1. Field of the Invention
The invention relates generally to offshore drilling systems which are used to drilling subsea wells. More particularly, the invention relates to a subsea pump and an associated control system for use in offshore drilling systems.
2. Background Art
In conventional offshore drilling operations from, for example, a floating drilling vessel, a large diameter marine riser (e.g., a 21 inch marine riser) generally connects surface drilling equipment on the floating drilling vessel to a blowout preventer stack connected to a subsea wellhead located on the seabed. The marine riser is generally filled with drilling fluid (or “drilling mud”) so that a total hydrostatic pressure on a formation being drilled in a wellbore is determined by the hydrostatic pressure of the mud in the drilled wellbore (below the seabed) plus the hydrostatic pressure of the mud in the marine riser (above the seabed). In many cases, the total hydrostatic pressure of the “mud column” may exceed a fracture pressure of the formation being drilled. Accordingly, a large number of casing strings may need to be placed in the wellbore to protect the formation and maintain well control. In deep water drilling operations, the total cost of installing a large number of casing strings, combined with smaller oil and gas production rates possible through reduced diameter casing, can often result in wells which are uneconomical to drill and produce.
It has been determined that an important aspect of improving the economics and well control of deep water wells lies in reducing the hydrostatic pressure of the mud in the marine riser to that of a column of seawater, while at the same time filling the wellbore with drilling mud of sufficient weight to maintain well control. Various concepts have been presented in the past for achieving this goal, and the concepts can be grouped into two categories: mud lift drilling with a marine riser and riserless drilling.
Mud lift drilling with a marine riser typically includes a dual density mud gradient system, and the density of the mud return in the riser is generally reduced so that the hydrostatic pressure of the mud column in the riser, measured at the seabed, more closely matches that of seawater. The mud in the well bore remains weighted at a higher density to maintain proper well control. For example, U.S. Pat. No. 3,603,409 issued to Watkins et al. and U.S. Pat. No. 4,099,583 issued to Maus both disclose methods of using injected gas to reduce the density of the mud column in the marine riser, thereby reducing the hydrostatic pressure of the mud in the marine riser as measured at the seabed.
Riserless drilling generally includes eliminating the riser as a mud return path and replacing it with one or more small diameter mud return lines. For example, U.S. Pat. No. 4,813,495 issued to Leach discloses a system that eliminates the need for the marine riser and, as an alternative, uses a centrifugal pump to lift mud returns from the seafloor to the surface through a mud return line. A rotating apparatus isolates the mud in the wellbore annulus from seawater as the drillstring is run into and out of the wellbore.
U.S. Pat. No. 6,102,673, issued to Mott et al. and assigned to the assignee of the present invention, discloses a dual gradient riserless drilling system that uses a pressure actuated drillstring valve to control mud free fall, rotating and non rotating subsea diverters to isolate the mud in the wellbore from fluids, such as seawater, above the wellbore, a solids control system to control the size of solids in mud return lines, and a subsea positive displacement pump actively controlled in a coordinated manner with surface equipment on a drilling vessel to maintain the volume of mud in the wellbore.
Generally, the riserless drilling is preferred over the mud lift system because riserless drilling employs a pressure barrier between the wellbore and the surrounding environment. The pressure barrier allows the wellbore to be drilled in an “underbalanced” condition where formation pressures typically exceed the pressure of the drilling mud in the wellbore. Underbalanced drilling may significantly improve the rate of penetration of a drill bit and also helps reduce the risk of formation damage.
U.S. Pat. No. 6,102,673 issued to Mott et al discloses a subsea positive displacement pump with multiple pump elements, each pump element comprising a pressure vessel divided into two chambers by a separating member and powered by a closed hydraulic system using a subsea variable displacement hydraulic pump. The subsea positive displacement pump includes hydraulically actuated valves to ensure proper valve seating in the presence of, for example, cuttings from the drill bit that are present in mud returns from the wellbore. The hydraulically actuated valves also provide flexibility in valve timing (which is typically not available with conventional spring biased check valves) and provide quick valve response in high flow coefficient (Cv) arrangements necessary for high volume pumping (e.g., substantially high flow rates).
The subsea positive displacement pump disclosed in U.S. Pat. No. 6,102,673 issued to Mott et al is controlled by a unitary control module which receives the following signals: (1) position signals from a position indicator on the separating member in each pump element, wherein the position signals are converted into volume measurements; (2) flow and pressure signals from devices on a return side of the closed hydraulic system; (3) flow signals from a supply side of the hydraulic system (usually positioned proximate the variable displacement hydraulic pump); and (4) pressure signals from a mud suction pressure transducer.
Control signals from the control module: (1) control the operation of the flow control valve on the hydraulic fluid return to ensure that the flow rate from the variable displacement hydraulic pump is equal to the flow rate returning to the hydraulic reservoir; (2) operate the two hydraulic control valves and two hydraulically actuated mud valves on each pumping element to control the pumping rate of the subsea mud pump; and (3) control the flow rate of the variable displacement hydraulic pump. The control module algorithm is designed to provide “pulsationless” flow by precisely controlling the “phasing” of the multiple pumping elements to overlap both the fill and discharge cycles of the pumping elements.
The control system is difficult to precisely adjust because it has proven difficult to accurately model both the non-linear responses of many of the hydraulic components of the system and the wellbore hydraulic characteristics over time. In practice, significant load changes from a stable pump operating condition, such as step load changes of plus or minus fifty percent, have been found to cause instability in the system. Further, the response of the variable displacement hydraulic pump to the control signals, which is adequate at low and steady pumping rates, has proven to be inadequate at higher mud pump rates (e.g., pump rates above about 4-5 strokes per minute).
The subsea pump disclosed in U.S. Pat. No. 6,102,673 issued to Mott et al generally requires that the hydraulic power source be located proximate the subsea mud pumping elements with high flow capacity (e.g., high Cv piping between the hydraulic pump and the mud pumping elements) to minimize lag in the hydraulic response. This precludes, for example, using high pressure pumps located on the floating rig as a source of hydraulic power. Moreover, because the hydraulic valves controlling the mud pumping elements in the disclosed arrangement must have a high Cv to allow the mud pumps to operate at high flow rates, the disclosed control valve arrangement may be prone to hydraulic “water hammer” effects whenever the large bore valves open or close under differential pressure during the pumping cycle, especially at high pump rates.
It would be advantageous, therefore, to design a subsea mud pump and a coordinated control system that would enable stable, efficient operation of deep water drilling systems, including riserless drilling systems. It would also be advantageous to design a control scheme that insures that bottom hole pressure (BHP) is maintained whenever drilling mud pumps are stopped, for example, to add lengths of drillpipe to the drillstring (e.g., when “making a connection”).
Finally, it would be advantageous to design a control system that can compensate for drilling mud that has some degree of compressibility, whether because of the high hydrostatic pressures encountered in deepwater subsea operations (e.g., at depths of 10,000 feet, fresh water exhibits compressibility on the order of 2.5-3%) or because of entrained gas or volatile liquids/hydrocarbons that may be present in the drilling mud leaving the wellbore.
