Embodiments of the present invention relate to a hydrocarbon production system, and more particularly, to a system and method for disposal of water produced from multiple wells of a well-pad.
Non-renewable hydrocarbon fluids such as oil and gas are widely used in various applications for generating energy. Such hydrocarbon fluids are generally extracted from the hydrocarbon wells which extend below a surface of earth to a region where the hydrocarbon fluids are available. Generally, the hydrocarbon fluids are not available in a purified form and are available as a mixture of hydrocarbon fluids, water, sand, and other particulate matter together referred to as a well fluid. Such well fluids are filtered using different mechanisms to extract a hydrocarbon rich stream and a water stream.
In one approach, well fluids are extracted from a hydrocarbon well to a surface of the earth and then separated using a surface separator to produce oil and water. In such an approach, water separated from the well fluids are distributed and transported to a plurality of locations for disposal. However, such a process may increase capital investment and operational costs for water disposal.
In another approach, a downhole separator is used within the hydrocarbon well for separation of oil and water from well fluids. In such an approach, water separated from the hydrocarbon stream is disposed within the hydrocarbon well. The downhole separator is susceptible to scaling leading to reduction in efficiency. Further, operation of such a downhole separator may increase electric power consumption leading to additional operational costs.
Accordingly, there is a need for an enhanced system and method for disposal of water produced from a plurality of wells of a well-pad.
In accordance with one exemplary embodiment, a system for disposal of water produced from multiple wells of a well-pad is disclosed. The system includes a downhole separator, a plurality of pumps including a first pump and a second pump, a first surface separator, a first tube, and a second tube. The downhole separator is disposed within a first wellbore of the well-pad. The downhole separator is configured to receive a first production fluid from a first production zone and generate a hydrocarbon rich stream and a water stream from the first production fluid. The first pump is disposed within the first wellbore and coupled to the downhole separator. The second pump is disposed within a second wellbore of the well-pad. The first surface separator is coupled to the first pump via a first channel and to the second pump via a second channel. The first surface separator is configured to receive the hydrocarbon rich stream from the downhole separator, using the first pump and a second production fluid from a second production zone, using the second pump. The first surface separator is further configured to generate oil and a water rich stream from the hydrocarbon rich stream and the second production fluid. The first tube is coupled to the downhole separator and configured to dispose the water stream from the downhole separator in a first disposal zone. The second tube is coupled to the first surface separator and configured to dispose the water rich stream from the first surface separator in a second disposal zone.
In accordance with another exemplary embodiment, a method for disposal of water produced from multiple wells of a well-pad is disclosed. The method involves receiving a first production fluid from a first production zone to a downhole separator disposed within a first wellbore of the well-pad. The method further involves generating a hydrocarbon rich stream and a water stream from the first production fluid, using the downhole separator. Further, the method involves feeding the hydrocarbon rich stream from the downhole separator, using a first pump of a plurality of pumps, to a first surface separator via a first channel. The first pump is disposed within the first wellbore and coupled to the downhole separator. The method further involves feeding a second production fluid from a second production zone, using a second pump of the plurality of pumps, to the first surface separator via a second channel. The second pump is disposed within a second wellbore of the well-pad. Further, the method involves generating oil and a water rich stream from the hydrocarbon rich stream and second production fluid, using the first surface separator. The method further involves disposing the water stream from the downhole separator in a first disposal zone, using a first tube coupled to the downhole separator and disposing the water rich stream from the first surface separator in a second disposal zone, using a second tube coupled to the first surface separator.
