Bi-directional grip mechanism for a wide range of bore sizes

CROSS-REFERENCE TO RELATED APPLICATIONS

Not applicable.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not applicable.

BACKGROUND OF INVENTION

1. Field of the Invention

The present invention relates generally to logging tool conveyance methods for highly deviated or horizontal wells. More specifically, the invention relates to downhole tractor tools that may be used to convey other logging tools in a well.

2. Background Art

The invention is a device that selectively grips or releases the well wall. It can also position the tractor tool at the center of the well bore.

Once a well is drilled, it is common to log certain sections of it with electrical instruments. These instruments are sometimes referred to as “wireline” instruments, as they communicate with the logging unit at the surface of the well through an electrical wire or cable with which they are deployed. In vertical wells, often the instruments are simply lowered down the well on the logging cable. In horizontal or highly deviated wells, however, gravity is frequently insufficient to move the instruments to the depths to be logged. In these situations, it is necessary to use alternative conveyance methods. One such method is based on the use of downhole tractor tools that run on power supplied through the logging cable and pull or push other logging tools along the well.

Downhole tractors use various means to generate the traction necessary to convey logging tools. Some designs employ powered wheels that are forced against the well wall by hydraulic or mechanical actuators. Others use hydraulically actuated linkages to anchor part of the tool against the well wall and then use linear actuators to move the rest of the tool with respect to the anchored part. A common feature of all the above systems is that they use “active” grips to generate the radial forces that push the wheels or linkages against the well wall. The term “active” means that the devices that generate the radial forces use power for their operation. The availability of power downhole is limited by the necessity to communicate through a long logging cable. Since part of the power is used for actuating the grip, tractors employing active grips tend to have less power available for moving the tool string along the well. Thus, an active grip is likely to decrease the overall efficiency of the tractor tool. Active grips have another disadvantage. This is the relative complexity of the device and, hence, it's lower reliability. A more efficient and reliable gripping device can be constructed by using a passive grip that does not require power for the generation of high radial forces. In one such design, the gripping action is achieved through sets of arcuate-shaped cams that pivot on a common axis located at the center of the tool. This gripping system allows the tractor tool to achieve superior efficiency. However, by virtue of the physics of their operation, the cams allow tractoring in only one (downhole) direction. Another limitation of this system is the relatively narrow range of well bore sizes in which these cams can operate. In addition, the cams cannot centralize the tool by themselves. This requires the usage of dedicated centralizers, which increase the tractor tool length.

Downhole tractor tools that use various methods of operation to convey logging tools along a well have been previously disclosed and are commercially available.

U.S. Pat. No. 6,179,055 discloses a conveyance apparatus for conveying at least one logging tool through an earth formation traversed by a horizontal or highly deviated borehole. The conveyance apparatus comprises a pair of arcuate-shaped cams pivotally mounted to a support member, a spring member for biasing the arcuate surface of each cam into contact with the borehole wall, and actuators operatively connected to each cam. A logging tool is attached to the conveyance apparatus. When either actuator is activated in a first direction, the cam connected to the activated actuator is linearly displaced forward and the arcuate surface of the cam slides along the borehole wall. When either actuator is activated in a second direction, the activated actuator pulls the connected cam backwards and the spring member thereby urges the arcuate surface of the cam to lock against the borehole wall. Once the cam is locked, further movement of the actuator propels both the conveyance apparatus and the logging tool forward along the highly deviated or horizontal borehole.

U.S. Pat. No. 6,089,323 discloses a tractor system which, in certain embodiments, includes a body connected to an item, first setting means on the body for selectively and releasably anchoring the system in a bore, first movement means having a top and a bottom, the first movement means on the body for moving the body and the item, the first movement means having a first power stroke, and the tractor system for moving the item through the bore at a speed of at least 10 feet per minute.

U.S. Pat. No. 6,082,461 discloses a tractor system for moving an item through a wellbore with a central mandrel interconnected with the item, first setting means about the central mandrel for selectively and releasably anchoring the system in a wellbore, the central mandrel having a top, and a bottom, and a first power thread therein, the first setting means having a first follower pin for engaging the first power thread to power the first setting means to set the first setting means against an inner wall of the bore. In one aspect, the tractor system is for moving the item through the bore at a speed of at least 10 feet per minute. In one aspect, the tractor system has second setting means on the central mandrel for selectively and releasably anchoring the system in the bore, the second setting means spaced apart from the first setting means, and the central mandrel having a second power thread therein and a second retract thread therein, the second retract thread in communication with the second power thread, and the second setting means having a second follower pin for engaging the second power thread to power the second setting means to set the second setting means against the inner wall of the bore.

U.S. Pat. No. 5,954,131 discloses a conveyance apparatus for conveying at least one logging tool through an earth formation traversed by a horizontal or highly deviated borehole. The conveyance apparatus comprises a pair of arcuate-shaped cams pivotally mounted to a support member, means for biasing the arcuate surface of each cam into contact with the borehole wall, and actuators operatively connected to each cam. A logging tool is attached to the conveyance apparatus. When either actuator is activated in a first direction, the cam connected to the activated actuator is linearly displaced forward and the arcuate surface of the cam slides along the borehole wall. When either actuator is activated in a second direction, the activated actuator pulls the connected cam backwards and the biasing means thereby urges the arcuate surface of the cam to lock against the borehole wall. Once the cam is locked, further movement of the actuator propels both the conveyance apparatus and the logging tool forward along the highly deviated or horizontal borehole.

U.S. Pat. No. 5,184,676 discloses a self-propelled powered apparatus for traveling along a tubular member that includes power driven wheels for propelling the apparatus, a biasing means for biasing the driven wheels into contact with the inner surface of the tubular member, and a retracting means for retracting the driven wheels from the driving position so that the apparatus can be withdrawn from the tubular member. The retracting means also include means to automatically retract the driven wheels from the driving position when the power to the apparatus is cut-off.

