KR102133740B1 - Earth penetrating projectile having enhanced penetration movement stability - Google Patents

Abstract

Disclosed is an underground infiltrator with improved stability of an infiltration motion during an infiltration process. The underground infiltrator includes a body unit, and a flare disposed on the circumferential surface of the body unit. According to the present invention, imbalance of a rotary force of the infiltrator can be solved so that stability of infiltration movement is improved during an inclined collision with a soil medium, which is an incompressible medium.

Description

Underground penetrating projectile having enhanced penetration movement stability

The present invention relates to an underground penetration body, and more particularly, to an underground penetration body having improved stability of penetration movement by applying a detachable flare.

Underground infiltrators are intended to neutralize the solid targets of concrete structures built underground, and the upper part of most underground solid targets is protected and concealed with a medium such as soil. The behavior of the penetrant in the soil greatly affects the penetrating performance of the solid target and the viability of the penetrant after penetrating, so the behavior of the penetrant in the soil determines the overall performance.

The phenomenon in which a penetrating body that acts in the soil does not maintain a straight motion before it collides with a solid target and draws a curved J in the shape of the English letter is called a J-hook phenomenon. This phenomenon occurs because the straightness of the penetrating movement in the soil of the penetrating body is not sufficient.

When a J-hook occurs in the soil, it not only adversely affects the posture and speed of the infiltrator colliding with the solid target in the soil, but also causes angular motion. To reduce the penetrating performance for the overall robustness target.

Therefore, the underground intrusion body must be designed in such a way that the J-hook phenomenon in the soil is minimized until a solid target collision, so that it can move straight. The main shape design variables affecting the linear behavior are the nose shape at the front and the flare shape at the rear, and only the nose shape design at the front is limited in the linear behavior of the infiltrator. Flare shape design is important.

It is known that a flare is important for the straight motion of a penetrating body if the length of the penetrating device (L/D, Length-to-Diameter) is 6 or less. In addition, when the penetrating object hits the soil target obliquely, the J-hook phenomenon is intensified, so that the importance of flare as well as the shape of the nose becomes greater.

Flare is a kind of drag stabilizer, which serves to offset the angular motion of the infiltrator in the soil, and there is an optimal flare shape. However, when the penetrant penetrates only concrete without soil medium, there is almost no J-hook phenomenon. In the case of a flare-integrated penetrant, there is a problem in that the flare acts as a resistance during the penetrating process and degrades the penetrating performance.

1. Korean Registered Patent No. 10-1257877 (Registration Date: 2013.04.12)

The present invention has been proposed to solve the problems according to the above background art, and has an object to provide an underground infiltrator with improved penetration stability during the infiltration process.

In addition, the present invention has another object to provide an underground permeate with improved straightness during the infiltration process.

In addition, another object of the present invention is to provide an underground infiltrator capable of attaching/detaching flares depending on whether or not a solid target includes a soil medium.

In order to achieve the above-described problems, the present invention provides an underground infiltrator with improved stability of infiltration during the infiltration process.

The underground permeate,

Body part; And

It characterized in that it comprises a; flare disposed on the circumferential surface of the body portion.

In addition, the flare is characterized in that fixedly attached to the rear circumferential surface of the body portion in a detachable manner.

In addition, a first hollow portion is formed inside the body portion.

In addition, the flare is characterized in that the 360 ° annular shape having a second hollow in the center.

In addition, the surface of the flare is characterized in that the taper shape.

In addition, the inclination angle of the tapered shape is characterized in that 35 ° to 45 °.

In addition, the detachable method is characterized in that any one of a screw fastening method and a screw bolt fastening method.

In addition, the flare is characterized in that the 360 ° annular shape having a second hollow in the center.

At this time, the surface of the annular shape is characterized in that the uneven structure is formed or the uneven structure is not formed.

In addition, the total length of the underground penetration body is characterized in that 4.5D ~ 5.5D. Here, D is the diameter of the body portion.

