In wellsite sampling and testing, downhole fluid retrieved from subterranean formations often includes particulate matter and/or objects that can damage sensitive downhole testing equipment. Current filtering solutions to filter particulate matter from the downhole fluid may become clogged very quickly, may be difficult to clean and/or replace, and/or may be tailored for a particular type of matter, all of which may result in these filtering solutions being ineffective, expensive and time consuming.
The present disclosure is best understood from the following detailed description when read with the accompanying figures. It is emphasized that, in accordance with the standard practice in the industry, various features are not drawn to scale. In fact, the dimensions of the various features may be arbitrarily increased or reduced for clarity of discussion.
It is to be understood that the following disclosure provides many different embodiments, or examples, for implementing different features of various embodiments. Specific examples of components and arrangements are described below to simplify the present disclosure. These are, of course, merely examples and are not intended to be limiting. In addition, the present disclosure may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed. Moreover, the formation of a first feature over or on a second feature in the description that follows may include embodiments in which the first and second features are formed in direct contact, and may also include embodiments in which additional features may be formed interposing the first and second features, such that the first and second features may not be in direct contact.
The example systems and methods described herein may be used to filter and collect downhole fluid samples retrieved from a subterranean formation. One or more sampling chambers may be coupled in series, where one of the sampling chambers may collect and/or filter downhole fluid at a given time such that a plurality of filtering and sampling operations may be performed. In other words, each of the sampling chambers may be used in a corresponding sampling operation. Of course, if desired, more than one sampling chamber may be used in connection with a given sampling operation.
The sampling chambers may each have one or more cone-shaped filters and the flow of downhole fluid into the sampling chambers may be controlled by respective spool valves. A spool valve may be initially in a first operating position in which the spool valve may direct downhole (e.g., formation) fluid from a first or inlet port to a sampling line on a second or outlet port. The spool valve may then be moved or otherwise controlled to be in a second operating position in which the spool valve may cut off or prevent the flow of fluid to the sampling line.
From the sampling line, the downhole fluid may flow into the sampling chamber, where the downhole fluid is filtered by one or more cone-shaped filters. A first cone-shaped filter to filter the downhole fluid may be the coarsest filter of the cone-shaped filters and may capture the largest matter or objects from the downhole fluid while allowing downhole fluid and smaller matter, particles and/or objects to pass through. Additional filters may capture progressively smaller objects and/or particles from the downhole fluid. In general, the cone shape of the filters may increase the surface area and volume to filter the downhole fluid and may also prevent clogging of the filters. Additionally, by passing the downhole fluid through multiple, progressively finer filters, the filters may be less likely to clog than a single filter configured to filter all fluids passing through the single filter.
When the downhole fluid has passed through all filters in the sampling chamber, the filtered fluid may be collected in a portion of the sampling chamber and/or may exit the sampling chamber to be collected in another portion of a downhole tool. When the sampling chamber is full or at some operator-determined time, the spool valve may be moved into the second or closed position to cut off or prevent fluid flow to the sampling chamber and redirect the downhole fluid to another spool valve and/or sampling chamber. To close the spool valve, the spool valve may provide a pressure port. In this manner, fluid (i.e., hydraulic) pressure may be applied to the pressure port on the spool valve to overcome a spring force holding the spool valve in the first, sampling or open position to move the spool valve to the second position. A locking pin may then lock the spool valve in the second position. If multiple spool valves have pressure ports that are fluidly coupled in parallel, the spool valves may have different spring pressures or forces to allow each of the spool valves to be moved to the second or closed position one at a time. That is, the spool valves may be operated (e.g., closed) in a desired sequence at different times to facilitate a downhole fluid filtering and/or sampling operation.
As illustrated in
In the example depicted in
The example bottom hole assembly 100 of
The example LWD tools 120 and 120A of
The logging and control computer 160 may include a user interface that enables parameters to be input and or outputs to be displayed that may be associated with an extent of a zone invaded by the drilling fluid (e.g., filtrate), measurements obtained and/or predictions associated with sampling a formation F. While the logging and control computer 160 is depicted uphole and adjacent the wellsite system, a portion or all of the logging and control computer 160 may be positioned in the bottom hole assembly 100 and/or in a remote location.
The example LWD tool 200 of
The LWD tool 200 may be provided with devices such as, for example, a chamber 245 for collecting fluid samples for retrieval at the surface. Backup pistons 225 may also be provided to assist in applying force to push the LWD tool 200 and/or the probe 205 against the borehole wall 220.
