EP0787888A2

EP0787888A2 - Circulating sub

Info

Publication number: EP0787888A2
Application number: EP96306334A
Authority: EP
Inventors: Andrew Mcdonald
Original assignee: Specialty Tools Ltd
Current assignee: National Oilwell UK Ltd
Priority date: 1995-09-01
Filing date: 1996-09-02
Publication date: 1997-08-06
Anticipated expiration: 2016-09-02
Also published as: EP0787888B1; DE69634399T2; DE69634399D1; EP0787888A3

Abstract

There is provided a circulating sub apparatus (50; 100) having a tubular outer body member (1; 51, 53, 54, 55, 56, 57) and a tubular inner body member (4; 52, 65). The outer body member (1; 51, 53, 54, 55, 56, 57) and the inner body member (4; 52, 65) each have one or more holes (8, 16; 66, 68) substantially transverse to the longitudinal axis of the outer (1; 51, 53, 54, 55, 56, 57) and inner (4; 52, 65) body members. A displacement mechanism produces relative movement between the outer (1; 51, 53, 54, 55, 56, 57) and inner (4; 52, 65) body members such that the outer (1; 51, 53, 54, 55, 56, 57) and inner (4; 52, 65) body members may be repeatably moved between an aligned position, in which the one or more holes (8, 16; 66, 68) on the inner body member (4; 52, 65) are aligned with the one or more holes (8, 16; 66, 68) on the outer body member (1; 51, 53, 54, 55, 56, 57), and an obturated position, in which the one or more holes (8, 16; 66, 68) on the inner body member (4; 52, 65) are obturated by the outer body member (1; 51, 53, 54, 55, 56, 57).

Description

This invention relates to a circulating sub, and more particularly to a multi-opening circulating sub for use in energy exploration, milling and drilling.
Conventional oil and gas drilling techniques utilise drill-bits which are conveyed on individual lengths (usually 30 feet) of drill-pipe and rotated from the surface of the drilling rig floor to produce the necessary rotary cutting action required to drill well bores. Alternatively, the rotary cutting action can be supplied by using a Positive Displacement Motor (PDM) located above the drill-bit and connected to the surface by either coil tubing that is provided in one continuous length, or by more conventional drill-pipe. The PDM produces the rotary action when drilling fluid is pumped through it from the surface. The main advantage of using coil tubing in conjunction with a PDM is that of a decrease in the running-in time of the equipment into the well-bore.
Debris or cuttings are produced from the cutting action, which are transported to the top of the well bore by the drilling fluid. In order to clean the well bore effectively the drilling fluid must be pumped at a high enough flow rate to lift the cuttings to the surface. However, only relatively low volumes of drilling fluid can be pumped through the complete Bottom Hole Assembly (BHA) without a large pressure drop at the surface.
This problem can be alleviated by using nitrogen to clean the well-bore which gives increased hole cleaning capabilities.
However, the use of nitrogen gives rise to a second problem, in that, nitrogen can only be pumped through a PDM motor for very short periods of time without damaging the PDM motor. Hence, the benefits of using nitrogen to clean the well-bore with existing technology are limited.
Traditionally, this first problem is overcome by using an additional tool in conjunction with the motor and drilling/milling assembly, known as a drop-ball circulating sub. This tool is run above the motor and is operated by dropping a ball, from the surface, down the drill-pipe or coil tubing. The ball seats on top of a piston within the tool and pressure is applied to the upper end of the piston and ball. The pressure is increased until shear pins, which are located within the main body of the drop-ball circulating sub, break allowing the piston to move axially downwards within the main body thereby uncovering circulating holes in the main body drilled transverse to the centre-line of the drop-ball circulating sub. These holes allow an increased flow rate to be pumped through the drill-pipe or coil tubing, thus giving a more effective hole cleaning capability.
However, this tool has the disadvantage that once the ball has been dropped to the circulating sub, no further milling or drilling can take place as the fluid path to the PDM has been blocked by the ball. If further milling or drilling is required then the tool must be removed from the well-bore so that the ball can be removed. Also, the length of time that the ball takes to drop down the drill-pipe or coil tubing can be considerable.