In one aspect, the invention relates to sub-sea mud pump system includes a plurality of pump units, and each pumping unit includes a plurality of pumping elements. Each pumping element includes a pressure vessel with a first and a second chamber, a separating member between the first and second chambers, a measurement device adapted to measure the volume of at least one of the first and second chambers, a hydraulic inlet control valve and a hydraulic outlet control valve coupled to the first chamber, a mud suction valve and a mud discharge valve coupled to the second chamber. The first chamber is hydraulically coupled to receive and discharge a hydraulic fluid, and the second chamber is hydraulically coupled to receive and discharge a drilling fluid. The separating member is adapted to move within its the pressure vessel in response to a pressure differential between the first and second chambers. The pump system also includes a hydraulic control unit adapted to control the plurality of pump units.
Other aspects and advantages of the invention will be apparent from the following description and the appended claims.
The flow of hydraulic fluid energizes the pumping elements 220, and the flow of hydraulic fluid into the pumping elements 220 generates a flow of drilling fluid out of the pumping elements 220 through a discharge line 270. Similarly, a flow of drilling fluid into the pumping elements 220 generates a flow of hydraulic fluid out of the pumping elements 220. Hydraulic fluid flows out of the pumping elements 220 through a hydraulic fluid discharge line 280. In some embodiments, a valve 290 is hydraulically coupled to the hydraulic fluid discharge line 280 and is operatively coupled to the valve controller 300. The valve controller 300 is adapted to operate the valve 290 so as to control a rate of discharge of the hydraulic fluid from the pumping elements 220.
By controlling, for example, the timing and rate of the application and discharge of hydraulic fluid to and from the pumping elements 220, respectively, operating characteristics of the subsea pump 200 such as a pump inlet pressure, a pump discharge pressure, and a total volume of drilling fluid in the pumping elements 220 may be selectively controlled. These and other aspects of the invention are described in detail below.
Further, the embodiment shown in
Each of the pumping elements A, B, C comprises a vessel 1a, 1b, 1c with two chambers. The chambers comprise mud chambers 2a, 2b, 2c and hydraulic power chambers 3a, 3b, 3c, where the chambers are typically separated by separation elements, one example of which is substantially impermeable pump diaphragms 4a, 4b, 4c. In some embodiments, the diaphragms 4a, 4b, 4c comprise an elastomeric material. However, the diaphragms 4a, 4b, 4c may be formed from other materials, such as non-elastomeric materials or reinforced elastomeric materials, and the type of diaphragm material is not intended to be limiting.
In some embodiments of the invention, it is desirable to maintain a substantially constant inlet pressure (e.g., in the mud suction line 27). In other embodiments, it is desirable to maintain a substantially constant discharge pressure at a pump outlet (e.g., in the mud discharge line 28). If, for example, the inlet pressure is maintained at a substantially constant level, it is typical to let the discharge pressure “float” or vary during drilling operations. The opposite is also true when, for example, the discharge pressure is maintained at a substantially constant level. Various aspects of these embodiments of the invention are described in detail below. Note that operator preference, drilling conditions, etc. help determine which of the inlet pressure or the discharge pressure is maintained at a substantially constant level during drilling operations. Accordingly, the invention contemplates operating at all of the aforementioned conditions and incorporates the flexibility necessary to, for example, change from maintaining a substantially constant inlet pressure to maintain a substantially constant discharge pressure (and, if required, back again) during the process of drilling a well.
At the time interval shown in
Mud from the mud suction line 27 then flows through actuated mud suction valves 9a, 9b, 9c and into the mud chambers 2a, 2b, 2c of the pumping module AA. After the mud chambers 2a, 2b, 2c have been filled, mud may then be pumped from the mud chambers 2a, 2b, 2c through actuated mud discharge valves 8a, 8b, 8c and into a mud discharge line 28. The mud discharge line 28 is typically connected to a mud return line (not shown) that is connected to mud handling and processing equipment (not shown) located at the water surface.
In some embodiments of the invention, the mud suction valves 9a, 9b, 9c and mud discharge valves 8a, 8b, 8c are power actuated valves of the type described in U.S. Pat. No. 6,102,673 issued to Mott et al. Power actuated valves are preferable, for example, when pumping mud returns from a drilled wellbore because the suction valves 9a, 9b, 9c and the discharge valves 8a, 8b, 8c may have to close and seal against large and irregularly shaped obstructions such as formation cuttings. Accordingly, power actuated valves are desirable because conventional spring biased check valves may be unable to close against such obstructions and thereby form an effective seal. However, conventional spring biased check valves may be used with embodiments of the invention. For example, spring biased check valves may be used with embodiments of the invention that use a diaphragm type mud pump of the type disclosed in U.S. Pat. No. 2,703,055 issued to Veth et al.
Hydraulic fluid is pumped into the hydraulic power chambers 3a, 3b, 3c from a flow regulated hydraulic fluid source 23 through respective hydraulic inlet control valves 6a, 6b, 6c. Hydraulic pressure in the hydraulic power chambers 3a, 3b, 3c is monitored by respective hydraulic chamber pressure transducers 11a, 11b, 11c. The inflow of hydraulic fluid moves the pump diaphragms 4a, 4b, 4c and displaces the diaphragms 4a, 4b, 4c so as to pump the mud out of the respective mud chambers 2a, 2b, 2c. For example (referring to FIG. 1B), when hydraulic fluid flows into the “upper” hydraulic power chambers 3a, 3b, 3c, mud is forced out of the “lower” mud chambers 2a, 2b, 2c and into the mud discharge line 28.
In contrast, when the mud chambers 2a, 2b, 2c are filling with mud, respective hydraulic outlet control valves 7a, 7b, 7c are opened and hydraulic fluid in the hydraulic power chambers 3a, 3b, 3c flows out through a discharge line 25. Note that in some embodiments that use seawater as the hydraulic fluid, the discharge line 25 may dump the seawater hydraulic fluid into the ocean proximate the subsea pump AA. The seawater embodiments are advantageous in that additional equipment (such as a hydraulic fluid recirculation system (not shown)) is not required to further transport the seawater hydraulic fluid. However, other embodiments may include a hydraulic fluid recirculation system (not shown) attached to the discharge line 25 so that the hydraulic fluid is reusable by returning the hydraulic fluid to the surface. For example, some embodiments of the invention may use oil as the hydraulic fluid. The oil-based hydraulic fluid may be recirculated rather than dumped into the sea. The oil-based hydraulic fluid is also advantageous because a pump pressure required to pump the oil-based hydraulic fluid at depth is typically less than a pump pressure required to pump the seawater hydraulic fluid at a similar depth.
