RU45156U1 - VERTICAL WELL DRILLING RIG - Google Patents

Abstract

The utility model relates to drilling techniques, in particular to deep deep freezing wells, and can be used in the production of mineral waters, brines and engineering-geological studies to prevent curvature of the wells during their drilling. Installation 13 contains a bed 1 with three support adjustable jacks 2 and a mast 3 rigidly connected to it with a movable rotator 4, a drill string from pipes 8 with a weighted bottom layout (UNBK) from pipes 10 and a rock cutting tool - a bit 9, as well as stabilization systems and vertical control. According to a utility model, the vertical stabilization system contains two paired centralizers 12 and two calibrators 11 as part of the UNBK, the latter being made with the possibility of hard centering with the axis of the well 14. The control system contains level 6 sensors functionally connected to the support jacks 2, which are mounted to support in two mutually perpendicular planes of the horizontal position of the frame 1 with a strictly vertical stroke of the movable rotator 4. A drill string composed of a storm of flax pipes 8 and pipes УБТ 10 is stretched under an axial load of not more than 80% of the weight of UNBK.

Description

The utility model relates to drilling techniques, in particular to the drilling of vertical freeze wells, to prevent their curvature during drilling and can be used in the extraction of mineral waters, brines, geotechnical studies, and in many other cases.

A device is known as part of an installation for drilling wells, comprising a rotating stand with a drive mounted on the surface (1). The device comprises a housing rigidly connected to the drill stand and a rock cutting tool, which is made in the form of several elements having a working part and a shank. Elements are installed in the housing with the possibility of swinging in the radial direction by placing the shanks of the elements of the rock cutting tool in the profile grooves of the housing. The drill rig is periodically raised and it interacts through the rock cutting tool with the bottom of the well, impacts radially along the bottom with the destruction of the rock by chipping. This embodiment of the device provides due to the radial movement of the elements, as well as the effect of the pendulum, a warning from the bending of the wells.

The disadvantage of this device is not effective prevention of curvature of the wells, which is provided due to the design of the drill string, which complicates the drilling process.

A known layout of the drill string for rotary drilling with the transmission of torque through the string of drill pipes (2). The arrangement comprises a drill pipe with a displaced center of gravity of the cross section due to the displacement of the axis of the inner cylindrical surface relative to the axis of the outer cylindrical surface of the pipe body. Moreover, rolling bearings are installed on the lateral surface of the support-centering devices, so that the contact with the borehole wall falls precisely on the rolling bearings. In the drill string, the layout is installed either above the rock cutting tool or between conventional drill pipes with a certain pitch over the entire interval of the compressed part of the string. When drilling during rotation, the arrangement is pressed against the wall of the well by rolling bearings, which reduces the friction force, power consumption for sinking and bending of the wells.

The disadvantage of this design can be attributed to the indirect effect on the process of preventing well bending solely due to the interaction of the layout with the walls of the latter.

A device is also known to reduce the intensity of natural curvature of wells (3). The device includes an inner pipe with subs at the ends and a spring-loaded outer pipe freely located between them. The ends of the sub and the ends of the outer pipe facing each other have profile surfaces with protrusions, which are formed by straight and inclined walls in the direction of rotation. If the outer pipe is stuck, the drill string is unloaded and the ends of the sub and the outer pipe are engaged. Then the drill string is rotated and the profile surfaces of the ends of the sub and the outer pipe are engaged. As a result, when the inclined surfaces slip relative to each other, a vibration mode is created to eliminate sticking. To increase the effect on the end surfaces of the pipe, additional pins with spherical heads are installed.

The disadvantage of the design of the device is, in fact, the elimination of already occurred curvature of the well, however, in this way it is impossible to prevent the occurrence of the curvature process as such.

A device for drilling deep wells is proposed, which provides a warning of their curvature (4). The device includes a housing, upper and lower sub, a centralizer and an annular load mounted on the housing. The load is made of several sections, which are provided with radial grooves at the upper end and are mounted with the possibility of rotation and movement in the axial direction. The bottom end of each section is equipped with an elastic element. A chisel is tightly connected to the lower sub. During drilling, collisions of the load sections occur due to longitudinal vibration of the tool, while due to the elastic elements, the longitudinal vibrations are partially damped, and since the load sections are mounted on the body with a gap, they move in the vertical direction, which helps to prevent bending of the well.

This embodiment of the device, however, does not exclude the phenomenon of curvature of the wells as such, but only ensures their partial elimination during drilling.

