This disclosure relates to flow through flowlines or trunk lines that carry fluids, for example, a mixture of two or more fluids.
Flowlines or trunk lines are often implemented to transport fluids between locations. Fluids transported through a flowline or trunk line can be non-homogenous, for example, a mixture of two or more fluids or multi-phase fluids, for example, a mixture of a fluid in the gas. In hydrocarbon implementations, the flowlines or trunk lines can be implemented to transport hydrocarbons between locations. In such implementations, the hydrocarbon can be mixed with water, which can cause corrosion, slugging, back pressure, combinations of them, or other issues in the flow lines or trunk lines.
This disclosure describes water separation in flowlines or trunk lines.
An example implementation of the subject matter described within this disclosure is a system with the following features. A sink is configured to attach to a bottom surface of a flowline that is configured to flow a mixture of at least two immiscible fluids. One of the immiscible fluids is water. The water is more dense than the other of the at least two immiscible fluids. An outlet formed at a bottom portion of the sink. A valve system is connected to the opening. The valve system is configured to open the outlet in response to the water occupying at least a portion of the sink.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. A perforated plate is configured to attach to the bottom surface of the flowline between the flowline and the sink. The perforated plate is configured to flow at least a portion of the mixture of the at least two immiscible fluids from the flowline into the sink.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The valve system includes a valve and a pressure sensor attached to the valve. The pressure sensor is configured to sense hydrostatic fluid pressure.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The pressure sensor is configured to store a pressure value and transmit a valve-open signal to the valve in response to the sensed hydrostatic fluid pressure satisfying the stored pressure value.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The pressure sensor is configured to transmit a valve-close signal to the valve in response to the sensed hydrostatic fluid not satisfying the stored pressure value.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The valve is connected to one or more data networks and is configured to receive a valve-open signal over the one more data networks, open the opening in response to receiving the valve-open signal, receive a valve-close signal over the one or more data networks, and close the opening in response to receiving the valve-close signal.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The valve system includes a valve, a perforated cylinder positioned in the sink, and a sensor system positioned within the cylinder. The sensor system is configured to open the valve based on the water occupying at least a portion of the perforated cylinder.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The sensor system includes an upper sensor attached to an upper surface of the perforated cylinder, a lower sensor attached to a lower surface of the perforated cylinder, and a floating member positioned in the perforated cylinder between the upper sensor and the lower sensor. The floating member is configured to float in water.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The upper sensor is configured to transmit a valve-open signal in response to being contacted by the floating member. The lower sensor is configured to transmit a valve-close signal in response to being contacted by the floating member.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The valve is configured to open the outlet in response to receiving the valve-open signal from the upper sensor. The valve is configured to close the outlet in response to receiving the valve-close signal from the lower sensor.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. A weir is positioned in the sink. The weir is configured to accumulate the water in a portion of the sink.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. A height of the weir is less than a distance between the bottom surface of the flowline and the bottom portion of the sink.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The sink includes a first portion with an upper end and a lower end. The upper end of the first portion is attached to an upstream end of the bottom portion of the flowline. A second portion includes an upper end and a lower end. The upper end of the second portion is attached to a downstream end of the bottom portion of the flowline. The downstream end is downstream of the upstream end. An intermediate portion includes an upstream end and a downstream end. The upstream end of the intermediate portion is attached to the lower end of the first portion. The downstream end of the intermediate portion is attached to the lower end of the second portion.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. Each of the first portion and the second portion is substantially curved.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. Each of the first portion and the second portion is substantially flat.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. Each of the first portion and the second portion angles downward from the bottom surface of the flowline toward the sink.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. An up-slope portion is attached to the flowline. The up-slope portion is positioned downstream of the sink. The up-slope portion tapers in an upstream direction.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The sink is a first sink, and the outlet is a first outlet and the valve system is a first valve system. The system also includes a second sink configured to attach to a bottom surface of the flowline downstream of the second sink, a second outlet formed at a bottom portion of the second sink. and a second valve system connected to the second opening. The second valve system is configured to open the second outlet in response to the water occupying at least a portion of the second sink.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. A flowline segment has the bottom surface to which the sink is configured to attach. The flowline segment is separate from the flowline through which the mixture of the at least two immiscible fluids is configured to flow.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. An outer diameter and cross-section of the flowline segment is substantially identical to an outer diameter and cross-section, respectively, of the flowline.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. A flange system is configured to fluidically connect the flowline segment and the flowline.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. A heating coil is positioned within the sink. The heating coil is configured to heat a fluid within the sink to prevent hydrate formation.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The heating coil includes an electric heating coil.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. a temperature sensor is configured to detect a temperature within the sink. A temperature controller is configured to regulate an energy flow into the heating coil.
Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The temperature controller includes a current regulator.
The details of one or more implementations of the subject matter described in this specification are set forth in the accompanying drawings and the description. Other features, aspects, and advantages of the subject matter will become apparent from the description, the drawings, and the claims.
Like reference numbers and designations in the various drawings indicate like elements.
This disclosure describes technologies relating to removing water from flowlines (or trunk lines) that carry oil or other hydrocarbons that do not mix with water. Implementing the water separation systems described here can result in the separation of water from the fluids flowed through the flowlines. The separated water can be removed from the flowlines or diverted to other portions of the flowlines or both. Removing water can minimize or eliminate corrosion, slugging, back pressure, combinations of them or other water-related issues in flowlines.
The fluids flowed through the flowline 102 can include a mixture of at least two immiscible fluids, one of which is water. The fluids can be single phase (that is, liquids only) or multi-phase (that is, a combination of liquids and gas). In some implementations, the fluids can be hydrocarbons flowed between locations, for example, a production site and a storage site. In the example implementations described here, the water is denser than the other fluids in the mixture allowing the system to separate the water from the other fluids. The system 104 and techniques described here can be implemented in a flowline through which a mixture of any two immiscible fluids are flowed, where one of the fluids is denser than other fluids in the mixture.
The system 104 includes a sink 106 that can be attached to a bottom surface of the flowline 102. To do so, in some implementations, a bottom portion of the flowline 104 can be removed and replaced with the system 104. For example, the system 104 can be welded to the bottom surface of the flowline 102.
An outlet is formed at a bottom portion of the sink 106. A valve system 127 is connected to the opening 129. As described later, the valve system 127 can open the outlet in response to the water in the fluids occupying at least a portion of the sink 106. For example, the fluids flowed through the flowline 102 can include a mixture of hydrocarbons and water, which is denser than the hydrocarbons. Initially, a portion of the mixture flows into and settles in the sink 106. The portion that initially flows into the sink 106 can include hydrocarbons and water in any ratio. Because of the difference in density, the water in the portion settles to the bottom of the sink 106 while the hydrocarbons rise to the top. Over time, as more of the mixture flows into and settles in the sink 106, the quantity of water that settles to the bottom of the sink 106 increases raising the hydrocarbons toward the upper surface of the flowline 102. When the water occupies all or substantially all of the sink 106, the valve system 127 opens the opening 129 allowing the water to be drained from the flowline 102. The water occupies substantially all of the sink 106, for example, 95% or more of the volume of the sink 106 can be occupied by water. After the water has been drained from the flowline 102, the valve system 127 closes the opening 129, and the water collection and separation processes begins once again.
In some implementations, the system 104 includes a heating coil 121 positioned within the sink 106. The heating coil 121 is located near the bottom of the sink near the outlet. The heating coil 121 is configured to heat a fluid within the sink to prevent hydrate formation. The heating coil 121 can include an electric heating coil, a fluid-filled heating coil, or any other type of heating element. When the heating coil 121 includes an electric heating coil, the heating coil can include a Nichrome wire or any other suitable material. While nichrome is the most common resistance wire for heating purposes because it has a high resistivity, other type of heating material, such as aluminum, brass, carbon (amorphous), copper, iron, manganin, molybdenum, nickel, platinum, kanthal, constantan, stainless steel, steel, zinc, or conductive materials can also be used. When the heating coil 121 includes fluid-filled heating coil, the fluid-filled coil includes a flow-line configured to flow heat media through. In such an instance, the heating coil 121 is configured to transfer heat from the heat media to a fluid within the sink 106.
