There is provided a torque device for oil field use and method of operation for same. More precisely there is provided a torque device for oil field use and method of operation for same where the torque device includes a first torque device member that has an operational axis of rotation, and where a first torque actuator is pivotally connected to the first torque device member at a first radial distance from a centre line of the first torque device member. There is also provided a method for operation of a torque device for oil field use.
In this document that is related to onshore and offshore oilfield equipment and methods, the word pipe is used to describe elongate elements in general. Depending on the operation in question the elongate element may be a tubular or nontubular, a tool or any related item that is associated with a tool joint.
A typical powered torque device used for making up or breaking out pipe connections in oilfield-related applications includes a pair of torque device members, here termed “first torque device member” and “second torque device member”, but often referred to as “power tong” and “backup tong.” In use, the power tong rotates a first pipe relative to a second pipe while the backup tong holds the second pipe relatively stationary. Each of these tongs has a slot for receiving its respective pipe. Typically, each of these tongs has a set of clamp bodies that normally includes clamp dies for engaging the pipe when the pipe is received in the tong slot.
In some powered torque devices, the torque applied to the first pipe by the power tong is derived from a pair of push-pull hydraulic actuators. These powered torque devices typically impose significant shear loads on the pipe connection as a result of inherent push-pull force imbalance of the push-pull hydraulic actuators and eccentricity of the backup and power tongs induced by tong clamping error. These shear loads can contribute to improper make-up of pipe connections. In these powered torque devices, lateral loads on the threads of the pipe connection can change the friction in the pipe connection and cause some degree of torque masking. Here, the term “torque masking” refers to anything that causes the torque reading from the powered torque device to deviate from the actual torque experienced by the pipe connection.
In some powered torque devices, mechanical guiding is used between the backup and power tongs to ensure that the backup tong and power tong have a common pipe rotation axis while the power tong is rotating. The guiding typically takes the form of a system of guide rings concentric to a theoretical pipe axis and arranged between the backup tong and the power tong and/or between the power tong and an outer structure. The current-art guide system will typically work during torque application when both the backup and power tongs are clamped to the pipes and during non-torque rotation when the power tong is not clamped to a pipe. In these powered torque devices, clamp center deviation between the power and backup tongs can cause torque masking. Specifically, if the clamped center deviation exceeds the guide ring clearance, some portion of the clamping force will be transferred onto the guide ring surfaces. The resulting friction during rotation of the power tong will then function as a drum brake leading to an apparent torque larger than the actual torque.
Errors in torque reading can make it difficult to make-up pipe connections with accuracy, particularly in applications where pipe connections are to be made up with torque in a narrow torque bandwidth.
The object of the invention is to remedy or reduce at least one of the disadvantages of the prior art.
The object is achieved according to the invention by virtue of the features disclosed in the description below and in the subsequent claims.
According to a first aspect of the invention there is provided a torque device for oil field use that includes a first torque device member that has an operational axis of rotation, and where a first torque actuator is pivotally connected to the first torque device member at a first radial distance from a centre line of the first torque device member, wherein a rod or a second torque actuator is pivotally connected to the first torque device member at a second radial distance extending in the opposite direction relative the first radial distance from the centre line, and where the first torque actuator is pivotally connected to a first portion of an actuator support, and where the rod, alternatively the second torque actuator, is pivotally connected to a second portion of the actuator support, and where the actuator support is radially movable relative the operational axis, but is restricted from rotating in a plane that is perpendicular to the operational axis.
The suspension of the torque device renders the first torque device member substantially free to slide in a plane perpendicular to the operational axis.
When attached to a pipe that is fixed in the radial direction, the operational axis coincides with a length axis of the pipe. The first torque device member turns with the pipe. If the torque device is equipped with the first torque actuator and the rod, the actuator support may, while the first torque device member pivots with the pipe, move towards or away from the operational axis.
If the torque device has the first torque actuator and the second torque actuator where one extends while the other contract at about equal speeds during pivoting of the first torque device member, the actuator support may be substantially stationary. Any discrepancy in speed between the two torque actuators results in a movement of the actuator support towards or away from the operational axis.