The design of the UBZSh-2 installation for drilling freezing wells with a depth of up to 400 m by the rotary and turbine methods is known (5). The drilling unit contains a platform with four supports equipped with hydraulic cylinders for leveling the platform in a horizontal plane and wheels for moving along the ring rails. On the platform, horizontal jacks with a cable grip are mounted to move the unit from one well to another, a drawworks with a rotor, a drive motor and electric starting equipment. The rotor is rotated by an electric winch motor through a gearbox and a driveshaft. The installation is completed with drill pipes with a diameter of 114 mm and weighted drill pipes (UBT) with a diameter of 178 mm.

The disadvantage of this design of the installation is not high mobility when moving it from one well to another, and also not effective stabilization of the wellbore during drilling, which is ensured by the pendulum effect of rigging the heavier bottom of the drill collar.

Closest to the proposed utility model is the technical solution of the installation for drilling freezing wells of the UBZSh type - modifications 2-20 and 2-30, which is chosen as a prototype (6). The installation contains a drilling unit mounted on a bed, which is installed on the chassis of the MAZ. A pump and power unit on a trailer chassis, for example, MAZ-5207V and on a separate trailer chassis, a block with equipment, a work platform with candlesticks, attachments. Power equipment, a winch, a mast rigidly connected to the bed, a driving rod, a rotor, a hydraulic breaker, a pipe screwing mechanism, a hoisting and fishing tool, are mounted on the drilling block. The drilling unit also includes portable support regulatory jacks, a drill string with a weighted bottom layout (UNBK) of a pendulum type with a rock cutting tool, as well as a stabilization and vertical control system. The vertical control is carried out during installation of the installation above the wellhead by vertical installation of the mast by means of plumb lines and periodic subsequent control of theodolite and adjustment of the axial load on the drill string. In this case, stabilization of the verticality of the well is ensured through the use of the pendulum effect and turning the lead rod

The disadvantage of the prototype is the ineffective stabilization of the verticality of the sinking of the wells, which is provided exclusively by the pendulum effect of rigging the weighted bottom and drilling the borehole vertically without UNBK.

The objective of the utility model is to eliminate this drawback and increase the efficiency of the drilling process, by eliminating the curvature of the wells and ensuring strictly vertical penetration.

The technical result of the utility model is to ensure a strictly vertical stroke of the movable rotator during the drilling process by maintaining the horizontal position of the rig bed in two mutually perpendicular planes, as well as monitoring the stabilization of vertical drilling by level sensors.

The problem is solved in that in the installation for drilling vertical wells, comprising a bed with support adjustable jacks and a mast rigidly connected to it, a drill string with a weighted bottom layout with a rock cutting tool, and also a stabilization and vertical control system, according to a utility model, the mast is equipped a movable rotator, and the vertical stabilization system contains two calibrators as a milling cutter and two paired centralizers as part of a weighted bottom layout, the latter in it can be rigidly centered with the axis of the well, and the control system contains level sensors functionally connected with support jacks, which are mounted with the possibility of maintaining in two mutually perpendicular planes the horizontal position of the bed with a strictly vertical stroke of the movable rotator, while the drill string is stretched under axial load no more than 80% of the weight of the layout of the weighted bottom.

The level sensors are mounted on a bed or mast, or a rotator and are functionally connected to a vertical control system that contains a theodolite mounted on the surface of the earth outside the bed of the rig.

Level sensors are made on the basis of cylindrical or round bubble hydraulic levels with a division price of 1-10 seconds.

The essence of the utility model is illustrated by drawings.

Figure 1 presents the principal block diagram of a mobile drilling rig.

Figure 2 - diagram of the drill string with the layout of the weighted bottom

(UNBK).

Installation 13 contains a frame 1, with three supporting adjustable jacks 2 (one of them is not shown in the drawing). On the bed 1 there is a mast 3 rigidly connected to it with a movable rotator 4 and hydraulic feed cylinders 5. On the mast 3, two horizontal level sensors 6 are installed in mutually perpendicular planes in the form of cylindrical hydraulic bubble levels. The sensors 6 are functionally connected to the theodolite 7, which is installed on the ground separately from the bed 1 of the installation 13 and is designed to adjust the level 6 and track the verticality of the rotation of the rotator 4. The rotator 4 is driven by a drive shaft (not shown in the drawing) with a drill string containing drill pipes 8, arrangement of UNBK with rock cutting tool-chisel 9, weighted drill pipes (UBT) 10, two calibrators 11 mounted at the ends of the first UBT, two centralizers 12 installed in the middle and at the upper end of the UBT string.

Installation works as follows.