One or more aspects of the probe assembly 316 may be substantially similar to those described above in
The flow of downhole fluid into the sampling chambers 402a-402c is controlled by a plurality of spool valves 404a, 404b, and 404c. Generally, one spool valve 404a, 404b, or 404c is provided for each of the sampling chambers 402a-402c to control the flow of downhole fluid into the sampling chambers 402a-402c. However, multiple spool valves may be used with each chamber, if desired. Each example spool valve 404a, 404b, and 404c has two positions: a sampling, filtering or open position and a bypass or closed position. When the spool valve 404a is in the sampling, filtering or open position, downhole fluid may flow into the corresponding sampling chamber 402a. When the spool valve 404a is in the bypass position, downhole fluid is prevented from flowing into the sampling chamber 402a and instead is directed to flow to the next spool valve 404b in line. In other words, the sampling chambers 402a-402c and the spool valves 404a-404c are arranged in a series configuration to enable a cascade filtering and/or sampling operation with the chambers 402a-402c.
To allow downhole fluid into the example downhole filtering and sampling apparatus 400 (e.g., from the probe assembly 316 of
The first spool valve 404a is fluidly coupled to the second spool valve 404b via a transfer line 412a. Similarly, the second spool valve 404b is fluidly coupled to the third spool valve 404c via a transfer line 412b. While the spool valve 404a is in the sampling position, the transfer line 412a does not have any fluid flowing therein. When the spool valve 404a is moved or operated to be in the bypass position, the transfer line 412b becomes fluidly coupled to the seal valve 406 via the spool valve 404a. Thus, with the spool valve 404a in the bypass position, downhole fluid may flow from the seal valve 406 through the spool valve 404a and the transfer line 412a to the spool valve 404b. Similarly, while the spool valve 404b is in the sampling position, the transfer line 412b does not have any fluid flowing therein. When the spool valve 404b is moved or operated to the bypass position and the spool valve 404a is already in the bypass position, the transfer line 412b becomes fluidly coupled to the seal valve 406 via the spool valves 404a and 404b. The downhole filtering and sampling apparatus 400 also includes a transfer line 412c to allow fluid to flow from the final spool valve 404c when the spool valve 404c is in the bypass position.
The example downhole filtering and sampling apparatus 400 further includes a setting line 414. As described in more detail below, the setting line 414 may be used by an operator of the downhole filtering and sampling apparatus 400 to control the spool valves 404a-404c, to bleed pressure and/or collect fluid from the sampling chambers 402a-402c and/or from the final spool valve (shown in
The operator of the downhole filtering and sampling apparatus 400 may increase the fluid (e.g., hydraulic fluid) pressure in the setting line 414 via a pump-out module 416 to cause one or more of the spool valves 404a-404c to move to the bypass position. The example pump-out module 416 is fluidly coupled to the setting line 414 via the seal valve 408 and, thus, may increase the fluid pressure in the setting line 414 when the seal valve 408 is open and the seal valve 406 is closed.
As depicted in
In the example of
The number of sampling chamber 402a-402c that may be disposed in the downhole filtering and sampling apparatus 400 is dependent on the pressure that can be withstood by the materials and joints in the downhole filtering and sampling apparatus 400, as well as the precision with which the setting line 414 pressure may be controlled. As precision of control over the setting line 414 pressure increases, the springs forces or constants may be spaced closer together within the range of pressures that the downhole filtering and sampling apparatus 400 can withstand.
To bypass all of the sampling chambers 402a-402c and allow downhole fluid to flow between the seal valves 406 and 408 in either or both directions, the operator of the downhole filtering and sampling apparatus 400 may increase the pressure in the setting line 414 to burst a pressure disk 418. The example pressure disk 418 may withstand pressures greater than the highest pressure to move all spool valves 404a-404c to their bypass or closed positions. If the burst pressure of the pressure disk 418 is lower than the pressure to close any of the spool valves 404a-404c, the pressure disk 418 may burst before all of the spool valves 404a-404c move to their bypass or closed positions. Accordingly, the spool valves 404a-404c are all configured to be in a bypass position at a pressure which is lower than the burst pressure of the example pressure disk 418 and, when the pressure disk 418 is burst, the seal valves 406 and 408 are directly fluidly coupled via the setting line 414 and allow downhole fluid to flow in either or both directions.