In some implementations, a temperature sensor 123 can be included with the heating coil. The temperature sensor 123 is configured to detect a temperature within the sink 106. A temperature controller 125 is configured to regulate an energy flow into the heating coil. The heating coil is configured to deliver enough heat to prevent or eliminate hydrate formation. For example, in the case of a fluid-filled heating coil, the temperature controller 125 can include a temperature control valve. In the case of an electric heating coil, the temperature controller can include a current regulator.
In some implementations, the system 104 includes a perforated pipe 108 attached to the bottom surface of the flowline 102 between the flowline 102 and the sink 106. The perforated pipe 108 can flow the portion of the mixture of the hydrocarbons and water into the sink 106. To do so, the perforated pipe 108 can include multiple perforations (not shown) distributed along a surface of the plate. In some implementations, the sizes of the perforations can be selected to be small enough to prevent solid particles from falling into the sink 106, for example, rust particles, black powder, flocculent, sand, and other particles. Such an implementation can prevent the drain pip 112 from clogging. Alternatively, or in addition, the size of the perforations can be large enough to allow the mixture of the hydrocarbons and water to fall into the sink 106. The perforated pipe 108 can protect the fluid in the sink 106 from disturbances by the fluid velocity of the mixture in the flowline 102 above the sink 106. To do so, the perforated pipe 108 can be manufactured using a material that can not only resist corrosion due to the flowing mixture but can also absorb forces from the flowing mixture in the flowline 102. For example, one or more or all components of the system 104 can be manufactured using a metal such as chrome 13. In this manner, the perforated pipe 108 can increase a likelihood that the fluid in the sink 106 remains static to allow separation of the water from the hydrocarbons.
The valve system 127 includes a valve 110 and a pressure sensor 111 connected to the valve 110. The pressure sensor 111 can sense hydrostatic fluid pressure. In the example implementation shown in
In some implementations, the opening 129 and closing of the valve 110 can be controlled based on a pre-determined pressure value stored in the pressure sensor 111. For example, the pressure sensor 111 can store an opening pressure value defined by Equation 1:
Opening pressure=Flowline pressure+(sink depth×ρwater) Equation 1
The flowline pressure is the pressure of the fluid flowing through the flowline 102 above the sink 106. The sink depth is the distance between the perforated pipe 108 and the opening 129, and represents a hydrostatic pressure head on the pressure sensor 111. The density of water is denoted by “ρwater”. Initially, the pressure sensed by the pressure sensor 111 is the pressure of a mixture of hydrocarbons and water. As water accumulates in the sink 106 and raises the hydrocarbons towards the upper surface of the flowline 102, the pressure sensed by the pressure sensor 111 is the pressure of water alone. When the pressure sensed by the pressure sensor 111 satisfies (that is, is equal to or greater than) the opening pressure value defined by Equation 1, the sink 106 is filled with water. In response, the pressure sensor 111 can transmit a valve-open signal to the valve 110 causing the valve 110 to open the opening 129 allowing the water to be drained out of the sink 106, for example, through a drain pipe 112.
The pressure sensor 111 can store a closing pressure value defined by Equation 2:
Closing pressure=Flowline pressure+(sink depth×ρhydrocarbons) Equation 2
The density of oil is denoted by “ρhydrocarbons” As water drains through the drain pipe 112, the quantity of water in the sink 106 decreases and fluids in the mixture begin to flow from the flowline 102 through the perforated pipe 108 into the sink 106 to occupy the volume of the draining water. The pressure sensed by the pressure sensor 111 is the pressure of the mixture of hydrocarbons and water. Once all the water has drained from the sink 106, the sink 106 is filled with the mixture, a portion of which includes the hydrocarbons. Because the water has not had time to settle to the bottom of the sink 106, substantially all of the portion may include hydrocarbons. In such instances, the pressure sensed by the pressure sensor 111 is the pressure of the hydrocarbons. When the pressure sensed by the pressure sensor 111 satisfies (that is, is equal to or lesser than) the closing pressure value defined by Equation 2, the pressure sensor 111 can transmit a valve-close signal to the valve 110 causing the valve 110 to close the opening 129. The water separation process described earlier begins again.
