Wells are generally drilled into the ground to recover natural deposits of oil and gas, as well as other desirable materials, that are trapped in geological formations in the Earth's crust. A well is typically drilled using a drill bit attached to the lower end of a “drill string.” Drilling fluid, or “mud,” is typically pumped down through the drill string to the drill bit. The drilling fluid lubricates and cools the drill bit, and it carries drill cuttings back to the surface in the annulus between the drill string and the borehole wall.
It is often desirable to have information about the subsurface formations that are penetrated by a well. For example, one aspect of standard formation evaluation relates to the measurements of the formation pressure and formation permeability. These measurements are essential to predicting the production capacity and production lifetime of a subsurface formation.
One technique for measuring formation properties includes lowering a “wireline” tool into the well to measure formation properties. A wireline tool is a measurement tool that is suspended from a wire as it is lowered into a well so that is can measure formation properties at desired depths. A typical wireline tool may include a probe that may be pressed against the borehole wall to establish fluid communication with the formation. This type of wireline tool is often called a “formation tester.” Using a probe, a formation tester can measure the pressure of the formation fluids, generate a pressure pulse to determine the formation permeability, and withdraw a sample of formation fluid for later analysis.
In order to use a wireline tool, the drill string must be removed from the well so that the tool can be lowered into the well. This is called a “trip” downhole. Because of the great expense and rig time required to “trip” the drill pipe, wireline tools are generally used only when the information is absolutely needed or when the drill string is tripped for another reason, such as changing the drill bit. Examples of wireline formation testers are described, for example, in U.S. Pat. Nos. 3,934,468; 4,860,581; 4,893,505; 4,936,139; and 5,622,223.
Another technique for measuring formation properties uses measurement tools and devices that are positioned near the drill bit in a drilling system. Measurements are made during the drilling process. A variety of downhole drilling tools, such as logging-while-drilling tools and measurement-while-drilling tools, commercially are available. “Logging-while-drilling”(“LWD”) is used to describe measuring formation properties during the drilling process. Real-time data, such as the formation pressure, allows the driller to make decisions about drilling mud weight and composition, as well as decisions about drilling rate and weight-on-bit, during the drilling process. It is noted that LWD and “measurement-while-drilling”(“MWD”) have different meanings to those having ordinary skill in the art. MWD typically refers to measuring the drill bit trajectory as well as borehole temperature and pressure, while LWD refers to measuring formation parameters, such as resistivity, porosity, permeability, and sonic velocity, among others. The distinction between LWD and MWD is not germane to the present invention, thus, this disclosure does not distinguish between the two terms.
Formation evaluation while drilling tools capable of performing various downhole formation testing typically include a small probe or pair of packers that can be extended from a drill collar to establish fluid communication between the formation and pressure sensors in the tool so that the formation fluid pressure may be measured. Some existing tools use a pump to actively draw a fluid sample out of the formation so that it may be stored in a sample chamber in the tool for later analysis. Such a pump is typically powered by a battery or by a generator in the drill string that is driven by the mud flow.
What is still needed, therefore, are techniques for downhole formation evaluation while drilling tool that are more reliable and efficient, yet able to conserve space in a downhole drill collar.
In some embodiments, the invention relates to a downhole fluid pump that includes a pump chamber and a piston disposed in the pump chamber so that the piston will move in one selected from a charge stroke and a discharge stroke when the piston is exposed to an internal pipe pressure.
In other embodiments, the invention relates to a downhole fluid pump that includes a pump chamber and a hydraulic chamber. The pump may also include a piston assembly having a first piston disposed in the pump chamber and defining a first section of the pump chamber, and a second section of the pump chamber, the piston assembly also having a second piston disposed in the hydraulic chamber and defining a first section of the hydraulic chamber and a second section of the hydraulic chamber. The first piston and the second piston may be connected by a connecting member, wherein the piston assembly is moveable with respect to the pump chamber and the hydraulic chamber. The pump may also include a valve in fluid communication with the pump chamber for selectively placing the pump chamber in fluid communication with a charge line or a discharge line, an internal pipe pressure isolation valve for selectively hydraulically coupling the hydraulic chamber to an internal pipe pressure, and an annular pressure isolation valve for selectively hydraulically coupling the hydraulic chamber to an annular pressure. In some embodiments the pump includes a spring disposed in one of the first section of the hydraulic chamber and the second section of the hydraulic chamber and positioned to exert a force on the piston assembly.
