KR20050031807A - Drilling centralizer - Google Patents

Abstract

A drilling centralizer is provided to improve reliability of test result and accuracy by arranging a drilling rod in a center of a housing supported by a large diameter drilling hole and continuously boring a small diameter drilling hole on a center of the large diameter drilling hole. A drilling centralizer is composed of a tubular housing(10) composed of a sliding part(11) opened at both sides and axially formed in a center, inserted to a large diameter drilling hole(T) in a solid foundation and supported by a wall of the large diameter drilling hole, a slider(20) inserted to the sliding part of the housing by sliding, and a small diameter hole drilling rod(30) connected to the slider and slid with the slider in applying force from a drilling machine to continuously bore a small diameter drilling hole(S) concentrically in a center of the large diameter drilling hole.

Description

Drilling Centralizers {DRILLING CENTRALIZER}

The present invention relates to a drilling centralizer, and more particularly, to a drilling centralizer for drilling a small diameter in the center of a large diameter when drilling a large diameter in a large diameter for the measurement of the initial stress of the rock. .

In general, when constructing a facility such as a tunnel or oil storage base in a rock, the characteristics of the rock, such as strength, are measured before the design of the facility, and the design of the facility is changed according to the measured value to promote the safety of the facility.

The hydraulic fracturing test, one of the rocks' initial stress measurement methods, measures the initial stress in the rock for the detailed design of the tunnel and based on it, the stability analysis of the tunnel structure including the optimal section / support design of the tunnel and the mechanical behavior of the surrounding rock. It is aimed at obtaining all the information about the state of initial stress field which is essential for

The principle of the hydraulic fracturing test is to artificially form tensile cracks in the boreholes using high water pressure, and to obtain various information on the stress state acting on the local rock using field measurements such as pressure and flow rate obtained in this process. It is one of the methods of measuring initial stress obtained.

Information on the stress states obtained in this method includes principal stresses, in particular the magnitude and direction of the maximum (minimum) principal stress in the horizontal direction, the ratio of horizontal stress to vertical stress (K), and Changes in stress field with depth are included. In addition, it can be applied to the quantitative evaluation of the hydraulic conductivity of the rock around the measurement section.

Briefly introducing the terminology related to the basic mechanism of hydraulic fracturing testing, hydraulic fracturing is a brittle material in which rock has a significantly lower tensile strength than compressive strength (generally, tensile strength is 1/10 to 1/20 of compressive strength). When the hydraulic pressure applied to the rock in the borehole by external pressure reaches Pb (Pc) (break down pressure), which is a certain critical level, a tensile crack in the rock in the borehole tension) occurs, and a pressure drop occurs due to loss of fluid in the borehole. After the crack is generated, the crack propagates from the hollow wall to the interior by the injection of the fluid. The pressure at this time is called Pp (crack propagation pressure).

Then, when the pressurization is stopped, a pressure reduction section is formed for a predetermined time in the measurement section. Generally, the pressure decreases rapidly in the early stages and then slowly decreases in later stages. The initial rapid pressure reduction is caused by the fluid entering the fracture tip formed in the rock, and the later slow pressure reduction is caused by the fluid penetration into the rock around the borehole wall. In this process, the pressure level decreases rapidly and then gradually decreases to a transition level, which is called Ps (shut in pressure), which indicates the closing of tensile cracks in the rock. Because this pressure is equal to or slightly greater than the pressure required to maintain the crack, it exhibits a minimum horizontal principal stress acting perpendicular to the crack plane. This completes the first pressurization cycle and this pressurization cycle is repeated several times. In the course of repeated cycles, cracked cracks are reopened by pressurization, which is called Pr (cracking re-opening pressure).

For hydraulic fracturing, large diameter boreholes and small diameter boreholes are drilled continuously in the rock if necessary. When drilling vertically, it is not difficult to drill small diameter boreholes in the center of large diameter boreholes. In the case of drilling a borehole of a ball or having a deep borehole, it is difficult to drill a small borehole in the center of a borehole. In this case, the small diameter borehole cannot be drilled in the center of the large diameter borehole because the small diameter borehole greatly affects the rock test results depending on the position of the small diameter borehole, that is, whether the small diameter borehole is located at the center of the large diameter borehole. As a result of failing to design according to the characteristics of the rock, the safety of the facility is consequently lowered. Therefore, a defect occurs in the facility within a short period of time, resulting in enormous cost of repair cost, and the risk of a safety accident. This has the disadvantage of falling.

