KR102492264B1 - Elastic wave well logging type borehole installation method using inelastic soft tube - Google Patents

Abstract

The present invention relates to a seismic wave logging borehole construction method using a soft tube of an inelastic material, which can prevent damage to a seismic wave logging device due to the collapse of a borehole wall. The seismic wave logging borehole construction method comprises the steps of: inserting a soft tube in a flat state; injecting water into the soft tube through an injection hose; drawing the injection hose out of the soft tube; and performing seismic wave logging.

Description

Elastic wave well logging type borehole installation method using inelastic soft tube}

The present invention relates to a method for constructing a borehole for elastic wave logging, and more particularly, by injecting water into a soft tube made of an inelastic material inserted into the borehole to the surface of the earth to bring the outer surface of the soft tube into close contact with the borehole wall, thereby collapsing the borehole wall. It relates to a borehole construction method for seismic logging using a soft tube made of inelastic material that reliably prevents the

Suspension PS logging is a representative method of borehole testing to calculate the dynamic stiffness ratio, dynamic stiffness modulus, and dynamic elastic modulus, which are the ground properties essential for seismic design of offshore or land structures.

As shown in FIG. 1, the above floating PS logging method uses a probe 100 with a length of about 6m including a lower oscillator 101 and two upper receivers 102 for a single borehole. When an elastic wave is oscillated through the lower oscillator 101 in the state of being located at the depth of exploration within, the oscillated elastic wave passes through the ground and reaches the upper two receivers 102. At this time, the upper two receivers 102 Using the time difference of the elastic wave arriving at , the velocity of the elastic wave in the upper ground of the test subject is measured.

In addition, ground property values such as dynamic stiffness ratio, dynamic stiffness, and dynamic elastic modulus of the ground to be investigated are calculated using the measured elastic wave velocity of the upper ground of the test subject.

On the other hand, in the floating PS logging method, the probe (100) is continuously tested by raising the probe (100) at intervals of 1 m from the bottom of the borehole (H'). 101) and the receiver 102 can be tested only below the groundwater level, which is the section submerged in water.

Therefore, there is a problem in that the absence of measurement data occurs because the elastic wave is not transmitted in the section between the groundwater level of the borehole H' and the ground surface.

The present invention has been made to solve the above problems, and an object of the present invention is to inject water up to the surface of a soft tube made of inelastic material inserted into a borehole to bring the outer surface of the soft tube into close contact with the borehole wall. It is to provide a borehole construction method for seismic logging using a soft tube made of an inelastic material that reliably prevents collapse of the hole wall and expands the seismic logging area to the ground surface.

According to the present invention for achieving the above object, a soft tube made of inelastic material with an upper end open and a lower end shielded by a weight means is introduced in a flat state into a borehole drilled in the ground to be investigated, but clear water is poured into the lower end. Injecting the injection hose in a state where the lower end of the injection hose is disposed, injecting water into the soft tube through the injection hose at a level equal to or higher than the ground surface, and withdrawing the injection hose from the soft tube and inserting a probe for elastic wave logging into the soft tube to perform elastic wave logging, wherein the weight means

It is shaped like a tubular body with upper and lower parts open, and a locking jaw for supporting a lifting means protrudes from one side of the inner surface of the upper end, and an upper binding part in which the outer circumferential surface of the upper end is coupled to the inner circumferential surface of the lower end of the soft tube, and the outer circumferential surface of the upper end slides on the inner circumferential surface of the lower end of the upper binding part. Possibly coupled, connected to the lower end of the injection hose on one side of the upper part, a ring through which an auxiliary strap passes for arranging the lower end of the injection hose inside the lower end of the soft tube is formed, and on one side of the outer surface of the lower end of the soft tube. A lower weight body having an outlet communicating with the inside and a sealing member interposed between the inner circumferential surface of the lower end of the upper coupling part and the outer circumferential surface of the upper end of the lower weight body located below the outlet, in the process of introducing the soft tube When an upward force is applied to the lower weight body using the auxiliary strap and the upper binding part is raised by the lifting means, the sealing member moves upward of the outlet together with the upper binding part, so that the discharge port Provided is a borehole construction method for elastic wave logging using a soft tube made of an inelastic material, characterized in that it communicates with the inside of the borehole.