In other embodiments, the invention relates to a method of operating a fluid pump including operating the fluid pump in one selected from the group consisting of a charge stroke and a discharge stroke by applying an annular pressure to a piston, operating the fluid pump in the other of the charge stroke and the discharge stroke by applying an internal pipe pressure to the piston, and selectively repeating the applying the annular pressure to the piston and the applying the internal pipe pressure to the piston.
In some embodiments, the invention relates to a formation evaluation while drilling tool that includes a drill collar, a fluid inlet disposed in the drill collar, and a fluid pump in fluid communication with the fluid inlet. In some embodiments the fluid pump comprises a pump chamber and a first piston disposed in the pump chamber so that the piston will move in one selected from a charge stroke and a discharge stroke when the piston is exposed to an internal pipe pressure.
In some embodiments, the invention relates to a method of formation evaluation that includes establishing fluid communication between a fluid inlet in a formation evaluation while drilling tool and a formation, and drawing fluid into the tool by selectively repeating applying an annular pressure to a first side of a piston and applying an internal pipe pressure to the first side of the piston.
Other aspects and advantages of the invention will be apparent from the following description and the appended claims.
In one or more embodiments, the invention relates to a fluid pump that may be used in a downhole drilling environment. In some embodiments, the invention relates to a method for using a fluid pump. In one or more embodiments, the invention relates to a formation evaluation while drilling tool that includes a fluid pump. In some other embodiments, the invention relates to a method of formation evaluation while drilling. The invention will now be described with reference to the attached drawings.
The phrase “formation evaluation while drilling” refers to various sampling and testing operations that may be performed during the drilling process, such as sample collection, fluid pump out, pretests, pressure tests, fluid analysis, and resistivity tests, among others. It is noted that “formation evaluation while drilling” does not necessarily mean that the measurements are made while the drill bit is actually cutting through the formation. For example, sample collection and pump out are usually performed during brief stops in the drilling process. That is, the rotation of the drill bit is briefly stopped so that the measurements may be made. Drilling may continue once the measurements are made. Even in embodiments where measurements are only made after drilling is stopped, the measurements may still be made without having to trip the drill string.
In this disclosure, “hydraulically coupled” is used to describe bodies that are connected in such a way that fluid pressure may be transmitted between and among the connected items. The term “in fluid communication” is used to describe bodies that are connected in such a way that fluid can flow between and among the connected items. It is noted that “hydraulically coupled” may include certain arrangements where fluid may not flow between the items, but the fluid pressure may nonetheless be transmitted. Thus, fluid communication is a subset of hydraulically coupled.
The lower end of the drill string 105 includes a bottom-hole assembly 110 (“BHA”) that includes the drill bit 107, as well as a number of drill collars (e.g., 112, 114) that may include various instruments, such as LWD or MWD sensors and telemetry equipment. A formation evaluation while drilling tool may, for example, be disposed in a stabilizer 114. The stabilizer 114 includes blades 115 that are in contact with the borehole wall and reduce the “wobble” of the drill bit 107. “Wobble” is the tendency of the drill string, as it rotates, to deviate from the vertical axis of the wellbore and cause the drill bit to change direction. Advantageously, a stabilizer 114 is already in contact with the borehole wall, thus, requiring less extension of a probe to establish fluid communication with the formation fluids. Those having ordinary skill in the art will realize that a formation evaluation while drilling tool could be disposed in locations other than in a stabilizer without departing from the scope of the invention.
The tool 601 includes subsections, or modules, that house instruments for performing downhole operations. For example, subsection 602 is a battery module that includes a battery to power the electronics in the control system. Subsection 604 is a mandrel e-chassis that houses the electronic control systems and the telemetry equipment. Subsection 606 is a hydraulic module that controls the distribution of hydraulic power through the tool. Those having ordinary skill in the art will realize that other subsections or modules may be included in a formation evaluation while drilling tool, without departing from the scope of the invention. The tool may also be unitary, rather than having separate modules.
The formation evaluation while drilling tool 601 of
One or more of the probes may be selectively activated for performing formation evaluation, such as sampling and pressure testing. As shown in
The tool 601 includes a passage 640 that enables the downward flow of mud through the tool 601. Instruments are preferably positioned within the subsections such that the passage permits the mud to flow through the passage 640 in the tool 601. The arrangement and order of the subsections, or modules, in the tool 601 may be modified depending on the circumstances. The module arrangement is not intended to limit the invention.