The actuators may be of any useful form such as hydraulic, pneumatic and electric.
The first torque actuator and the rod, alternatively the second torque actuator, may at the first portion respective the second portion of the actuator support be pivotally connected to the actuator support about an support axis that joins the first portion and the second portion.
Although only minor movements of the first torque device member are envisaged along the operational axis, the torque actuators and the rod are thus free to tilt about the support axis that joins the first portion and the second portion.
The first torque device member may be connected to a second torque device member sharing the operational axis. The first torque device member may be a power tong while the second torque device member may be a backup tong.
The actuator support may be connected to the second torque device member.
The actuator support may be pivotally connected to the second torque device member about a pivot axis that has a direction to let the actuator support be pivotable to and from the operational axis.
The two torque device member may thus be operational as a pair, as the second torque device member forms a base for the actuator support and thus for the first torque device member. The first torque actuator may be connected to a torque device member body of the first torque member by a first actuator fixture.
The rod, alternatively the second torque actuator, may be connected to a torque device member body of the first torque member by a second actuator fixture. The length of the actuator fixtures has to be adapted to the length of the actuators and to the length between the first and second portion of the actuator support.
The first portion and the second portion of the actuator support may be positioned at the same height in the direction of the operational axis.
The first torque actuator may, at least over some of its working range, be parallel with the rod, alternatively with the second torque actuator.
According to a second aspect of the invention there is provided a method of operation of a torque device for oil field use that includes a first torque device member that has an operational axis of rotation, and where a first torque actuator is pivotally connected to the first torque device member at a first radial distance from a centre line of the first torque device member, wherein the method further includes:
The method may further include pivotally connecting the first torque actuator at the first portion of the actuator support, and the rod, alternatively the second torque actuator, to the second portion of the actuator support about a support axis that join the first portion and the second portion.
The method may further include connecting the first torque device member to a second torque device member that shares the operational axis.
The method may further include connecting the actuator support to the second torque device member.
The method may further include pivotally connecting the actuator support to the second torque device member about a pivot axis that has a direction to let the actuator support be pivotable to and from the operational axis.
The method may further include positioning the first portion and the second portion of the actuator support at the same height relatively the operational axis.
The device and method according to the invention render it possible to torque the first pipe without inducing lateral forces. Lateral forces as induces by prior art tools due to their laterally fixed connections, tend to set up additional friction forces in threads, thus masking or disturbing torque readings for threaded tool joint connection.
Below, an example of a preferred device and method is explained under reference to the enclosed drawings, where:
It should be noted that the figures, in order to better disclose the inventive features, generally only show features necessary for the disclosure. This implies that a number of necessary items such as fixings, power supplies, control cables and equipment are not shown. These items and their function are however known to a skilled person.
In the figures the reference number 1 denotes a powered torque device for making up or breaking out a connection tool joint 2 between a first pipe 4 and a second pipe 6. The torque device 1, see
The torque device member body 12 is in this embodiment made up of an upper part 14 and a lower part 16 where both parts 14, 16 have “U” formed slots 18 for placing the first pipe 4. The upper and lower parts 14, 16 are spaced apart and joined by side parts 20. Upper and lower refer to operational positions of the torque device 1.
The first torque device member 10 has three clamp bodies 22, 24, 26 that are designed to move between a refracted passive position, wherein the clamp bodies 22, 24, 26 are disengaged from the first pipe 4, and an active extended position, wherein the clamp bodies 22, 24, 26 are in contact with the first pipe 4. Of these clamp bodies 22, 24, 26, the first clamp body 22 includes a clamp arm extension 27 that hinges on a first clamp pin 28, see
A coordinate XYZ system is shown in
The first torque device member body 12, that is supported by a structure not shown, is substantially free to slide, or slidable in the XY plane.
When viewed from the opposite side relative to the “U” formed slot 18, see
The first, second and third clamp bodies 22, 24, 26 are coupled to and moved by a first clamp actuator 36, a second clamp actuator 38 and a third clamp actuator 40 respectively. The clamp actuators 36, 38, 40 are fitted to the side part 20 of the torque device member body 12 and are connected to their respective clamp bodies 22, 24, 26 by intermediate struts 43.