Substantially instantaneous positions of the pump diaphragms 4a, 4b, 4c may be determined by position transducers 5a, 5b, 5c attached to the pump diaphragms 4a, 4b, 4c of each of the pumping elements A, B, C. In the embodiment shown in
The position of pump diaphragms 4a, 4b, 4c determined by the diaphragm position transducers 5a, 5b, 5c is used by sequencing devices 21a, 21b, 21c to determine when the pump diaphragms 4a,4b,4c have reached the “end” or limit (e.g., the top or bottom) of their stroke. In addition, the diaphragm position information may be conveyed to personnel and equipment aboard the floating drilling vessel (not shown) and is used in the operation of a constant volume flow control system (D in
In order to ensure substantially constant discharge pressures from the subsea pump AA, it is important to compress drilling mud to a desired discharge pressure before it is discharged from the pump. Drilling mud returns at the seabed are likely to be more compressible than drilling mud pumped by mud pumps on the surface. For example, mud pumped through the mud pumps at the surface is typically cleaned of large cuttings (e.g., shale), sand, silt, and fluid returns from the well such as oil and/or brine, and is degassed before it is returned to the mud pumps for recirculation into the wellbore. On the seabed, it is possible that drilling mud returned directly from the wellbore to the subsea pump AA contains quantities of entrained gas or volatile liquid petroleum fractions, and even small quantities of gas and/or volatile liquids may substantially increase the compressibility of the drilling mud. Furthermore, at the high hydrostatic pressures encountered in deepwater drilling (e.g., at 10,000 feet below the surface, hydrostatic pressure is about 4500 psi), even completely gas free water based drilling mud may be compressible by 2-3% (with respect to a unit volume). Oil based drilling mud and certain drilling mud additives will typically be even more compressible than water based drilling mud.
Prior art subsea pumping relied on the belief that complete compression of the drilling mud could be achieved by properly controlling the hydraulic inlet valves. However, it has been determined that if a flow regulated hydraulic power source is used to finish the compression of the drilling mud prior to pumping the mud, it can result in negative pressure spikes in the mud chamber (e.g., mud chamber 2a) of the affected pump element (e.g., pump element A) and, as a result, can transmit the negative pressure spikes through the mud return line 28 (and, as a result, possibly damage other equipment).
In practice, it has been determined that negative pressure spikes are generally more severe at higher pump rates (e.g., at pump rates of approximately 4-5 strokes per minute or greater) because there is less time during the pump cycle for compressible mud to be compressed to the desired discharge pressure. In addition, high flow coefficient (Cv) piping is generally required for higher pump rates, and the high flow coefficient piping makes it difficult to precisely control the hydraulic inlet control valves at lower flow rates.
Referring again to
Further, it has been determined that rapid opening of the hydraulic outlet control valves 7a, 7b, 7c (as required by high pump stroke rates), combined with the relatively high flow coefficients (Cv) of the hydraulic outlet control valves 7a, 7b, 7c, can cause severe hydraulic hammering of the system. Hydraulic hammering is produced by the “water hammer effect,” where a sudden release of high pressure fluid into, for example, a flow conduit that is at a lower pressure generates a hydraulic “shock wave” in the system. The hydraulic hammering may damage the system by, for example, fatiguing tubular joints, valves, etc. after repeated occurrences.
Accordingly, embodiments of the invention include decompression control valves 12a, 12b, 12c that have flow coefficients (Cv) on the order of 0.01 to 0.1 times the Cv of the hydraulic outlet control valves 7a, 7b, 7c. Activation of the decompression control valves 12a, 12b, 12c produces a gradual reduction in pressure and helps ensure smooth discharge of the hydraulic fluid from the hydraulic power chambers 3a, 3b, 3c without hydraulic hammering. For example, after the mud has been completely pumped from the mud chamber 2a, 2b, 2c through the mud discharge valve 9a, 9b, 9c and hydraulic inlet control valve 6a, 6b, 6c is completely closed, the decompression control valve 12a, 12b, 12c is opened to gradually relieve pressure from the hydraulic power chamber 3a, 3b, 3c. In some embodiments that use filtered seawater as the hydraulic fluid, the decompression control valves 12a, 12b, 12c are vented to the sea. However, as previously explained, other arrangements are possible when, for example, the hydraulic fluid comprises a fluid other than seawater.
Both the compression 10a, 10b, 10c and decompression 12a, 12b, 12c control valves can be actuated for a selected period of time (for example, a fixed number of seconds or a fraction of the time required to complete a pump cycle), selectively actuated with reference to the pressure in the hydraulic power chamber 3a, 3b, 3c measured by pressure transducers 11a, 11b, 11c, or controlled by an algorithm that evaluates both time and pressure at any selected instant and actuates the valves accordingly.
In the embodiment shown in
The pump system operator can set various operational parameters via sequencing device data links 29a, 29b, 29c. The operational parameters are described in detail in the description of
Each sequencing device 21a, 21b, 21c may in turn be bussed together with the other sequencing devices through a sequencing device controller bus 22 so that the sequencing devices 21a, 21b, 21c may exchange data with each other. For economy, ease of programming, maintenance, and ease of trouble-shooting, it is preferable that the sequencing devices 21a, 21b, 21c be separate entities. In this manner, each sequencing device 21a, 21b, 21c controls the operation of one diaphragm pumping element A, B, C. However, it will be understood by those skilled in the art that one sequencing device could be used to control all three diaphragm pumping elements A, B, C, which would allow the elimination of the sequencing device controller bus 22 because the function of the bus would be handled internally by the independent sequencing devices 21a, 21b, 21c. Alternately, the sequencing devices 21a, 21b, 21c could be separate “virtual machines” that are physically operated and controlled by, for example, a single computer.
The absolute diaphragm position data from the diaphragm position LDTs 5a, 5b, 5c are transmitted by a diaphragm position data link 20a, 20b, 20c to the sequencing devices 21a, 21b, 21c and are compared to “full” and “empty” set points to determine if the mud chambers 2a, 2b, 2c have reached the point where they are full or empty of drilling mud. The full or empty status for each pumping element is used to trigger steps in the logic sequences performed by the sequencing devices 21a, 21b, 21c. The full and empty set points may be selected by the pump system operator or may be stored in a memory (not shown) of the sequencing devices 21a, 21b, 21c. Further, the set points may be modified by the pump system operator at any time during the operation of the pump AA.
For example, the pump arrangement AA shown in
Logic Sequence
The embodiment of the logic sequence BB shown in
After a START signal 30 (which may be initiated, for example, by a signal from the sequencing device 21a or by the pump system operator), the logic sequence BB queries a pump A standby status register 32 at a pump A standby decision step 31. Note that “standby status” is typically designated by the pump system operator. However, standby status could be designated by, for example, pump monitoring software or by downhole sensors. Accordingly, the method of designating standby status is not intended to be limiting.
For example, in some embodiments of the invention, if any of the pump elements A, B, C require service while the subsea pump AA is running, the standby status of the pump element A, B, C requiring service can be set to a “YES” value by a signal from the pump system operator. When a pump element A, B, C of, for example, a triplex pump arrangement, is set to “STANDBY,” the standby status will have the effect of temporarily converting the operation of the triplex subsea pump into a duplex pump (e.g., the standby setting will effectively remove the standby pump element from the pumping sequence).
If the pump element A has a “NO” value as its standby status, the logic sequence BB then queries a pump C fill status register 36 at a pump C fill status decision step 35 to determine whether pump element C (e.g., mud chamber 2c) is full of drilling mud. Note that a “FULL” set point 37 of the pump C fill status register 36 may be defined by personnel on the floating drilling vessel (not shown) or may be preprogrammed into the logic sequence BB.