SUMMARY OF INVENTION

One embodiment of the invention comprises a linkage apparatus for selectively gripping and releasing the inside walls of a conduit, the apparatus comprising: a first arm; a bi-directional gripping cam rotatably attached to the arm; and an extension and locking device adapted to selectively radially extend the arm from a tool housing to an inside wall of a conduit and adapted to selectively lock the arm in an extended position.

Another embodiment of the invention comprises an apparatus for selectively gripping and releasing the inside wall of a conduit, the apparatus comprising: a plurality of linkages, each linkage comprising a first arm having a first end and a second end; a second arm having a first end and a second end, the second end of the first arm pivotably attached to the second end of the second arm, and a bi-directional gripping cam rotatably attached to at least one of the second end of the first arm and the second end of the second arm; a grip body, the first end of the first arm pivotably attached to the grip body; a hub, adapted to slide relative to the grip body, the first end of the second arm pivotably attached to the hub; and an extension and locking device adapted to selectively radially extend the linkages from the grip body and adapted to selectively lock the linkages in an extended position.

Another embodiment of the invention comprises a method for conveying a tool body through a conduit, comprising: moving a bi-directional gripping cam into contact with an inner wall of a conduit; laterally locking a position of the cam; and moving the tool body axially with respect to the cam in a first direction.

Advantages of the invention include one or more of the following:

A device that acts as a tool centralizer;

A device that selectively grips or releases the inside walls of a circular conduit such as a well or a pipe;

A device with an extended operational range of well bore sizes;

A device having double-sided cams that can grip in both the downhole and uphole directions;

A device that provides superior efficiency and reliability; and

A device having a passive grip system;

Other aspects and advantages of the invention will be apparent from the following description and the appended claims.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1

is an cross-sectional view of the overall architecture of a downhole tractor conveyance system.

FIG. 2

is a three dimensional perspective view of the invention.

FIG. 3

is a magnified perspective view of one of the linkages of the invention.

FIG. 4

is an exploded view of the elements of the linkage shown in FIG.

3

.

FIGS. 5A and 5C

are side views of the double-sided cam geometry,

FIG. 5B

is a perspective view of same.

FIGS. 6A

,

6

B, and

6

C are side views that demonstrate the gripping action of the cam.

FIGS. 7A through 7H

are side views that illustrate the process of cam reversal.

FIGS. 8A

,

8

B, and

8

C are longitudinal cross-sectional views of a hydraulic embodiment of the invention.

FIGS. 9A and 9B

are longitudinal cross-sectional views of a hydraulic a embodiment of the invention in different states of operation.

FIG. 10A

is a top view of the invention in its fully open state.

FIG. 10B

is a sectional view of a hydraulic embodiment of the invention in a fully closed state taken along the section line A—A of FIG.

9

A.

FIG. 11A through 11E

are longitudinal cross-sectional views of a hydraulic embodiment of the invention that schematically show the major operational processes.

FIGS. 12A

,

12

B, and

12

C are longitudinal cross-sectional views of an electro-mechanical embodiment of the invention that schematically show the major operational processes.

DETAILED DESCRIPTION

The present invention proposes an improved passive grip system. It may be used to centralize a logging or other well tool, allow bi-directional motion, and/or have a much wider operational range of well bore sizes than prior art systems. The invention is a combination of gripping cams and a centralizer with lockable geometry. It may be used to perform two major functions. The first is to act as a tool centralizer. The second is to selectively grip or release the inside walls of a conduit such as a well or a pipe. In one embodiment, the invention may be used as a part of a downhole tractor conveyance system. Its major elements may include a grip body, double-sided cams, cam springs, centralizer arms, wheels, hub, centralizer opening/closing device, and/or a locking device. The arms and the hub may be combined into linkages that can expand or contract radially as the hub slides with respect to the grip body in the axial direction. These linkages provide extended operational range, centralizing action, and when the hub is locked in place, support for the cams when they grip. The centralizer opening/closing device may selectively bias the linkages towards the well walls or close the arms back into the grip body. The cams are mounted at the tips of the linkages that come in contact with the well wall. The cams may be used to provide the gripping action. Since the cams are double-sided they can be used to grip in both the downhole and uphole directions. Cam springs may be provided to keep the cams in contact with the conduit wall. The wheels reduce the friction between the arms and the conduit wall when the device does not grip. The function of the locking device is to selectively lock or unlock the hub and thus the geometry of the centralizer. All these elements may be mounted onto the grip body.

The invention may be combined with a linear actuator, rails, a compensator, and an electronics block to form a tractor tool sonde. The grip body can slide back and forth on the rails of the sonde. One of the linear actuator's functions may be to reciprocate the grip body with respect to the rest of the sonde. The compensator provides pressure compensation of internal volumes and the fluid necessary for the operation of the grip. The electronics block may drive and control the electric motor of the linear actuator and the locking device. Two or more sondes may be used in a complete tractor tool to enable continuous motion of the tractor. In addition, the tractor tool may contains an electronics cartridge and a logging head that connects the tool to the logging cable. It may also contain additional auxiliary devices. The tractor tool may be attached to other logging tools that it can convey along the well.

In one embodiment, the invention, further referred to as grip, may be a part of a downhole tractor conveyance system. One possible embodiment of the tractor system in a tool string is schematically shown in FIG.

1

. The tool string shown in the figure comprises a logging head

4

that connects the tool string to the logging cable

2

, auxiliary equipment

6

, electronics cartridge

8

, two tractor mechanical sondes

10

, and multiple logging tools

12

. The electronics cartridge

8

and the two mechanical sondes

10

comprise the downhole tractor conveyance system. The electronics cartridge

8

is responsible for communication with surface equipment and other tools in the tool string, supply of power to the logging tools, and control of the mechanical sondes

10

. In another embodiment, the elements of the tractor system are not connected to each other and may have logging tools

12

between them as shown in FIG.