The present invention is to solve the above-described problems, the center of the large diameter borehole to the small diameter borehole irrespective of the characteristics of the rock, the borehole direction when drilling a small diameter borehole in the large diameter borehole to test the initial stress of the local rock The aim is to provide a drilling centralizer that can be drilled into the.

Drilling centralizer according to the present invention provided to achieve the above object is provided with a sliding portion (11) having both sides opened along the axial direction at the center thereof is inserted into the large diameter borehole in the rock and is supported on the large diameter borehole wall surface A tubular housing; A slider slidably inserted into the sliding part of the housing; And a small diameter drilling rod connected to the slider to drill a small diameter borehole that is slid with the slider by a force applied from the drilling machine and continuously drills a small diameter borehole coinciding with the center of the large diameter borehole in succession to the large diameter borehole. It is characterized by.

The features and advantages of the present invention will become more apparent from the following detailed description. Prior to this, the terms or words used in the present specification and claims are defined in the technical spirit of the present invention on the basis of the principle that the inventor can appropriately define the concept of the term in order to explain his invention in the best way. It must be interpreted to mean meanings and concepts.

As shown in Figures 1 to 3, the drilling centralizer 100 according to the present invention, the housing 10 supported by the large-diameter borehole T (see Fig. 3) in the rock so as to be slidable inside the housing. It is composed of a slider 20 to be inserted, and a drilling rod 30 inserted into the slider 20 to drill a small diameter borehole S (see FIG. 3) coinciding with the center of the large diameter borehole T.

As shown in FIGS. 1 and 3, the housing 10 has a longitudinal structure, and includes a hollow sliding part 11 (see FIG. 3) in which both ends of the left and right sides of the drawing are opened in the central portion along the axial direction. And it may be made of a body 12 that is supported in the large diameter borehole (T) while being made up and down symmetry based on the drawing center with respect to the center of the sliding portion (11).

When the housing body 12 is inserted into the large diameter borehole T for the drilling of the small diameter borehole S, the housing body 12 is supported on the wall surface of the large diameter borehole T such that up and down, left and right flows are not generated inside the large borehole bore T. In order to prevent flow and detachment of the slider 20, support structures are employed at both ends of the body 12, respectively. As the support structure, for example, the first support ring 14 is connected to one side of the body 12 through a plurality of support angles 13 disposed radially around the housing body 12. The blind cap 15 is detachably coupled to the other side.

The blind cap 15 is provided through a body 15a fastened to the outer peripheral surface of the end of the housing body 12 by a bolt 16 or the like and a plurality of support angles 15b radially disposed around the body 15a. The second support ring 15c may be connected to and supported on the wall surface of the large-diameter borehole T.

Both ends of the housing 10 are formed to have a smaller diameter than the other section so that the slider 20 does not fall out therein.

The slider 20 is formed in the body 21 to which the drilling rod 30 is connected, and an annular support part which is extended to a circumference of the body 21 and is supported on the inner wall surface of the sliding part 11 of the housing 10 ( 22).

The drilling rod 30 is connected to and fixed to the right side of the slider 20 by the bolt 16 or the like, and is slidably inserted into the sliding part 11 of the housing 10 via the slider 20. The small diameter borehole S of the same center as the center of the large diameter borehole T is drilled in succession to the large diameter borehole T by the operation of the borehole.

Power transmission rod 40 for transmitting power from the drilling machine to the drilling rod 30 may be screwed to the left end of the reference to the slider 20. Here, although the drilling rod 30 and the power transmission rod 40 has been described as being composed of a single piece, respectively coupled to both sides of the slider 20, but not limited to this, the drilling rod 30 and the power transmission rod 40 is a slider One drilling rod may be inserted into the slider 20 so as to have the same structure as the structure coupled to both sides of the 20.

Drilling of the small diameter borehole S while preventing the housing 10 from being pushed backward due to friction with the large diameter borehole T when the centralizer 100 for drilling according to the present invention is introduced into the large diameter borehole T. The milling prevention portion 41 is formed at the end of the power transmission rod 40 so that the drilling rod 30 operates normally. The rolling prevention part 41 may be a tape or a cable tie wound around the periphery of the power transmission rod 40.