Here, after the elastic wave logging step, the lifting means is inserted to raise the upper coupling part, thereby discharging the clear water contained in the soft tube into the borehole through the discharge port, and flattening the soft tube It is characterized in that it further comprises the step of drawing back from the regular borehole.

According to the present invention as described above, by injecting water into the soft tube made of inelastic material injected into the borehole up to the surface of the borehole to bring the outer surface of the soft tube into close contact with the borehole wall, it is possible to reliably prevent the borehole from collapsing. It is possible to prevent damage to equipment for seismic logging due to collapse of the ball wall.

In addition, since the present invention injects water up to the ground surface inside the soft tube made of inelastic material, the elastic wave logging area can be expanded to the ground surface, so abundant logging data can be secured over the entire area of the ground to be investigated corresponding to the borehole.

1 is a schematic diagram for explaining a conventional seismic wave logging method;
Figure 2 shows the process flow of a borehole construction method for elastic wave logging using a soft tube made of inelastic material according to an embodiment of the present invention.
3A to 3K are views for explaining each step of a borehole construction method for elastic wave logging using a soft tube made of inelastic material according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings. It should be noted that like elements in the drawings are indicated by like reference numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the invention will be omitted.

2 shows a process flow of a borehole construction method for elastic wave logging using a soft tube of inelastic material according to an embodiment of the present invention, and FIGS. 3A to 3K are soft tubes of inelastic material according to an embodiment of the present invention. It is a drawing for explaining each process of the borehole construction method for seismic wave logging using a tube.

Referring to FIG. 2, a method for constructing a borehole for elastic wave logging using a soft tube made of an inelastic material according to an embodiment of the present invention includes a borehole drilling step (S1), a soft tube inputting step (S2), a water injection step (S3), It includes the injection hose drawing step (S4), the elastic wave logging step (S5) and the soft tube drawing step (S6).

In the borehole drilling step, as shown in FIG. 3A, a part of the borehole H is first drilled in the upper region of the ground to be investigated, which is composed of the soil layer SL.

And, in order to prevent the inner wall of the borehole H made of the soil layer SL from collapsing, as shown in FIG. 3B, the same outer diameter as the inner diameter of the borehole H made of the soil layer SL The hard casing (HC) is inserted so that the outer circumferential surface of the hard casing (HC) adheres to the hole wall of the borehole (H) made of the soil layer (SL).

Next, as shown in FIG. 3C, when the lower region of the ground to be investigated composed of rock mass RL is drilled to a preset depth, the drilling of the remaining part of the borehole H is completed. (S1)

In the soft tube insertion step, as shown in FIG. 3D, the soft tube 10 made of an inelastic material, the upper end of which is open and the lower end of which is shielded by the weight means 20, is inserted into the borehole H in a flat state.

At this time, the lower end of the injection hose 30 for injecting water into the lower end of the soft tube 10 is placed inside the borehole (H).

As described above, the operation of disposing the lower end of the injection hose 30 inside the lower end of the soft tube 10, as shown in enlarged view A, one end is connected to the lower end of the injection hose 30, and the other end is a weight means It is made by an operation of pulling the other end of the auxiliary strap (T) disposed outside the soft tube (10) in the upper direction of the soft tube (10) through the towing ring (22a) of (20).

In addition, as an upward force is applied to the traction hook 22a by an operation of pulling the other end of the auxiliary strap T upwards of the soft tube 10, the weight means 20 in the process of inserting the soft tube 10 An upward force is applied to the lower weight body 22 of ) to maintain a state in which the sealing member 23 is positioned below the discharge port 22b of the lower weight body 22.

As described above, the reason why the injection hose 30 is introduced together with the soft tube 10 is that when the soft tube 10 is first introduced into the borehole H in a flat state, the injection hose into the soft tube 10 ( 30) is difficult to inject.