The second problem of pumping nitrogen is helped, but not solved, by using a drop-ball circulating sub as the drop-ball does not effect a complete seal on the piston allowing nitrogen to flow through the motor.
According to a first aspect of the present invention, there is provided a circulating sub apparatus having a tubular outer body member and a tubular inner body member, the outer body member and the inner body member each having one or more holes, the holes being substantially transverse to the longitudinal axis of the outer body member and the inner body member, and a displacement mechanism for producing relative movement between the outer body member and the inner body member, such that the inner body member and the outer body member may be repeatably moved between an aligned position, in which the one or more holes on the inner body member are aligned with the one or more holes on the outer body member, and an obturated position, in which the one or more holes on the inner body member are obturated by the outer body member.
Preferably, when the outer body member and the inner body member are positioned relative to one another in the obturated position, fluid can pass from the inner bore of the outer body member to the inner bore of the inner body member and out of the bottom end of the inner body member.
Preferably, when the outer body member and the inner body member are positioned relative to one another in the aligned position, a bypass passage is formed that allows fluid to flow from the internal bore of the circulating sub apparatus to the annulus between the outside diameter of the tool and the inside diameter of the well bore, in use.
Preferably, the displacement mechanism is controlled by fluid pressure. Preferably, the displacement mechanism comprises a piston assembly and a restrictor nozzle in the fluid path.
Preferably, the displacement mechanism includes a detent system.
Alternatively, the displacement mechanism typically includes a restraining device.
Preferably the restrictor nozzle is located on the uppermost portion of the inner body member such that fluid passing through the inner bore of the circulating sub apparatus passes through the restrictor nozzle.
Typically, the piston assembly is coupled to the inner body member.
Typically, an increase in the fluid pressure displaces the inner body member in a downwards direction.
Preferably, the detent system is a one-way detent system comprising a hydraulic fluid chamber filled with viscous fluid and a flow restrictor.
Preferably, the flow restrictor comprises a restrictor orifice in parallel with a one-way check valve.
Typically, the detent system is arranged such that downwards movement of the piston and hence the inner body member is hindered, whilst upwards movement of the piston is not hindered due to the viscous fluid bypassing the restrictor orifice through the one-way check valve.
Typically, there is provided a return spring, one end of which butts against the outer body member and the other end butts against the inner body member.
The combination of the detent system and the return spring has the advantage that the outer body member and the inner body member can be quickly returned to their equilibrium position.
Preferably, a bottom sub is slidably coupled to the bottom portion of the inner body member. More preferably the bottom sub has a shoulder against which the bottom end of the piston can butt. Most preferably the bottom end of the piston only butts against the shoulder portion of the bottom sub when the bottom sub is engaged within the inner body member as far as possible.
This has the advantage that when weight is set down on the circulating sub apparatus, the bottom sub is stroked into the inner body member and the piston butts against the shoulder located on the bottom sub, thus preventing the piston from moving further downwards and accordingly providing a through fluid path onwards to the tools located below the bottom sub.
Typically, the restraining device comprises at least one restraining member mounted on each of the inner and outer body members, the restraining member(s) mounted on the inner body member being selectively co-operable with the corresponding restraining member(s) mounted on the outer body member.
Preferably, there are two restraining members mounted on each of the inner and outer body members.
Preferably, the two restraining members mounted on one of the body members are spaced further apart than the two restraining members mounted on the other of the body members. More preferably, it is the two restraining members mounted on the inner body member that are spaced further apart than the two restraining members mounted on the outer body member.
Typically, the two restraining members mounted on the inner body member are mounted on the piston assembly.
Typically, longitudinal movement of the inner body member with respect to the outer body member moves one of the restraining members mounted on the inner body member into contact with the corresponding restraining member mounted on the outer body member.
Preferably, one of the restraining members mounted on the inner body member and the corresponding restraining member mounted on the outer body member are adapted to rotate the inner body member with respect to the outer body member, following continued longitudinal movement of the inner body member with respect to the outer body member.