In the assembling operation of the drilling centralizer 100 according to the present invention, the power transmission rod 40 and the drilling rod 30 are respectively fastened to both sides of the slider 20, and the blind cap 15 is attached to the housing body 12. After the separation, the slider and the rod assembly are inserted into the sliding portion 11 of the housing 10, and the blind cap 150 is fastened to the housing body 12 with screws, bolts 16 and the like.

Hereinafter, the operation of the drilling centralizer according to the present invention.

First, after drilling a large diameter borehole (T) in the rock, the drilling centralizer 100 according to the present invention is inserted into the large diameter borehole (T). At this time, the first and second support rings 14 and 15c on both sides of the housing 10 are supported on the wall surface of the large-diameter borehole T, but the housing 10 is not pushed backward by the sliding preventing portion 41.

When the drilling bit 31 of the drilling rod 30 is disposed at the end of the large diameter borehole T, the small diameter borehole S is drilled. When a force is applied to the power transmission rod 40 through the drilling machine, the drilling rod 30 along with the slider 20 slides forward, and the small diameter borehole S is drilled through the drilling bit 31. At this time, the small-diameter drilling rod 30 is firmly supported in the large-diameter borehole T through the housing 10 and is disposed at the center of the large-diameter borehole T so that the small-diameter borehole S has a center of large borehole ( Same as T).

After drilling the small diameter borehole (S) by this method, the drilling centralizer 100 according to the present invention is recovered.

The recovery of the centralizer 100 is performed when the support 22 of the slider 20 slides the inside of the housing 10 to complete the small diameter drilling to recover the small diameter drilling rod 30. It is caught by the support ring 14 and recovered.

As described above, according to the drilling centralizer according to the present invention, since the drilling rod is disposed at the center of the housing supported by the large diameter borehole, the small diameter borehole can be drilled continuously to the large diameter borehole, so that the reliability of the test results It can improve the precision and prevent additional expenses due to drilling failure.

While the invention has been described and illustrated in connection with a preferred embodiment for illustrating the principles of the invention, the invention is not limited to the configuration and operation as such is shown and described. Rather, it will be apparent to those skilled in the art that many changes and modifications to the present invention are possible without departing from the spirit and scope of the appended claims. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

1 is an exploded perspective view of a drilling centralizer according to the present invention.

Figure 2 is a perspective view of the drilling centralizer according to the present invention.

Figure 3 is a side cross-sectional view of the drilling centralizer according to the present invention.

<Description of the symbols for the main parts of the drawings>

10 housing, 11 sliding part

12: housing body, 14, 15c: support ring

20: slider, 21: slider body

22: support portion, 30: drilling rod

31: drilling bit, 40: power transmission rod

41: jungle prevention part,

Claims (5)

A tubular housing (10) having a sliding portion (11) having both sides opened in an axial direction at a central portion thereof and inserted into a large diameter borehole (T) in a rock and supported by the large diameter borehole wall; A slider 20 slidably inserted into the sliding part of the housing; And, A small diameter drilling rod 30 connected to the slider for drilling a small diameter borehole S that is coincident with the center of the large diameter borehole while being slid with the slider by a force applied from a drilling machine and is continuously aligned with the large diameter borehole. Drilling centralizer, characterized in that configured to include. According to claim 1, The housing is connected through a tubular body 12 having the sliding portion in the center, a plurality of support angles 13 disposed radially around the one end portion of the body to the large diameter borehole Drilling centralizer, characterized in that consisting of a first support ring (14) supported on the wall of the blind cap (15) detachably coupled to the other end of the body and supported on the wall surface of the large diameter borehole. 3. The blind cap according to claim 2, wherein the blind cap is provided through a body (21) fastened to the end of the housing body with screws and bolts (16) and a plurality of support angles (15b) disposed radially around the body. Drilling centralizer characterized in that it comprises a second support ring (15c) connected to and supported on the wall surface of the large diameter borehole. According to claim 1, The slider is for drilling, characterized in that consisting of the body 21 to which the drilling rod is coupled and the support portion 22 is formed in the circumference of the body and inscribed in the sliding portion of the housing Centralizer. The centralizer for drilling according to claim 1, wherein the drilling rod end portion of the drilling rod is formed with a rolling preventing portion (41) which prevents the housing from being pushed and restricts the drilling rod to be operated.