These and other features and aspects of embodiments of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
Embodiments of the present invention discussed herein relate to a system and method for disposal of water produced from a plurality of wells into a well-partition well. In one or more embodiments, the system functions as a closed loop system for disposal of produced water. In one embodiment, the system includes a downhole separator, a plurality of pumps including a first pump and a second pump, a first surface separator, a first tube, and a second tube. The downhole separator is disposed within a first wellbore of a first well (hereinafter also referred as “a downhole-separator well”) of the well-pad. The downhole separator is configured to receive a first production fluid from a first production zone and generate a hydrocarbon rich stream and a water stream from the first production fluid. The first pump is disposed within the first wellbore and coupled to the downhole separator. The second pump is disposed within a second wellbore of a second well (hereinafter also referred as “a well-partition well”) of the well-pad. The first surface separator is coupled to the first pump via a first channel and to the second pump via a second channel. The first surface separator is configured to receive the hydrocarbon rich stream from the downhole separator, using the first pump and a second production fluid from a second production zone, using the second pump. The first surface separator is further configured to generate oil and a water rich stream from the hydrocarbon rich stream and the second production fluid. The first tube is coupled to the downhole separator and configured to dispose the water stream from the downhole separator in a first disposal zone. The second tube is coupled to the first surface separator and configured to dispose the water rich stream in a second disposal zone. In such embodiments, the first disposal zone is located either below the first production zone or above the first production zone and second disposal zone is located above the second production zone.
The well-pad 100 includes a plurality of wells 104a, 104b, 104c referred to as downhole-separator wells or first wells. The well-pad 100 further includes a well 104d referred to as a well-partition well or a second well. In one embodiment, each of the plurality of wells 104a-104d is a hydrocarbon well. It should be noted herein that the term “well-pad” is referred to the group of wells 104a-104d located within a cluster of a geological source which share common hydrocarbon fluid processing facilities. The number of wells of the well-pad 100 may vary depending on the application. It should be noted herein that the term “a well-partition well” is a hydrocarbon well which does not include a downhole separator disposed within the corresponding wellbore and includes a disposal zone located above a production zone. Similarly, the term “a downhole-separator well” is referred to a hydrocarbon well having a downhole separator disposed within the corresponding wellbore and the disposal zone located either above or below the production zone. In certain embodiments, each of the plurality of wells 104a-104d extends below a surface of earth to a region where the hydrocarbon fluids are available. Each of the plurality of wells 104a-104d is configured to produce a production fluid (hereinafter also referred to as “well fluid”) which is a mixture of hydrocarbon fluids, water, sand, and other particulate matter.
The system 102 includes a plurality of downhole separators (not shown), a plurality of pumps (not shown), a first surface separator 106, a second surface separator 108, a plurality of first channels 110a, 110b, 110c, a second channel 112, an inlet manifold 114, a plurality of first tubes (not shown), a second tube 116, an oil stream tube 118, a plurality of sensors 120a, 120b, 120c, 120d, a control unit 122, and a plurality of control valves 124a, 124b, 124c, 124d. In such embodiments, each of the plurality of downhole separators, the plurality of pumps, and the plurality of first tubes are disposed within the corresponding wellbore of the plurality of wells 104-104d. The system 102 further includes a gas outlet manifold 126 and an oil outlet manifold 128.
The first surface separator 106 is coupled to the plurality of first channels 110a-110c and the second channel 112 via the inlet manifold 114. In one embodiment, the first surface separator 106 is a gravity-based separator. In some embodiments, the first surface separator 106 may be a heater-treater, a filtering device, or the like. In some other embodiments, the first surface separator 106 may be an active separator such as a centrifugal separator. In the illustrated embodiment, the first surface separator 106, the second surface separator 108, the plurality of sensors 120a-120d, and the plurality of control valves 124a-124d are disposed on a surface of earth. Further, the first surface separator 106 is coupled to the plurality of pumps via the corresponding plurality of first channels 110a-110c and the second channel 112. In certain embodiments, each of the sensors 120a-120d is density meter or a densometer.
