FR2519686A2 - Pipe connector with variable angle for directional drilling - where hydraulically actuated valve is used to restrict flow of drilling liq. while connector angle is changed - Google Patents

Abstract

This is the fourth addn. to 7822063, the others being 7908803, 7908804, 8021890, all of which describe a pipe connector with a variable angle, used for directional drilling. The novelty in the present invention is the use of a valve which reduces the force of the drilling liq. while the angle of the pipe connector is being changed, but which does not affect the flow of the drilling liq. during normal drilling operation. The valve consists of two radially-opposed pistons located in a drill rod, and normally kept in a retracted position by spring pressure. But hydraulic fluid can be used to drive the two pistons inwards to restrict the dia. of the bore of a drill rod while the angle of the connector is altered.

Description

 The present addition relates to an improvement to the variable angle elbow fitting for directional drilling) described in the main application and produced as indicated in the first addition.

 This angled connection, the angle of which is adjustable from the ground surface, essentially comprises first and second tubular elements assembled together, the second element being able to pivot around an axis forming an angle with the axis of the first element, means for securing in rotation these tubular elements and remote-controlled means for changing step by step the angular setting of the second tubular element relative to the first.

According to the embodiment described in the first addition
EN 79/08 803, the remote-controlled means are of the hydraulic type and use a member creating a determined pressure drop in the flow of drilling fluid.

 The present invention provides a particular embodiment of this member so that the pressure drop has said value determined during the operation of the remote-controlled means and a significantly lower value when the remote-controlled means are not actuated.

The invention can be well understood and all its advantages will become clear on reading the description which follows, illustrated by the appended figures among which
- Figure 1 schematically shows the elbow fitting according
the main patent,
- Figure 2 shows the embodiment of this elbow fitting
according to the first certificate of addition to the main patent,
- Figure 3 shows schematically and in section the organ
adapted to create the pressure drop determined in the flow
- drilling fluid, and
- Figure 4 shows in perspective one of the compo pistons
the said organ.

 Figure 1 recalls the principle of the elbow fitting described in the main application.

 This connector consists of two tubular bodies 1 and 2 connected together by an interlocking element 2a of axis and integral with the body 2. The axis X'X of the upper tubular body 1, the axis Y'Y of the body lower tubular 2 and the axis compete at the same point 0.

The angles (h, X'X) and (A, Y'Y) formed by the axis and the axes X'X and Y'Y respectively have the same value a. Thus, during the rotation of the body 2 around the axis A, the angle delimited by the axes
X'X and Y'Y varies between a maximum value 2a (position of body 2 shown in solid line) and a zero value (position of body 2 represented in broken lines).

 Figures ZA and 2B show the embodiment of the elbow fitting, described in the certificate of addition 2,483,268, this fitting being in the position where the axes X'X and Y'Y of the tubular bodies 1 and 2 form between them a zero angle, in other words when these bodies are aligned.

 The upper body 1, which for example consists of several elements 1a, 1b, 1c joined end to end, is connected to the drill string 3 by a thread 4. The lower body 2 is screwed onto a bottom motor 5, such than a turbine, through thread 6.

At the lower part of the body 1 is a bore 11 of axis t; The lower face 12 of the body 1 is perpendicular to the axis and the plane which contains it passes through the point of intersection of the axes
X'X and h.

The upper end of the body 2 carries a fitting element 2a complementary to the bore ll, the axis of which forms with the axis
Y'Y of body 2 an angle a. The body 2 has a shoulder 13 whose face perpendicular to the interlocking axis 2a is contained in a plane passing through the intersection of the axis Y'Y and the axis of the housing element 2a .

 The tubular bodies 1 and 2 are held in their nesting position by a stop 14 supporting the axial forces applied to the connector during its use. The centering of the element 2a in the bore is ensured by bearings such as those shown diagrammatically in 15, 16 and 17 which allow the relative rotation of the two tubular bodies. Seals 18 and 19 seal between the two bodies 1 and 2.

 Inside the tubular bodies 1 and 2, a hollow shaft 20 is arranged coaxially with the element 2a and the bore 11, that is to say coaxially with the axis A. The shaft 20 and the body 1 are permanently united in rotation. This is obtained by the cooperation of a grooved bore 21 machined in the upper body 1 and of complementary grooves 22 carried by the shaft 20. The latter is also provided with grooves 23 which can cooperate with a grooved bore 24 of the lower body 2 when the shaft 20 is placed, by the action of the spring 25, in the position shown in Figure 2B. In this position the body 2 and the shaft 20 are linked in rotation.