A first torque actuator 42 is pivotally connected to the first torque device member 10 at a first actuator fixture 44 and at a first radial distance 46 from a centre line 48 of the first torque device member 10. When the first torque device member 10 is at its mid position, the centre line 48 is parallel with the X direction. A rod 50 is pivotally connected to the first torque device member 10 at a second actuator fixture 52 at a second radial distance 54 from the centre line 48. The first and second radial distances 46, 54 are on opposite sides relative the centre line 48. The connections of the first torque actuator 42 and the rod 50 at the first actuator fixture 44 and the second actuator fixture 52 respectively may be in the form of ball type connections as often used on actuators.
The first actuator 42 is also pivotally connected to a first portion 56 of an actuator support 58, while the rod 50 is pivotally connected to a second portion 60 of the actuator support 58. The first and second portions 56, 60 of the actuator support 58 are here fork formed.
As shown inn
The actuator support 58 is movable in the X direction which is the radial direction relative the operational axis 34 of the first torque device member 10. The actuator support 58 is however restrained from rotating in the XY plane that is perpendicular to the operational axis 34.
In
During normal operations the centre line 48 is perpendicular to the operational axis 34. Due to a possible imperfect clamping position of the first pipe 4 relative the first torque device member 10, the operational axis 34 may or may not intercept the centre line 48.
When a torque is to be applied to the first pipe 4, the first pipe 4 is positioned in the “U”-formed slot 18 of the first torque device member 10. The clamp bodies 22, 24, 26 are moved by their respective clamp actuators 36, 38, 40 to their active positions engaging the first pipe 4. As the first torque device member 10, prior to being clamped to the first pipe 4, apart from being connected to the first torque actuator 42 and the rod 50, is free to move in the XY plane, the first torque device member 10 will, when the clamp bodies 22, 24, 26 engage the first pipe 4, position itself on first pipe 4, the centre axis of the first pipe 4 thus becoming the operational axis 34 of the torque device 1.
In the embodiment shown in
In an alternative embodiment, the rod 50 may be exchanged for a second torque actuator 66 as shown in
As shown in
The second torque device member 68 is similar in design to the first torque device member 10 and includes a torque device member body 70 with an upper part 72.
A yoke 74 extends in the X direction from the second torque device member 68 and to below the actuator support 58. The actuator support 58 is connected to the yoke 74 via a pivot bearing 76 that pivots about a pivot axis 77 that is parallel to the Y direction. The actuator support 58 may pivot freely in the pivot bearing 76 to move in the radial direction to and from the first torque device member 10, see
In the embodiment shown in
If the torque device 1 is to be used for making up the tool joint 2, see
The support pad 80 includes a top layer 82 and a bottom layer 84. The top layer 82 may be laminated to the bottom layer 84 by any suitable means such as, but not limited to, bonding. The support pad 80 may have a disc shape. The top layer 82 is the layer that is in contact with the first torque device member 10. The top layer 82 is made of a low-friction, wear-resistant material, which would allow the first torque device member 10 to slide freely relative to the second torque device member 68. The bottom layer 84 is the layer that is in contact with the upper part 72 of the second torque device member body 70.
The bottom layer 84 is made of a compressible, spring material that allows a small amount of compression without permanent deformation in order to sustain a relative movement along the operational axis 34 between the first torque device member 10 and the second torque device member 68. The material of the bottom layer 84 is compressed against the second torque device member 68 by the weight of the first torque device member 10 and by the first torque device member 10 moving a physical distance, not shown, while being rotated through a rotation angle to make-up a connection tool joint 2. The compressibility of the material of the bottom layer 84 is chosen to support the first torque device member 10 a sufficient distance above the second torque device member 68 and to allow sufficient movement of the first torque device member 10 along the operational axis 34 while making up a connection tool joint 2, thereby preventing other physical contact between the first torque device member 10 and the second torque device member 68.