1

.

In another embodiment, the grip, which is denoted with the reference number

20

, may be a part of a mechanical sonde

10

. Other elements of the mechanical sonde can include an electronics section

14

, linear actuator section

16

, rail section

18

, compensator section

22

, and lower head

24

. The grip

20

slides back and forth inside the rail section

18

and is connected to the linear actuator section

16

and compensator section

22

through push rods

26

and

28

. The grip

20

and the linear actuator

16

, rail

18

, and compensator

22

sections are oil-filled, while the electronics section

14

and the lower head

24

are typically air-filled. Bulkheads

30

and

48

separate the oil and air-filled sections of the tool and provide electrical communications between these sections. The role of the linear actuator

16

is to reciprocate the grip

20

along the rails

18

. In this embodiment, the major elements of the linear actuator

16

are a motor

32

, a gearbox

34

, a ball screw

36

, and a ball nut

38

. The ball nut

38

is attached to push rod

26

. The motor

32

is the prime source of mechanical power for the tool. The power and control circuits for the motor can be located in the electronics section

14

. The ball screw

36

and the ball nut

38

convert the rotary motion at the output shaft of the gearbox

34

into linear motion. As the motor

32

rotates back and forth, the ball nut

38

reciprocates along the ball screw

36

. This reciprocating motion is transmitted to the grip

20

through the push rod

26

. The push rod

26

also contains a cocking piston

42

, which acts as a source of high pressure when activating the grip

20

. A compensator-side push rod

28

is mainly responsible for electrical and hydraulic communications between the grip

20

and the rest of the tool. This is schematically shown by the wire

44

. Note that the grip

20

is exposed to well bore fluid. The push rods

26

and

28

have to repeatedly exit the oil-filled sections of the tool, get into the well bore fluids and then reenter the tool. Dynamic seals

40

and

46

prevent any entry of well fluids into the tool. The function of the compensator

22

is to provide pressure compensation, and hydraulic fluid necessary for the operation of the grip

20

. The compensator

22

is piston-type, which major elements are a piston

50

, spring

52

and dynamic seals

54

. Except for the grip

20

, all other elements of the mechanical sonde have been previously disclosed and are commercially available in embodiments similar to those shown in FIG.

1

. These devices are discussed here because their presence is helpful in explaining the operation of the invention.

In general, the invention comprises a grip body, double-sided cams, wheels, biasing springs, centralizer linkages, a hub, a centralizer opening/closing device and a locking device. A three dimensional view of the one possible embodiment of the invention is shown in

FIG. 2

where the grip body is denoted by the reference number

60

. Three sets of linkages

62

are attached to the grip body

60

and to a hub

64

, which can slide with respect to the grip body

60

. The grip body

60

is attached to the other parts of the tool (not shown) with push rods

26

and

28

. A magnified view of one of the linkages

62

is shown in FIG.

3

. The linkages

62

are comprised of a first arm

66

, a second arm

67

, and pins

68

, which attach the first arm

66

and the second arm

67

to the grip body

60

and to the hub

64

. The cams

70

and the wheels

72

are mounted on a common axle

74

, which also joins the two arms

66

. One possible arrangement of the elements that are located at the tip of the linkage

62

is shown in FIG.

4

. The wheels

72

can rotate freely on the axle

74

. The cams

70

also can rotate on the axle

74

but are oriented in an outward pointing direction by biasing springs (not shown in the figure) located in slots

76

cut in the arms

66

. The wheels

72

and the cams

70

are separated by spacers

78

, which prevent direct frictional interaction between the wheels

72

and the cams

70

. The axle

74

is secured in place by a retaining ring

79

.

The shape of the cams

70

is an important feature of the invention. The shape is used to provide both gripping action and bi-directionality. A bi-directional gripping cam is shown in

FIGS. 5A

,

5

B, and

5

C.

FIG. 5A

is a front view, while

FIG. 5B

represents a three-dimensional view of the cam. The geometry of the cam is characterized by a constant contact angle, designated by the letter α in

FIGS. 5A and 5C

. The contact angle is defined as the angle between a line connecting the center of the cam pivot with the point of contact between the cam surface and a tangential plane, and the normal to that plane that passes through the cam axle. The advantage of this cam is that the contact angle does not change with the location of the contact point on the cam surface, which ensures consistent gripping force. Although the constant-angle is the geometry for the embodiment shown in

FIG. 4

, other geometries such as eccentric wheels (shown in

FIG. 5C

) or cams with variable contact angle may also be constructed to provide similar functionality.

The combination of the double-sided cam

70

with the wheels

72

is an important feature of the invention. Its different ways of interaction with the well wall determine the most important functions of the invention, including its ability to act as a centralizer, its ability to grip the well wall, and its ability to reverse direction. The interaction of the cam

70

and the wheels

72

with the well wall is explained in

FIGS. 6A

,

6

B, and

6

C.

FIG. 6B

represents a static contact between the cam/wheel system and the well wall

150

. The contact is described as static because no axial forces F

C

152

is applied to the centerline) are applied to the axle

74

. A radial centralizing force F

C

152

is applied to the axle

74

by a centralizing device, which is not shown in the figure and which is discussed in detail later. In addition, a much smaller force F

S

154

is applied to the cam surface, which is the resultant of the action of two cam springs (shown at

157

in FIGS.

11

A-E). The function of the cam springs

157

is to keep cam

70

in constant contact with the well wall

150

. The centralizing force F

C

gives rise to a reaction force F

N

156

in the point of contact between the wheel

72

and the wall

150

. The cam

70

also contacts the wall

150

but in a different contact point. As explained in

FIG. 5A

, this contact point is always at an angle α from the normal direction. The force at the point where the cam

70

contacts the wall is denoted by F

RS

158

. Note that this force is much smaller than F

C

152

because force F

S

exerted by the cam spring

157

is much weaker than the force F

C

exerted by the centralizing device. Thus, in this situation, the wheel

72

carries the majority of the radial load.