During operation, each downhole separator is configured to generate a hydrocarbon rich stream 130 and a water stream (not shown) from a first production fluid (not shown) received from a first production zone. The first surface separator 106 is configured to receive the hydrocarbon rich stream 130 from the plurality of downhole-separator wells 104a-104c and a second production fluid 132 from the well-partition well 104d. Specifically, the first surface separator 106 is configured to receive the hydrocarbon rich stream from the corresponding downhole separator using the corresponding first pump and the second production fluid using the second pump. Further, the first surface separator 106 is configured to generate oil 134 and a water rich stream 136 from the hydrocarbon rich stream 130 and the second production fluid 132. The first surface separator 106 is also configured to separate a gaseous stream 138 from the hydrocarbon rich stream 130 and the second production fluid 132. In one specific embodiment, the constituents of the hydrocarbon rich stream 130 and second production fluid 132 are segregated based on density of each constituent. In the illustrated embodiment, the oil 134 is filled in a bottom section, the water rich stream 136 is filled in a middle section, and the gaseous stream 138 is filled in a top section of the first surface separator 106.
The sensors 120a-120c are coupled to the plurality of first channels 110a-110c respectively. The control valves 124a-124c are coupled to the plurality of first channels 110a-110c respectively. The control valves 124a-124c are disposed downstream relative to the plurality of sensors 120a-120c respectively. Further, the sensors 120a-120c and the control valves 124a-124d are communicatively coupled to the control unit 122.
During operation, each of the plurality of sensors 120a-120c is configured to measure a density of the hydrocarbon rich stream 130 in the corresponding first channels 110a-110c. Further, the sensors 120a-120c are configured to generate a plurality of signals 140a, 140b, 140c, respectively representative of the density of the hydrocarbon rich stream 130. The control unit 122 is configured to receive the signals 140a-140c from the plurality of sensors 120a-120c and determine an amount of water content in the hydrocarbon rich stream 130. Further, the control unit 122 is configured to generate a plurality of signals 142a, 142b, 142c to selectively regulate the control valves 124a-124c respectively to allow a flow of the hydrocarbon rich stream 130 through the corresponding first channels 110a-110c to the first surface separator 106. In one embodiment, the control unit 122 may determine the amount of water content in the hydrocarbon rich stream 130 by comparing obtained values of the plurality of signals 140a-140c with predefined values stored in a look-up table, database, or the like. In one embodiment, if the obtained value is less than the predefined value, the control unit 122 may allow continuous flow of the hydrocarbon rich stream 130 through the first channel 110a. In another embodiment, if the obtained value is greater than the predefined value, the control unit 122 may control an outlet pressure of the hydrocarbon rich stream 130 flowing through the first channel 110a by controlling the control valve 124a.
In one embodiment, if the amount of water content in the hydrocarbon rich stream 130 is greater than 30 parts per million (ppm), the control unit 122 is configured to control the outlet pressure of the hydrocarbon rich stream 130 flowing through the first channel 110a by controlling the control valve 124a based on at least one of the signals 140a-140c. As a result, the downhole separator disposed in the downhole-separator well 104a separates the water content from the first production fluid efficiently. In such embodiments, the sensors 120a, 120b, and 120c, along with control signals 142a, 142b, and 142c together with operation of the control valves 124a, 124b, and 124c and the control unit 122 enables the corresponding downhole separator to dispose the water stream having a residual oil content (hydrocarbon) of less of than 30 ppm in the corresponding disposal zone of the downhole separator wells 104a, 104b, and 104c. In another embodiment, if the amount of water content in the hydrocarbon rich stream 130 is less than or equal to 30 ppm, the control unit 122 may allow continuous flow of the hydrocarbon rich stream 130 through the first channel 110a.
The second tube 116 is coupled to the first surface separator 106, the second surface separator 108, and extends into the well-partition well 104d. Further, the second tube 116 extends proximate to a disposal zone (not shown) located in the well-partition well 104d. The sensor 120d and the control valve 124d are coupled to the second tube 116. The control valve 124d is disposed downstream relative to the sensor 120d. Further, the second surface separator 108 is disposed downstream relative to the control valve 124d. The sensor 120d and the control valve 124d are communicatively coupled to the control unit 122. In one embodiment, the second surface separator 108 is a coalescing filter. In some embodiments, the second surface separator 108 may be a media filter, a filter tube, or the like.