Possible movements of the first torque device member 10 are indicated in
The torque device 1 may be controlled by a power circuit 100 as shown in
When hydraulic fluid is supplied to the plus chambers 102, 106, the respective torque actuators 42, 66 extend, while they retract if hydraulic fluid is supplied to the minus chambers 104, 108.
Pressurized hydraulic fluid is in the normal way supplied to the pump port P(P port) of a direction valve 110, and hydraulic fluid is drained from the direction valve 110 through a drainage port T (T port). A first plus line 112 connects a make port M (M port) on the direction valve 110 to the first plus chamber 102 and to a first closable valve 114. A second plus line 116 connects a break port B (B port) of the direction valve 110 to the second plus chamber 106 and to a second closable valve 118. A first minus line 120 connects the first minus chamber 104 with a third closable valve 122 and the second closable valve 118. A second minus line 124 connects the second minus chamber 108 with the first and third closable valves 114, 122.
The torque device 1 has two modes of operation: a normal mode and a high torque mode. When making up a tool joint 2 in normal mode, see
The flow from the first minus chamber 104 to the second minus chamber 108 causes the second torque actuator 66 to retract. As the second torque actuator 66 retracts, fluid from the second plus chamber 106 flows via the second plus line 116 to the B port and then to the T port of the direction valve 110.
In one embodiment, se
When making up a tool joint 2 in high torque mode, see
The normal and high torque modes when breaking up a tool joint 2 are similar to those explained above for the making up of the tool joint. Such operations may also be utilized for the return idle movement of the torque actuators 42, 66. Table 1 shows the valve positions at different modes of operation.
As explained above, the first torque device 10 is free to slide in the XY plane, while the actuator support 58 may, to a limited extent illustrated by reference numeral 90 in
In order to explain the torque difference between the normal mode and the high torque mode, the operation of make up of the tool joint 2 is chosen. The first and second radial distances 46, 54, see
In normal mode, when the first torque actuator 42 extends, fluid is flowing from the first minus chamber 104 of the first torque actuator 42, and to the second minus chamber 108 of the retracting second torque actuator 66. The force in the two torque actuators 42, 66 are equal but acting in opposite directions in order to keep the actuator support 58, that is freely movable to and from the first torque actuator 42, stationary. The forces from the two torque actuators 42, 66 forms a force couple. The hydraulic pressure is shared by the two torque actuators 42, 66. The resulting forces that are equal but acting in opposite directions are each equal to f.
The resulting force in the first torque actuator 42 is also equal to F-f. As the two torque actuators 43, 66 are equal in dimensions; the force in the first torque actuator 42 is reduced by the same amount that is transferred to the second torque actuator 66. Thus, as F−f=f, the force acting in each torque actuator 42, 66 in normal mode is half that acting in the first torque actuator 42 at high torque mode.
In make up normal mode the torque exerted on the first pipe 4 is the sum of the force from the first torque actuator 42 (f=0,5F) multiplied with the first radial distance 46 (L), and the force from the second torque actuator 66 (f=0,5F) multiplied with the second radial distance 54 (L).
0,5F*L+0,5F*L=FL
In make up high torque mode the first minus chamber 102 is drained to the T port. The force from the first torque actuator 42 is F. The second torque actuator 66 is restrained from moving and the reaction force in this is also F. Total torque acting on the first pipe 4 in high torque mode is thus
F*L+F*L=2FL
At the same hydraulic fluid pressure, the torque at high torque mode is twice that at normal mode.
The operational “band width” of the torque device 1 is thus increased by utilizing the control circuit 100.
The second torque actuator 66, being restrained from extending during high torque make up, will move the actuator support 58 a distance during the high torque operation.