If pump element C is not full (e.g., if the pump C fill status register 36 has a “NO” value), the logic sequence BB loops until it receives indication that pump element C (e.g., mud chamber 2c) is full of drilling mud (e.g., until the Pump C fill status register 36 is set to “YES”). When pump element C is full of drilling mud, the sequencing device 21a sends signals 41a, 41b to open the mud suction valve 8a and the hydraulic outlet control valve 7a, respectively. Thereafter, mud begins flowing from the mud suction line 27, through the mud suction valve 9a, and into the mud chamber 2a. As the mud chamber 2a is filling, hydraulic fluid is displaced from the hydraulic power chamber 3a and flows out of the hydraulic power chamber 3a through the hydraulic outlet control valve 7a into the discharge line 25. The aforementioned process of filling mud chamber 2a and simultaneously emptying hydraulic power chamber 3a continues until a signal 39 from the diaphragm position transducer 5a matches a pump A “FULL” status set point 38. At this point, a pump A fill status 40 is set to a “FULL” value.
When the pump element A mud chamber 2a is full, a signal from a pump A full decision step 42 starts a mud suction close timer 43, which delays the logic sequence BB for a delay time 44. After the delay time 44 has expired, a “close” signal 45 is transmitted to the mud suction control valve 9a. Similarly, there is then a delay of delay time 47 initiated by a hydraulic outlet close timer 46 before a “close” signal 48 is sent to the hydraulic outlet control valve 7a. Further, a delay of delay time 50 is initiated by a compression valve open timer 49 before an “open” signal 51 is sent to the compression valve 10a. The delays are used to ensure that the drilling mud and hydraulic flow paths to the next chamber have been established prior to closing the currently filling or emptying chamber. Accordingly, the delays help prevent system damage that may occur if there is no flow path open on either the mud or hydraulic side of the system at a selected time.
Note that operation of the compression valve 10a is shown within the pump filling sequence B1 because the mud discharge valve 8a is still closed. Compression of the mud in the mud chamber 2a should be understood as a step to “condition” the mud to be pumped, rather than as a part of the pumping process (e.g., a part of the pump emptying sequence B2).
The compression valve 10a generally remains open until a pressure 55 in the hydraulic power chamber 3a, as measured by a pressure transducer 11a, reaches a predetermined set point 56 (as determined by a comparator 57), or until a Pump C status 60a is “YES.” A condition satisfying an “OR” element 54 initiates transmission of a signal 58 to close the compression valve 10a when the pressure 55 is achieved or the Pump C “YES” status 60a has been achieved.
After the compression valve 10a is closed, the logic sequence BB again polls the pump A standby status register 30 for pump element A at a pump A standby decision step 59. Note that this means that both the pump emptying B2 and pump filling B1 sequences start with a determination of whether the particular diaphragm pump element A, B, or C is in active or standby status. Consequently, if a pump element is placed on standby status during operation, the pump element (that is placed on standby during operation) will finish the current half cycle (e.g., filling B1 or emptying B2), and thereafter that particular pump element will be bypassed in the pumping order of the subsea pump AA.
If pump element A is not on standby status, the sequencing device 21a then polls a pump C fill status register 61 to determine if the mud chamber 2c of pump element C is empty of drilling mud. The “empty” condition is defined by an empty set point 62.
Note that the only external references in the logic sequence BB available to the sequencing devices 21a, 21b, 21c for each pump element A, B, C is the “full” and “empty” status of its “partner” pump element in the sequence, which is polled twice during each pump stroke (e.g., once before the pump filling sequence B1 and once before the pump emptying sequence B2). For example (and to further describe the pumping element “partners”), the only external reference for the sequencing device 21a for pump element A is the pump status register for pump element C. Similarly, the sequencing device 21b for pump element B refers to the fill status register for pump element A, and the sequencing device 21c for pump element C refers to the fill status register for pump element B. Note that while prior art diaphragm pump controls attempt to keep multiple diaphragm pumping elements strictly in a selected phase relationship, the sequencing devices 21a, 21b, 21c of the current embodiments only keep the pump elements A, B, C in a selected operating sequence.
Referring again to
When the pump A fill status register 40 is set to “EMPTY,” a pump A empty decision step 65 then sends a signal 66 to close the mud discharge valve 8a. There is a delay of delay time 68 (controlled by the hydraulic inlet close timer 67) before a signal 69 is sent to close the hydraulic inlet control valve 6a. There is then a further delay of delay time 71 (controlled by a decompression valve open timer 70) before a signal 72 is sent to open the decompression valve 12a. When the decompression valve 12a opens, hydraulic fluid is expelled (e.g., into the sea or into a hydraulic fluid recirculation chamber (not shown)) as pressure is gradually released from the hydraulic power chamber 3a.
The decompression valve 12a remains open until either a selected compression time 74 has passed, as determined by decompression open timer 73, or a pressure 76 in the hydraulic power chamber 3a, as measured by a pressure transducer 11a, reaches a predetermined set point 77 as determined by a comparator 78. A signal 79 to close the decompression valve 12a is initiated by an “OR” function 75 that is connected to the decompression open timer 73 and the comparator 78.
At this point, the second half (e.g., the pump emptying sequence B2) of the logic sequence BB has been completed. Pump element A is now ready to begin the logic sequence BB again after being activated by the sequencing device 21a.
Hydraulic Control System
The subsea pump AA shown in
The subsea pump AA comprises a self contained, self controlled pumping unit which pumps drilling mud at a selected flow rate and pressure increase from the mud suction line 27 to the mud discharge line 28, depending only on the hydraulic power supplied by the flow regulated hydraulic power source 23, the non flow regulated power source 24, and flow restriction, or throttling, applied to the discharge line 25.
In the embodiment shown in
The pressure of the inflow of hydraulic fluid at a hydraulic manifold 93 is controlled by a hydraulic pressure control system D. The hydraulic pressure control system D is designed to maintain the hydraulic fluid at a higher pressure than the mud being discharged from the subsea pump AA to ensure that there are no negative pressure spikes in the mud discharge line 28.
For example, the pump system operator can select a desired pressure differential between the mud discharge line 28 and hydraulic manifold 93 by controlling a pressure differential set point 94. Typically, the selected pressure differential will be between 50 and 150 psi, and a pressure differential in this range is generally high enough to prevent negative pressure spikes in the system when the mud discharge valves (8a, 8b, 8c in
Pressure in the hydraulic manifold 93 is regulated by a dump valve 85, and the dump valve 85 is modulated by a dump valve controller 82 via a dump valve controller data link 82a. The dump valve controller 82 operates in response to a differential pressure calculated by subtracting a value equal to a pressure in the mud discharge line 28 (typically measured by a mud discharge pressure transducer 84, preferentially located on or proximate the subsea pump AA) from a value equal to a pressure in the hydraulic manifold 93 (typically measured by a pressure transducer 83 located on the hydraulic manifold 93), and then modulates the dump valve 85 to achieve the preselected differential pressure. However, the differential pressure described above may also be measured by subtracting pressures measured at alternative locations in the pumping system, and the location at which the differential pressure is calculated is not intended to be limiting.