During operation, the second tube 116 is used to dispose the water rich stream 136 from the first surface separator 106 to a disposal zone located in the well-partition well 104d. The sensor 120d is configured to measure density of the water rich stream 136 in the second tube 116. Specifically, the sensor 120d is configured to generate a signal 140d representative of the density of the water rich stream 136. The control unit 122 is configured to receive the signal 140d from the sensor 120d and determine an amount of oil content in the water rich stream 136. Further, the control unit 122 is configured to generate a signal 142d to regulate the control valve 124d to allow a flow of the water rich stream 136 through the second tube 116 to the second surface separator 108. In one embodiment, the control unit 122 may determine the amount of oil content in the water rich stream 136 by comparing an obtained value from the signal 140d with a predefined value stored in a look-up table, database, or the like. In one embodiment, if the obtained value is less than the predefined value, the control unit 122 may control the control valve 124d to direct the water rich stream 136 via a bypass channel 144, bypassing the second surface separator 108 to the disposal zone. In another embodiment, if the obtained value is greater than the predefined value, the control unit 122 may stop direct transfer of the water rich stream 136 to the disposal zone, using the control valve 124d and transfer at least a portion of the water rich stream 136 from the first surface separator 106 to the second surface separator 108.
In one embodiment, if the amount of oil content in the water rich stream 136 is greater than 30 parts per million (ppm), the control unit 122 may stop direct transfer of the water rich stream 136 to the disposal zone, using the control valve 124d. Further, the control unit 122 may transfer at least the portion of the water rich stream 136 from the first surface separator 106 to the second surface separator 108, using the control valve 124d. The second surface separator 108 is configured to further separate the oil content 134a from the water rich stream 136. The second surface separator 108 is further configured to transfer a separated water rich stream 136a to the disposal zone and the separated oil content 134a to the first surface separator 106 via the oil stream tube 118. In another embodiment, if the amount of oil content in the water rich stream 136 is less than or equal to 30 ppm, the control unit 122 may control the control valve 124d to direct the water rich stream 136 via the bypass channel 144, bypassing the second surface separator 108 to the disposal zone in well-partition well 104d.
The gas outlet manifold 126 is coupled to the top section of the first surface separator 106 and configured to transfer the gaseous stream 138 to a distant storage facility or production facility, or the like. The oil outlet manifold 128 is coupled to the middle section of the first surface separator 106 and is configured to transfer the oil 134 to a distant storage facility or production facility, or the like.
In one embodiment, the downhole-separator well 104a includes a first wellbore 146 drilled from a surface 147 of the earth. The first wellbore 146 extends up to a predetermined depth, for example, about 6500 feet from the surface 147 to form a vertical leg 148. The downhole-separator well 104a also includes a lateral leg 150 which is coupled to the vertical leg 148 via a leg junction 152. The lateral leg 150 is configured to receive a first production fluid 154 from a first production zone 156. The downhole-separator well 104a further includes a first disposal zone 158 located below the first production zone 156 and a water zone 160 located below the surface 147 of the earth. In one embodiment, a portion of the first wellbore 146 proximate to the leg junction 152 includes a plurality of perforations 164 for extracting the first production fluid 154 from the first production zone 156 into the first wellbore 146. In the illustrated embodiment, cement 166 is affixed to a surface of the first wellbore 146.
The system 102 further includes a downhole separator 168, a first pump 170, a first tube 172, and a sensor 120e. It should be noted herein that in the illustrated embodiment, sensor 120a is also referred to as a “first sensor” and the sensor 120e is also referred to as a “second sensor”. The system 102 further includes a packer 174, a jet pump 176, a motor 178, and a motive fluid tube 188.