The formation evaluation while drilling system 300 shown in
The discharge line 303 includes a dump valve 307 that can be selectively operated to put the pump 301 in fluid communication with the borehole discharge 311. For example, the dump valve 307 may lead to a borehole discharge 311 that comprises an exit port in the side of the tool. Each of the sample chambers 306a, 306b, 306c preferably includes a sample chamber isolation valve 305a, 305b, 305c that may be selectively operated to put the pump 301 in fluid communication with one or more of the sample chambers 306a, 306b, 306c.
Referring again to
Before the operation of the pump 301 is described, it is important to note that, in some embodiments, the formation evaluation while drilling system (300 in
In general, a reciprocating positive displacement pump, such as the one shown in
The pump 301 shown in
It is noted that the embodiment shown includes a three-way valve 309, but a three-way valve is not required. For example, the junction could be controlled with a check valve and a two-way valve, or it could be controlled with two or more check valves. Additionally, a pump 301 could be devised where the charge line and the discharge line are not connected. In
The piston assembly 408 is in a discharge stroke when it moves in a direction opposite to that of the charge stroke (i.e., to the left in
In the embodiment shown in
The bellows 421 is used so that the pump mechanisms will operate, as will be described, based on the pressure applied by the clean hydraulic oil in the clean fluid cavity 425. The pressure that the bellows 421 is exposed to may be transmitted to the second piston 411 through a connecting member 422 that puts the clean fluid cavity 425 in fluid communication with the pressure cavity 415 of the hydraulic chamber 410. This protects the pump mechanisms (e.g., the second piston 411 of the piston assembly 408) from the harsh and abrasive mud. Those having ordinary skill in the art will realize that the bellows 421 form part of one or more preferred embodiments that separate the mud from the moving piston, and that the bellows 421 are not required by all embodiments of the invention.
The charge stroke of the pump 301 is preferably driven by a spring 413 disposed in the spring cavity 414 of the hydraulic chamber 410. The spring 413 pushes on the second piston 411 of the piston assembly 408 in a direction of a charge stroke (i.e., to the right in
To operate the pump 301 in the discharge stroke, the annular pressure isolation valve 432 is closed, and the internal pipe pressure isolation valve 434 is opened. In this configuration, the bellows chamber 423 experiences the internal pipe pressure PI. The internal pipe pressure PI forces the bellows 421 to compress, and hydraulic oil in the bellows 421 is forced into the pressure cavity 415 of the hydraulic chamber 410. By virtue of the flexible bellows 421, the hydraulic oil is at the internal pipe pressure PI, and that pressure is exerted against the second piston 411 of the piston assembly 408. In some embodiments, the spring 413 has a spring constant that is selected so that the internal pipe pressure PI is enough to overcome the force of the spring 413 and compress it. In these embodiments, the internal pipe pressure PI drives the discharge stroke.
Selection of a spring 413 with an appropriate spring constant may be advantageous. By selecting a spring 413 with a desirable spring constant, the spring 413 will be compressed when exposed to internal pipe pressure PI, and it will relax when exposed to the annular pressure PA. As an example, referring to
It is noted that those having ordinary skill in the art will be able to devise other embodiments of the invention that do not depart from the scope of this invention. For example, an embodiment could be devised where the spring 413 is disposed in the pressure cavity 415, and the annular and internal pipe pressure may be selectively applied to the spring cavity 414 of the hydraulic chamber 410. Essentially, the functions of each section could be reversed. In such an embodiment, the spring would drive the discharge stroke, and the internal pipe pressure PI would drive the charge stroke. It is noted that the names of the cavities and chambers are not intended to be limiting. In
Note that in some embodiments, it is preferable to maintain at least one of the pressure isolation valves 432, 434 closed at all times. Thus, one must be completely closed before the other is opened. This is because, in some embodiments, having both the annular pressure isolation valve 432 and the internal pipe pressure isolation valve 434 open at the same time will enable mud in the drill string to flow straight into the annulus. When this occurs, the pressure differential that drives the pump 301 will no longer exist. Additionally, the abrasive mud flow may “washout” the isolation valves 432, 434, so that they cannot be fully closed. Mud would be able to flow through isolation valves 432, 434, and drilling will be impossible. The drill string would have to be tripped for valve replacement before drilling may continue.
