KR800000953B1 - Method for placement of production casing under obstacle - Google Patents

Abstract

A method is for emplacing a relatively large casing(20) under a river(12). The casing(20, 21) is emplaced along the path(30) of a previously bored & placed existing pilot string(34) running beneath the obstacle. The pilot string extends in an inverted curved contour from a 1st. position(14) at ground level on one side of the obstacle to a 2nd. position(16) at ground level on the other side. The pilot hole is reamed to an enlarged diam. & the cuttings are entrained from the excavated annulus of the reaming operation in drilling mud. The casing is advanced along the reamed pilot hole in following relationship to the reaming tool.

Description

Casing laying method

1 is a perspective view of a cross-sectional view of a portion of an extension casing laid in accordance with the present invention.

2 is a view showing the first step of the embodiment suitable for the present invention, the guide hole is drilled under the obstacle.

3 is a view showing a second step of an embodiment suitable for the present invention, in which the largest casing is provided from one side of the obstacle.

4 shows a third step suitable for the present invention, in which the second largest casing is laid from the first side of the obstacle.

5 is a view showing a fourth step suitable for the present invention, in which a large engine casing is laid from the second side of the obstacle.

6 shows a fifth step of an embodiment suitable for the present invention, in which a second engine casing is placed on the second side of the obstacle.

7 is a view showing the final step of the embodiment suitable for the present invention, in which the casing is laid over the obstacle.

The present invention relates to a method and apparatus for laying a casing in contact with an underground arcuate passageway underneath an obstacle such as a river, and more particularly to an apparatus and method for overcoming a very wide obstacle.

Recently, a technique has been developed for laying a relatively large diameter straight casing under a river or other obstacle, without drilling the river bottom or affecting the obstacle itself. Instead, the guide hole is first drilled along the reverse arched underground passage from one side of the obstacle or near the ground to the other ground or near the ground. After drilling the guide hole, the guide drill string remains in the hole.

A reamer is then attached to one side of the drill string to force the hole wide by pulling it through the guide hole to enlarge the guide hole to a diameter of a preselected size. The extension casing or other large diameter casings enter the enlarged guide hole, depending on the expansion device. As a result, when the guide hole expands from one side to the other, the larger casing occupies an enlarged hole.

The above-described technique of placing the exhaust casing under an obstacle is difficult when crossing a relatively wide obstacle such as a main river. The passage of the leading casing is relatively horizontal, and also the weight of the casing, the friction to be overcome when moving, increases in proportion to the width of the obstacle. The casing can be sealed to pierce it to balance its weight, but it is very difficult to balance the weight correctly when the long straight casing is laid. As a result, the frictional force of the casing increases, and thus when crossing a wide obstacle, the casing is eventually frozen by the frictional force between the casing and the enlarged guide hole so that the obstacle cannot be completely burned out.

The present invention is to obtain an apparatus and method for laying a straight casing over the obstacle of the relegation. The casing is laid along the reverse arched underground guideway beneath the obstacle. The guideway jumps over the obstacle from one side of the obstacle or a first position close to the ground and a second position close to the other ground or ground. A large casing having an inner diameter larger than the outer diameter of the forward casing first enters the guide hole along some guide holes on one side of the obstacle. The large casing enters the guideway passage until it freezes, ie stops, in place. The leading casing then advances through the interior of the casing to the other side of the obstruction along the rest of the guideway passageway occupied by the large casing. If desired, it is also possible to run a second large casing along the part of the guideway passage in the same shape from the other side of the obstacle.

When traversing a very wide obstacle, it is desirable to move the first large casing again along the guide hole passage inside the first large casing until they are blocked. In this way, it is possible to lay the straight casing over a very wide obstacle.

The apparatus and method of the present invention provide several techniques that allow the use of a single or multiple combinations in laying out casings that overcome relatively wide obstacles.

The first technique is to lay the first large casing along the guideway passage until the laying of this casing is prevented by normal friction.

Thus, the straight casing is laid through the inside of the large casing and again along the rest of the guide holes. In the second technique, this large casing is laid on both sides of the obstacle until the advance of the two large casings becomes impossible.

The leading casing is then laid through one of the large casings and through the part of the guide that is not occupied by either large casing, and then through the remaining large casing to overcome the obstacle. The guide drill string guides the positioning of the casings so that they are registered along the guide hole passage so that the leading casing is engaged with each large casing.

The third technique places the first large casing as far along the guideway as possible on one side, and then inserts the second large casing as far along as possible along the rest of the guideway in the first large casing. do.

The leading casing is inserted along the remainder of the guide hole through the interior of the second large casing. This third technique can be used in combination with the second technique to overcome very wide obstacles.

The purpose of the above-described technique is to limit the distance that the dust casing should be in direct contact with the soil and without having to circumscribe the large casing. The distance that this casing is in contact with the soil is limited to the distance that can be crossed to the leading casing without encountering sufficient friction to prevent further laying of the casing.

Such a casing is typically composed of iron, and the friction between iron and iron between the two casings is much smaller than the friction between one casing and soil.