Equations 1 and 2 define opening pressure and closing pressure values, respectively, as being caused by the hydrostatic head of water alone or the hydrostatic head of hydrocarbons alone. Because the hydrostatic head at any time can include both fluids, the control logic executed by the pressure sensor 111 can incorporate some tolerances. For example, the pressure sensor 111 can transmit the valve-open signal if the sensed pressure is within 95% of the opening pressure defined by Equation 1. Similarly, the pressure sensor 111 can delay transmitting the valve-close signal until the sensed pressure is about 105% of the closing pressure defined by Equation 2.
In some implementations, the pressure sensor 111 and the valve 110 need not be connected directly to each other, but instead can be connected indirectly through one or more data networks (not shown). For example, the pressure sensor 111 can be connected to a computer system (not shown) located remotely from the pressure sensor 111 through one or more data networks (for example, a local area network, a wide area network, a wireless network, a Bluetooth network, the Internet, any combination of them or other data networks). The pressure sensor 111 can periodically transmit sensed pressure values over the one or more data networks to the remotely located computer system. For example, the pressure sensor 111 can transmit the sensed pressure values in real-time. That is, a time between the pressure sensor 111 sensing the pressure value and transmitting the pressure value over the data networks can be so small that the sensing and transmission appear to be simultaneous. For example, the time between the sensing and the transmission can be less than one millisecond or between 1 millisecond and one second. Based on the pressure values received from the pressure sensor 111, the remotely located computer system can periodically (for example, in real-time) transmit valve-open or valve-close signals to the valve 110. The valve 110 can open or close the opening 129 in the sink 106 based on the received valve-open or valve-close signals, respectively.
As shown in
The system 404 includes a perforated cylinder 414 positioned in the sink 406. The cylinder 414 can be open or closed on either or both ends. The sensor system is positioned within the cylinder 414. As described later, the sensor system can open the valve 410 based on the water occupying at least a portion of the cylinder 414. For example, the cylinder 414 spans a distance between the perforated pipe 408 and the bottom of the sink 406. The sensor system includes an upper sensor 418 and a lower sensor 416 attached to an upper surface 420 and a lower surface 422 of the cylinder 414, respectively. The sensor system includes a floating member 415 positioned in the cylinder 414 between the upper sensor 418 and the lower sensor 416. The floating member 415 can be manufactured from a material that causes the floating member 415 to float at a contacting junction between the hydrocarbons and water. That is, as a quantity of water increases and that of hydrocarbons decreases in the sink 406 or vice versa, the contacting junction between the hydrocarbons and water rises or drops. The floating member 415 can remain at the contacting junction between the hydrocarbons and water despite the variations in the quantities of the hydrocarbons and the water. The floating member 415 can be a sphere or any geometric shape.
Each of the upper sensor 418 and the lower sensor 416 is connected to the valve 410, for example, using wires or wirelessly or both. Each sensor is a contact sensor configured to transmit a signal (for example, a valve-open signal or a valve-close signal) in response to being contacted by the floating member 415. For example, a force on either the upper sensor 418 or the lower sensor 416 by the rising floating member 415 or the falling floating member 415, respectively, can be greater than a force on either sensor by either the water or the hydrocarbons. Each of the upper sensor 418 and the lower sensor 416 can be configured to differentiate between a contact by the floating member 415 and a contact by a fluid based on a difference in the force on each sensor by the contacting feature.