As shown in
A common problem with sampling operations is that the mud in the borehole will often seep into the formation. Because of this mud filtrate “invasion,” the first fluid that is withdrawn from the formation will typically be mud filtrate that has seeped into the formation. To correct for this, fluid is withdrawn from the formation and pumped into the borehole until the sample “cleans up” that is, until the fluid withdrawn is no longer mud filtrate, but the native formation fluid. Using various sensors to monitor how certain properties change during pumping may enable the determination of when the fluid has cleaned up. Once it is determined that the fluid has cleaned up, a sample may be taken by changing the valve settings and directing the fluid flow into a sample chamber (e.g., sample chamber 306a in
The embodiment of a pump 301 shown in
In some embodiments, the formation evaluation while drilling system includes sensors that enables the system to determine fluid properties without having to take a sample. For example, a pump may include a density sensor, a resistivity sensor, or an optical sensor that enables the determination of certain fluid properties. The sensors included in the pump are not intended to limit the invention.
Another problem that may be encountered when taking samples is that the pressure of the formation fluid may drop below its “bubble point.” The “bubble point”is the pressure below which dissolved gasses in the formation fluid will come out of the solution, and bubbles will form in the fluid. When the formation fluid pressure drops below its bubble point, several problems may result. First, the gas in the fluid will decrease the efficiency of the fluid pump. In extreme cases, it may become impossible to pump fluid and take a sample. Another potential problem is that once bubbles form in a fluid sample, the additional gas in the sample makes it impossible to identify the exact nature of the fluid in the formation. Also, the bubbles affect the pressure pulses created by pumping the fluid out of the formation. The effect makes it difficult to estimate the permeability of the formation itself. Thus, in some embodiments, it is desirable to maintain the fluid sample above its bubble point and in a single phase.
To protect against this problem, in some embodiments, a formation evaluation while drilling system (e.g., 300 in
In some cases, a downhole fluid pump may be used to pump a gas sample out of a formation. In those cases, the formation evaluation while drilling system may also includes an override that will enable the pump to operate even though there is gas in the sample.
The pump 500 is connected to a charge line 503, which, in some embodiments, is in fluid communication with a probe. The charge line 503 is connected to the first pump section 501 through valve 505, and the charge line 503 is connected to the second pump section 502 through valve 506. In some embodiments, the valves 505, 506 are check valves that will only allow flow in one direction—from the charge line 503 to the pump sections 501, 502.
The pump 500 is also connected to a discharge line 504, which, in some embodiments, is in fluid communication with the borehole and one or more sample chambers (shown as “System” to indicate the remainder of the formation evaluation while drilling system). The discharge line 504 is connected to the first pump section 501 through valve 507, and the discharge line 504 is connected to the second pump section 502 through valve 508. In some embodiments, the valves 507, 508 are check valves that will only allow flow in one direction—from the pump sections 501, 502 to the discharge line 504.
The first hydraulic section 511 is connected to an annular pressure line 513 that is hydraulically coupled to the annular pressure PA. An annular pressure isolation valve 515 can be selectively opened and closed to either expose the first hydraulic section 511 to the annular pressure PA or to isolate it from the annular pressure PA. The first hydraulic section 511 is also connected to an internal pipe pressure line 514 that is hydraulically coupled to the internal pipe pressure PI in the drill string. An internal pipe pressure isolation valve 517 can be selectively opened and closed to either expose the first hydraulic section 511 to the internal pipe pressure PI or to isolate it from the internal pipe pressure PI.
The second hydraulic section 512 is connected to the annular pressure line 513 that is hydraulically coupled to the annular pressure PA. A second annular pressure isolation valve 516 can be selectively opened and closed to either expose the second hydraulic section 512 to the annular pressure PA or to isolate it from the annular pressure PA The second hydraulic section 512 is also connected to the internal pipe pressure line 514 that is hydraulically coupled to the internal pipe pressure PI in the drill string. A second internal pipe pressure isolation valve 518 can be selectively opened and closed to either expose the second hydraulic section 512 to the internal pipe pressure PI or to isolate it from the internal pipe pressure PI.