On the other hand, as shown in the enlarged view A, the weight means 20 of the present invention includes an upper binding portion 21, a lower weight body 22, and a sealing member 23.

The upper coupling part 21 has a tubular shape with upper and lower parts open, and a locking jaw 21a for supporting a lifting means protrudes from one side of the inner surface of the upper part, and the outer circumferential surface of the upper part is inserted into the inner circumferential surface of the lower part of the soft tube 10, and the fixing band It is coupled to the lower end of the soft tube 10 through (B).

In the lower weight body 22, the outer circumferential surface of the upper end is slidably coupled to the inner circumferential surface of the lower end of the upper coupling part 21, and the lower end of the injection hose 30 is connected to the lower end of the injection hose 30 at one side of the upper portion, so that the lower end of the injection hose 30 is connected to the soft tube ( 10) is formed with a ring 22a through which an auxiliary strap (T) for disposing inside the lower end is formed, and an outlet 22b communicating with the inside of the soft tube 10 is formed on one side of the outer surface of the lower end.

The sealing member 23 is interposed between the inner circumferential surface of the lower end of the upper coupling part 21 and the outer circumferential surface of the upper end of the lower weight body 22 located below the discharge port 22b, and is discharged from the soft tube 10 through the discharge port 22b. It serves to shield the lower end of the soft tube 10 by preventing the water being discharged to the outside of the weight means 20.

In the weight means 20 as described above, the upper coupling part 21 and the lower weight body 22 are separated by a separate separation prevention screw (N) in a state in which the sealing member 23 is disposed below the discharge port 22b at the initial stage of input. , and in the process of inserting the soft tube 10, an upward force is applied to the lower weight body 22 of the weight means 20 by the auxiliary strap T, so that the lower end of the soft tube 10 is shielded. (S2)

In the water injection step, as shown in FIG. 3E, water is injected into the lower end of the soft tube 10 through the injection hose 30. Then, as shown in enlarged view B, the soft tube 10 is pressed outward by the water pressure of the injected water, so that the outer surface is sequentially expanded from the bottom to the top, and the hole wall of the borehole H and the hard casing ( H) adheres to the inner wall.

Accordingly, the turbid drilling water present inside the borehole H moves upward and is discharged to the upper surface of the ground, and as shown in FIG. 3F, the water filled inside the soft tube 10 has a water level slightly higher than the ground surface. will be located

Next, in order to perform seismic logging, the hard casing HC installed on the inner wall of the borehole H made of the soil layer SL is removed, and water is placed inside the soft tube 10 by the volume of the removed hard casing HC. When is additionally injected, as shown in FIG. 3G, the outer surface of the soft tube 10 is in close contact with the hole wall of the borehole H made of the soil layer SL, and water at a higher level than the ground surface is inside the soft tube 10. is filled. (S3)

In the injection hose withdrawal step, as shown in FIG. 3H, the injection hose 30 inserted into the soft tube 10 is withdrawn to the outside. (S4)

In the elastic wave logging step, as shown in FIG. 3I, the elastic wave logging is performed by positioning the probe 40 for elastic wave logging inside the soft tube 10 at a desired depth of exploration.

At this time, the probe 40 may include one oscillator 41 at the bottom and two receivers 42 at the top.

In particular, since the present invention can inject water at a higher level than the ground surface into the soft tube 10 installed inside the borehole H, as shown in FIG. Seismic wave logging is possible over the entire area of the borehole (H).

Accordingly, the present invention can secure abundant logging data over the entire area of the ground to be investigated corresponding to the borehole H. (S5)

In the soft tube drawing step, as shown in the enlarged view C of FIG. 3J, the body 51 having weight inside the borehole in which the soft tube 10 is installed and the support wings rotatably coupled to both sides of the body 51 facing each other The lifting means 50 consisting of (52) is put in.

Then, as the support wing 52 of the lifting means 50 is rotated upward, it flows into the upper part of the upper binding part 21 of the weight means 20, and the lifting means 50 flowing into the upper binding part 21 As shown in the enlarged view D of FIG. 3K, the support wings 52 of the unfold again to both sides.