The setting line 414 may also be used to bleed pressure from the sampling chambers 402a-402c via respective check valves 420a-420c. The check valves 420a-420c allow fluid to flow in only one direction (e.g., from the sampling chambers 402a-402c to the setting line 414). The check valves 420a-420c may be fluidly coupled to the respective sampling chambers 402a-402c such that any downhole fluid that exits via the check valves 420a-420c is filtered downhole fluid. As described below, the filters within the sampling chambers 402a-402c may filter a large amount of downhole fluid without clogging and, thus, a large amount of filtered downhole fluid may exit via the seal valve 408 and be directed to any other portion of a tool for storage or other uses.
The setting line 414 may further be used to bleed pressure from the final spool valve 404c via the transfer line 412c and a check valve 422. The check valve 422 allows fluid to flow from the spool valve 404c to the setting line 414. To bleed pressure, an operator of the downhole filtering and sampling apparatus 400 may reduce the pressure in the setting line 414 (e.g., via the pump out module 416) to a pressure less than that of the sampling chambers 402a-402c and/or the transfer line 412c. The appropriate check valve(s) 420a, 420b, 420c, and/or 422 will then allow fluid to flow from respective ones of the sampling chambers 402a-402c and/or the transfer line 412c to the setting line 414 and out the seal valve 408.
The example downhole filtering and sampling apparatus 400 may further include equalization lines 424a and 424b. The equalization line 424a fluidly couples the sampling chambers 402a and 402b to equalize the pressures of the sampling chambers 402a and 402b relative to each other. Similarly, the equalization line 424b fluidly couples the sampling chambers 402b and 402c to equalize the pressures of the sampling chambers 402b and 402c relative to each other. Thus, the equalization lines 424a and 424b maintain the pressures in the sampling chambers 402a-402c equal.
The example spool valve includes a fluid flow control member or piston 502 to move between the sampling position as illustrated in
In the sampling position shown in
The example spool valve further includes an escape line 518 that fluidly couples a chamber 519 surrounding the spring 516 to the port 510. The escape line allows the spring 516 to compress when surrounded by fluid. While the escape line 518 is shown as coupled to the port 510, the escape line 518 may be coupled to one or more of the other ports 508, 512, and/or 514, provided that fluid can flow from the chamber 519 surrounding the spring 516 through the escape line 518 to equalize pressure in the chambers (e.g., the chambers 402a-402c of
To secure the example piston 502 when the bypass position has been achieved, the example spool valve 500 includes a locking pin 520 or, more generally, a lock 521. The example lock 521 further includes a locking spring 522 to push the locking pin 520 toward the piston 502. The piston 502 has a locking aperture or hole 524, and the spool valve 500 includes a locking slot 526 that receives the locking pin 520 when the bypass position is achieved. When the piston 502 is pushed toward the spring 516 due to fluid or hydraulic pressure from the setting line 414, the locking hole 524 passes over the locking pin 520 and locking slot 526, at which time the locking spring 522 pushes the locking pin 520 into the locking hole 524 and the locking slot 526. The final position of the locking pin 520, the locking spring 522, the locking hole 524 and the locking slot 526 are illustrated in
The example spool valve 502 further includes a plurality of seals 528 (e.g., o-rings). The seals 528 prevent undesired fluid communication between the ports 508-514 and/or the setting line 414.
To install the piston 502 and the spring 516, the example spool valve 500 may include a cap 530. Similarly, a cap 532 may be provided to install (and enable resetting of) the locking pin 520 and the locking spring 522. When assembling the spool valve 500, the example piston 502 is inserted. The spring 516 may then be inserted and compressed, and the cap 530 may then be installed to retain the spring 516 and the piston 502. When the piston 502 is installed, the locking pin 520 and locking spring 522 may be inserted. The cap 532 is then installed to retain the locking pin 520 and locking spring 522.
The example piston 502 is further provided with a glide ring 534 to allow the piston 502 to slide or move easily within the spool valve. The glide ring 534 may be used to block fluid flow to a port (e.g., the port 510 or 514) that is not considered open. For example, in
In the downhole filtering and sampling apparatus 400 of
As shown in
While the example spool valve 500 illustrated in
Additionally, the locking pin 520, the locking spring 522, the locking hole 524, the locking slot 526 and/or, more generally, the lock 521 may be implemented using any locking mechanism or member to lock the piston 502 or prevent the piston 502 from moving from the bypass or closed position. Other locking or arresting mechanisms that may be used to implement the lock 521 include, but are not limited to, locking rings, locking clips, friction locks, electromechanical locks, electropneumatic locks, electromagnetic locks, or similar mechanisms.