The downhole separator 168 is disposed within the first wellbore 146 and proximate to the leg junction 152. The downhole separator 168 is a rotary separator such as a centrifugal separator including a plurality of rotating elements 184. The motor 178 is disposed within the first wellbore 146 and coupled to the downhole separator 168 and the first pump 170 via a shaft 182. Specifically, the motor 178 is coupled to the plurality of rotating elements 184 disposed within a casing 186 of the downhole separator 168. In one embodiment, the motor 178 is an electric motor powered by electricity supplied via a cable (not shown) from the surface 147 of the earth. In some other embodiments, the motor 178 may be a hydraulic motor. A hydraulic fluid (i.e. water) is supplied (not shown) from the surface 147 of the earth to the motor 178 via a tube (not shown). The jet pump 176 is disposed within the first wellbore 146 and coupled to an inlet 180 of the downhole separator 168. Specifically, the jet pump 176 is disposed proximate to the plurality of perforations 164. The jet pump 176 includes a plurality of fixed vanes 190 located around the inlet 180 of the downhole separator 168. The packer 174 is disposed within the first wellbore 146 and located upstream relative to the downhole separator 168. The motive fluid tube 188 is disposed within the first wellbore 146 and located downstream relative to the packer 174. The motive fluid tube 188 is coupled to the first tube 172 and to an inlet 192 of the jet pump 176. The first tube 172 is inserted through the packer 174 to the first disposal zone 158.
The first pump 170 is disposed within the first wellbore 146 and located downstream relative to the downhole separator 168. The first pump 170 is coupled to the motor 178. A gas separator 206 is disposed between the motor 178 and the first pump 170. The gas separator 206 is configured to separate the gaseous medium 204 from the first production fluid 154 before feeding the first production fluid 154 to the first pump 170. Further, the first surface separator 106 is directly coupled to the first pump 170 via a production tubing 194, the first channel 110a, and the inlet manifold 114. In the illustrated embodiment, the production tubing 194 is located within the first wellbore 146. The first channel 110a and the inlet manifold 114 are located at the surface 147 of the earth. The oil outlet manifold 128 coupled to the first surface separator 106 and to a distant storage facility such as an oil tank 196. The first sensor 120a and the control valve 124a are coupled to the first channel 110a. Specifically, the first sensor 120a is disposed upstream relative to the control valve 124a. The second sensor 120e is coupled to an outlet 198 of the downhole separator 168. In certain embodiments, the second sensor 120e may be disposed in a tube (not shown in
During operation, the vertical leg 148 receives the first production fluid 154 from the lateral leg 150. Specifically, the vertical leg 148 receives the first production fluid 154 from the first production zone 156 via the plurality of perforations 164. The jet pump 176 directs the first production fluid 154 to the downhole separator 168. Specifically, the plurality of fixed vanes 190 is configured to generate pre-swirl to the first production fluid 154 before feeding to the downhole separator 168. In other words, the jet pump 176 may be used to pressurize the first production fluid 154 prior to introducing to the downhole separator 168 to improve efficiency of the system 102.
The downhole separator 168 is configured to generate the hydrocarbon rich stream 130 and a water stream 200 from the first production fluid 154. Specifically, the motor 178 is configured to drive the downhole separator 168 so as to rotate plurality of rotating elements 184 at a predetermined speed to generate the hydrocarbon rich stream 130 and the water stream 200 from the first production fluid 154. During rotation of the downhole separator 168, hydrocarbons having a lower molecular weight are separated from water and other particulate matter having a higher molecular weight in the first production fluid 154. Further, the downhole separator 168 is configured to discharge the hydrocarbon rich stream 130 via the outlet 198 and the water stream 200 via an outlet 199 to the first tube 172.
The first tube 172 is used to dispose the water stream 200 from the downhole separator 168 to the first disposal zone 158. The motive fluid tubing 188 is used to transfer a portion of the water stream 200 to the inlet 192 of the jet pump 176 so as to create suction pressure at the inlet 192 of the jet pump 176. In one or more embodiments, the suction pressure at the inlet 192 aids in drawing the first production fluid 154 into the jet pump 176 from the first wellbore 146.