In addition, the diameter of the flare is characterized in that 1.20D ~ 1.30D.

In addition, a first screw thread is formed on the rear circumferential surface of the body portion for the screw fastening method, and a second screw thread is formed on the inner circumferential surface of the flare.

In addition, a fastening groove is formed on the rear circumferential surface of the body for the screw bolt fastening method, and an insertion hole is formed on the surface of the flare.

In addition, the diameter (D) of the body portion is characterized in that 15cm ~ 50m.

According to the present invention, it is possible to solve the imbalance of the rotational force of the penetrating body so that the stability of the penetrating motion is improved upon the inclined collision with the soil medium which is an incompressible medium.

In addition, as another effect of the present invention, by improving the straight-line behavior of the infiltrator in the soil medium, it minimizes the J-hook phenomenon occurring in the existing ozive or conical (or conical) intrusion body and to the underground solid target. It is mentioned that it is possible to increase the penetrating performance and the viability after penetrating.

In addition, another effect of the present invention is that it can be used even in the case of a solid target that does not have a J-hook behavior because there is no soil medium due to detachment/adhesion.

1 is a conceptual diagram showing the behavior in a soil medium of an underground infiltrator to which a flare is applied according to an embodiment of the present invention.
2 is a view comparing the penetration behavior according to the presence or absence of flare attachment of an underground infiltrator to an inclined target.
Figure 3 is a view showing the main dimensional ratio of the detachable basement of the infiltration permeable flare according to an embodiment of the present invention.
4 is an exploded perspective view of an underground permeant according to an embodiment of the present invention.
5 is a perspective view of a flare according to another embodiment of the present invention.

The above-described objects, features, and advantages will be described in detail below with reference to the accompanying drawings, and accordingly, a person skilled in the art to which the present invention pertains can easily implement the technical spirit of the present invention. In the description of the present invention, when it is determined that detailed descriptions of known technologies related to the present invention may unnecessarily obscure the subject matter of the present invention, detailed descriptions will be omitted. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals in the drawings are used to indicate the same or similar components.

Underground infiltrators have almost no vertical impact when they collide with targets in operation, and they collide inclined, resulting in unbalanced forces and asymmetric cavities acting on the infiltrators. In general, when an object behaves at high speed in an incompressible medium such as water, a cavity is generated in the nose of the object. However, when a local cavity occurs around the object, the motion characteristics of the vehicle are adversely affected by the cavity, resulting in a decrease in the speed of the object and instability in the flight position, which ultimately causes a J-hook phenomenon. .

On the other hand, if the force generated from the nose is balanced and the cavity is supercavitated so as to surround the entire area of the vehicle, the speed of the object and the instability of the flight posture are reduced. Therefore, as a result, the J-hook phenomenon is minimized, which has a good effect on the attitude and speed of the vehicle, thereby improving the straightness and/or stability.

In general, it is known that in the case of a medium such as water, a penetrating body (or a projectile) behaves at a speed of about 80 MPa or more, and in the case of sand at a speed of 125 to 150 kW or more, supercavity occurs. When angular motion occurs due to the imbalance of force of the penetrating body traveling in the soil medium, even if supercavity is formed over the entire area of the penetrating body, the tail of the penetrating body comes into contact with the surrounding medium and receives resistance. Depending on the tail shape of the and the penetrant, the penetrating performance is affected.

Therefore, an embodiment of the present invention proposes an underground infiltration body to which a detachable flare structure is applied to minimize the effect on such infiltration performance. Figure 1 shows this.

1 is a conceptual diagram showing the behavior in the soil medium of the underground permeator 100 to which a flare is applied according to an embodiment of the present invention. 1, the underground infiltrator 100 with time when the infiltrator 100 to which the flare is applied penetrates the inclined inclined soil target 11 which is the soil medium of the soil target 10 It is a diagram explaining the behavior of the.