 The shaft 20, axially movable inside the tubular bodies 1 and 2, carries on its outer face a profiled guide groove 28 which cooperates with at least one guide finger 26 integral with the body 2 to rotate the latter in rotation about the axis A when the shaft 20 is moved axially from its position shown in Figure 2B. This groove makes it possible to obtain a stepwise rotation of the tubular body 2 around the axis h.

 The lower end of the shaft 20 is extended by a hollow lower piston 27 which can slide, against the action of the spring 25, in the bore 29 of the body 2, the axis of this bore being coincident with the axis h . Seals 30 seal between the piston 27 and the bore 29. The upper end of the shaft 20 is extended by a hollow piston 31 which slides in the bore 32 of the body 1, the axis of this bore being merged with the axis b Seals 33 ensure the seal between the piston 31 and the bore 32.

 The diameter of the lower piston 27 is greater than that of the upper piston 31.

 The bores 29 and 32, the pistons 27 and 31 and the shaft 20 define between them a sealed annular space 34.

 In the upper part of the bore of the body 1 is placed a reservoir 35 containing a hydraulic fluid such as oil.

This reservoir consists of a deformable wall 36 made, for example, of neoprene. This reservoir is housed in a rigid protective enclosure 37, the wall of which is provided with orifices 38 so that the drilling fluid which circulates in the elbow connector exerts its pressure on the wall 36 of the reservoir 35. A conduit 39 provided in the body 1 connects the space 34 and the reservoir 35 through a valve 70 having an open position and a closed position.

The position of this valve, which is for example a solenoid valve, is controlled from the surface as indicated below.

 An element 40, adapted to create a pressure drop in the flow of the drilling fluid, is placed upstream of the piston 27.

More specifically, this member is placed at an intermediate level located between that of the space 34 and that of the reservoir 35. In the case illustrated by the figures, this member 40 is placed in the bore of the body 1, but no one would exit not within the scope of the present invention by placing this member 40 in the bore of the hollow shaft 20.

 A compensator, designated as a whole, by the reference 41, makes it possible on the one hand to maintain the pressure of the fluid which fills the confined space 34 at a value substantially equal to the value of the pressure prevailing in the bore of the body 2 when the valve 70 is closed and allows, on the other hand, to compensate for hydraulic leaks.

 This compensator comprises a flexible membrane 42 which, with the bore of the body 1, determines an annular space 43 which communicates by orifices 44 with the conduit 39. This membrane delimits with the body 45 of the compensator 41 a space which communicates by orifices 46 with inside the elbow fitting, downstream of the element 40 creating the pressure drop, consider the direction of flow of the drilling fluid.

 The control signals of the solenoid valve 70 are transmitted from the surface by a cable or line 47 which can be placed in the bore of the drilling string 3 or integrated into the structure of this lining. An electrical connector 48 which can be of any known type provides the electrical connection between the cable 47 and the solenoid valve 70.

 Means for locating the relative position of the two bodies 1 and 2 making up the connector can be provided. These means are, for example, constituted by a magnetic piece, such as a permanent magnet 49, fixed at the end of the connector 2 and by a set of switches 50 secured to the body 1. These switches will for example be of the type flexible blade switch marketed by RADIOTECHNIQUE under the reference R 122. At each position of the body 2, the magnet 49 actuates only one of the switches 50. The location of this switch indicates the relative position of the bodies and 2. To this end, these switches are connected to the surface, for example, by electrical conductors 51, the electrical connector 48 and the cable 47.

 The operation of the elbow fitting is described above with reference to the figures and assuming that initially the bodies 1 and 2 are aligned. The connector is in the position shown in Figures 2A and 2B and the solenoid valve 70 is closed.

The drilling fluid circulates in the direction indicated by the arrows to supply the downhole motor 5 when the latter is, for example a turbine and to irrigate the drilling tool (not shown). The pressure of the hydraulic fluid filling the reservoir 35 has a value P1 equal to the pressure of drilling fluid supplying the elbow fitting. The element 40 creates in the flow of the drilling fluid a pressure drop AP. The pressure P2 downstream of the element 40 is less than the value P1 and equal to:
P2 P1 AP-
The pressure of the hydraulic fluid filling the annular space 34 defined above is maintained by the compensator 41 at a value substantially equal to P2. The calibrated spring 25 then maintains the shaft 20 in the high position shown in FIG. 2B.