By selectively operating the annular and internal pipe pressure isolation valves 515, 516, 517, 518, the piston 524 can be operated in a reciprocating manner to pump fluid from the probe to the borehole (not shown) or to a sample chamber (not shown). For example, by opening the first annular pressure isolation valve 515 and the second internal pipe pressure isolation valve 518, and by closing the first internal pipe pressure isolation valve 517 and the second annular pressure isolation valve 516, the first hydraulic section 511 will experience annular pressure PA and the second hydraulic section 512 will experience internal pipe pressure PI. Because the internal pipe pressure PI is greater than the annular pressure PA, the piston 524 will be moved in a direction so that the first hydraulic section 501 is in a charge stroke and the second hydraulic section 501 is in a discharge stroke (i.e., to the right in
Conversely, by opening the second annular pressure isolation valve 516 and the first internal pipe pressure isolation valve 517, and by closing the second internal pipe pressure isolation valve 518 and the first annular pressure isolation valve 515, the first hydraulic section 511 will experience internal pipe pressure PI and the second hydraulic section 512 will experience annular pressure PA. Because the internal pipe pressure PI is greater than the annular pressure PA, the piston 524 will be moved in a direction so that the first hydraulic section 501 is in a discharge stroke and the second hydraulic section 501 is in a charge stroke (i.e., to the left in
The pump 500 shown in
Again, in some embodiments, it is advantageous to ensure that only one of the annular pressure isolation valve and the internal pipe pressure isolation valve for a hydraulic section (e.g., annular isolation valve 515 and internal pipe pressure isolation valve 517 for first hydraulic section 511) is open at any one time. This will prevent the mud from freely passing from the inside of the drill string to the annulus, thereby defeating the pressure differential used to operate the pump 500.
In some embodiments, the valves 505, 506, 507, 508 that connect the pump sections 501, 502 to the charge line 503 and the discharge line 504 are check valves that allow flow in only one direction. In these embodiments, operation of these valves is not required. In other embodiments, it may be advantageous to use valves that must be selectively operated. Those having ordinary skill in the art will realize that the discharge valves 507, 508 must be opened for the discharge stroke of their respective pump sections 501, 502, and the charge valves 505, 506 must be opened for the charge stroke of their respective pump sections 501, 502. Those having ordinary skill in the art will also realize that only one of the charge and discharge valves for any pump section (e.g., valves 505 and 507 on first pump section 501) should be open at any one time. The type of valves used in a fluid pump are not intended to limit the invention.
Alternate configurations of a pump and a formation evaluation while drilling system may be devised. For example, the bellows 421 and the bellows chamber 423 in
The intake subsection or module as depicted in
The drill collar 201 shown includes blades 205 (or ribs) that stabilize the drill string, and the probe assembly 211 is positioned so that it will extend through one of the blades 205, which may be in contact with the borehole wall 206. While the probe is shown as being able to extend through a blade in the drill collar, it will be appreciated by one of ordinary skill in the art that a probe may be used in a drill collar that does not includes a blade.
One feature of drill collars and any associated tools is that they must allow mud flow both inside the drill string and in the annulus. To that end, the blades 205 are preferably spaced around the drill collar 201, in this case 120° apart, to provide an annular space 222 for the return mud flow. Additionally, the probe assembly 211 is disposed in the interior 221 of the drill collar 201, but is preferably positioned and sized so that there is enough space in the interior 221 of the drill collar 211 for the downward mud flow.
The probe assembly 211 includes a flow path 212 in fluid communication with a flow line 219 that enables the formation fluids to flow from the probe assembly 211 to additional sections of the drilling tool (not shown). In some embodiments, such as the one shown in
During normal drilling operations, the probe 215 is in a retracted position so that the packer 214 and the flow path 212 are recessed inside the drill collar 201. When it is desired to perform formation evaluation, such as measuring the formation pressure or taking a sample of the formation fluid, the probe 215 may be moved to an extended position such that the packer 214 is in contact with the borehole wall 206. In some embodiments, the drill collar 201 rotates with the rest of the drill string. In these embodiments, drilling is typically stopped so that the probe may be extended to take a measurement or a sample. In other embodiments, a drill collar may be a counter rotating collar (not shown) where the blades counter rotate at the same rate as the drill string rotation so that the blades do not rotate with respect to the borehole. In these embodiments, the probe may be positioned into fluid communication with the borehole even when the drill string is being rotated. Any type of drill collar may be used with the invention. The type of drill collar used to house a probe is not intended to limit the invention.