Preferably, after a predetermined longitudinal movement of the inner body member, the restraining members in contact on the inner and outer body members are adapted to restrain the inner body member in a first position from further rotation.
Preferably, longitudinal movement in the opposite direction moves the other of the restraining members mounted on the inner body member into contact with the corresponding restraining member mounted in the outer body member.
Typically, the other of the restraining members mounted on the inner body member and the corresponding restraining member mounted on the outer body member are adapted to rotate the inner body member with respect to the outer body member, following continued longitudinal movement of the inner body member in the opposite direction with respect to the outer body member.
Typically, a second restrained position is reached upon longitudinal movement in the opposite direction to the direction of longitudinal movement for which the first restrained position was reached.
Typically, the direction of rotation of the inner body member with respect to the outer body member for which the first restrained position is reached is the same direction of rotation for which the second restrained position is reached.
Preferably, the first position is the aligned position and the second position is the obturated position.
Alternatively, the first position is the obturated position and the second position is the aligned position.
Preferably, when the circulating sub is in the aligned position, a sealing device deters the flow of fluid through the bottom end of the circulating sub, and more preferably deters the flow of fluid through the bottom end of the inner body member.
Typically, when the circulating sub is in the aligned position, the sealing device seals the bottom end of the inner body member.
The invention has the advantage that nitrogen gas may be pumped through the circulating sub and through the circulating holes, when the circulating sub is in the aligned position, to clean the well bore without damaging any tools located below the circulating sub.
According to a second aspect of the present invention there is provided a method of drilling or milling in a borehole, the method comprising (a) inserting in the borehole a drill string which includes a drill or mill and a circulating sub according to the first aspect, (b) putting weight on the tool to permit drilling or milling, (c) lifting weight off the tool and increasing the flow rate of fluid to move the body members to the aligned position to permit circulation, and (d) repeating steps (b) and (c) as required.
Preferably, the drill string also includes a fluid operated motor, such as a positive displacement motor, and/or a reamer.
The fluid may be a liquid or a gas and is preferably a drilling fluid. Alternatively, or in addition the fluid may be nitrogen gas.
Embodiments of the invention will now be described, by way of example, with reference to the accompanying drawings wherein:-

Fig. 1 is a split sectional view of a first example of a circulating sub in a first running in arrangement which is in a normal position;
Fig. 2 is a split sectional view of the circulating sub of Fig. 1 in a second running in arrangement;
Fig. 3 is a detailed split sectional view of the circulating sub of Fig. 1 during a milling/drilling operation;
Fig. 4 is a detailed split sectional view of the bottom portion of the circulating sub of Fig. 1 whilst initiating a circulating operation;
Fig. 5 is a detailed split sectional view of the middle portion of the circulating sub of Fig. 1 whilst initiating a circulating operation;
Fig. 6 is a detailed split sectional view of the circulating sub of Fig. 1 during a circulating operation;
Fig. 7 is a detailed split sectional view of the circulating sub of Fig. 1 whilst initiating a milling/drilling operation;
Fig. 8 is a detailed split sectional view of the circulating sub of Fig. 1 during a milling/drilling operation;
Fig. 9 is a split sectional view of a second example of a circulating sub during a milling/drilling operation;
Figs. 10(a) and (b) are schematic drawings of the positional relationship between restraint devices mounted on the circulating sub of Fig. 9;
Figs. 11(a) and (b) show the restraint devices of Figs. 10 (a) and (b) during a milling/drilling operation;
Figs. 12 (a) and (b) show the restraint devices of Figs. 10 (a) and (b) whilst initiating a circulating operation;
Figs. 13 (a) and (b) show the restraint devices of Figs. 10 (a) and (b) during a circulating operation;
Fig. 14 is a detailed split sectional view of the lower portion of the circulating sub of Fig. 9 during a milling/drilling operation; and
Fig. 15 is a detailed split sectional view of the lower portion of the circulating sub of Fig. 9 during a circulating operation.

Fig. 1 shows a first example of multi-opening circulating sub 100 in accordance with the present invention, consisting of a main outer body 1, a bottom sub 2 which can stroke in and out of the main outer body 1, a hydraulic detent system 25 and an internal piston assembly 4 which will be detailed subsequently.