According to the technique of the present invention, the total casing on the leading casing is reduced by reducing the distance that the casing is placed in direct contact with the soil and increasing the distance that the casing is circumscribed by the large casing. As a result the extension casing can be laid over, riding this under a very wide obstacle.

The large casing used in the apparatus and method of the present invention to help lay out the casing is of very low value after the casing is actually laid. Removing the large casing from the hole after the lead casing is laid is not usually carried out, and therefore it is advantageous to minimize the size and length of the large casing used. When it is impossible to completely lay the straight casing by using one large casing on one side of the obstacle, it is advisable to lay the large casing on both sides of the obstacle. In this manner, the large casings do not need to overlap each other, and the amount of the large casings overlapping is minimized, thereby reducing the size or length of the large casings required for laying the casing.

BRIEF DESCRIPTION OF THE DRAWINGS The novel features of the present invention, both as configurations and methods of operation, are to be understood as being described below with reference to the accompanying drawings, by way of example and with reference to the accompanying drawings, along with other objects and advantages.

It will be apparent, however, that the drawings are for purposes of illustration and description only and are not intended to determine the limits of the invention.

1 shows a casing 10 laid in accordance with the present invention along an inverted arched underground passageway over the river 12. The casing 10 is located on one side of the river 12 or on the ground. In the first position 14, it extends to the second position 16 close to the ground or the other side of the river. U.S. Patent No. 3,878,903, "A device and method for drilling underground arches," of April 22, 1975, has already published a device and method for drilling a guide hole.

The basic principle is outlined as follows.

A drill rig with an arcuate propagation angle with respect to the horizon is placed in the pit. From there, the drill rig enters the ground at a right angle to the side wall of the pit. A drill rig is forced down the ground by a drill rig that provides power to a motor driven drill.

The drill at the end of the string is slightly angled to the drill string. Since the drill is pushed into the ground and the drill is at an angle to the string, an inverted arched passage is drilled by the drill. Thus, at the entrance, angle into the ground and enter, at the exit angle to and above the ground, an inverted archway is created between the two points. Reducing the speed of the drill and increasing the driving force on the drillstring, ie, turning the drill up, reduces the radius of curvature of the drill passage. Conversely, if the speed of rotation of the drill is increased and the propulsion force applied to the drill string is reduced, that is, the bend of the drill string is aligned horizontally or downward, the radius of curvature of the reverse arched passage increases.

In the present invention, the transverse side of the river has been described as an example, but can also be used for other obstacles such as a highway.

The central portion 10 of the dust casing 10 is in direct contact with the soil 18.

However, the extension casings 10 are circumscribed on both sides of the central portion by overlapping with the large casings 20 to 23. The inner and outer diameters of the large casings are chosen such that the casings are in an overlapping relationship as shown. The large casings 20 and 23 make it possible to lay out the casing by overcoming a relatively wide obstacle as described below (for the purpose of the description, the casing 10 of the casing 10 and the large casings 20 and 23). Note that the width is greatly exaggerated in the drawing).

The first step of laying the lead casing 10 according to the present invention is to drill a guide hole 30 over it below the steel 12, as shown in FIG. The guide hole 30 is drilled at one first position 14 of the steel 12 at the second position 16 on the other side of the steel. In passing under the river 12, the technique of drilling the guiding hole 30 along an inverted arched underground passage from position 14 to position 16 is described in US Pat. No. 3,878,903 dated April 22, 1975. , “Apparatus and method for drilling underground archways”.

In order to drill the guide hole 30, a drill bit operated by the following drill string is used. Once the guide hole 30 is complete, the drill string remains in the hole, providing guidance for the straight casing laying.

A second step of an embodiment suitable for the present invention is shown with reference to FIG. In this second step, the large casing 20 is marked by an arrow 40 along the passage of the guide hole 30 circumscribed to the drill string 34, and pushed into the ground as either a rotation or non-rotation. . The casing 20 is suitable for entering non-rotation in order to minimize this stress in the case of curved casings, especially large diameters, so that pre-curved casings which cannot be rotated can also be used. In a preferred embodiment of the present invention, the large casing 20 is pushed along the guide hole 30 at one position 14 of the steel 12. However, if desired, it is clear that the laying of large casings can also be started without departing from the description of the present invention from the other position 16 of the steel 12.

It is suitable for the 1st large casing 20 to advance in a hole with respect to the reamer 42. The reamer 42 is provided on the rotational cleaning pipe 44, and it is good to operate by this. Various techniques for advancing the large casing 20 along this in the guide hole 30 are described in US Pat. No. 3,894,402, entitled "A device and method for installing a conduit along an underground arched passage" on July 15, 1975. The same date is shown in my pending patent “Guidestring Track Reamer for Large Straight Casing”. However, a technique other than laying a large diameter casing along the guide hole passage can be used in the same manner.

When laying a large diameter casing, such as a large casing 20 under the obstacle, the friction between the casing and the enlarged guide hole wall increases as the length of the casing increases. When traversing a relatively narrow obstacle, the friction on the casing does not increase to the point where the casing does not go any further, so that it is possible to lay a straight casing that completely overcomes the obstacle in one step. However, across a relatively wide obstacle, the friction on the casing increases to the point where the casing freezes, i.e. the friction is impeded, so that it is no longer possible to put the casing there.