The gas separator 206 is configured to receive the separated hydrocarbon rich stream 130 from the downhole separator 168. In such embodiments, the gas separator 206 is configured to separate the gaseous medium 204 from the hydrocarbon rich stream 130 before feeding the hydrocarbon rich stream 130 to the first pump 170. Further, the gas separator 206 is configured to discharge the gaseous medium 204 to a portion of the first wellbore 146 above the first pump 170. The first pump 170 is configured to receive the separated hydrocarbon rich stream 130 from the downhole separator 168 via the gas separator 206. In one embodiment, the first pump 170, the gas separator 206, and the motor 178 are collectively referred to as an “artificial lift system”. In such embodiments, the artificial lift system is an electrical submersible pump (ESP). In some other embodiments, the first pump 170 is a rod pump. The motor 178 is configured to drive the first pump 170 to transfer the hydrocarbon rich stream 130 to the first surface separator 106. In certain embodiments, a gear box (not shown) may be disposed between the downhole separator 168 and the first pump 170 and configured to vary the speed of the shaft 182. The first surface separator 106 is configured to receive the hydrocarbon rich stream 130 directly from first pump 170 and generate the oil 134 and the water rich stream 136 from the hydrocarbon rich stream 130. The oil 134 is transferred to the oil tank 196 via the oil outlet manifold 128. The water rich stream 136 is disposed in a second disposal zone of the well-head well via the second tube 116. A gas manifold 202 is disposed at the surface 147 of the earth and coupled to a wellhead 210 of the first wellbore 146. The gas manifold 202 is used to discharge a gaseous medium 204 collected within the first wellbore 146 to the discharge storage facility, a compressor, or the like.
The second sensor 120e is configured to measure a flow rate of the hydrocarbon rich stream 130. The second sensor 120e is configured to generate a second signal 140e representative of the flow rate of the hydrocarbon rich stream 130. The control unit 122 is configured to receive at least one of the first signal 140a and the second signal 140e from the first sensor 120a and the second sensor 120e respectively. As discussed earlier, in one embodiment, the control unit 122 is configured to generate the signal 142a to regulate the control valve 124a to control an outlet pressure of the hydrocarbon rich stream 130 flowing via the first channel 110a to the first surface separator 106. In some other embodiments, the control unit 122 is configured to generate a signal 142e and transmit the signal 142e to the motor 178 to control a speed of the motor 178 based on at least one of the first signal 140a and the second signal 140e. In one or more embodiments, the control unit 122 may determine the amount of water content in the hydrocarbon rich stream 130 by comparing obtained values in the first signal 140a and the second signal 140e with predefined values stored in a look-up table, database, or the like.
As discussed, in the embodiments of
The downhole-separator well 104b includes a first wellbore 146a having a vertical leg 148a and a lateral leg 150a coupled to the vertical leg 148a via a leg junction 152a. The lateral leg 150a is used to transfer a first production fluid 154a from a first production zone 156a to the vertical leg 148a via a plurality of perforations (not shown) formed in at least one of the lateral leg 150a proximate to the leg junction 152a. In the illustrated embodiment, the downhole-separator well 104b further includes a first disposal zone 158a located above the first production zone 156a. Cement 166 is affixed to a surface of the first wellbore 146a.
In the illustrated embodiment, the portion of the system 102 further includes a downhole separator 168a, a first pump 170a, a first channel 110b, a first tube 172a, a first sensor 120b, a second sensor 120f, a control valve 124b, and a packer 174a.