The torque device 1 is equipped with a guide system 130 for aligning the first torque device member 10 to the second torque device member 68, see
The guide system 130 also includes a first guide element 140, a second guide element 142 and a third guide element 144 that are movably connected to the other of the first or second torque device members 10, 68, here to the first torque device member 10 and moves with its respective first clamp body 22, second clamp body 24 and third clamp body 26, see
In
In
When the clamp bodies 22, 24, 26 are in their retracted position, the guide system 130 will guide the first and second torque device member 10, 68 relative each other during the return stroke of the first and second torque actuators 42, 66 as the rotational position 86 of the first torque device member 10 is altered, see
It should be noted that the support pads 80 as well as the first, second and third guide ring sections 134, 136, 138 as shown in
As the first torque device member 10 is free to slide in the XY plane, the guide system 130 safeguards that the first torque device member 10 is roughly aligned with the second torque device member 68 when the first torque device member 10 is unclamped from the first pipe 4. Still, the guide system 130 is not engaged when the clamp bodies 22, 24, 26 of the first torque device member 10 are in their extended active position.
A compliant die retainer 150 is shown in
In
In
In another embodiment, see
As shown in
The die retainer 158 as shown in
A not shown end stop may be provided to limit the movement of the clamp die 152 in the clamp fixture 154.
When a force is moving the clamp die 152 in the clamp fixture 154 as shown in
Similarly, when the clamp die 152 is moved a distance 178, see
As a similar movement occurs in the embodiment shown in
In
During a clamping operation, the first clamp body 22 and the second clamp body 24, see
As the position of the first clamp pin 28 in this embodiment is fixed relative the first torque device member 10, the centre line 182 of the clamp die 152 intersects a larger pipe centre position 192 at a larger pipe tangent position 194, a medium pipe centre position 196 at a medium pipe tangent position 198 and a smaller pipe centre position 200 at a smaller pipe tangent position 202.
The centre positions 192, 198, 200 that are different, correspond with the operational axis 34 for larger diameter pipe 186, the medium diameter pipe 188 and the smaller diameter pipe 190 respectively.
The third clamp body 24, see also
The distance I, II the first and second clamp bodies 22, 24 need to move to achieve alignment of the different pipes 186, 188, 190 are different from the distance III the third clamp body 26 must move. The relationship between the equal distances I, II and the distance III is not linear. However, by using a first order approximation as shown in
In
As the travel speed of the clamp bodies 22, 24, 26 in one embodiment are constant; the retracted positions of the respective clamp bodies 22, 24, 26 are on the line 210 at a first and second retracted position 212 and a third retracted position 214 respectively. The positions 212 and 214 are also indicated in
As explained above, the third clamp body 26 has to start at the third retracted position 214 that is closer to the first pipe 4 than the first and second clamp bodies 22, 24 that are at the first and second retracted position 212.
The flow valves 216, 218, 220 are supplied with hydraulic fluid through a supply line 222 that receives fluid through a pressure reducing valve 224. The clamping sequence terminates when no flow is detected through the pressure reducing valve 224. The pressure set at the reduction valve 224 and present after the flow control valves 216, 218, 220 is equivalent to the desired clamp force.
This allows for detection of when flow is still going through the reducing valve 224 and thus to monitor if clamping has finished or not. The first pipe 4 will be clamped also when off-centered relative to the first torque device member 10 because the clamp bodies 22, 24, 26 will continue to move until they all make contact with the first pipe 4. The set pressure has to be above the minimum value that would allow the flow valves 216, 218, 220 to be within the operational range; otherwise, the clamp bodies 22, 24, 26 may move at unpredictable speeds.
The system is applicable to both the first torque device member 10 and the second torque device member 68.
In
In one embodiment the first clamp pin 28 has a lock 236 that includes a lock pin 238. The lock pin 238 may be inserted into any of a number of lock apertures 240 in the first torque device member body 12.
By turning the clamp pin 28 with the bearings 232 in the first torque device member body 12, the position of the first clamp body 22 relative the first torque device member 10 may be adjusted, see
In
The centre line 182 of the clamp die 152 in the second clamp body 24 has an offset distance 180 relative the small pipe centre position 200 that corresponds with the operational axis 34.
By turning the first clamp pin 28 through an angle 242 as shown on the left hand side of the
An arrow 244 shows the present relative position of the first clamp pin 28.
The system is applicable to both the first torque device member 10 and the second torque device member 68.
In one embodiment shown in
In one embodiment a position sensor 255 may be contact less relative the first torque device member 10.