In certain operations the multi-opening circulating sub 100 is required to be run into the borehole in a closed position such as that shown in Fig. 1. Drilling fluid flows from a coil tubing through an inner passage 110 of the multi-opening circulating sub 100 and subsequently onwards to equipment located below the circulating sub 100 such as a PDM.
Whilst running the BHA in hole it is advantageous and in the majority of cases advisable to circulate the drilling fluid through the coil tubing (not shown), but, however, it is not beneficial to pump fluid through the PDM for any longer than is necessary. Traditional circulating subs suffer from the disadvantage that fluid is forced to pass through the complete BHA, including the PDM, until a ball is dropped to actuate the piston and expose the circulating holes.
As shown in Fig. 2, by inserting shear pins (not shown) through threaded holes 14 until they rest in recesses 13, the multi-opening circulating sub 100 is pinned in an open position, since circulation holes 16 located on the main outer body 1 are aligned with bypass ports 8 located on the internal piston assembly 4. Thus, when drilling fluid is pumped through the coil tubing, it flows down the inner passage 110 of the multi-opening circulating sub 100 and out of the circulating holes 16 via the bypass ports 8. This fluid flow arrangement bypasses the PDM whilst the BHA is run into the borehole.
Once the correct milling depth has been reached, setting sufficient weight down on the BHA will shear the shear pins, allowing the piston 4 to return to its natural position, the movement of the piston 4 provided by a spring 23 that forces the piston 4 to its furthest position of travel, as shown in Fig. 3.
Fluid will now flow down the inner passage 110 and onto the PDM, which will then start to rotate. Seals 7, 9 prevent fluid leaking from the inner passage 110 through the bypass port 8.
At any time whilst the multi-opening circulating sub 100 is in the borehole, the circulation operation can be initiated, by observing the following procedure.
The tool string and BHA is lifted off the bottom of the borehole and the drilling fluid supply rate is increased to approximately 90 to 100% of the maximum available. Fig. 4 shows that the bottom sub 2 is coupled to a drive-shaft 11, the drive-shaft 11 being slidably coupled to the main outer body 1. Fig. 4 shows that lifting the tool string off the bottom of the borehole allows the bottom sub 2 to stroke out from within the main outer body 1 of the multi-opening circulating sub 100. This lifting action is necessary if for instance milling or drilling operation had been occurring just previously.
Fig. 5 shows that as the drilling fluid pump rate is increased, a back pressure of drilling fluid is created by a restricting nozzle 20 and from the bottom hole assembly. This back pressure forces the piston 4 to move downwards within the main outer body 1. The piston 4 is not only deterred from downward movement by the spring 23 but also by a hydraulic detent system 25. The hydraulic detent system 25 comprises a hydraulic fluid chamber 3 filled with viscous fluid, the piston 4 and a one-way flow restrictor 5. The hydraulic detent system 25 restricts the downward movement of the piston by the action of the viscous fluid passing through the one-way flow restrictor 5. As seen in Fig. 5 the viscous fluid flows from one side of the one-way flow restrictor 5 to the other side of the flow restrictor 5 through a restrictor orifice causing the piston 4 to travel slowly.
Fig. 2, and in detail Fig. 6 shows that when the piston 4 has travelled its full stroke the circulation holes 16 will be aligned with the bypass ports 8 and so the drilling fluid is able to flow therethrough. Further, with an exit path into the borehole annulus being provided for the drilling fluid above the PDM and under-reamer assembly, increased flow rates can be achieved thus increasing the borehole cleaning efficiency, without increasing the surface pressure.
When the circulation cycle is complete, the circulation holes 16 can be misaligned from the bypass ports 8 by reducing the flow rate of the drilling fluid to 50% or less of the maximum. This action decreases the backpressure caused by the restricting nozzle 20, thus relieving the load on the piston 4, which allows the spring 23 to return the piston 4 to its normal position. The one-way flow restrictor 5 incorporates a one-way check valve located in parallel with the restrictor orifice, the check valve preventing fluid passing on the downstroke of the piston 4 but allowing fluid bypass on the return up stroke. Thus the check valve eliminates any waiting period while the piston 4 returns following a circulation operation. The fluid path through the circulation holes 16 via the bypass ports 8 is discontinued, and fluid now flows down the inner passage 110 and onwards to the PDM and/or the under-reamer assembly below. This fluid flow path can be seen in Fig. 1.