In the embodiment shown, the probe 215 may be selectively moved between the extended and retracted position (
The foregoing is only one example of a mechanism that may be used to move a probe between a retracted and an extended position. Those having skill in the art will be able to devise other mechanisms, without departing from the scope of the invention. For example, the spring 216 may be omitted and the probe block 217 may be moved to the retracted position using a motor or fluid pressure from inside the drill string.
As shown in
In some embodiments, the invention relates to methods for operating a pump. In some other embodiments, the invention relates to methods of formation evaluation. The description of the method includes many steps that are not required by the invention, but are included for illustrative purposes.
The method also includes (shown at arrow 856) selectively repeating applying the lower pressure to the first side of the pump and applying the higher pressure to the first side of the piston. This will cause the piston to alternate between the charge stroke and the discharge stroke. It is also noted that the starting point in some embodiments of the method may not be applying the lower pressure (i.e., step 852). In cases where the starting position of the pump is with the lower pressure applied to the first side of the piston in the pump, the higher pressure must be applied to begin the operation of the pump. Those having ordinary skill in the art will realize that beginning point in the repeating operation of the pump does not limit the invention.
Referring to
There are numerous methods for communicating with downhole devices, including various types of mud-pulse telemetry. These methods are known in the art and are not intended to limit the invention.
In some embodiments, the next step 704 includes stopping drilling and step 705 includes stopping the mud pumps so that the mud flow through the drill string is stopped. Stopping the rotation of the drill string will enable the formation evaluation while drilling tool to extend a probe or packers. Sensors may be included in the formation evaluation while drilling tool to determine when the mud flow has stopped. At that point, the system may begin a formation evaluation operation. In other embodiments, the formation evaluation while drilling tool may include other types of sensors that determine when drilling has stopped. For example, a sensor that detects when rotation has stopped may be used without departing from the scope of the invention. The type of sensor used is not intended to limit the invention.
It is noted that the step of stopping the drill string may not be required in embodiments of the invention where a formation evaluation while drilling tool is disposed in a counter-rotating drill collar. In these embodiments, the following steps may be performed while the drill string is still rotating.
Next, the method may include the step 706 of establishing fluid communication with the formation. In some embodiments, this is accomplished by extending a sample probe to be in fluid communication with the formation fluids. In some other embodiments, this is accomplished by inflating packers to be in contact with the borehole wall. In some embodiments, this step is initiated at a preselected time after the mud flow is stopped. The method may also include measuring the formation pressure using a pressure sensor disposed in the formation evaluation while drilling system, as shown at step 708. Following the measurement of the formation pressure, if performed, the method includes restarting the mud pumps at the surface so that mud is flowing through the drill string and back through the annulus, as shown at step 710. In some embodiments, the formation evaluation while drilling tool is preprogrammed to extend the probe (step 706) and measure the formation fluid pressure (step 708) once the mud flow is stopped. Those steps are performed in a preselected time interval, and the mud pumps are restarted after the preselected time interval.
In some embodiments, the method includes performing a pretest (step 711) using a fluid pump in the formation evaluation while drilling tool. The pretest may include operating the pump in one charge stroke (described below at step 712) and then measuring the pressure transient that is experienced at the probe or fluid inlet. This will enable an estimation of the formation pressure as well as an estimation of the formation permeability, as is known in the art.
Following step 711, the flow chart in
In step 712, the charge stroke is initiated, for example, by applying the annular pressure PA to a hydraulic chamber in the pump. A spring in the pump will drive the charge stroke against the annular pressure PA. At the beginning of the charge stroke, a pump chamber in the pump is put into fluid communication with the fluid in the formation so that formation fluid will be drawn into the pump during the charge stroke.
In step 714, the discharge stroke is initiated, for example, by applying the internal pipe pressure PI to a hydraulic chamber in the pump. The internal pipe pressure PI will drive the discharge stroke against the spring. At the beginning of the discharge stroke, the pump chamber is put into fluid communication with a discharge line in the formation evaluation while drilling system. The discharge line may selectively be put into fluid communication with a sample chamber or with the borehole.
The charge stroke (step 712) and the discharge stroke (step 714) are continuously repeated so that the effect is that formation fluid will be drawn out of the formation and into the pump and then pumped into the discharge line. This process may continue until it is no longer desired to pump fluid out of the formation.