The example process 700 may begin with the wireline tool 300 disposed downhole and provided with the example downhole filtering and sampling apparatus 400. An operator of the downhole filtering and sampling apparatus 400 may determine whether to bypass one or more remaining sampling chambers 402a-402c to allow bidirectional fluid circulation (e.g., downhole fluid flow in either or both directions (i.e., bidirectional fluid circulation) between the seal valves 406 and 408) (block 701). If the operator does not want to allow bidirectional fluid circulation (block 701), the operator may determine whether to bypass one or more remaining sampling chambers 402a-402c while maintaining forward downhole fluid flow (e.g., from the seal valve 406 to the seal valve 408 via the remaining sampling chambers 402a-402c) (block 702). If the operator desires to collect samples using one or more remaining sampling chambers and, thus, to not bypass these chambers (block 702), the seal valves 406 and 408 are closed (block 704). The operator of the downhole filtering and sampling apparatus 400 positions the sampling tool (e.g., the wireline tool 300) at a desired downhole depth and performs a pressure test (block 706). If the wireline tool 300 determines that the pressure test fails (block 708), control will return to block 706 to reposition the wireline tool 300 and retest.
If the pressure test passes (block 708), the example seal valves 406 and 408 are opened above and below the sampling chambers 402a-402c (block 710). As a result of opening the seal valves 406 and 408, downhole fluid flows into an open sampling chamber (e.g., the chamber 402a) via the spool valve 404a (block 712). The downhole fluid is filtered in the sampling chamber 402a to collect one or more filtered samples of the downhole fluid in the sampling chamber 402a. The example process 700 determines whether the sample collection is finished (e.g., whether the sampling chamber 402a is full, or whether another condition is met) (block 714). If the sample collection is not finished (e.g., if the sampling chamber 402a is not full) (block 714), control loops to block 712 to continue sampling downhole fluid.
When the sample collection is finished (block 714), the example downhole filtering and sampling apparatus 400 increases the pressure in the setting line 414 to activate the spool valve 500 (e.g., the spool valve 404a) to move the spool valve 500 from the sampling position to the bypass position to close the sampling chamber 402a (block 716). In block 714, the pressure 414 should only increase enough to close the spool valve 404a above the now full sampling chamber 402a. If the pressure is increased too much, additional spool valves 404b and 404c may move to the bypass position prematurely, thereby preventing fluid from entering the corresponding sampling chambers 402b and 402c.
The example process 700 then determines whether all sampling chambers 402a-402c have been used (block 718). If all sampling chambers 402a-402c have not been used (block 718), the process 700 determines whether another downhole location is to be sampled (block 720). For example, the operator of the downhole filtering and sampling apparatus 400 may determine whether another downhole location is to be sampled. If the same location is to be sampled using another sampling chamber 402b (e.g., to filter the sample differently) (block 720), control returns to block 712 to pass downhole or formation fluid to another sampling chamber 402b via a corresponding spool valve 500 in the sampling position (e.g., the spool valve 404b). If a different location is to be sampled (block 720), control returns to block 704 to close the seal valves 406 and 408 in preparation to reposition the wireline tool 300. Although not illustrated in
When all sampling chambers 402a-402c have been used (block 718), the setting line 414 increases fluid or hydraulic pressure to close the final sampling chamber 402c (block 722). Closing the sampling chamber 402c may include moving the spool valve 404c to a bypass or closed position.
If the operator of the example downhole filtering and sampling apparatus 400 determines that one or more sampling chambers 402a-402c should be bypassed and forward flow is desired (block 702), control passes to block 722 to increase the pressure in the setting line 414 to close any remaining sampling chambers. If the operator determines that one or more sampling chambers 402a-402c should be bypassed and bidirectional flow is desired (block 701), control passes to block 724 to increase the pressure in the setting line 414 to burst a disk (e.g., the disk 418) (block 724). When the disk 418 is burst, the seal valves 406 and 408 are fluidly coupled and downhole fluid may bypass the spool valves 404a-404c and the sampling chambers 402a-402c. After either block 722 or 724, the example process 700 may end.