Now consider the application on axle

74

of an axial force F

R

160

pointing to the right. This situation is shown in FIG.

6

C. The axial force creates a tendency of the whole system to move to the right and gives rise to frictional forces at both contact points on the wheel

72

and the cam

70

. Under the influence of the axial force F

R

160

, the wheel

72

starts to roll on the well wall

150

, as indicated by the arrow

164

. Since rolling contacts are characterized by very small coefficients of friction, the frictional drag due to the interaction between the wheel and the well wall is negligible. For this reason it is not shown in FIG.

7

C. The other contact point is between the cam

70

and the well wall

150

. It is characterized by sliding friction and, hence, a much larger coefficient of friction. This contact, however, does not generate much frictional drag either. The reason is that the frictional force F

FR

162

tends to rotate the cam in the clockwise direction and thus out of contact with the well wall

150

. Thus, the spring force F

S

154

and the frictional force F

FR

162

act against each other, which results in minimal frictional drag. Another reason for the small magnitude of F

FR

is that the radial force F

S

that generates it is quite small. In summary, the motion of the cam/wheels system to the right generates very little frictional interaction between the tip of the linkage

62

(

FIG. 4

) and the well wall

150

. This results in practically free rolling of the grip with respect to the well wall

150

when pushed to the right. Also note that during this rolling motion, the axle

74

stays at a substantially constant distance from the well wall.

Application of an axial force F

P

166

in the opposite direction (pointing to the left) is shown in FIG.

6

A. As the direction of motion changes, so are the friction forces at all contact points. The friction force, which in

FIG. 6C

tended to rotate the cam

70

in the clockwise direction and, thus, away from the wall

150

, now forces the cam to rotate in the counterclockwise direction, as indicated by the arrow

172

. The geometry of the cam

70

is such (see

FIG. 5

) that when it rotates on its axle, its contact radius (defined as the distance between the contact point and the axis of the cam axle) either increases or decreases. In this case it increases. Thus, as the cam

70

rotates, it becomes wedged against the well wall

150

by the frictional force F

FP

176

at the contact point. Also, its contact radius becomes larger than the radius of the wheels

72

and the wheels

72

come out of contact with the well wall. Note that this action also requires that the axle

74

move away from the well wall, as indicated by the change in distance denoted by Δh

170

. This change in distance usually involves an increase in the magnitude of the radial force. In

FIG. 6A

, this is shown by the addition of the force F

L

to the existing centralizing force F

C

168

. After the wheels lift off from the wall surface, the whole radial load is carried by the cam

70

. This, in turn, leads to higher normal contact forces and, consequently, higher friction. Higher friction forces wedge the cam harder against the wall, which leads to even higher frictional forces, and so on. This is a self-actuating process, which can result in an extremely high radial contact force. This is especially true if the axle

74

is prevented from moving away from the well wall by some mechanical locking device (not shown). In the latter case, the rolling of the cam

70

with respect to the well wall stops and the only possibility for relative motion between the cam and the well wall is through sliding friction. A moderate coefficient of friction at the contact point between the cam

70

and the well wall

150

combined with the very large force F

N

174

can generate high enough frictional force F

FP

176

to prevent any relative sliding between the cam

70

and the well wall

150

. In this situation, the grip (

20

in

FIG. 1

) grips the well wall and becomes anchored in place.

FIGS. 7A through 7H

show the reversal of the cam

70

, which then allows change in the direction of tractoring. The cam reversal process is similar to the process of gripping the casing that was explained with regards to FIG.

6

A. However, in this case, the vertical displacement of axle

74

is not constrained. In the position of the cam/wheel system shown in

FIG. 7A

, the system can move freely to the left and grip if forced to the right. In its initial stage, the cam reversal process follows the events explained in FIG.

6

A. An axial force F

R

160

is applied to the cam axle

74

. A reaction friction force μF

RS

162

is then generated by the tendency of the cam

70

to slide with respect to the well wall

150

. The forces F

R

and μF

RS

rotate the cam

70

in the direction indicated by the arrow

164

. The rotation of the cam

70

in the clockwise direction tends to increase the contact radius of the cam, which pushes axle

74

upward. Since the wheels' radius is smaller than the contact radius of the cam

70

, the wheels

72

come out of contact with the well wall. These events are shown in

FIG. 7B

, wherein the axial force on the axle

74

is denoted by F

P

166

. This indicates the increase in axial force necessary to push the axle

74

upwards and to roll the cam towards increasing its contact radius. The next phase in the rotation of the cam is shown in FIG.

7

C. This figure is the mirror image of FIG.

6

A. As explained with respect to

FIG. 6A

, the rotation of the cam

70

will stop and the cam will grip the casing if axle

74

is locked in place radially. In contrast, in

FIG. 7C

, the axle

74

remains unlocked and the rotation of cam

70

continues. This process leads to the situation shown in FIG.

7

D. In this position, cam

70

makes contact at its largest contact radius and is at the turning point of flipping over.

FIG. 7E

shows the moment just after flipping the cam beyond its largest radius. Note that the axial force has dropped substantially in value and is again indicated by F

R

160

. From this point on forces F

C

, F

N

, and F

R

all act to continue the rotation of the cam, which for this reason proceeds very quickly. Consecutive positions of the cam are shown in

FIGS. 7F and 7G

. Finally the can comes to the position shown in

FIG. 7H

, which is exactly the same as that shown in FIG.

6

C. From this point on, the cam/wheel assembly moves with very little resistance with respect to the well wall

150

, as explained with respect to FIG.

6

C. This completes the reversal of the cam

70

. Note that the cam/wheel system now moves freely to the right and grips when an attempt is made to move it to the left as long as the radial position of the axle

74

is locked or fixed. This is exactly the opposite of the position shown in FIG.

7

A. Thus, the reversal of the cam

70

has the effect of changing the direction of tractoring.