 To modify the adjustment of the angle of the elbow fitting, the circulation of the drilling fluid being maintained, a control signal is transmitted from the surface, via the cable 47.

This signal causes the opening of the valve 70 which places the reservoir 35 and the space 34 in communication via the conduit 39. The hydraulic fluid in the space 34 which is then under pressure
P1 acts on the lower piston 27 and displaces it against the action of the spring 25, the space 34 being supplied by the reservoir 35. The guide finger 26 cooperates with the groove 28 to cause the rotation of the body 2 around the axis a by an angle 2s
n (n being an integer) the bodies 1 and 2 then making between them an angle e 'between 0 and 2e which it is easy to determine by calculation.

 The circulation of the drilling fluid is stopped. The value of the pressure of the hydraulic fluid in the reservoir 35 and in the space 34 then becomes substantially equal to the value of the pressure of the drilling fluid in the tubular body 2. The calibrated spring 25 pushes the shaft 20 towards the top of FIG. 2B by driving the hydraulic fluid back into the reservoir 35 until the body 2 and the shaft 20 are again linked in rotation. The valve 70 is then closed.

 These operations can be repeated until the angle of the elbow has reached the desired value.

 With the valve 70 closed, the drilling operation can be resumed by restoring the circulation of drilling fluid.

 As indicated above, the element or member 40 creates a determined pressure drop necessary for the operation of the connector when it is desired to modify the angle of inclination between the two tubular elements 1 and 2.

 The present invention provides a particular embodiment of the element 40 which makes it possible to obtain the desired pressure drop in the flow of the drilling fluid during the periods of modification of the angle of the elbow fitting and which only introduces '' a pressure drop determined outside these modification periods.

 The element 40 is shown schematically and in section in Figure ^ 3.

 I1 comprises two cylindrical pistons 100 and 101 placed in radial housings 102 and 103 which open into the bore of the body 1. These housings communicate with each other by an annular groove 104 which is connected to the hydraulic conduit 39.

 Each of the pistons is provided with a rod 105 and 106 respectively. Springs 107 and 108 are placed around the rods 105 and 106 and bear, on the one hand, on washers 109 and 110 integral with the rods 105 and 106 and immobilized by nuts 111 and 112 and on the other hand, on plates 113 and 114 fixed to the body 1.

 The ends of the pistons are profiled as shown in Figure 4 which shows one of the pistons seen in perspective.

 When the solenoid valve 70 is closed, the springs 107 and 108 maintain the pistons in a position away from the axis of the body 1, as shown in the lower part of FIG. 3. In this position, the pistons create in the flow of fluid which circulates in the bore of the body 1, a determined pressure drop AP ′ significantly less than the value bP indicated above.

 When the solenoid valve 70 is opened by remote control, the pressure of the hydraulic fluid in the line 39 is established at a value about bP ′ higher than that which prevails in the bore of the body 1 in line with the pistons. The determined value AP ′ is chosen to be as low as possible but sufficient to allow the pistons 100 and 101 to be displaced against the action of the springs 107 and 108. The pistons approach the axis as shown in the upper part of FIG. 3 This results in a reduction in the cross section of the bore of the body 1 and the appearance of the pressure drop AP necessary for the operation of the elbow fitting as indicated above.

 When the circulation of the fluid in the bore of the body 1 is interrupted, the pressure in the pipe 39 decreases and the springs 107 and 108 act on the pistons to move them away from the axis of the body 1.

 The advantage of this device lies in the fact that the determined pressure drop AP necessary for the operation of the elbow fitting, is only created when the setting of the position of the two elements constituting the fitting is modified.

Claims (2)

1. - Angled fitting according to claim 1 of the main patent, in which the remote-controlled means are of the hydraulic type and employ a member adapted to create a determined pressure drop in the flow of drilling fluid passing through the fitting, characterized in that the said member is constituted by at least one piston disposed in a radial housing of the connector communicating with said means for supplying hydraulic fluid under pressure and in that elastic means keep the piston in a position away from the axis of the fitting as long as the hydraulic fluid pressure does not exceed the pressure of the drilling fluid in the bore of the body to the right of the piston. 2. - Elbow fitting according to claim 1, characterized in that said member comprises two opposite pistons having a profiled front face and in that said elastic means are constituted by springs.