The example method 700 and the example downhole filtering and sampling apparatus 400 may be used with the example MWD or LWD systems described with reference to
The example upper block 802 is generally coupled to the first sampling chamber 800 (e.g., the sampling chamber 402a of
The example mandrel 814, in addition to supporting the filters 806-812, may conduct electrical signals and/or fluids between the upper block 802 and the intermediate adaptor 804. The mandrel 814 is shown and described in more detail below in connection with
As illustrated in
The example mandrel 814 illustrated in
The sampling chamber 800 may include one or more filters 916 and 918 to filter solids of different sizes from downhole fluids. For example, the sampling chamber 800 illustrated in
The mandrel transfer line 908 and the mandrel setting line 912 are fluidly coupled to respective ones of the transfer line 412 and the setting line 414 via hollow stabbers 928. The mandrel equalizing line 910 is also coupled to an upper block equalizing line 930 via a stabber 928. The upper block equalizing line 930 is a dead end because the equalizing line 910 fluidly couples different sampling chambers and the upper block 802 is one end of a cascade of sampling chambers. To prevent fluid coupling of the upper block transfer line 412, the upper block setting line 414, the electrical line 906, the mandrel transfer line 908, the mandrel equalizing line 910, and/or the mandrel setting line 912 to the sampling chamber 800 (e.g., the volume 920), the stabbers 928 are encircled by one or more seals 932. The seals 932 also function to hold the stabbers 928 and the mandrel 814 in place.
The mandrel electric line 906 is coupled to an electric line 937 in the upper block 802 via one or more pins 934 corresponding to the conductors 914. The upper block 802 includes one or more receptors 936 to make contact with the pins 934, and also includes one or more conductors 938. The conductors 938 conduct one or more signals to upper block pins 940, which may conduct the signals to or from another downhole or surface location.
The example mandrel 814 is aligned by one or more keys 942, which fit into one or more corresponding recesses or slots 944 in the upper block 802. One or more seals 946 may fluidly decouple the sampling chamber 800 (e.g., the volume 920) from the lines 906-912 through the mandrel 814 and the lines 904, 412, and/or 414 in the upper block 802.
To mechanically couple the upper block 802 to the sampling chamber 800, the upper block 802 may include a threaded ring 948. The upper block 802 has corresponding threads to mechanically couple the upper block 802 to the sampling chamber 800 via the threaded ring 948. To prevent fluid coupling of the sampling chamber 800 to the outside of the example apparatus 400, the upper block 802 and/or the sampling chamber 800 further includes one or more seals 950.
The mandrel 814 is inserted into the sampling chamber 800 at a surface location. One or more cone-shaped filters 916 and 918 and one or more spacers 926 are then inserted into the sampling chamber 800 around the mandrel 814. Some example cone-shaped filters 916 and/or spacers 926 may include notches to slide over the keys 942. The filters 916 and 918 and the spacers 926 may be alternately inserted to space the filters 916 and 918. To prevent air or other gas from becoming trapped in the sampling chamber 800 and/or the mandrel 814 and compressed downhole, the example sampling chamber 800 and/or the example mandrel 814 may be filled with a fluid such as an oil or water prior to continuing assembly.
When the filters 916 and 918 and the spacers 926 are inserted into the sampling chamber 800, the upper block 802 is coupled to the sampling chamber 800 via the threaded ring 948 and the one or more seals 950. When the upper block 802 and sampling chamber 800 are mechanically coupled, the mandrel lines 906-912 become electrically and/or fluidly coupled to the respective upper block lines 412, 414, 930, and/or 938. For example, the electrical pins 934 on the mandrel 814 mate with the receptors 936 on the upper block 802. Additionally, the stabbers 928 and the seals 932 fluidly couple the mandrel transfer line 908 to the transfer line 412, the mandrel equalizing line 910 to the upper block equalizing line 930, and/or the mandrel setting line 912 to the setting line 414.