At this time, when the lifting means 50 is lifted upward, the support wings 52 of the lifting means 50 are supported by the locking jaws 21a of the upper coupling part 21, and the upper coupling portion 21 is moved upward. will lift

Then, as the sealing member 21 of the weight means 20 is moved to the top of the outlet 22a, the outlet 22a communicates with the borehole H, and the water inside the soft tube 10 passes through the outlet 22a. As shown in FIG. 3K, while being discharged through the borehole H, the soft tube 10 lifted upward together with the weight means 20 drains water from the top to the bottom and returns to the bonded form, returning to the borehole H ) from which it can be drawn more easily. (S6)

As described above, in the borehole construction method for elastic wave logging using an inelastic soft tube according to an embodiment of the present invention, the outer surface of the soft tube is formed by injecting water into the inelastic soft tube inserted into the borehole to the surface of the borehole. By adhering to the hole wall of the borehole, it is possible to reliably prevent the hole wall from collapsing, so that the equipment for elastic wave logging can be prevented from being damaged due to the hole wall collapse of the borehole.

In addition, since the present invention injects water up to the ground surface inside the soft tube made of inelastic material, the elastic wave logging area can be expanded to the ground surface, so abundant logging data can be secured over the entire area of the ground to be investigated corresponding to the borehole.

In addition, the present invention, after the elastic wave logging operation is completed, opens the outlet formed on one side of the weight means to easily discharge the water inside the soft tube to the outside, so that the soft tube can be returned to a flat state and more easily drawn out from the borehole do.

Although the present invention has been described with respect to the above preferred embodiments, it is possible to make various modifications and variations without departing from the spirit and scope of the invention. Accordingly, the appended claims will cover such modifications and variations as fall within the subject matter of this invention.

10: soft tube 20: weight means
21: upper coupling part 21a: locking jaw
22: lower weight body 22a: ring
22b: outlet 23: sealing member
30: injection hose 40: tampon
41: oscillator 42: receiver
50: lifting means
51: body 52: support wing
H: borehole HC: hard casing
B: Fixing band N: Anti-separation screw
SL: Soil layer RL: Rock layer

Claims (2)

A soft tube made of inelastic material with the upper end open and the lower end shielded by a weight means is inserted into the borehole drilled in the ground to be investigated in a flat state, and the lower end of the injection hose for injecting clear water into the lower part is placed. Injecting into;
injecting water into the soft tube through the injection hose at a level equal to or higher than the ground level;
withdrawing the injection hose from the soft tube;
Including the step of performing elastic wave logging by inserting a probe for elastic wave logging into the inside of the soft tube,
The weight means
an upper coupling part having a tubular shape with upper and lower portions open, wherein a locking jaw for supporting a lifting means protrudes from one side of an inner surface of the upper end, and an outer circumferential surface of the upper end is coupled to an inner circumferential surface of the lower end of the soft tube;
The outer circumferential surface of the upper end is slidably coupled to the inner circumferential surface of the lower end of the upper coupling part, and a ring through which an auxiliary string passes for arranging the lower end of the injection hose inside the lower end of the soft tube connected to the lower end of the injection hose on one side of the upper portion a lower weight body having an outlet communicating with the inside of the soft tube formed on one side of the outer surface of the lower end;
Including a sealing member interposed between the inner circumferential surface of the lower end of the upper coupling part and the outer circumferential surface of the upper end of the lower weight body located below the outlet,
In the process of introducing the soft tube, an upward force is applied to the lower weight body using the auxiliary strap,
When the upper coupling portion is raised by the lifting means, the sealing member moves upward of the outlet together with the upper coupling portion, so that the outlet communicates with the inside of the borehole. Borehole construction method for seismic logging using
According to claim 1,
After the elastic wave logging step, the lifting means is inserted to raise the upper binding part, thereby discharging the clear water accommodated inside the soft tube into the borehole through the discharge port, and returning the soft tube to a flat shape at all times A borehole construction method for elastic wave logging using a soft tube made of an inelastic material, further comprising the step of drawing from the borehole.

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