The present invention deals with this situation, and the advancement of the casing ends when the straight casing 20 is moved along the guide hole 30 to the point where it is further prevented from advancing this further.

After the first large casing 20 has gone as far as possible, the second large casing 21 passes through the inside of the large casing 20 and is guided again, as indicated by the arrow 50 in FIG. Follow along with the rest of the ball 30. Both of the large casings 20 and 21 are typically made of iron. As the large casing 21 passes through the interior of the large casing 20, the friction between iron and iron is considerably smaller than what happens when the casing proceeds in direct contact with the flow, so that the casing 21 follows the casing 20. Will slide smoothly.

When 21 reaches the end of 20, it proceeds along the passage of guide hole 30 using the technique described above.

Representatively, the casing 21 advances in relation to the reamer 52 which is constructed on the washing water pipe 54 and operated again by this. The large casing 21 proceeds in this way until no further casing of friction between the casing and the soil is allowed to proceed, at which point the progression of (21) ends.

After the advance of the large casings 20 and 21 at the Han Chinese position 14 of the river 12 is finished, the other large casing 22 is moved from the position 16 of the other leg of the river to the guide hole 30. Proceed with it accordingly (see Figure 5). 22 proceeds along this into the guide hole 30 indicated by the arrow 60 using the technique described above. Again, this technique is possible using the reamer 62 which is constructed on the washing water pipe 64 and operated by it.

The large casing 22 passes through the interior of the drill string 34 until further advance thereof is blocked, advancing along the drill string, and at this point further advancement of the casing ends.

The large casing 23 is later placed along the passage of the guide hole 30 passing through the inside of the large casing 22 and circumscribed to the drill string 34, as shown in FIG. 6. The large casing 23 again travels along the guide hole 30 as indicated by the arrow 66 until this again prevents friction.

After the large casings 20 and 23 are laid, the central portion of the guide hole 30 is torn down in the larger casing and left. However, when the remaining guide hole portion is short enough to be freed there, i.e. not prevented by friction, and it is possible to cover this distance with one casing, the laying of a larger casing is stopped. Instead, the leading casing 10 itself guides through the inside of the large casing 22, 23 from the position 16 (or from the position 14 and through the central portion of the guide hole using the technique described above). Advance along this in the cavity and then pass through the interior of the casings 21, 20 completely over the steel 12.

Controlled by the passages and drillstrings 34 of each casing, each casing follows the desired arcuate underground passage. The drillstring 34 guides the forward casing 10 when laid and is combined with the large casing 21 close to the central portion of the obstacle. Each casing 10 and 20-23 is admitted to advance along the guide hole circumscribed to 34. As shown in FIG. However, it is also possible to attach one or more casings, such as the leading casing 10, to the drillstring 34 so that when the 34 moves through the hole, the attached casing proceeds therein.

The apparatus and method of the present invention include several techniques that make it possible to lay over the casing over a wide obstacle. These techniques can be summarized in the following sections. That is, (a) laying the casing along the part of the passageway to be struck (b) laying the large casing on each side of the obstacle (c) placing two or more large casings before laying the casing. It is a duplicate. Such techniques may be used separately or in combination with each other to achieve the objects of the present invention.

One of the objects of the present invention is to enable laying of the casing using the smallest amount of casing. Such large casings, once used, cannot normally be recovered from the holes and are therefore discarded substantially. For this reason, the redundant use of large casings, which usually occurs when the same number of large casings are laid on each side of the obstacle, is minimized. For example, if an embodiment suitable for the present invention is modified so that it overlaps from one side of an obstacle so that the whole of the four large casings is laid, both the length of the casing used and the original casing must increase. By using the same number of large casings on each side of the obstacle, the overlap of the large casing itself is minimized and the efficiency of the laying process is improved.

Although embodiments suitable for the apparatus and method of the present invention have been described in detail, those skilled in the art will be able to make modifications and applications to this embodiment. In particular, the order of the steps may be modified, and the above-described techniques may be used in different combinations. With this in mind, when predicates such as "first", "second", etc. are used within the scope of the claims, it is worth noting that such predicates do not necessarily indicate the temporal order in which such items are to be used. have. It is to be understood that such modifications and applications are within the spirit and scope of the invention.

Claims (1)

A drill string over and above the obstacles mentioned above, from a first position close to the ground or one side of an obstacle, such as a river, to a second position close to the other side or the ground of the obstacle In the method of laying the casing open over the obstacle that was posted along the underground arch-shaped guide common path occupied by The inner diameter of the large casing described above is greater than the outer diameter of the electrically extended casing, including the step of advancing along the guideway passage of the large casing until it stops, passing through the inside of the large casing on one side of the obstruction, Along the range of the guideway passage occupied by the casing, the forward casing is advanced to the other side of the obstacle along the rest of the guideway passage, so that the forward casing The casing laying method laying it over the other below.

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