In operation, when the example sampling chamber 800 and the example upper block 802 are inserted downhole to filter and collect a fluid sample, the example spool valve 500 is in a sampling position as shown. In the sampling position, the seal valve 406 is opened to allow fluid to enter the flowline 902. A second seal valve (e.g., the seal valve 408 of
In the sampling position, the piston 502 allows fluid to flow from the flowline 902 to the sampling line 904 and into the sampling chamber 800 (e.g., the volume 920). In the sampling position, the piston 502 also blocks or prevents fluid from flowing from the flowline 902 to the transfer line 412. As downhole fluid enters the sampling chamber 800 from the sampling line 904, the downhole fluid displaces any fluid placed in the sampling chamber 800 at the surface. The displaced fluid may exit the sampling chamber 800 via the equalizing line 910 as shown in
The downhole fluid enters the first volume 920 and is first filtered by the filter 916 to enter the second volume 922. The filter 916 is the coarsest of the filters 916 and 918 and retains the largest objects. Thus, the downhole fluid that enters the second volume 922 does not include objects as large as those that enter the volume 920. The downhole fluid then passes through the filter 918, which is finer than the example filter 916, to reach the third volume 924. The filter 918 removes smaller objects and/or particles from the downhole fluid than the filter 916. The downhole fluid in the volume 924 includes smaller particles than those in the volumes 922 and 920. When the sampling chamber 800 is retrieved at the surface, three different fluid samples may be retrieved from the different volumes 920-924. While only two filters 916 and 918 and three volumes 920-924 are illustrated in
When the sampling chamber 800 is filled with downhole fluid, or at the direction of an operator at the surface, the example upper block 802 may move the piston 502 to a bypass or closed position. To move the piston 502, the setting line 414 (e.g., via the mandrel setting line 912) increases fluid pressure relative to the flowline 902. The fluid pressure overcomes the force applied to the piston 502 via the spring 516 to push the piston 502 toward the spring 516. The spool valve 500 then enters the bypass position as illustrated in
When the piston 502 moves to the bypass position, the fluid passage 504 no longer allows fluid flow between the flowline 902 and the sampling line 904. Instead, the fluid passage 506 allows fluid to flow from the flowline 902 to the transfer line 412 and the mandrel transfer line 908. The fluid may then flow to, for example, an intermediate adaptor 804 as illustrated in
As described in connection with
The example equalizing line 910 includes an equalizing port 1002 to fluidly couple the sampling chamber 800a to the equalizing line 910. Fluid may enter and/or exit the equalizing line 910 from the sampling chamber 800a via the equalizing port 1002. The sampling chamber 800a further includes a filter 1004 to filter downhole fluid. The filter 1004 separates volumes 1006 and 1008, and filters the fluid from the volume 1006 to remove particles in the downhole fluid. As a result, the example downhole fluid in the volume 1008 is the most-filtered downhole fluid in the sampling chamber 800a. In some applications, the filter 1004 may be sufficiently fine to remove sand or other very fine particulate matter from a downhole fluid sample.
To couple the mandrel 814a to the intermediate adaptor 804, the example sampling chamber 800a includes a threaded ring 948 similar to the threaded ring 948 illustrated in
The intermediate adaptor 804 further includes a transfer line 412, a setting line 414, and an electrical line 1014. The example electrical line 1014 includes one or more conductors 1016 to transfer electrical signals and/or power along the wireline tool 300. The conductors 1016 are terminated at respective pins 934. The pins 934 are mated to receptors 936 at the mandrel electrical line 906 when the sampling chamber 800a is mechanically coupled to the intermediate adaptor 804.
The transfer line 412 is coupled to the mandrel transfer line 908 via a stabber 928, and performs in substantially the same manner as the example transfer line 412 described in connection with
The example setting line 414 is coupled to the mandrel setting line 912 via a stabber 928. Additionally, the setting line 414 is coupled to the sampling chamber 800a (e.g., the volume 1008) via a check valve 420. The check valve 420 allows fluid to flow from the sampling chamber 800 to the setting line 414. For example, the check valve 420 may bleed pressure from the sampling chamber 800 and/or may allow fluid used to fill the sampling chamber 800a at the surface to escape as the filling fluid in the sampling chamber 800a is displaced with downhole fluid.
The spool valve 500 is set to a sampling position at a surface location. While in the sampling position, the spool valve 500 (e.g., via the fluid passage 504) fluidly couples the flowline 1010 to a sampling line 1018. The sampling line 1018 is also fluidly coupled to the sampling chamber 800b to allow downhole fluid to flow into the sampling chamber 800b for filtering and/or sampling.
The example intermediate adaptor 804 is further mechanically coupled to the sampling chamber 800b via a threaded ring 948 and one or more seals 950. A second mandrel 814b includes an electrical line 1022, a transfer line 1024, an equalizing line 1026, and a setting line 1028. The example electrical line 1022 includes one or more conductors 1030 to transmit electrical signals and/or power along the wireline tool 300. The conductors 1030 may be electrically coupled to corresponding conductors 1016 in the intermediate adaptor 804 electrical line 1014.