In addition to the elements explained above, the grip (

20

in

FIG. 1

) also includes a centralizer opening/closing device and a locking device. There are a number of possible embodiments for these devices, including but not limited to a fully hydraulic system, an electromechanical system, and combinations of these systems. The embodiment of a fully hydraulic system for the centralizer opening/closing device and the locking device is presented in detail in

FIGS. 8-11

. The embodiment of an electromechanical system is schematically presented in FIG.

12

.

The top portion of the hydraulic embodiment of the grip is shown in FIG.

8

A.

FIG. 8B

is a continuation of

FIG. 8A

, and

FIG. 8C

is a continuation of FIG.

8

B. The grip body

60

is connected to other parts of the tractor tool (not shown in

FIG. 8

) through push rods

26

on the top and

28

on the bottom. As explained earlier, the push rods are used to reciprocate the grip in the rail section (

18

in

FIG. 1

) and to provide electrical and hydraulic communications.

The embodiment of the grip shown in

FIG. 8

can be subdivided into several major sections depending on their functionality. These major sections from top to bottom are drive rod attachment

80

, opening/closing hydraulic block

90

, high pressure accumulator

100

, linkages section

110

, grip actuator

120

, locking hydraulic block

130

, and compensator rod attachment

140

. These elements are discussed in more detail below.

The forces involved in reciprocating the grip along the rails are equal to the pull that the tractor tool creates and can be substantial. Therefore, special attention should be paid to the attachment of the push rods

26

and

28

to the grip body

60

. The drive section attachment consists of a split clamp

83

and an end cap

82

, which is attached to the grip body

60

with bolts

84

. Passage

81

in the push rod

26

is used for fluid communication between the grip and a cocking piston (not shown in FIG.

8

), which will be explained later. Static seals

85

are used to seal off external well fluids from the internal volumes of the tool. The invention also includes several identical fill ports

86

, which are used for initial filling of the tool with oil, for pressure measurements, and inspection.

The opening/closing hydraulic block

90

includes a hydraulic block body

96

, a solenoid valve

92

, check valves

98

and a contact assembly

94

. The latter is used to supply electrical power to the solenoid valve

92

, which can be selectively opened or closed by the control circuits located in the electronics block (

14

in FIG.

1

). The function of the check valves

98

is to direct the fluid flow in the proper chamber of the grip. A more detailed description of the role of the various hydraulic components is provided later with respect to FIG.

11

.

The third major section presented in

FIG. 8

is the high-pressure accumulator

100

. It is located inside chamber

108

of grip body

60

. The major elements of the high-pressure accumulator are a floating piston

103

and a spring

106

. High-pressure dynamic seals

102

mounted on the piston

103

separate the high- pressure region

101

on the top of the piston from the low-pressure region

105

at the bottom. In addition, a pressure relief valve

104

is mounted inside the piston

103

. The role of the valve

104

is to set the maximum pressure of the high-pressure accumulator

100

.

The next section of the grip is the linkages section

110

. In the embodiment shown, this section houses three identical linkages

62

(described earlier in

FIGS. 3-6

) as well as the centralizer hub

64

. In other embodiments the linkages section

110

may have 2, 4, 5, or 6 linkages. The hub

64

is connected to the piston rod

118

with a bolt

116

, ensuring that the motion of the piston rod

118

is transmitted to the hub

64

. Other elements of this section are the auxiliary wheels

112

that pivot on hubs

114

. These wheels

112

are used to assist the opening of the arms in small-diameter well bore sizes. Features of the grip body

60

in this section include special cuts

115

and slots

117

that provide space for the linkages when the grip is fully closed. The closing of the linkages

62

into the grip body

60

can be better understood by examining

FIG. 9

, which will be discussed later. Also shown in

FIG. 8

are internal passages

107

, which are used for hydraulic communication, as well as for passage of electrical wires. The hydraulic connections are discussed in more detail in FIG.

11

.

The function of the grip actuator

120

is to force the hub

64

to slide with respect to the grip body

60

, thus, opening or closing linkages

62

into the grip body

60

. Another function of the actuator

120

is to react the large axial forces that may be created by the cams

70

and then transmitted through the linkages

62

and the hub

64

to the actuator rod

118

. The actuator

120

is similar to a single-acting hydraulic cylinder. It consists of a piston

125

that is attached to the actuator rod

118

. The piston

125

slides inside bore

128

in the grip body

60

. The piston

125

separates the cylinder chamber

128

into a low-pressure region

124

on top of the piston

125

and a high-pressure region

127

at the bottom. High-pressure dynamic seals

126

prevent fluid communication between the low

124

and high

127

pressure regions. In addition, dynamic seals

122

mounted in a seal cartridge

121

seal around the surface of the actuator rod

118

and prevent external fluid from entering the cylinder chamber

128

. When the pressure in region

127

exceeds the pressure in region

124

, the piston

125

is pushed upward. This motion is transmitted through the actuator rod

118

to the hub

64

, which, in turn, drives linkages

62

out of the grip body

60

. When the pressure on both sides of the piston

125

is the same, spring

123

pushes piston

125

downward, resulting in closing linkages

62

into the grip body

60

.

The pressure in the actuator

120

is controlled by the locking hydraulic block

130

. Its function is to open or close the ports that connect chamber

128

to the rest of the grip. When these ports are closed, the fluid volume inside the actuator

120

is trapped. Since this fluid is practically incompressible (in one embodiment, oil), the effect of trapping the fluid is to lock the hub

64

in place and, thus, the geometry of linkages

62

. Similar to the hydraulic block

90

, discussed previously, the locking hydraulic block

130

consists of a body

132

, solenoid valve

134

and a contact assembly

136

that provides electric power to the solenoid valve. The contact assembly is connected to other electrical contacts

141

with the wire

138

, which runs along a hole

139

in the grip body

60

.