Pressure modulation via the dump valve 85 helps ensure that the pressure in the hydraulic control system CC is greater than the pressure of the discharged mud so that when the mud discharge valves 8a, 8b, 8c open during the pumping cycle, the mud inside the mud chambers 2a, 2b, 2c is generally at a higher pressure than the mud in the mud discharge line 28. Moreover, in some embodiments of the invention, the dump valve 85 may be modulated to maintain a substantially constant mud discharge pressure. In these embodiments, the dump valve controller 82 monitors the discharge pressure measured by the pressure transducer 84 and adjusts the dump valve 85 to maintain the substantially constant discharge pressure.
Hydrostatic pressure (e.g., ambient pressure at depth) is measured by a hydrostatic pressure transducer 95 and is communicated to the dump valve controller 82 via a hydrostatic pressure data link 95a. If desired, the measured hydrostatic pressure can be used by the dump valve controller 82 as a reference pressure. For example, pressure in the hydraulic manifold 93 could be regulated at 150 psi above pressure in the mud discharge line 28, but in no case less than the reference hydrostatic pressure. Also note that hydraulic fluid in the hydraulic manifold 93 flows directly into the subsea pump AA as the non flow regulated hydraulic power source 24 and through a total volume control valve 86 as the flow regulated hydraulic power source 23.
The hydraulic pressure control system D is advantageous because, in prior art designs, a pressure of the hydraulic fluid is not controlled relative to a mud discharge pressure measured proximate a subsea positive displacement pump, which can result in mud discharge pressure “spikes” if the hydraulic pressure drops so that the mud in the discharge piping is at a higher pressure than the mud in the mud chambers (2a, 2b, 2c in
Constant Volume Flow Control System
One of the fundamental control strategies used to control fluid flow both into and out of the subsea pump AA is to maintain a constant volume of drilling mud in the hydraulic power chambers 3a, 3b, 3c at any selected time by regulating the flow of hydraulic fluid into the subsea pump AA. A net result is maintenance of a selected total volume of drilling mud in the mud chambers 2a, 2b, 2c at any selected time.
The flow rate of hydraulic fluid in the flow regulated hydraulic power source 23 is regulated by the constant volume flow control system E, the goal of which is to maintain the total volume of drilling mud in the subsea pump AA (e.g., in the mud chambers (2a, 2b, 2c in FIG. 1B)). The embodiment shown in
A pump volume totalizer 88 determines an instantaneous total volume of the mud chambers (2a, 2b, 2c in
Total volume control valve 86 receives control signals from total volume valve controller 87 via a valve control signal 87a. The total volume valve controller 87 compares a total volume set point 97a with an instantaneous volume of the mud chambers (2a, 2b, 2c in
Alternative Embodiment
As in the previous embodiment, the subsea pump AA is a simplified representation of the schematic diagram shown in FIG. 1B. The subsea pump AA has the hydraulic power source 81 as an input. The subsea pump AA also has outlets that comprise the discharge line 25, the diaphragm position totalizer data links 26a, 26b, 26c, and the mud discharge line 28. Note that the total volume control valve (86 in
The flow rate of hydraulic fluid in the flow regulated hydraulic power source 23 is regulated by the constant volume flow control system E, the goal of which is to maintain a substantially constant total volume of drilling mud in the subsea pump AA (e.g., in the mud chambers (2a, 2b, 2c in FIG. 1B)) at any selected time. The embodiment shown in
The pump volume totalizer 88 determines an instantaneous total volume of the mud chambers 2a,2b,2c by summing the instantaneous total mud volume of the mud chambers (2a, 2b, 2c in
The dump valve 85 receives control signals from the dump valve controller 82 via the valve control signal 87a. The dump valve controller 82 compares the total volume set point 97a with an instantaneous volume of the mud chambers (2a, 2b, 2c in
Hydrostatic pressure is measured by the hydrostatic pressure transducer 95 and is communicated to the dump valve controller 82 via a hydrostatic pressure data link 95a. If desired, the measured hydrostatic pressure can be used by the dump valve controller 82 as a reference pressure. For example, pressure in the hydraulic manifold 93 could be regulated at 150 psi above pressure in the mud discharge line 28, but in no case less than the reference hydrostatic pressure.
It has been determined that, in some embodiments of the invention, the accumulator 98 and the inherent compressibility of the hydraulic fluid enables adequate conditioning (e.g., compression, filtering, etc.) to pressurize the hydraulic fluid to a sufficient level relative to the mud being discharged from the subsea pump AA to ensure that there are no negative pressure spikes in the mud discharge line 28. Note that although the accumulator 98 is shown to be a separate item in
Fill-Rate Flow Control System
In some embodiments of a pump according to the invention, the rate at which the hydraulic fluid is discharged from the pump elements (A, B, C in
The hydraulic fluid discharged from the subsea pump AA passes through the discharge line 25. The discharge flow rate is measured by a discharge flow meter 92. The flow rate in the discharge line 25 is regulated by a discharge control valve 89. The discharge control valve 89 is, in turn, controlled by a discharge controller 90, and the discharge controller 90 uses data received through an inlet pressure data link 91a (from an inlet pressure transducer 91 that measures the pressure of the drilling mud in the mud suction line 27) or through a flow data link 92a (from the discharge flow meter 92).
There are three particular drilling mud flow rate modes that are typically required during subsea mudlift drilling operations: a constant annulus pressure mode, a constant flow rate mode, and a “make connection” mode. The constant annular pressure mode is designed to maintain a substantially constant pressure at the subsea pump inlet regardless of flow rate. Assuming that the hydrostatic and friction pressures in the wellbore annulus are generally constant, a substantially constant inlet pressure results in a substantially constant bottom hole pressure (BHP), which is required to maintain well control. In the constant pressure mode, the control system CC adjusts the pump rate of the subsea pump AA to maintain pump inlet pressure at a substantially constant level. For example, if the wellbore annulus pressure starts to rise above a preselected pressure set point, the subsea pump AA must operate at a higher stroke rate (e.g., pump at a higher flow rate) to maintain the inlet pressure at a preselected level. Moreover, if the inlet pressure drops below another preselected pressure set point, the stroke rate of the subsea pump AA must be decreased to maintain the inlet pressure at the preselected level.
In contrast, the constant flow rate mode seeks to maintain a constant volumetric flow rate from the wellbore annulus regardless of wellbore pressure. The constant flow rate mode is analogous to the “pulsation free” pumping method disclosed in U.S. Pat. No. 6,102,673 issued to Mott et al. The ability to pump at a substantially constant flow rate is required for selected well control activities used in dual gradient drilling systems.
The “make connection” mode is used when, for example, surface pumps must be stopped to add more drillpipe to a drillstring (e.g., when drilling personnel on the floating drilling vessel “make a connection”). The make connection mode is described in detail below.