At any time whilst the multi-opening circulating sub 100 is in the well bore, the circulation holes 16 can be aligned with the bypass ports 8 so that drilling fluid can circulate therethrough. However, it is conventional for a circulation cycle to follow after a period of drilling or milling as debris will have been produced which requires removal from the well bore. This operation of drilling or milling using the multi-opening circulating sub 100 will now be described.
The tool string and BHA is lifted off the bottom of the borehole and the drilling fluid pressure is sufficiently increased so that rotation of the PDM is initiated and if applicable under-reamer arms are opened if an under-reaming tool is being used. Ordinarily, increasing the pressure of the drilling fluid would initiate a circulation operation which will be detailed subsequently. However, the hydraulic detent system 25 provides resistance to downwards movement of the piston 4 and effectively provides the operator with a period of time before the circulation operation starts.
This period of time is used to set down milling weight on the mill or drill bit. This weight pushes the bottom sub 2 upwards, and forces the drive-shaft 11 back into the main outer body 1 as shown in Fig. 7. This in turn prevents the piston 4 from moving downwards far enough for the circulation operation to occur, by a shoulder 10 located on the drive-shaft 11 butting against the piston 4, as shown in Fig. 8.
Fig. 9 shows a second example of a multi-opening circulating sub 50 in accordance with the present invention, consisting of an outer tubular body formed by a number of outer body sections 51, 53, 54, 55, 56 and 57, and an inner tubular body comprising an upper piston 52 and a lower piston 65. The upper piston 52 is coupled at its lower end to the lower piston 65. The upper end of the upper piston 52 is coupled to a restrictor nozzle 60.
For a milling or drilling operation, drilling fluid flows from a coiled tubing that is connected to an upper outer body section 53, through the restrictor nozzle 60, through a bore 70 of the circulating sub 50, out of the lower outer body section 57 and subsequently onwards to equipment located below the circulating sub 100, such as a PDM.
To obtain a circulating operation, the fluid flow rate through the circulation sub 50 is increased. This increased fluid flow rate through the restrictor nozzle 60 creates a back pressure of drilling fluid across the restrictor nozzle 60, which forces the piston assembly 52, 65 longitudinally downwards within the outer body sections 51, 53, 54, 55, 56.
As the piston assembly 52, 65 moves longitudinally downwards, mating angles 61 mounted on the upper piston 52 contact an upper clutch 58 which is mounted to an outer body section 54, the contact rotating the piston assembly 52, 65 within the outer body sections 51, 53, 54, 55, 56.
The upper clutch 58 is formed to have two restraint positions. The first restraint position allows the piston assembly 52, 65 to only travel a short distance, so that the drilling fluid continues to flow through the circulating sub 50 and onto equipment located below.
The second restraint position allows the piston assembly 52, 65 to travel a greater distance, so that bypass ports 66 located on the lower piston 65 move into alignment with circulating holes 68 located on an outer body section 56. Drilling fluid will now flow down the bore 70 of the circulating sub 50 and out of the circulating holes 68 via the bypass ports 66. A pack-off sealing element 69 prevents any drilling fluid from flowing through the lowest outer body section 57 and on towards equipment located below. The operation of the pack-off sealing element 69 will be described subsequently.
Once the circulating sub 50 has been operated for the required period in one of the restrained positions, that is either in the drilling mode or the circulating mode, to change to the other operating mode, the drilling fluid flow rate is reduced. This action reduces the drilling fluid back pressure across the restrictor nozzle 60. A return spring, 63 which acts between a shoulder 72 mounted on the outer body section 54 and a thrust bearing 62 mounted on the upper piston 52, biasses the upper piston 52 upwards, and when the drilling fluid flow rate is reduced the piston assembly 52 moves upward.