The last major section of the grip is the compensator-side push rod attachment

140

, which joins the push rod

28

to the grip body

60

. This attachment is very similar to the drive rod attachment

80

. It consists of a clamp

143

and an end cap

144

that is bolted to the grip body

60

with screws

145

. The attachment

140

also has static seals

142

that isolate the internal volumes of the grip from external fluids. The compensator-side push rod attachment

140

also provides oil communication with the tractor tool low-pressure compensator (

24

in

FIG. 1

) through an internal channel

148

. The major difference between rod attachments

80

and

140

is the presence of electrical contacts

142

in attachment

140

. These contacts are used to supply power to solenoid valves

92

and

134

. These contacts are also connected with the electronics block (

14

in

FIG. 1

) by wires

146

that run in the channel

148

.

In

FIG. 8

, linkages

62

are shown in a filly open position. This corresponds to the topmost position of the hub

64

and the piston

125

. As mentioned earlier, one of the advantages of a grip according to various embodiments of the invention is its capability to cover a large range of well bore sizes. To achieve this, linkages

62

can fold completely into the grip body

60

. Linkages

62

are also capable of assuming any intermediate position between their fully open and fully closed states. This is demonstrated in

FIGS. 9A and 9B

.

FIG. 9A

shows the same elements of the grip that were described in

FIG. 7B

with linkages

62

in the fully closed position.

FIG. 9B

, on the other hand, shows linkages

62

in an intermediate position. Note that in

FIG. 9A

, the arms

66

are completely retracted into the grip body cuts

115

. Even the cams

70

are retracted below the outline of the grip body

60

. Also note that the hub

64

is in contact with the seal cartridge

121

and the actuator rod

118

is completely inside the cylinder chamber

128

. In

FIG. 9B

, the actuator rod is extended upward by the distance denoted by “STROKE” in FIG.

9

B. The hub

64

has moved the same distance. This has forced linkages

62

to move out of cuts

115

in the grip body

60

and to expand outwardly in the radial direction. Further upward movement of the actuator rod

118

will cause the linkages

62

to extend even further out. This process of outward expansion can continue until the rod

118

exhausts its stroke or the spring

123

is compressed solid.

In the front cross-sectional view of the grip shown

FIG. 9A

, it is difficult to appreciate the amount of radial expansion that can be achieved by the grip. This is more clearly shown in FIG.

10

.

FIG. 10A

represents a top view of the grip in its fully open state.

FIG. 10B

, on the other hand, shows a cross section through the middle of the grip (denoted by

10

B—

10

B in

FIG. 9A

) when it is fully closed.

FIG. 10A

shows that the grip's radial dimensions can reach several times the envelope of the grip body

60

.

FIG. 10A

also presents a different view for the elements of the linkages

62

that were explained in

FIGS. 3 and 4

. Also note the three-lobe shape of the grip body

60

. This shape is required because the grip has to slide inside the rail section (

18

in FIG.

1

). The space

149

between the lobes and the circle

147

defined by the outlines of the grip body is occupied by the rails, on which the grip slides.

FIG. 10B

also shows how the cams

70

, wheels

72

, axles

74

, and the other elements located at the tips of the linkages

62

fit inside the grip body

60

. Note that when the linkages are fully closed the cams

70

meet at the centerline of the grip body

60

. The cross section in

FIG. 10B

also shows three of the oil and wire communication passages

107

that are machined into the grip body

60

.

The principle of operation of the embodiment of the invention that was shown in

FIGS. 8-10

is explained in

FIGS. 11A through 11C

. This figure shows a simplified representation of the embodiment of the invention. The simplification is done for the sake of clarity when explaining the principle of operation. In

FIG. 11

, only one of the linkages

62

is shown because all linkages operate in a substantially identical manner. Similarly, only one of the rails of rail section

18

is shown.

FIGS. 11A through 11C

also depict the hydraulic communications between different sections of the grip. The numerical notations used in

FIGS. 11A through 11C

are the same as those in the figures explained earlier.

FIG. 11A

shows the invention in its initial non-powered state. In this state, linkages

62

are fully closed into the grip body

60

. This state corresponds to the cross sectional view of the grip shown in FIG.

10

B. If the tractor tool is located in a horizontal section of a well, and if the grip is closed, the tractor tool body lies at the bottom of the well bore. Note that in

FIG. 11A

both solenoid valves

92

and

134

are not powered and open. Solenoid valve

134

allows hydraulic communication between chambers

101

of the high-pressure accumulator (

100

in

FIG. 8B

) and

128

of the grip actuator (

120

in FIG.

8

B). The other solenoid valve

92

and check valves

95

,

97

,

98

, and

99

allow communication between chamber

101

, the cocking piston chamber

180

and through push rod

28

the compensating section of the tool (

22

in FIG.

1

). Thus, all internal volumes of the grip are at the same pressure, which is equal to the pressure generated by the tractor tool compensator (

22

in FIG.

1

). In this situation, piston

102

is kept in its topmost position by spring

106

and piston

125

is pushed down by spring

123

. The hub

64

is also all the way down and the actuator rod

118

is fully retracted into the grip body

60

. Through piston

125

, actuator rod

118

, and hub

64

, spring

123

exerts closing force on linkages

62

and keeps them retracted into the grip body

60

. Thus, the linkages

62

do not extend beyond the outlines of the grip body

60

, which corresponds to the situation shown in FIG.

9

A.

FIG. 11B

demonstrates one function of the grip, which is to centralize the tractor tool in the well bore. This centralization is achieved by pushing linkages

62

out of the grip body in the radial direction until they lift the tool off the well wall and position it at the center of the bore. This process begins by powering solenoid valve

92

, which is indicated by arrow

186

. Next, the grip (

20

in

FIG. 1

) is pulled up by the linear actuator section (

16

in FIG.