When the subsea pump AA is operating (in a substantially steady state mode during, for example, normal drilling operations), the bottom hole pressure (BHP, or annular pressure at a drill bit) may be defined as:
BHP=PHYD+PAFP+PINLET (1)
where PHYD is a hydrostatic pressure of a mud column from the drill bit to the pump inlet, PAFP is an annular friction pressure generated by resistance to drilling mud flow in the annulus between the drillpipe and the walls of the wellbore (not shown), and PINLET is a pressure in the wellbore annulus measured at the suction line 27 to the subsea pump AA. Note that the relationship between PAFP and flow rate will usually be linear at the flow rates expected in normal drilling operations (e.g., return flow of drilling mud in the wellbore annulus will generally be laminar). Further, during normal drilling operations, the largest contribution to BHP will be the hydrostatic pressure of the mud column in the wellbore annulus above the drill bit.
In order to prevent the well from flowing (e.g., to prevent formation fluids from entering the wellbore and generating a “kick”), the BHP must generally be maintained at a known, constant level during the entire drilling process, including during the “make connection” process. If the surface pumps on the floating drilling vessel are stopped, the contribution of PAFP is lost. The pressure drop attributable to the loss of PAFP must be compensated for in order to maintain a substantially constant BHP so as to maintain proper well control. Because the hydrostatic pressure of mud in the drillpipe (PHYD) is substantially constant, the inlet pressure (PINLET) must be increased to compensate for the loss PAFP.
In practice, because there are several “throttles” or controls in a fluid path between the surface pumps (not shown) and the wellbore annulus (not shown) (including, for example, nozzles (not shown) in the drill bit (not shown)), if the surface pumps (not shown) are stopped abruptly, PINLET and flow rate will drop to the left of the line 103. If this occurs, then the BHP at zero flow rate will be at a level below PINLET required to maintain a substantially constant BHP (e.g., lower than the minimum PINLET 101 required to maintain BHP at zero flow rate). This situation may be avoided by implementing control schemes
In order to maintain at least the minimum PINLET 101, the BHP can be automatically controlled during a surface pump shut down process. For example, when the “make connection” mode is activated (e.g., either manually or automatically upon initiation of surface pump shutdown), the surface pumps (not shown) are stopped. The flow rate valve controller (90 in
Alternatively, the loss of PAFP may be compensated for just prior to shutting down the surface pumps (not shown) by controlling the flow rate valve controller (90 in
Another advantageous method would be to combine the two previously described methods by, for example, automatically raising PINLET by some small amount during drilling operations in anticipation of shutting down the surface pumps (not shown) to make a connection (e.g., this essentially involves creating a BHP “safety margin” a selected level above the formation pressure). Next, a control algorithm could be implemented (as described above) to automatically control BHP during surface pump shutdown. This method avoids a sudden increase in BHP that may be experienced when achieving the desired offset pressure 106.
Phase and Total Volume
At time T, the mud volumes of the mud chamber (2a, 2b, 2c in
where the volume of mud chamber 2c equals the minimum volume plus the elapsed time Tc multiplied by the slope of the curve 110. Equation (4) may be rewritten as:
and a total volume at time T can be expressed as:
Moreover, phase (Φ) may be defined as a difference between the compression and the decompression times, normalized by the fill time:
By substituting Equation (9) into Equation (6):
Accordingly, once the values of Vmin and Vmax are selected, there is a direct linear correlation between the steady state values of total volume (Vt) and phase (Φ). As long as the total volume in the system is being controlled during drilling operations, the pump cycle should not shift out of phase.
Measuring Mud Chamber Volume
In some embodiments, the pump diaphragm (4a, 4b, 4c in
Some embodiments of the invention use diaphragm pump elements similar to diaphragm type pulsation dampers such as those disclosed in U.S. Pat. Nos. 2,757,689, 2,804,884, 3,169,551, 3,674,053, and 3,880,193, all assigned to the assignee of the present invention. The diaphragms disclosed in these references are generally in a fully “unfolded” position when a pump element is empty of drilling mud. Diaphragms according to these designs help avoid gas lock that may be caused by compressible fractions of drilling mud. Other embodiments comprise diaphragms such as those disclosed in U.S. Pat. No. 4,755,111, where a thickness of the diaphragm tapers from a thickest portion near edges of the diaphragm to a thinnest portion near a middle of the diaphragm. These diaphragms are stiffest in bending near the edges and less stiff near the middle, and this design encourages the diaphragm to roll back on itself (rather than simply bending back and forth) during displacement. Further, other types of diaphragms may be used with the invention, and the type of diaphragm is not intended to be limiting.
When rolling diaphragms are used in embodiments of the invention, volume measurement is complicated by the fact that the volume displaced by the diaphragm is a nonlinear function of the linear displacement of the diaphragm as measured by, for example, the diaphragm LDT. Further, because the diaphragm rolls differently depending upon the direction of displacement (e.g., when the pump element is either filling with mud or discharging mud), the function relating volume displacement to lineal displacement is “path dependent.”
A lower substantially linear segment 51 may be modeled with the following equation:
y=1.75x−a (12)
where “y” is a volume displaced, “x” is a linear displacement, and “a” is a coefficient related to an output of the LDT.
A nonlinear segment of a filling curve 52 may be expressed as:
y=0.085x2+3x−b. (13)
An upper substantially linear segment 53 may be expressed as:
y=1.4x−c. (14)
Finally, a nonlinear segment of an emptying curve 54 may be modeled as:
y=0.125x−2.5x+d. (15)
Note that “b,” “c,” and “d” are also coefficients related to the output of the LDT.
Modeling functions for other sizes of torispherical-type diaphragm pumping elements would be similar to equations (12)-(15) above, but the functions relating linear displacement to volume displaced for any size and type of rolling diaphragm pump element must generally be determined separately by empirically measuring the displaced volume per length of diaphragm stroke and fitting a function to the measured curve by, for example, regression or other curve fitting techniques known in the art. Moreover, other methods, such as look-up tables, may be used in determining instantaneous volume measurements. If, for example, linear piston-type pumps are used in embodiments of the invention, volume calculations are much simpler and are known in the art.
In practice, equations such as equations 51-54 may be used to calculate instantaneous mud chamber volumes. First, a determination must be made relating to whether the mud chamber is in a filling mode or a discharge mode. This determination may be made, in some embodiments, by evaluating a status of the mud discharge valves. For example, if the mud discharge valves (8a, 8b, 8c in
In some situations, differential pressure control may not be beneficial. In these situations, other embodiments of the invention may be used that do not control differential pressure, but that have other advantages. Using a slightly different control system and an additional sub-sea pump, a sub-sea mud pump and control system may operate to maintain a constant annulus pressure or a constant mud flow rate, or sub-sea mud pump may operate in a “make-up” mode. Further, some embodiments of the invention enable pumping mud in the mud return line back into the well bore. Some embodiments enable the clearing of a blockage in a pump system, in the piping of a pump system, or in a rock crusher, as will be described.
The pumps AA, AA′ shown in
Hydraulic fluid is pumped from the hydraulic power system 881 through a control system and into the pumping elements A, B, C, D, E, F. The control system includes a dump valve 811, two differential volume control valves 821, 822, a first pump volume totalizer 805, a second pump volume totalizer 806, and a total volume controller 832.