The thrust bearing 62 ensures that any residual torque retained in the return spring 63 is dissipated, and hence does not interfere with the rotation of the piston assembly 52, 65.
As the piston assembly 52, 65 moves upward, an indexer 64 mounted on the lower piston 65 contacts a lower clutch 59 which is mounted to the outer body section 54. The contact between the indexer 64 and the lower clutch rotates the piston assembly 52, 65 in the same direction as the rotation produced by the upper clutch 58 and the mating angles 61 on a downward movement. Through this rotation as the piston assembly travels upwards, it will have moved onto it's next restrained position and hence it's next mode of operation.
Figs. 10 (a) and (b), 11 (a) and (b), 12 (a) and (b) and 13 (a) and (b) shows the positional relationship between firstly the lower clutch 59 and the indexer 64, and secondly the upper clutch 58 and the mating angles 61, for a complete cycle of the circulating sub 50, with the components being shown laid out flat for clarity.
Fig. 10(a) shows the indexer 64 and the lower clutch 59 in an engaged position, and Fig. 10 (a) shows the mating angles 61 longitudinally displaced from the upper clutch 58. Figs. 10 (a) and (b) show the piston assembly 52, 65 in the position as shown in Fig. 9.
Fig. 11 (b) shows that the indexer 64 and the lower clutch 59 have been longitudinally and rotationally displaced, due to downward movement of the piston assembly 52, 65. It can be seen in Fig. 11 (a) that the mating angles 61 are in contact with the upper clutch 58, and are restrained in the second, or furthest position possible by the upper clutch 58. This position corresponds to the drilling fluid circulation mode. It can also be seen that the piston assembly rotates in only one direction due to the combination of the profiles of firstly the upper clutch 58 and the mating angles, and secondly the lower clutch 59 and the indexer 64.
Figs. 12 (a) and (b) show that as the back pressure across the restrictor nozzle 60 is reduced, the indexer 64 and the lower clutch 59 come into contact and the piston assembly 52, 65 is further rotated in the same direction as previously. The upper clutch 58 and the mating angles 61 are longitudinally and rotationally spaced once again, and await an increase in the drilling fluid flow rate to enter a drilling fluid flow through cycle.
Fig. 13 (b) shows that the lower clutch 59 and the indexer 64 are once again longitudinally and rotationally further displaced, although the longitudinal displacement is not as great as shown in Fig. 11 (b). This is due to the mating angles 61 being restrained in the first and least travel position by the upper clutch 58, as shown in Fig 13 (a). This is the drilling fluid flow through mode of operation of the circulating sub 50.
As has previously been described, the circulating sub 50 has two modes of operation, drilling fluid flow through and circulation, for when the piston assembly 52, 65 is restrained in a first and a second position respectively.
The lower portion of the circulating sub 50 in the first restrained position is shown in detail in Fig. 14. A seal 67 prevents any leakage of drilling fluid between the bypass port 66 and the circulating hole 68, whilst the circulating sub 50 is in the first position, and hence in drilling fluid flow through mode of operation.
The lower portion of the circulating sub 50 in the second restrained position is shown in detail in Fig. 15. The lower piston 65 has moved downwards so that bypass ports 66 are now aligned with the circulating holes 68, thus allowing drilling fluid to exit from the bore 70 of the circulating sub 50 out through the circulating holes 68. When the bypass ports 66 are aligned with the circulating holes 68, the bottom end of the lower piston 65 engages with the pack off sealing element 69 such that no drilling fluid can pass through an aperture 71 in a bottom plug 72 at the bottom end of the circulating sub 50 to the equipment below. Further if nitrogen gas is being circulated through the bore 70 of the circulating sub 50 and out through the circulating holes 68, the seal between the pack off sealing element 69 and the lower piston 65 ensures that no nitrogen gas can pass through any of the tools below the circulating sub 50.
Modifications and improvements can be made to the embodiments, without departing from the scope of the invention.