The first torque actuator 42 has a first force sensor 256 that is designed to give a signal that reflects the force exerted by the first torque actuator 42. In an embodiment where the first torque actuator is electrically driven, the first force sensor 256 may be positioned at the first portion 56 of the actuator support 58; alternatively it may measure the power. In an embodiment where the first torque actuator 42 is fluid driven, the first force sensor 256 may be in the form of a fluid pressure sensor. The force may then be calculated.
Similarly the second torque actuator 66 has a second force sensor 258.
In one embodiment the torque may be measured by use of a third force sensor 259 positioned in the actuator support 58.
The sensors 250, 252, 254, 255, 256, 256, 258 and 259 may be of any suitable design as known to a skilled person.
The sensors 250, 252, 254, 256, 256, 258 and 259 are connected to a torque control system 260 by wires 262.
The torque control system 260 is programmed to calculate torque or torque-turn data. The torque-turn data is determined by relating a torque value to the actual turn position of the first torque device member (10). It is thus possible to relate the actual torque exerted on the first pipe 4 by the first torque device member 10 to the actual rotational position 86 of the first torque device member 10.
In one embodiment the torque control system 260 is equipped with memory 264 for storing at least said information.
As the first torque device member 10 alter its rotational position 86, see
This change in moment arm 266 length may be compensated by a change in torque actuator force.
In the case of fluid driven first and second torque actuators 42, 66, the fluid pressure may be adjusted. The adjustable pressure regulating valve 126 of the control circuit 100 for the first and second torque actuators 42, 66 is shown in
In an embodiment where the first and second torque actuators 42, 66 are electric, the supply current or/and the voltage may be altered as the length of the moment arm 266 changes in order to keep the torque of the first torque device member 10 constant or in line with a preset torque-turn curve.
A typical box connection 270 of the tool joint 2 is shown in
As the box connection 270 is pipe formed, it is exposed to deformation from the clamp bodies 22, 24, 26 particularly if gripped close to the box tool joint shoulder 280 of the box connection 270, see
The second pipe 6 has a pipe diameter Øp while the overall shoulder to shoulder length is G. The box connection 270 has connection upset to box tool joint shoulder distance A and a cylindrical face distance B. Further, the box connection 270 has a base hardband 274 to box tool joint shoulder distance C and a top hardband 274 to box tool joint shoulder distance D.
The hard band 274 has the form of a protruding ring that is made of a relatively hard wearing material. The clamp dies 152 of the torque device 1 should not grip on the hard band 274 as the clamp dies 152 by doing so may be damaged. The clamp dies 152 should preferably grip the box connection 270 as close as possible to the hard band 274 and as far away from the box joint shoulder 280 in order to avoid or reduce the above mentioned deformation. A clamp die 152 is shown in
The sensor tip 292 is in one embodiment biased against the first pipe 6 by a tip actuator 304, here in the form of a fluid driven ram. The tip actuator 304 may in one embodiment be connected to the measuring tip 222 via a tip spring 306 as shown in
In one embodiment as shown in
In
A sensor spring 310 in the linear sensor 294 is biasing the guide 296 towards the sensor tip 292 with a relatively small force. The linear sensor 294 is thus only marginally influenced by the movement of the tip actuator 304.
The TJF 290 is in one embodiment positioned on one of the torque device members 10, 68 of the torque device 1. As the torque device 1 is vertically moved relative the tool joint 2, the TJF 290 will read the surface of at least a part of the first or second pipes 4, 6. The position of the hard band 274 of the box connection 270 is determined and the clamp dies 152 of the second torque device member 68 positioned as close to the hard band 274 as desirable.
A datum point 312 may be chosen on the box joint shoulder 280 in order to overcome some reference drawbacks of certain TJF 290.
A pipe tally system 320, as known from oilfield use, includes a database 322, see
As the identity of the pipes 4, 6 are identified when built into a string, not shown, the length and weight of said string may be updated by the prior art tally system as new pipes are added.
The torque device 1 and the TJF 290 may have separate or a common control system 324 that in one embodiment at least includes one of the torque control system 260, or the measuring control system 300.