The pump volume totalizers 805, 806 may be similar to the volume totalizer 88 shown in
The embodiment shown in
The total volume controller 832 determines an instantaneous total mud volume in the pump system 800. In the embodiment shown, the instantaneous total mud volume in the system (“VT”) is equal to VABC+VDEF. The total volume controller 832 is operatively coupled to the dump valve 811. In one or more of the above described embodiments, a dump valve (e.g., 85 in
If the instantaneous mud volume (VT) is smaller than desired, the total volume controller 832 operates the dump valve 811 to a more open position. A more open position of the dump valve 811 will cause a larger amount of hydraulic fluid to be dumped out of the pump system 800, thereby causing a corresponding increase in the instantaneous volume of mud (VT). The dump valve 811 is located upstream of both volume choke valves (differential volume control valves) 821, 822, thus it affects the entire pump system 800.
Conversely, if the instantaneous mud volume (VT) is larger than desired, the total volume controller 832 operates the dump valve 811 to a more closed position. A more closed position of the dump valve 811 will cause a smaller amount of hydraulic fluid to be dumped out of the pump system 800, thereby causing a corresponding decrease in the instantaneous volume of mud (VT).
The embodiment of a pump system 800 shown in
In a preferred embodiment, each pump AA, AA′ operates in symmetry; that is, each pump AA, AA′ operates at the same flow rate. The relative pump flow rates can be determined by a comparison of the instantaneous mud volume in each pump. Thus, at a preferred condition, VABC is equal to VDEF. In that situation, the differential volume (“Vδ”, which is equal to VABC−VDEF) would equal zero. In some embodiments, the differential volume controller 831 outputs a signal that varies between 0% and 100%. When the differential volume (Vδ) equals zero, the differential volume controller 831 may output a 50% signal. In some embodiments, the differential volume controller 831 is a reverse acting controller, thus an increase in the differential volume (Vδ) will cause a decrease in the signal from the differential volume controller 831.
The volume choke valves 821, 822 may respond to the output signal of the differential volume controller 831. For example, in some embodiments, the first volume choke valve 821 is in a 100% open position when the differential volume controller signal is at 50% and when it is between 0% and 50%. When the differential volume controller signal is between 50% and 100% the first volume choke valve 821 may correspondingly vary between 100% open and 0% open. When the differential volume controller signal at 100% the first volume choke valve is 0% open.
In some embodiments, the second volume choke valve 822 operates in an opposite manner from the first volume choke valve 821. The second volume choke valve 822 is in a 100% open position when the differential volume controller signal is at 50% and when it is between 50% and 100%. When the differential volume controller signal is between 50% and 0% the second volume choke valve 822 may correspondingly vary between 100% open and 0% open. When the differential volume controller signal at 0% the first volume choke valve is 0% open.
If the pumping rate in pump AA becomes greater than the pumping rate in pump AA′, that difference will be reflected in the mud volumes (VABC, VDEF) of the pumps AA, AA′. An increase of the instantaneous mud volume of pump AA (VABC) will cause the differential volume (Vδ) to become positive and the signal from the reverse acting differential volume controller 831 would drop below 50%. A signal below 50% may cause the second volume choke valve 822 to partially close, causing less hydraulic fluid to flow into pump AA′ than into pump AA. The decrease in hydraulic fluid volume in pump AA′ may cause the mud volume (VDEF) in pump AA′ to increase. Once the differential volume (Vδ) returns to zero, the signal from the differential volume controller 831 may return to 50% and both volume choke valves 821, 822 will be 100% open.
Conversely, if the pumping rate in pump AA becomes greater than the rate in pump AA′, the differential volume (Vδ) to become negative and the signal from the reverse acting differential volume controller 831 would rise above 50%. A signal above 50% may cause the first volume choke valve 821 to partially close, causing less hydraulic fluid to flow into pump AA than into pump AA′. The decrease in hydraulic fluid volume in pump AA may cause the mud volume (VABC) in pump AA to increase. Once the differential volume (Vδ) returns to zero, the signal from the differential volume controller 831 may return to 50% and both volume choke valves 821, 822 will be 100% open.
It is noted that if a persistent non-symmetry is present that favors one pump over the other, the differential volume controller 831 may continuously generate a signal above or below 50%. The signal will choke one side while leaving the other side fully open so that a continuous symmetry may be maintained.
Referring to
The pressure-flow rate controller 890 may operate to maintain a constant mud pressure in the annulus, or the pressure-flow rate controller 890 may operate to maintain substantially equal hydraulic discharge rates from pump units AA, AA′. When the pressure-flow rate controller 890 operates to maintain a substantially constant mud pressure in the annulus, it operates the hydraulic discharge valves 823, 824 in the same direction. For example, if the pressure in the annulus begins to rise, the pressure-flow rate controller 890 may act to open both hydraulic discharge valves 823, 824, thereby increasing the pumping rate of the pump system 800 and decreasing the pressure in the annulus. Conversly, if the pressure in the annulus begins to drop, the pressure-flow rate controller 890 may act to close both hydraulic discharge valves 823, 824, thereby decreasing the pumping rate of the pump system 800 and increasing the pressure in the annulus.
In embodiments where the pressure-flow rate controller 890 operates to maintain substantially equal hydraulic discharge rates from each pump unit AA, AA′, it restricts only one of the hydraulic discharge valves 823, 824. For example, if the hydraulic discharge from pump AA were greater than the hydraulic discharge rate from pump AA′, the pressure-flow rate controller 890 would act to close hydraulic discharge valve 893 to a point where the hydraulic discharge rates were again equal. Likewise, if the hydraulic discharge from pump AA′ were greater than the hydraulic discharge rate from pump AA, the pressure-flow rate controller 890 would act to close hydraulic discharge valve 894 to a point where the hydraulic discharge rates were again equal.
Those having ordinary skill in the art will realize that the pressure-flow rate controller 890 may be a reverse acting controller, similar to the differential volume controller 831, described above. The pressure-flow rate controller 890 signal may vary between 0% and 100% to control the hydraulic discharge valves 823, 824 to be between 0% open and 100 open, similar to the way that the differential flow rate controller 831 operates the volume choke valves 821, 822.
Sub sea pump AA may be used to pump mud into the annulus at a constant pressure when the drillstring is being removed. The mud in the mud return line may be pumped back into the annulus to make up for the volume of the drillstring that is being removed. By pumping mud into the annulus at a desired constant pressure, the bottom hole hydrostatic pressure may be maintained at a desired pressure to prevent fracturing of the formation or a kick from the formation.
For example, diaphragm pump element A in pump AA may be filled with mud from the mud return line by opening both the mud discharge valve 8a and the hydraulic outlet control valve 7a. The mud in the mud return line (not shown) will flow backwards through the mud discharge valve 8a and into the mud chamber 2a. The hydraulic fluid in the hydraulic fluid chamber 3a will flow out through the hydraulic outlet control valve 7a. This occurs because the higher density of the mud versus sea water creates a hydrostatic pressure in the mud return line that is greater than the ambient sea water pressure. Once the mud chamber 2a is filled with mud, the mud discharge valve 8a and the hydraulic outlet control valve 7a may be closed.