The first surface separator 106 is coupled to the first pump 170a via the downhole separator 168a. The downhole separator 168a is coupled to the first surface separator 106 via a production tubing 194a, the first channel 110b, and the inlet manifold 114. In such embodiments, the downhole separator 168a is disposed downstream relative to the first pump 170a. In the illustrated embodiment, a motor 178a is disposed within the first wellbore 146a and configured to drive both the first pump 170a and the downhole separator 168a via a shaft 182a. In one embodiment, the downhole separator 168a is a rotary separator such as a centrifugal separator. A gas separator 206a is disposed between the motor 178a and the first pump 170a and configured to separate the gaseous medium 204a from the first production fluid 154a before feeding the first production fluid 154a to the first pump 170a. The packer 174a is disposed within the first wellbore 146a and located downstream relative to the downhole separator 168a. The first tube 172a is inserted through the packer 174a and coupled to the downhole separator 168a. A gas tube 208 is also inserted through the packer 174a and disposed around the downhole separator 168a. The first sensor 120b and the control valve 124b are coupled to the first channel 110b. The second sensor 120f is coupled to an outlet (not labeled) of the downhole separator 168a. In certain embodiments, the second sensor 120f may be disposed in a tube (not shown in
During operation, the first wellbore 146a receives the first production fluid 154a from the first production zone 156a. In such embodiments, the first production fluid 154a enters the gas separator 206a. The gas separator 206a is configured to separate the gaseous medium 204a from the first production fluid 154a before feeding the first production fluid 154a to the first pump 170a. Further, the gas separator 206a is configured to discharge the gaseous medium 204a around the downhole separator 168a. The motor 178a is configured to drive the first pump 170a so as to transfer the first production fluid 154a to the downhole separator 168a. The motor 178a is further configured to drive the downhole separator 168a via the shaft 182a. In certain embodiments, a gear box (not shown) may be disposed between the downhole separator 168a and the first pump 170a and configured to vary the speed of the shaft 182a. The downhole separator 168a is configured to generate a hydrocarbon rich stream 130a and a water stream 200a from the first production fluid 154a. The first surface separator 106 is configured to receive the hydrocarbon rich stream 130a from the downhole separator 168a and generate oil 134 and a water rich stream (not shown in
A gas manifold 202a is disposed at a surface of the earth and coupled to the gas tube 208 via a wellhead 210a. The gas manifold 202a is used to discharge the gaseous medium 204a collected within the first wellbore 146a and around the downhole separator 168a to a discharge storage facility, a compressor, or the like. The first tube 172a is used to dispose the water stream 200a from the downhole separator 168a to the first disposal zone 158a through a plurality of perforations 212 formed in the first wellbore 146a. In such embodiments, the first disposal zone 158a is located above the first production zone 156a.
The first sensor 120b is configured to measure density of the hydrocarbon rich stream 130a in the first channel 110b. The second sensor 120f is configured to measure a flow rate of the hydrocarbon rich stream 130a. The first sensor 120b is configured to generate a first signal 140b representative of the density of the hydrocarbon rich stream 130a. The second sensor 120f is configured to generate a second signal 140f representative of the flow rate of the hydrocarbon rich stream 130a. The control unit 122 is configured to receive at least one of the first signal 140b and the second signal 140f from the first sensor 120b and the second sensor 120f respectively. In one embodiment, the control unit 122 is configured to generate the signal 142b to regulate the control valve 124b to control an outlet pressure of the hydrocarbon rich stream 130a flowing through the first channel 110b to the first surface separator 106. In some other embodiments, the control unit 122 is configured to generate a signal 142f for controlling a speed of the motor 178a. In one or more embodiments, the control unit 122 is configured to determine the amount of water content in the hydrocarbon rich stream 130a by comparing obtained value from the first signal 140b and the second signal 140f with predefined values stored in a look-up table, database, or the like.