The frame 1 of the drilling rig 13 is mounted above the wellhead 14, the mast 3 is installed in a strictly vertical position. The installation of the mast 3 and the axis of rotation of the rotator 4 are adjusted using three jacks 2. The accuracy of the installation of the mast 3 vertically, and accordingly the axis of rotation of the rotator 4, is determined by level 6, which is pre-set using theodolite 7. During the adjustment, check that the horizontal the position of the level 6 bubbles tracked the vertical stroke of the rotator 4, while the accuracy of the vertical adjustment is determined by the division price of level 6 and is 1-10 seconds or more, depending on the set value that is required yderzhat during drilling. Then, vertical drilling of the well 14 is carried out, while the drill string is already equipped with UNBK at the time of drilling, which ensures stabilization of the acquired drilling direction. In the process of drilling in the same way as when installing the mast 3, continuously monitor

level 6 and the jacks 2 adjust the vertical stroke of the rotator 4, which in the same way is constantly monitored and regulated during further drilling of the well 14. At the same time, it is checked that the permissible deviation of the axis of the rotator 4 from the vertical is no more than the permissible design values. Stabilization of the vertical direction during drilling and further drilling is carried out by means of a drill string of pipes 8 with a rigidly centered arrangement of weighted pipes 10 with two calibrators 11 and two centralizers 12, while drilling is carried out on an extended drill string under an axial load on bit 9 of not more than 80% by weight of UNBK.

The installation according to the utility model was successfully tested during drilling of vertical freezing wells in the construction of mine shafts at the Krasnoslobodsky mine of RUE PO Belaruskali (Belarus, Soligorsk). 76 wells with a depth of 220 m and a diameter of 244.5 mm were drilled. The permissible design deviation from the vertical was 0.5 m and 0.9 m or 7.8 minutes at the final depth. The achieved vertical verticality of the wells by 70% corresponded to the design requirements, and in the remaining 30% only slightly exceeded them.

This result was obtained through the use of a fundamentally new design solution to ensure stabilization of vertical drilling, namely, strictly directed vertical movement of the movable rotator 4, which is constantly monitored by level 6 sensors and is adjusted by holding the frame 1 with the mast 3 rigidly connected to it in a horizontal position. The installation allows you to bore the well vertically, to stabilize the set direction, and, as tests have shown in production conditions, almost completely eliminates the occurrence of the phenomenon of curvature of wells.

The high efficiency of vertical stabilization allowed to abandon the drilling of 10 additional wells, originally envisaged by the project in case of significant deviation from the vertical of the main

freezing wells according to the results of previous similar drilling operations during the construction of 4 mines over the past 60 years and receive savings of about 180,000 US dollars.

Sources of information:

1. RU No. 99121060 A, IPC ⁷ E 21 V 7/00; E 21 B 10/00, (22) 1999.10.06, (54) “Method for drilling wells and a device for its implementation”.

2. RU No. 93037028 A, IPC ⁶ 1993.07.21, (54) “Layout of the drill string”.

3. RU No. 2010939 C1, IPC ⁵ E 21 V 7/10; (22) 1991.03.01, (54) “Device for reducing the intensity of natural curvature of wells”.

4. RU No. 2052068 C1, IPC ⁶ E 21 V 7/10; (22) 06/07/1990, (54) "Device for drilling wells."

5. The passage of mine trunks by freezing. Ed. NEDRA, Moscow - 1968, UBZSh-2 Drilling Rig, p.21-22.

6. Drilling rigs for sinking wells and shafts. Reference: A.T.Nikolaenko, B.Ya.Sedov, N.D. Terekhov, N.S. Bolotskikh, ed. 3rd, rev. and add., M. "Nedra", 1985, S. 52, 53 (prototype).

Claims (3)

1. Installation for drilling vertical wells, comprising a bed with support adjustable jacks and a mast rigidly connected to it, a drill string with a weighted bottom layout with a rock cutting tool, as well as a stabilization and vertical control system, characterized in that the mast is equipped with a movable rotator, and the system stabilization of verticality contains two calibrators as a milling cutter and two paired centralizers as part of the layout of the heavier bottom, the latter being made with the possibility of a hard center operation with the axis of the well, and the control system contains level sensors functionally connected with support jacks, which are mounted with the possibility of maintaining in two mutually perpendicular planes the horizontal position of the bed with a strictly vertical stroke of the movable rotator, while the drill string is stretched under an axial load of not more than 80% from the weight of the layout of the weighted bottom. 2. Installation according to claim 1, characterized in that the level sensors are mounted on a bed or mast, or rotator and are functionally connected to a vertical control system that contains a theodolite mounted on the surface of the earth outside the bed of the drilling rig. 3. Installation according to claims 1 to 2, characterized in that the level sensors are made on the basis of cylindrical or round bubble hydraulic levels with a division price of 1-10 seconds.