The example mandrel transfer line 1024 is coupled to the transfer line 412 via a stabber 928 and may allow downhole fluid to flow from the transfer line 412 when the spool valve 500 is in the bypass position. The transfer line 1024 may also be fluidly coupled to, for example, another intermediate adaptor 804 or a base block 816 as described below in connection with
The equalizing line 1026 is coupled to the equalizing line 1012 via a stabber 928. The equalizing line 1026 may allow fluid to flow to equalize fluid pressures between the sampling chambers 800a and 800b.
The setting line 1028 is fluidly coupled to the setting line 414 via a stabber 928. The setting line 1028 may allow fluid to flow, for example, to move the piston 502 to the bypass position, to bleed pressure from the sampling chamber 800a, and/or to provide fluid to another intermediate adaptor 804 and/or an upper block 802.
The example mandrels 814a and 814b may be aligned by one or more keys 942, which fit into one or more corresponding slots or recesses 944 in the intermediate adaptor 804. One or more seals 946 may fluidly decouple the sampling chamber 800a from the lines 906-912 through the mandrel 814a and the lines 1010, 1212, and/or 414 in the intermediate adaptor 804. Additionally or alternatively, one or more seals 946 may fluidly decouple the sampling chamber 800b from the lines 1022-1028 through the mandrel 814b and the lines 1012, 412, and/or 414 in the intermediate adaptor 804.
While the illustrated portion of the sampling chamber 800b does not show filters, one or more filters may be inserted into the sampling chamber 800b to filter downhole fluid and to separate different volumes. An example volume 1032 is illustrated in
The example mandrel 814 includes the example electrical line 906, the example transfer line 908, the example equalizing line 910, and the example setting line 912 described in connection with
The example base block 816 includes a transfer line 412 fluidly coupled to the mandrel transfer line 908 via a stabber 928. The example transfer line 412 may transfer fluid from the mandrel transfer line 908 to the setting line 414. When an upper block (e.g., the upper block 802 of
The setting line 414 is fluidly coupled to the mandrel setting line 912 via a stabber 928. The setting line 414 is further fluidly coupled to the seal valve 408, which may open and close to increase and/or decrease fluid pressure in the setting line 414 via the pump-out module 416. The pump-out module 416 may receive electrical signals and/or power from, for example, the electrical line 1106. A check valve 420 may be used to bleed pressure from the sampling chamber 800 to the setting line 414.
The example base block 816 further includes an equalizing line 1104 fluidly coupled to the mandrel equalizing line 1104 via a stabber 928. The example equalizing line 1104 is a dead-end chamber to cause the sampling chamber 800 to equalize fluid pressure with other sampling chambers 800.
The base block 816 further includes an electrical line 1106. The example electrical line 1106 includes one or more conductors 1108 to transfer electrical signals and/or power along the wireline tool 300. The conductors 1108 may be electrically coupled to the mandrel electrical line 906 via one or more pins 934, which are mated to corresponding receptors 936 on the mandrel 814. The base block 816 includes one or more receptors 1110 to electrically couple the conductors 1108 to an external device on the wireline tool 300.
The base block 816 may be mechanically coupled to the sampling chamber 800 via a threaded ring 948 and one or more seals 950. The example mandrel 814 is aligned by one or more keys 942, which fit into one or more corresponding slots or recesses 944 in the base block 816. One or more seals 946 may fluidly decouple the sampling chamber 800 from the lines 906-912 of the mandrel 814 and the lines 1104, 412, and/or 414 in the base block 804. Seals 932 may also be used to fluidly decouple the lines 906-912 of the mandrel 814 and the lines 1104, 412, and/or 414 from the sampling chamber 800 and/or from each other.
The example electrical line 906 includes the receptors 936 to receive corresponding pins (e.g., the pins 934 of
The keys 942 may be coupled to the outer housing 1200 to guide a mechanical coupling of the mandrel 1200 to an upper block (e.g., the upper block 802 of
The example cone-shaped filters 1302-1308 may be used to filter objects from a downhole fluid sample collected from a subterranean formation. In the example of
The cone-shaped filters 1302-1308 are inserted into the sampling chamber 1300 around a mandrel 1310. The mandrel 1310 provides support to the filters 1302-1308 to maintain the filters in position. The filters 1302-1308 are separated by spacers 1312, 1314, and 1316. The spacers 1312-1316 are inserted over the mandrel alternately with the filters 1302-1308, and may be different lengths to adjust the amounts of space between the filters 1302-1308. The example sampling chamber 1300 is divided into volumes 1318, 1320, 1322, 1324, and 1326 by the filters 1302-1308. Therefore, as the spacers 1312-1316 increase in length, respective ones of the volumes 1318-1326 increase. In the illustrated example, the length of the spacer 1312 affects the size of the volume 1320.