The well-partition well 104d includes a second wellbore 146b drilled from the surface 147 of the earth. The second wellbore 146b extends up to a predetermined depth from the surface 147 to form a vertical leg 148b. The well-partition well 104d further includes a lateral leg 150b which is coupled to the vertical leg 148b via a leg junction 152b. The lateral leg 150b is used to receive a second production fluid 154b from a second production zone 156b. The well-partition well 104d further includes a second disposal zone 158b located above the second production zone 156b. Additionally, the well-partition well includes a water zone 160 located below the surface 147 of the earth and above the second disposal zone 158b. The second wellbore 146b includes a plurality of perforations 164a proximate to the leg junction 152b for extracting the second production fluid 154b from the second production zone 156b into the second wellbore 146b.
The system 102 further includes a second pump 170b, a packer 174b, and a gas tube 208a. The second wellbore 146b includes a plurality of perforations 212b for disposing a water rich stream 136 into the second disposal zone 158b.
The first surface separator 106 is directly coupled to the second pump 170b which is disposed within the second wellbore 146b. In one embodiment, the second pump 170b is an electrical submersible pump. In such embodiments, the second pump 170b may include a gas separator (not shown) configured to separate a gaseous medium 204b from the second production fluid 154b and discharge the gaseous medium 204b below the packer 174b in the second wellbore 146b. In some other embodiments, the second pump 170b may be a rod pump or the like. The well-partition well 104d does not include a downhole separator. The packer 174b is disposed within the second wellbore 146b and located downstream relative to the second pump 170b. The packer 174b is used to prevent mixing of the water rich stream 136 with the second production fluid 154b.
The production tubing 194b is inserted through the packer 174a and coupled to the second pump 170b and the second channel 112. Further, the gas tube 208a is also inserted through the packer 174b such that one end of the gas tube 208a is disposed below the packer 174b. A gas manifold 202b is disposed at the surface 147 of the earth and coupled to another end of the gas tube 208a via a wellhead 210b. The gas manifold 202b is configured to discharge a gaseous medium 204b collected within the second wellbore 146b to the discharge storage facility, a compressor, or the like.
During operation, the second wellbore 146b receives the second production fluid 154b from the second production zone 156b. In such embodiments, a motor (not shown) is used to drive the second pump 170b so as to transfer the second production fluid 154b to the first surface separator 106. The first surface separator 106 is configured generate oil 134 and water rich stream 136 from the second production fluid 154b and the hydrocarbon rich stream.
As discussed earlier, the control unit 122 is configured to receive a signal 140d representative of the density of the water rich stream 136 from the sensor 120d and determine an amount of oil content in the water rich stream 136. Further, the control unit 122 is configured to generate a signal 142d to regulate the control valve 124d to allow a flow of the water rich stream 136 through the second tube 116 to the second surface separator 108. In one embodiment, the control unit 122 may determine the amount of oil content in the water rich stream 136 by comparing an obtained value from the signal 140d with a predefined value stored in a look-up table, database, or the like.
In one embodiment, if the amount of oil content in the water rich stream 136 is below a predefined limit, the control unit 122 may bypass the water rich stream 136 via a bypass channel 144 bypassing the second surface separator. In such an example, the first surface separator 106 is configured to directly transfer the water rich stream 136 to the second disposal zone 158b.
In accordance with one or more embodiments discussed herein, an exemplary system and method discloses disposing water produced from a plurality of wells of a well-pad in a well-partition. Hence, the need to have a separate gathering lines, pumping equipment, or trucks for transferring the produced water away from production sites is avoided. The employment of first and second surface separators for further separation and disposal of the water rich stream facilitates the underlying downhole separator in at least one well to operate at a reasonable efficiency.
While only certain features of embodiments have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended embodiments are intended to cover all such modifications and changes as falling within the spirit of the invention.
This patent application claims priority and benefit under 35 U.S.C. §119(e) from U.S. Provisional Application No. 62/195,814 (GE DOCKET NO. 281177-1) entitled “SYSTEM AND METHOD FOR WELL PARTITION AND DOWNHOLE SEPARATION OF WELL FLUIDS”, filed on Jul. 23, 2015, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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62195814 | Jul 2015 | US |