Claims

A circulating sub apparatus (50; 100) having a tubular outer body member (1; 51, 53, 54, 55, 56, 57) and a tubular inner body member (4; 52, 65), the outer body member (1; 51, 53, 54, 55, 56, 57) and the inner body member (4; 52, 65) each having one or more holes (8, 16; 66, 68), the holes (8, 16; 66, 68) being substantially transverse to the longitudinal axis of the outer body member (1; 51, 53, 54, 55, 56, 57) and the inner body member (4; 52, 65), and a displacement mechanism for producing relative movement between the outer body member (1; 51, 53, 54, 55, 56, 57) and the inner body member (4; 52, 65), characterised such that the inner body member (4; 52, 65) and the outer body member (1; 51, 53, 54, 55, 56, 57) may be repeatably moved between an aligned position, in which the one or more holes (8, 16; 66, 68) on the inner body member (4; 52, 65) are aligned with the one or more holes (8, 16; 66, 68) on the outer body member (1; 51, 53, 54, 55, 56, 57), and an obturated position, in which the one or more holes (8, 16; 66, 68) on the inner body member (4; 52, 65) are obturated by the outer body member (1; 51, 53, 54, 55, 56, 57).
A circulating sub apparatus (50; 100) according to claim 1, wherein when the outer body member (1; 51, 53, 54, 55, 56, 57) and the inner body member (4; 52, 65) are positioned relative to one another in the obturated position, fluid can pass from the inner bore (70; 100) of the outer body member (1; 51, 53, 54, 55, 56, 57) to the inner bore (70; 100) of the inner body member (4; 52, 65) and out of the bottom end of the inner body member (4; 52, 65).
A circulating sub apparatus (50; 100) according to claim 1 or claim 2, wherein when the outer body member (1; 51, 53, 54, 55, 56, 57) and the inner body member (4; 52, 65) are positioned relative to one another in the aligned position, a bypass passage (8, 16; 66, 68) is formed that allows fluid to flow from the internal bore (70; 100) of the circulating sub apparatus (50; 100) to the annulus between the outside diameter of the circulating sub apparatus (50; 100) and the inside diameter of the well bore, in use.
A circulating sub apparatus (50; 100) according to any of the preceding claims, wherein the displacement mechanism is controlled by fluid pressure.
A circulating sub apparatus (50; 100) according to any of the preceding claims, wherein the displacement mechanism comprises a piston assembly (4; 52, 65) and a restrictor nozzle (20; 60) in the fluid path.
A circulating sub apparatus (50; 100) according to claim 5, wherein the displacement mechanism further comprises a restraining device (58, 59, 61, 64).
A circulating sub apparatus (50; 100) according to claim 6, wherein the restraining device (58, 59, 61, 64) comprises at least one restraining member (58, 59, 61, 64) mounted on each of the inner (4; 52, 65) and outer body members (1; 51, 53, 54, 55, 56, 57), the restraining member(s) (58, 59, 61, 64) mounted on the inner body member (4; 52, 65) being selectively co-operable with the corresponding restraining member(s) (58, 59, 61, 64) mounted on the outer body member (1; 51, 53, 54, 55, 56, 57).
A circulating sub apparatus (50; 100) according to claim 7, wherein there are two restraining members (58, 59, 61, 64) mounted on each of the inner (4; 52, 65) and outer body members (1; 51, 53, 54, 55, 56, 57).
A circulating sub apparatus (50; 100) according to claim 8, wherein the two restraining members (61, 64) mounted on the inner body member (4; 52, 65) are spaced further apart than the two restraining members (58, 59) mounted on the outer body member (1; 51, 53, 54, 55, 56, 57).
A circulating sub apparatus (50; 100) according to claim 9, wherein one of the restraining members (61, 64) mounted on the inner body member (4; 52, 65) and the corresponding restraining member (58, 59) mounted on the outer body member (1; 51, 53, 54, 55, 56, 57) are adapted to rotate the inner body member (4; 52, 65) with respect to the outer body member (1; 51, 53, 54, 55, 56, 57), following continued longitudinal movement of the inner body member (4; 52, 65) with respect to the outer body member (1; 51, 53, 54, 55, 56, 57).