At a time t1 when the underground permeator 100 penetrates the inclined soil medium, the force F _Rt1 acting on the right side of the underground permeator 100 relative to the central axis is greater than the force F _Lt1 acting on the left, based on the center of gravity. At the center point 101, a rotational force such as M _t1 is generated and proceeds to the left.

In other words, at the moment t1 when the underground permeator 100 penetrates the inclined soil medium, the force imbalance (F _Rt1 > F _Lt1 ) acting on the nose formed at the front of the underground permeator 100 at t1. Due to this, the rotational force of M _t1 is generated around the center of gravity. Therefore, the underground infiltrator 100 behaves to the left in the traveling direction.

At time t2, when the time passes, the underground permeator 100 draws a J-hook and penetrates into the soil medium to the tail of the underground permeator 100, and the front nose of the underground permeator 100 (Nose) ) The forces acting on the part are almost the same on both sides. On the other hand, the force acting on the flare installed at the rear is larger than the force acting on the left side F _Ftt acting on the right side of the underground permeator 100 based on the central axis due to the rotational force of M _t1 F _{Lt2 Rotational} force such as M _t2 is generated based on the center and proceeds to the right. That is, the direction of penetration of the permeate body 120 is on the right.

Incidentally, at the moment t2 when the underground infiltrator 100 proceeds inside the soil medium, force imbalance (F _Rt2 >F) at the flare at the rear of the underground infiltrator 100 having a rotational force of M _t1 at t2 _Lt2 ) acts and the rotational force of M _t2 is generated around the center of gravity. Therefore, the underground infiltrator 100 behaves to the right in the traveling direction, and there is an optimal flare shape in which the underground infiltrator 100 can behave in a straight line.

2 is a view comparing the penetration behavior according to the presence or absence of flare attachment of the underground infiltration body 100 to the inclined target. That is, FIG. 2 is a simplified diagram reflecting the test results as schematically illustrating the penetration performance of the underground penetrating body 100 when the flare is attached to the soil target 10 and when the flare is not attached. In particular, it shows excellent linear performance of the underground through-body 100 with a flare according to an embodiment of the present invention (210). The underground penetrating body 100 goes straight to the soil target 20 and collides with the solid target 21 such as concrete.

Continuing with reference to FIG. 2, in the case of the underground through-body 20 without a flare attached, the progressing behavior when colliding with the soil target 10 draws a J-curve (ie, J-hook) without straightness. It becomes (220). Incidentally, when the underground through-body 20 to which the flare is not attached collides with the soil target 10, the tip of the underground through-body 20 penetrates the soil target 20 in the process of penetrating the soil target 20. The force acting on the right (F _R ) is greater than the force acting on the left (F _L ) about the axis. Therefore, the underground penetrating body 20 generates a rotational force M based on the center of gravity and draws a J-curve to proceed to the left.

Figure 3 is a view showing the main dimensional ratio of the removable infiltration permeable basement permeable 100 according to an embodiment of the present invention. Referring to FIG. 3, the dimension ratio range of the flare 320 that affects the straight-line behavior characteristics in the soil medium of the underground permeator 100 to which the detachable flare 320 is applied is defined. If you can easily understand this, the following table.

variable Justice Dimension ratio L Total length of underground infiltrator 4.5D to 5.5D D Body diameter 1D D _F Flare diameter 1.20D ~ 1.30D θ Tilting angle of taping shape 35° to 45°

The values specified as dimensional ratios are accumulated results of various tests. Here, D may be about 15cm ~ 50cm.

The total length (L) of the underground penetration body 100 is a distance from the left tip of the body portion 310 to the right end of the body portion 310. The left edge portion of the body portion 310 may be 360° symmetrically about the central axis, and may be a cone hat, an ogive shape, or the like.