1

). Initially, cocking piston

42

travels with the grip and is kept in its topmost position by cocking spring

182

. As the grip moves upwards, cocking piston

42

comes in contact with the end of the ball screw

36

, which prevents further upward motion of piston

42

. Since the motion of the grip

60

continues, the volume of chamber

180

in push rod

26

decreases. The pressure of the fluid trapped in this chamber increases, which is indicated by arrow

192

. The fluid used in the grip is substantially incompressible (in one embodiment, oil), hence, it forces its way out of the chamber. Since solenoid

92

is closed, the only possible way for the fluid to escape is through check valve

97

into chamber

101

. From chamber

101

, the high pressure fluid goes into passage

123

and through solenoid valve

134

, chamber

128

. The high pressure in chamber

101

pushes piston

102

down, compressing spring

106

. At the same time, the pressure in camber

128

pushes piston

125

up. The pressure exerted on piston

125

creates the axial force

190

designated by FA in the figure. The latter is transmitted through linkages

62

creating the radial centralizing force

152

, designated by F

C

in

FIGS. 6A

,

6

B,

6

C,

7

A through

7

H,

11

A,

11

B, and

11

C. As the pressure in chamber

180

increases, the centralizing force F

C

becomes high enough to overcome the weight of the tool and lifts the tool off the well wall. Due to the radial symmetry of linkages

62

(see

FIG. 2

) and due to the fact that they all are attached to the same hub

64

, the tool body moves towards the center of the well bore. When the tool is positioned at the center of the well bore, the pumping of fluid through rod

26

is stops. In this state, the grip

20

is ready to perform its function of a tool centralizer. Note, that although the grip

20

exerts radial forces that centralize the tool, the geometry of the linkages is not locked. This is demonstrated in FIG.

11

C. When the tool is pulled through a restriction by force F

R

160

, linkages

62

must contract radially. This requires the hub

64

, actuator rod

118

, and piston

125

to move down. This reduces the volume of chamber

128

and fluid must flow out of it. This is possible because solenoid valve

134

is still open. Through passage

129

the extra fluid goes to chamber

101

pushing piston

102

down. Thus, the flexibility of the centralizer and the capability of the invention to adjust to changes in well bore size are ensured by the high-pressure accumulator (

100

in FIG.

8

). The processes just described are reversed if the grip moves from a smaller to a larger well bore. In this case fluid flows from the high-pressure accumulator (camber

101

) to the grip actuator chamber

128

. Under all these circumstances, the grip continues to exert radial centralizing forces on the well wall.

The gripping function of the grip

20

is shown n FIG.

11

D. In this case, the drive rod exerts a pull force FP

166

in the upward direction, which is opposite to the direction of F

R

160

in FIG.

11

C. The solenoid valve

134

is now energized and closed, which is indicated by the arrow

194

. By closing solenoid valve

134

, the only passage out of chamber

128

is blocked and the fluid inside chamber

128

becomes trapped. Due to force F

P

166

, there is a tendency of the grip

20

to move upwards. This creates a friction force at the interface of the cam

70

and the well wall

150

, which tends to rotate the cam

70

in such a way as to enlarge the distance between the wall

150

and axle

74

. This process is the same as that described in FIG.

6

A. The tendency of axle

74

to move to the right requires that hub

64

moves down. However, the movement of hub

64

and hence piston

125

downward is prevented by the fluid that is trapped in chamber

128

. This makes the geometry of linkage

62

rigid, and prevents any further motion of axle

74

. As explained in

FIG. 6A

these are the conditions that cause the cam

70

to grip the well wall

150

and to become anchored in place. Since cams

70

and, therefore, grip

20

cannot move with respect to the well wall, the whole tool is pulled with respect to the anchored grip by force F

P

166

. Anchored grip

20

and pulling of the whole tool with respect to the grip

20

are the events characteristic of the power stroke of the tool.

Finally,

FIG. 11E

describes the closing of linkages

62

back into the grip body

60

when power to solenoid valves

92

and

134

is shut off. In this case, both solenoid valves become open and fluid can flow freely through them. Spring

123

pushes piston

125

down, which results in closing linkages

62

into the grip body

60

. The fluid from chamber

128

flows through solenoid valve

134

and then through passage

129

to chamber

101

. In

FIG. 11C

, the fluid could not escape from chamber

101

because solenoid valve

92

was closed. Now solenoid valve

92

is open and the fluid from chamber

101

is pushed through it by spring

106

. Next, the fluid passes through check valves

98

and

99

to the cocking piston chamber

180

and through passage

107

and rod

28

to the compensator (

22

_in FIG._

1

). At the end of this process, the grip returns back to the position shown in FIG.

11

A.

As indicated earlier, the hydraulic embodiment described in

FIGS. 8-11

is only one possible construction of centralizing and locking devices. Another embodiment uses electromechanical devices as shown schematically in

FIGS. 12A through 12C

. One of the major elements of the electromechanical centralizing and locking devices is ball screw

200

, which is supported by bearings

202

and

218

in the grip body

60

. The ball screw

200

is powered by an electric motor

222

. A first ball nut

210

and second ball nut

214

travel on the ball screw

200

. The first ball nut

210

travels with hub

64

. The first ball nut

210

can rotate with respect to the hub on bearings

208

. The second ball nut

214

is attached to the carrier

216

, which prevents rotation, but allows axial displacement with respect to the grip body

60

. Other important elements are electromechanical brakes

206

and

220

and springs

204

and

212

. Brake

206

selectively locks ball nut

210

with respect to hub

64

. Brake

220

locks the ball screw

200

with respect to the grip body

60

. Spring

204

is the closing spring and its action is similar to spring

123

in FIG.

8

. Spring

212

provides the flexibility necessary for the centralization function of the invention and is functionally equivalent to spring

106

in FIG.

8

.

FIG. 12A

shows the grip

20

in its non-powered state. The grip body

60

is in contact with the well wall

150

. Both hub

64

and ball nut

214

are pushed all the way down by springs

204

and

212

.