It is noted that, in some embodiments, the charge stroke may be accomplished by applying the internal pipe pressure PI, and the discharge stroke may be accomplished by applying the annular pressure PA. The method for operating the pump will depend on the configuration of the pump. Also, it is noted that although the charge stroke (step 712) is shown first, it may be necessary to perform the discharge stroke (step 714) first. In those situations where the pump has an initial position that corresponds to the end of the charge stroke, the discharge stroke (step 714) must be performed first. Those having ordinary skill in the art will realize that order in which the charge stroke and discharge stroke are first performed is not intended to limit the invention.
While the pumping is going on (steps 712, 714) the discharge line may first be placed in fluid communication with a borehole discharge so that the pumped fluid is directed into the borehole (step 716). In some embodiments, this is accomplished by opening a dump valve located in the discharge line. As the pumping continues (steps 712, 714), the fluid is monitored with sensors to determine when the fluid cleans up, as shown at step 718. This may include using telemetry to transmit data to the surface so that the sensor data may be monitored at the surface. Alternatively, the sensor data may be monitored using a processor unit included in the downhole tool.
In some embodiments, once it is determined that fluid has cleaned up, the method next includes the step 720 of taking a sample. This may include opening a sample chamber isolation valve and closing the dump valve so that the clean formation fluid is pumped into a sample chamber. In some embodiments, a downlink telemetry signal is sent to the formation evaluation while drilling tool that instructs the system to open a sample chamber isolation valve and close the dump valve. In other embodiments, the downhole processor sends the instruction.
Once a sample is taken, the pumping (steps 712, 714) may be stopped. The probe may then be retracted or the packers may be deflated. This is shown at step 722 as disengaging fluid communication with the formation. In some embodiment, where drilling is stopped for the formation evaluation, the drilling may continue, as shown at step 724.
Some embodiments include a step (not shown) of estimating the depth of invasion in the formation. “Invasion” occurs when mud filtrate a liquid part of the mud seeps into the formation once the formation is drilled. The depth of invasion may be determined from the total volume of fluid that is pumped out of the formation before the fluid is cleaned up. This may be called total volume to clean up. This step not specifically shown in
The method may also include monitoring the pressure pulses at another probe (e.g., probe 621 in
Embodiments of the invention may present one or more of the following advantages. For example, a downhole pump that is powered by a differential pressure does not require a battery or an electrical generator to be included in the formation evaluation while drilling tool to power the pump. This may reduce the space the is required by the tool. A typical generator will use mud flow to generate electrical energy. The electrical energy will then be transmitted to a motor that will power the pump. Advantageously, a downhole pump powered by a pressure differential will use the mud pressure to power the pump, eliminating the need for a generator, electric power, and a motor.
Advantageously, a downhole pump that includes a bellows will prevent the abrasive mud from coming into contact with the pump. This will reduce the wear and tear on the pump from normal operation.
Advantageously, the piston in a downhole pump may include piston ends having different surface areas. This will create a ratio of pumping areas that will provide a mechanical advantage for the pump that will enable more efficient operation base on the pressure differential.
While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.
Number | Name | Date | Kind |
---|---|---|---|
3901314 | Nutter et al. | Aug 1975 | A |
3934468 | Brieger | Jan 1976 | A |
4507957 | Montgomery et al. | Apr 1985 | A |
4591320 | Pope | May 1986 | A |
4860581 | Zimmerman et al. | Aug 1989 | A |
4893505 | Marsden et al. | Jan 1990 | A |
4936139 | Zimmerman et al. | Jun 1990 | A |
5377755 | Michaels et al. | Jan 1995 | A |
5411097 | Manke et al. | May 1995 | A |
5587525 | Shwe et al. | Dec 1996 | A |
5622223 | Vasquez | Apr 1997 | A |
5791414 | Skinner et al. | Aug 1998 | A |
6192984 | Schultz | Feb 2001 | B1 |
6230557 | Ciglenec et al. | May 2001 | B1 |
6301959 | Hrametz et al. | Oct 2001 | B1 |
6343650 | Ringgenberg | Feb 2002 | B1 |
6516898 | Krueger | Feb 2003 | B1 |
6568487 | Meister et al. | May 2003 | B1 |
6585045 | Lee et al. | Jul 2003 | B1 |
6609568 | Krueger et al. | Aug 2003 | B1 |
6837314 | Krueger et al. | Jan 2005 | B1 |
Number | Date | Country | |
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20050115716 A1 | Jun 2005 | US |