The control system 324 is connected to the torque device 1 and the TJF 290. Such connections include necessary not shown power cables or hydraulic lines as well as control cables.
Pipes 4, 6 and tool joint 2 data stored in the tally system that in one embodiment are utilized by the torque device 1 and profile sensing/mapping tool joint finder (TJF) 290 could include, but not be limited to, the following:
General data:
Pipe 4,6 identity
Box connection 270 identity
Pin connection 278 identity
Pipe/connection type
Hardbanding yes/no/type
Calibration factor(s)
Dimensional data for pipe 4, 6 and tool tool joint 2:
Dimensions may be generic for pipe type and/or specific to actual pipe/tool joints in current condition as tool joints may be re-machined, hardbanding re-applied etc. Tool joint dimensions can be for box connection and pin connection as required.
G—overall shoulder to shoulder length
Øt—diameter tool joint
Øp diameter pipe
A—upset to shoulder distance
B—cylindrical face distance
C—base of hardbanding to shoulder
D—top hardbanding to shoulder
Derived dimensions that may be calculated in the torque device 1/TJF 290 control system 324:
Width hardbanding=C-D
Upset slope=(Øt-Øp)/(A-B)
E=Datum distance for the TJF 290=A—(Register offset*upset slope)
Register offset: As certain tool joint finders may have a “deadband” F distance within which profile changes will not be registered, a register offset is thus associated with that particular TJF 290. This and any other torque device 1 or TJF 290 specific information would likely but stored in, or input into the torque device 1 or TJF 290 control system 324 rather than in the tally database 322.
Torque data to be stored in the database 322:
Torque operation date and time tagged.
Well data as required.
Maximum, minimum and recommended make up torque values for the tool joints 2. These may be stored in tally database 322 and output to torque device 1 control system 324 or be directly input by operator 326 to control system 324.
Target torque from operator 326 input may be stored in the torque device 1 control system 324 or in tally database 322.
Generally, inputs may be supplied by an operator 326 or read from an available source such as a radio frequency identification (RFID) reader 328 placed at the torque device 1 or at the TJF 290.
The control system 322 receives information of actual torque and related rotational position 86 of the first torque device member 10 as mentioned above. Measured torque-turn information is in one embodiment stored in the tally database 320 and related to the actual tool joint 2.
Data from measurements that may be stored in the tally database 320:
Actual make-up torque that are registered by the torque control system 260 and output to a historical tool joint database that may be part of the tally database 322 or could be a separate database not shown.
Expected or optimal break-out torque may be stored as an absolute value or as a derived function of actual make-up torque.
Actual break-out torque as registered by the torque control system 260 and output to the historical connection database. Optimal torque/turn curves may be stored in tally system database if the associated torque device 1 is torque/turn capable.
Actual torque/turn curves may be stored in tally historical database.
Out of range warnings may be logged.
Pipe profile data to be stored in the database 322:
Measurement operation date.
Generic and joint specific dimensional information as listed above.
Measured dimensional information as listed above from the TJF 290.
Based on available information to the control system 324, the control system may in one embodiment produce outputs to the operator 326. The output may include: actual torque compared with baseline torque, warnings, tong status, TJF 290 output and tool joint diagnosis.
Actual torque turn curves may be processed within tong control system in real time and out of range warnings given.
Tally historical database information may be output to and utilized by a maintenance planning system.
Additional benefits and possible uses of the integration of torque-turn and profile information in the pipe tally system 320 are discussed in the general part of the description.
This application is a 35 U.S.C. §371 national stage application of PCT/NO2012/050169 filed Sep. 5, 2012 and entitled “A Torque Device for Oil Field Use and Method of Operation for Same,” which claims priority to U.S. Provisional Application No. 61/532,770 filed Sep. 9, 2011 and entitled “Powered Torque Device,” both of which are hereby incorporated herein by reference in their entirety for all purposes.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/NO2012/050169 | 9/5/2012 | WO | 00 | 5/30/2014 |
Number | Date | Country | |
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61532770 | Sep 2011 | US |