gas could be wet, that is it could contain droplets of oil and/or water.

[0058] In FIG. 1 there is shown a pressure sensor 120 placed in the inlet separator tank 101 that can be connected to the controller and can be used to control the production flow into inlet separator tank 101 via conduit 103. The topmost exit 104 allows gas flow from the upper part 220 of the inlet separator tank 101 to be directed through a gas fluffer 119 which functions as an oil flotation device to cause oil droplets in the oil/water mixture to be floated upwardly by the action of rising gas bubbles from the gas fluffer 119. This gas fluffer 119 comprises perforated pipes covering the bottom section of the separation tank 101. Gas injected into it permeates through the perforations to form gas bubbles which then rise through the oil/water mix. The liquid leaving the hydrocyclone 108 is a mixture of oil and water and because of their density difference the oil will rise to the top to float on top of the water. The water level is labelled 118 and the top of the oil and water column is labelled 117. A linear resistivity sensor 122 is provided to measure where the interface between water and oil exists. As the resistivity of oil is very much higher than that of produced water, the measured resistance below the oil/water interface is low and the resistance above is much higher. Thus the position of the oil/water interface can be measured continually in real-time.

[0059] Returning to the description of the gas fluffer 119, as gas bubbles exit the perforations they rise through the oil/water liquid and will serve to enhance the separation of small droplets of oil from the water carrying them to the top of the liquid in the separation tank 102. The gas itself will leave the liquid and move above the level 117 into the top of the separation tank 102. As a result, the separation tank 102 will contain gas at its upper part 222, which is located above at least the first reservoir 210 and in the illustrated embodiment extends above both the first reservoir 210 and the second reservoir 212, and a liquid column that has two levels, namely level 118 indicating the top of water and level 117 indicating the top of oil (if there is any oil present). The linear resistance sensor 122 will provide a measurement of the thickness of the oil float on top of the water.

[0060] As discussed previously, the gas entering and leaving the hydrocyclone 108 can be wet and so can contain droplets of oil and or water. These will be very small but it is desirable to recover these liquids from the gas to improve the recovery of oil and gas. In FIG. 1 there is shown a coalescer 123 that comprises a fine mesh onto which oil and/or water condenses above the level 117 and runs down into the liquid column below. The oil will float on and the water will sink below level 118. Therefore, the gas to the upstream side of the coalescer 123 (i.e. the right-hand side shown in FIG. 1) may be wet but the gas column to the downstream side of the coalescer 123 (i.e. the left-hand side shown in FIG. 1) is dry.

[0061] The final stage of the four phase separation process is provided by the baffle 124, functioning as a weir, shown in FIG. 1. As the amount of liquid in the separation tank 102 increases, oil on the top of the liquid in the first reservoir 210 will flow over the baffle 124 into the second reservoir 212 downstream of the baffle 124. Water exits the bottom of the first reservoir 210 though water outlet 228. Oil exits the bottom of the second reservoir 212 though oil outlet 230. Gas exits the upper part 222 of the separation tank 102 through gas outlet 232, which is located above the second reservoir 212 but may alternatively be located above the first reservoir 210. The level of oil in the second reservoir 212 is measured using the ultrasonic level sensor 125. This oil can be boosted by the pump 126 and directed into the main oil production line (not shown) from the production platform or it could be drained through exit conduit 127 to another storage tank, not shown. Booster pump 126 can be controlled using a control that uses the oil level as measured by sensor 125 to control the process. Also, if the water level 118 rises to a point close to the top of the baffle 124, the water pump 128 can be turned on (or its flow rate increased) to ensure that no water passes over the top of the baffle 124, i.e. to the downstream side of the baffle 124, functioning as a weir, which would contaminate the oil. A water by-pass conduit and valve assembly 129 is provided to handle very high levels of water production entering the separation tank 102.

[0062] Gas that is collected on the downstream side of the coalescer 123 can exit the separator tank 102 through the conduit 130 to be flared or collected, or it can be boosted using the compressor 131 and pumped into the main gas production line (not shown) from the platform. The gas pressure within the separator tank 102 is measured using pressure sensor 132 that can be connected to the controller. Additionally a pressure relief safety valve 133 is provide to ensure that the pressure within the separator tank can never rise above a predefined value.

[0063] Those skilled in the art will appreciate that sensors 107, 120, 121, 122, 125 and 132 can be connected to a controller or controllers, schematically illustrated by a single controller 203, which in turn can be programmed to control the flow into the inlet separator tank 101 through conduit 103, the valves that direct flow from the inlet separator tank 101 into the separation tank 102 via the hydrocyclone 108, the pumps/boosters 126, 128 and 131 that allow oil, water and gas to exit the separation tank 102 as different phase flow streams, and the valves to the by-pass exit conduits 127, 129 and 130 that allow these flows to exit the system 100 as required. The details of such a programmed controller 214 to operate and provide the functions described above are well known to those skilled in the art. In addition, the same (or other) controller(s) can monitor the weight of solids collected in bucket 109 and can control the solids flushing process as described earlier. Again such a process is well known to those skilled in the art.

[0064] In any embodiment a coarse particle separator 216 may be located upstream of the separation tank 102, as shown schematically in FIG. 1, or alternatively upstream of the inlet separator tank 101.

[0065] Using the apparatus and method of the preferred embodiment described herein, production from a well or group of wells that contains oil, water, gas and solids can be separated into streams of four phases using a separation system 100 forming a compact unit as shown in FIG. 1, which optionally can be mounted on a single skid or frame. Additionally this separation unit will recycle the produced gas to improve the efficiency of oil/water separation and remove the requirement for another process product, for example, nitrogen gas. Such a system reduces the platform space required and improves the overall efficiency of the four phase separation process, thus reducing the capital and operational costs to the oil & gas operator.

[0066] The present invention may be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the invention to those skilled in the art.