The volumes 1318-1326 collect downhole fluid samples that may be retrieved at the surface. Because each filter 1302-1308 screens different sizes of matter or particulate from the downhole fluid, the volumes 1318-1326 may have different properties of fluid samples due to the different sizes of matter contained within.
The filter 1304 includes an inside ring 1328 and an outside ring 1330 to prevent downhole fluid from bypassing the filter 1302. The inside and outside rings 1328 and 1330 may seal along the outside of the sampling chamber 1300 and along the mandrel, respectively. The filters 1302, 1306, and 1308 include similar or identical inside rings 1332, 1334, and 1336, respectively, and/or similar or identical outside rings 1340 and 1342. The outside ring of the example filter 1302 is not shown. The rings 1328-1342 help maintain integrity of different downhole fluid samples in the different volumes 1318-1326. An additional ring 1344 around the mandrel 1310 may help seal the sampling chamber 1300 (e.g., the volume 1326) and determine the size of the volume 1326.
The example cone-shaped filters 1302-1308 may be manufactured using any of several methods. A first method that may be used is to machine a cone from a solid metal bar and perforate the outside with the desired screen pattern. A second method that may be used is to bend one or more perforated metal sheets into a cone shape.
A third method that may be used to form a cone filter is placing a very fine filter, such as a filter made of fabric, between two or more metal screens. In general, the very fine filters may be subject to tearing or other breach. Therefore, the filter may be strengthened by placing the filter between two cone-shaped metal sheets that are perforated in a pattern such as those illustrated in
A fourth method that may be used is to mechanically couple (e.g., solder, weld, etc.) a wire frame into a cone shape, and then couple wires around the frame. The spacing between the wires may determine the screen size.
In view of the above and the figures, it should be clear that the present disclosure introduces a system to filter and sample downhole fluids, which includes a first sampling chamber having one or more cone-shaped filters to receive downhole fluid, filter the downhole fluid, and store the downhole fluid, a second sampling chamber, a spool valve having first and second positions to allow the downhole fluid to flow into the first sampling chamber in the first position and to redirect the downhole fluid to the second sampling chamber or a base block in the second position, and a setting line to selectively move the spool valve from the first position to the second position.
The present disclosure also introduces a method to filter and sample downhole fluids, which includes setting a first valve to a first position to allow downhole fluid to flow into a first sampling chamber, filtering the downhole fluid via one or more filters in the first sampling chamber, collecting the downhole fluid in the first sampling chamber, and applying a first pressure to the first valve to set the first valve to a second position to allow fluid to flow into a second sampling chamber.
The present disclosure also introduces a spool valve to route downhole fluid, including a first port, a second port, a third port, and a flow control member, which includes a first flow passage to selectively fluidly couple the first port to the second port when the flow control member is in a first position, a second flow passage to selectively fluidly couple the first port to the third port when the flow control member is in a second position. The spool valve further includes a bias member to exert a force on the flow control member to urge the flow control member toward the first position, a pressure port to apply a pressure to move the flow control member from the first position to the second position, and a lock to prevent the flow control member from moving to the first position after the flow control member has achieved the second position.
The present disclosure also introduces a filter that includes a first plurality of wires to form a cone, a second plurality of wires mechanically coupled to the longitudinal wires to form a wire mesh, a first seal coupled to the first wires at a first end of the cone to prevent a downhole fluid from bypassing the filter, and a second seal coupled to the first wires at a second end of the cone to prevent the downhole fluid from bypassing the filter.
The foregoing outlines features of several embodiments so that those skilled in the art may better understand the aspects of the present disclosure. Those skilled in the art should appreciate that they may readily use the present disclosure as a basis for designing or modifying other processes and structures for carrying out the same purposes and/or achieving the same advantages of the embodiments introduced herein. Those skilled in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the present disclosure, and that they may make various changes, substitutions and alterations herein without departing from the spirit and scope of the present disclosure.
The Abstract at the end of this disclosure is provided to comply with 37 C.F.R. §1.72(b) to allow the reader to quickly ascertain the nature of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.