FIG. 12A

is functionally the same as FIG.

11

A.

FIG. 12B

shows the centralizing section of the grip

20

. The centralizing action begins by powering motor

222

, which turns ball screw

200

. Ball nut

214

is forced to travel upward until it reaches the position designated by “OPENING STROKE”

224

in FIG.

12

C. At this point, the motor

222

is turned off and brake

220

is activated. Brake

220

prevents ball screw

200

from rotating and, hence, keeps ball nut

214

in a fixed position. This action is equivalent to the action of the cocking piston in FIG.

11

B. Similarly, brake

220

performs the same function as solenoid valve

94

in FIG.

11

B.

FIGS. 12B and 12C

demonstrate the capability of the invention to accommodate changes in the well bore diameter. This is possible through the action of spring

212

, which either pushes hub

64

up in order to force linkages

64

further out or takes up the extra stroke when the grip goes through restrictions. In

FIG. 12B and 12C

, this is shown by the difference in displacements ΔS, designated by numbers

226

and

228

.

The other major function of the grip, the capability to grip the well wall is provided by linkages

62

and by the capability of the grip to lock the position of hub

64

with respect to the grip body

60

; the locking is achieved by brake

206

. When activated, brake

206

prevents the rotation of ball nut

210

with respect to the ball screw

200

. Since ball screw

200

cannot rotate due to the action of brake

220

, the prevention of the rotation of ball nut

210

with respect to ball screw

200

is equivalent to locking the position of hub

64

. After the geometry is locked, the gripping action of the cams is the same as that described in

FIGS. 6A

,

6

B, and

6

C.

Having explained the centralizing and locking functions of a grip according to the invention, it is now possible to explain the tractoring action of the whole tool, of which the grip is an essential part. As explained in

FIGS. 11A and 12A

, when the tractor tool is not operational, the arms and the cams of the grip are retracted into the grip body. When the tool is first powered, the centralizing function of the grip is activated. The grip arms extend from the grip body and position the tool at the center of the well. At this stage, the grip has the flexibility of a conventional biased-arm centralizer. The linkages automatically open or close to follow any variation in well bore size.

To begin tractoring, the linear actuator (

16

in

FIG. 1

) is activated. It starts reciprocating the grip with respect to the sonde body. If the tool has to tractor in the downhole direction, the radial position of the linkages

62

is kept unlocked during the downward stroke of the linear actuator and is locked during the upward stroke. During the downward stroke, the cams automatically orient themselves (see

FIG. 7

) in such a way that they can slide freely downhole and grip if an attempt is made to move them uphole. Thus, during the downward stroke the grip is easily pushed downhole by the linear actuator. During the upward stroke, the the radial position of the linkages

62

is locked and, as explained in

FIG. 11D

, the linkages

62

form a rigid body that keeps the axles of cams at fixed radial positions. The attempt to move the grip uphole creates frictional forces between the cam surfaces and the well wall. These forces tend to rotate the cams on their axles. Since the axles' positions are fixed, the tendency of the cams to rotate creates very strong radial forces on the axles. These forces are passively reacted by the centralizer linkages and by the locking device. The high radial forces create sufficient frictional interaction between the grip and the well wall to anchor the grip in place. Thus, during the upward stroke, the grip is anchored to the well wall and the linear actuator pulls the rest of the tool with respect to the grip in the downward direction. At the end of the upward stroke, the the radial position of the linkages

62

is unlocked and the grip releases the well wall. The grip is free to be moved further downhole during the second downward stroke. The sequence of locking the the radial position of the linkages

62

during the upward stroke and unlocking it during the downward stroke is repeated, which results in an “inchworm-like” downward motion of the tractor tool. With the linear actuators of the two sondes moving in opposite directions, it is possible to convert the inchworm motion of each individual sonde into a continuous motion for the whole tool.

To reverse the tractor's direction of motion from downhole to uphole, it is only necessary to change the locking sequence of the grip solenoid valves in the hydraulic embodiment. If the grip is unlocked during the upward stroke and locked during the downward stroke, the whole tool will travel uphole. It is to be noted that during the first upward stroke, the cams automatically reorient themselves to grip in the proper direction, following the events shown in

FIGS. 7A through 7H

.

The tractoring is achieved by a “ratchet” action of the tractor. When moving in the downhole direction, there are two “strokes” that are combined to produce the motion. In the downward stroke, the grip is unlocked and moves downhole, while the rest of the device is stationary. In the upward stroke, the grip is locked and stationary relative to the hole, while the rest of the device is pulled downhole with the grip acting as an anchor to the hole wall. When moving in the uphole direction, the same two strokes are combined to produce the motion. In the downward stroke, the grip is locked and anchors to the hole wall, while the rest of the device moves uphole. In the upward stroke, the grip is unlocked and moves uphole, while the rest of the device remains stationary. In a first embodiment, there are two grips operating simultaneously in opposite cycles that allows one grip to always be anchored to the wall while the other grip is moving which allows for a simulated continuous movement of the device. In a second embodiment, one grip is provided that moves, and a secondary stationary grip is also provided. In this embodiment, when the movable grip is released and moved, the stationary grip is engaged to hold the device stationary relative to the wall of the hole. When the movable grip reaches the top of its stroke, the movable grip is anchored to the hole and the stationary grip is released so that the device can be pulled up or down the hole while the grip remains stationary. This provides a “inchworm-like” motion.

When tractoring is no longer needed, the linkages can be closed back into the grip body by the closing device.

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.

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Number	Date	Country
0564500	Oct 1994	EP
0964131	Dec 1999	EP
481748	Sep 1975	SU
WO-9521987	Aug 1995	WO
WO-9806927	Feb 1998	WO
WO-9966171	Dec 1999	WO

Bi-directional grip mechanism for a wide range of bore sizes

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Term Extension

Abstract

Description

Claims

US Referenced Citations (54)

Foreign Referenced Citations (6)