Once the valves 7a, 8a are closed, decompression control valve 12a may be opened to reduce the pressure in the hydraulic power chamber 3a and the mud chamber 2a from the mud return line pressure to a pressure near the wellbore pressure. This will prevent a shockwave from entering the wellbore when the mud suction valve 9a is opened.
The mud received in the mud chamber 2a may be pumped into the annulus (not shown) by opening the mud suction valve 9a and the hydraulic inlet control valve 6a. The hydraulic power system 881 may then be used to pump hydraulic fluid into the hydraulic power chamber 3a and force the mud in the mud chamber 2a out through the mud suction valve 9a and into the wellbore annulus. The hydraulic power system 881 may be controlled to output the desired pressure in the annulus. Once the mud chamber 2a is empty, the mud suction valve 9a and the hydraulic inlet control valve 6a are closed.
The compression control valve 10a may then be opened to raise the pressure in the chambers 2a, 3a to enable the opening of the mud discharge valve 8a and the hydraulic outlet control valve 7a. The process may then be repeated in diaphragm pump element A.
The same process may be used in the remaining diaphragm pump elements B, C in the sub sea pump AA to pump mud from the mud return line into the wellbore annulus. The operation in the three pump elements A, B, C may be staggered so that there is a continuous pumping of mud into the annulus at a constant pressure. The fill-up process requires less mud flow than normal operations, so the fill-up process may be performed using only one of the pumps AA, AA′ in the pump system. Either pump AA, AA′ may be used with the above described procedure.
Further, the same fill procedure may be used with a pump system that only includes one pump. For example, those having ordinary skill in the art, with the benefit if this disclosure, will be able to operate pump AA, as shown in
The embodiment of a mud pump system 800 shown in
The mud flow path may contain two parallel flow paths, one comprising a rock crusher 902 and pump AA, and the other comprising a second rock crusher 903 and pump AA′. If for example, either rock crusher 903, piping proximate to pump AA′, or pump AA′ becomes clogged with formation cuttings present in the mud drawn in from the annulus, it may become necessary to clear the blockage. The blockage may be cleared by operating pump AA′ in reverse, in the manner described above relating to filling the annulus when the drill string is removed. Pump AA′ may be operated in reverse until the blockage is cleared. If the blockage occurs at a time when it is undesirable to pump mud into the annulus, the unclogged pump, pump AA, may be operated in normal mode at the same time that pump AA′ is operated in reverse to prevent mud from flowing into the annulus.
In some embodiments, when a blockage is being cleared from pump AA′, the piping in or near pump AA′, or rock crusher 903, the first volume choke valve (821 in
Further, by using a pressure transducer on the mud inlet (891 in FIG. 8A), a pressure controller (890 in FIG. 8A), and a hydraulic discharge valve (823 in FIG. 8A), the pressure in the annulus may be maintained at a desired constant pressure while a blockage is being cleared.
In some embodiments, when a blockage is being cleared, for example from the piping or rock crusher 903 proximate pump AA′, the other pump AA will be operated in the forward direction at the same pumping rate as pump AA′. In these embodiments, the drilling operations may be stopped while the blockage is being cleared.
Those having ordinary skill in the art will realize that a blockage in pump AA could be cleared using the same process described above, but operating pump AA in reverse and pump AA′ in normal mode.
Moreover, a blockage clearing procedure may be performed while the pump is in make-up mode, as described above. Because make-up mode requires a lower flow rate, the forward operating pump may pump the reverse flow from another pump while still operating the pump system in make-up mode. One or more embodiments of the invention enable a blockage clearing operation to be performed for each pump in a pump system while additional sections of pipe are being added at the surface. Once the blockage is cleared, normal pumping and drilling operations may proceed.
In some embodiments, a pump system 800 includes a reverse flow rate controller 892. The reverse flow rate controller 892 may be operatively connected to the flow meters 893, 894. The reverse flow meter 892 regulates the hydraulic discharge rates when one or more of the pump units AA, AA′ are operated in reverse mode. For example, if pump AA is operated in a reverse more to clear a blockage, the reverse flow meter 892 controls the hydraulic discharge valves 823, 824 to maintain a desired relative flow rate. For example, in some embodiments, the reverse flow rate controller operates the hydraulic discharge valves so that the hydraulic discharge rate from pump unit AA, operating in reverse mode, is substantially the same as the hydraulic discharge rate from pump AA′, operating in normal mode. In some embodiments, the reverse flow rate controller operates the hydraulic discharge valves so that the hydraulic discharge rate from pump unit AA, operating in reverse mode, is lower than the hydraulic discharge rate from pump AA′, operating in normal mode. In these embodiments, pump AA′ is able to pump the returns from pump AA and still pump mud from the annulus into the mud return line.
Advantageously, one or more embodiments of the present invention enable symmetrical pumping through more than one pump unit in a pumping system. The pump may be operated to maintain a constant flow rate or a constant pressure in the annulus, or the pump system may be operated in make-up mode.
Advantageously, one or more embodiments enable a pump or a pump system to operate in reverse to pump mud in the mud return line back into the wellbore to make up for the volume of the drillstring as it is withdrawn. A pump or pump system may be operated to maintain the pressure in the top of the annulus so that the hydrostatic pressure near the bottom of the wellbore also remains constant as the drillstring is withdrawn.
Advantageously, one or more embodiments of a pump system enable a blockage in a pump or rock crusher to be cleared by operating the clogged pump in reverse while another pump operates in normal more to maintain the mud pressure in the annulus.
Thus, one or more embodiments of the invention enable a single sub-sea pumping unit to operate normally in a variety of modes, to pump mud from the mud return line into the annulus at a constant pressure, and to clear blockages in the pumps. No additional pump units or other submersible equipment are necessary.
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.
This is a continuation in part of U.S. patent application Ser. No. 09/923,287 filed on Aug. 6, 2001 and assigned to the assignee of the present invention, and issued as U.S. Pat. No. 6,505,691. Application Ser. No. 09/923,287 is a continuation-in-part of U.S. patent application Ser. No. 09/276,404 filed on Mar. 25, 1999 and assigned to the assignee of the present invention; which claims the benefit of U.S. Provisional Patent Application Ser. No. 60/079,641, filed on Mar. 27, 1998.
Number | Name | Date | Kind |
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2419993 | Green et al. | May 1947 | A |
2703055 | Jan et al. | Mar 1955 | A |
2723681 | Macglashan, Jr. et al. | Nov 1955 | A |
2854998 | MacGlashan, Jr. et al. | Oct 1958 | A |
3929014 | Sharki | Dec 1975 | A |
4611973 | Birdwell | Sep 1986 | A |
5616009 | Birdwell | Apr 1997 | A |
6102673 | Mott et al. | Aug 2000 | A |
Number | Date | Country | |
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20040007392 A1 | Jan 2004 | US |
Number | Date | Country | |
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60079641 | Mar 1998 | US |
Number | Date | Country | |
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Parent | 09923287 | Aug 2001 | US |
Child | 10341511 | US | |
Parent | 09276404 | Mar 1999 | US |
Child | 09923287 | US |