Initially (that is, before water has been separated from the hydrocarbons in the sink 406), the floating member 415 is at the bottom of the cylinder 414 and in contact with the lower sensor 416. In this configuration, the lower sensor 416 transmits a valve-close signal to the valve 410, which, in response, retains the opening 429 in a closed state. As water accumulates in the sink 406, the floating member 415 rises towards the upper sensor 418. The lower sensor 416 continues to transmit the valve-close signal to retain the opening 429 in the closed state allowing water to accumulate in the sink 406. When sufficient water accumulates causing the floating member 415 to contact the upper sensor 418, the upper sensor 418 transmits a valve-open signal to the valve 410. Responsively, the valve 410 opens the opening 429 allowing the accumulated water to drain through the drain pipe 412. As the water drains, the floating member 415 falls towards the lower sensor 416. The upper sensor 418 continues to transmit the valve-open signal to retain the opening 429 in an open state allowing water to drain through the drain pipe 412. When sufficient water has drained causing the floating member 415 to contact the lower sensor 416, the lower sensor 416 once again transmits the valve-close signal to the valve 410, and the accumulation process begins again.
In some implementations, a weir 621 can be positioned in the sink 606. The weir 621 can accumulate the water in a portion of the sink 606. For example, the weir 621 can include a substantially vertical plate having a bottom surface attached to the bottom portion of the sink. That is, the weir 621 can be perpendicular to the bottom portion of the sink 606 or can deviate from perpendicularity by about 10°. The height of the weir 621 can span from the bottom portion of the sink 606 to less than the perforated pipe 608. In operation, the weir 621 can split the sink 606 into two sections—an upstream section and a downstream section. The weir 621 can increase water accumulation on the upstream section compared to the downstream section. As water accumulates in the upstream section, the hydrocarbons rise to the top of the upstream section and overflow into the downstream section. In this manner, loss of hydrocarbons can be minimized.
In some implementations, a valve system 627 can be implemented in the downstream section of the split sink 606. The valve system 627 can retain an opening 629 in the downstream section in a closed state when the overflowing fluid includes hydrocarbons, and can cause the opening 629 to transition to an open state when the overflowing fluid includes water.
The system 804 includes a sink that can be attached to a bottom surface of the flowline 802. An outlet is formed at a bottom portion of the sink. A valve system is connected to the opening. In some implementations, the system 804 includes a perforated plate attached to the bottom surface of the flowline 802 between the flowline 802 and the sink. The valve system includes a valve, a sensor system connected to the valve and a drain pipe. The structural and functional features of components of the system 804 can be substantially similar or identical to the structural and functional features of corresponding components of the system 104 or any of the water separation systems described in this disclosure.
The features of the flange system 808b can be substantially similar to those of flange system 808a. Implementing the flange systems 808a and 808b allows removably attaching the water separation system 804 to the flowline 802. The flow through the flowline 802 and the flowline segment 806 can be temporarily shut-off, and the water separation system 804 removed, for example, to perform any repairs, maintenance, cleaning or combination of them, to one or more of the water separation system 804, the flowline 802 or the flowline segment 806.
Thus, particular implementations of the subject matter have been described. Other implementations are within the scope of the following claims. For example, a water separation system can include one or more of any of the features shown in any of the schematic diagrams described earlier.
This application is a continuation of and claims the benefit of priority to U.S. patent application Ser. No. 15/833,059, entitled “Water Separation in Flowlines or Trunk Lines”, filed on Dec. 6, 2017, which claims priority to U.S. Patent Application No. 62/593,075, entitled “Water Separation in Flowlines or Trunk Lines”, filed Nov. 30, 2017, and U.S. Patent Application No. 62/430,564, entitled “Water Separation in Flowlines or Trunk Lines”, filed Dec. 6, 2016, the contents of which are incorporated herein by reference in its entirety.
Number | Date | Country | |
---|---|---|---|
62593075 | Nov 2017 | US | |
62430564 | Dec 2016 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 15833059 | Dec 2017 | US |
Child | 16928419 | US |