4 is an exploded perspective view of an underground permeator 100 according to an embodiment of the present invention. Referring to FIG. 4, a first hollow portion 400 for filling powder is formed inside the body portion 310. The space of the first hollow portion 400 is formed only to a certain distance from the left edge portion of the body portion 310. Therefore, the left tip portion is formed of a material such as hollow-free steel. Both the body portion 310 and the left tip portion are formed of one material.

The flare 320 is inserted and fixed on the rear circumferential surface of the body 310. Fixing may be made by a screw bolt fastening method using a screw bolt 430. Of course, for this purpose, an insertion hole 401 is formed on the surface of the flare 320, and a fastening groove (not shown) is formed on the rear circumferential surface of the body portion 310. A flat groove may be formed at the upper end of the insertion hole 401 so that the head portion of the screw 430 is in close contact.

A screw thread is formed inside the fastening groove (not shown) to be meshed with a screw thread formed on the outer surface of the screw 430.

Of course, in addition to the screw bolt fastening method, a bolting fastening method using a bolt and a nut is also possible. In this case, a through hole is formed through the circumferential surface of the rear end of the body part 310 to the first hollow part 400, and a bolt inserted into the through hole is protruded to the first hollow part 400. To be concluded.

The flare 320 may be a 360° annular shape having a second hollow portion 410 at the center. At this time, the surface of the flare 320 is tapered, and the slope of the tapered shape may be 35° to 45°. The flare 320 may also be made of steel or the like similar to the material of the body portion 310.

5 is a perspective view of a flare 320 according to another embodiment of the present invention. Referring to FIG. 5, an uneven structure may be formed on the surface of the flare 320. If it expands, the protruding iron part 510 and the recessed recess 520 may be alternately formed. The widths of the convex portions 510 and the concave portions 520 may be uniform. Alternatively, the widths of the one end and the other end may be different. That is, in the case of the iron portion 510, the width may be wider from the front end to the rear end. In this case, the concave portion 520 becomes narrower from the front end to the rear end.

In addition, a thread 501 is also formed on the trailing outer circumferential surface of the body portion 310, and a thread 502 is formed on the inner circumferential surface of the flare 320. Therefore, it is possible to rotate the flare 320 clockwise to assemble and fasten the rear end of the body portion 310. That is, the threads 502 of the flare 320 and the threads 501 of the body 310 are meshed and assembled.

100: underground infiltrator
310: body
320: flare
400: first hollow
410: second hollow
430: screw bolt
501,502: Thread
510: iron
520: main part

Claims (13)

Body portion 310; And
A flare 320 disposed on the circumferential surface of the body portion 310; as an underground permeate having improved stability of the infiltration motion,
The flare 320 is fixedly attached to the rear circumferential surface of the body part 310 in a detachable manner,
The flare 320 is a 360° annular shape having a second hollow portion 410 at the center,
The surface of the flare 320 is tapered,
The total length (L) of the underground permeate is 4.5D to 5.5D (where D is the diameter of the body portion 310),
The diameter (D _F ) of the flare 320 is 1.20D to 1.30D,
The material of the flare 320 is the same as the material of the body portion 310, an infiltrating body with improved stability of the penetration movement, characterized in that the steel.
delete According to claim 1,
An underground infiltration body having improved stability of infiltration motion, characterized in that a first hollow portion 400 is formed inside the body portion 310.
delete delete According to claim 1,
The inclined angle (θ) of the tapered shape is 35 ° to 45 °, characterized in that the penetration of the underground penetration improved stability of the infiltration movement.
The method of claim 6,
The detachable method is an underground infiltrator with improved stability of the penetration movement, characterized in that any one of a screw fastening method and a screw bolt fastening method.
delete delete delete The method of claim 7,
The first thread 501 is formed on the rear circumferential surface of the body portion 310 for the screw fastening method, and the second thread 502 is formed on the inner circumferential surface of the flare 320. Underground permeate with improved stability.
The method of claim 7,
For the screw bolt fastening method, a fastening groove is formed on the rear circumferential surface of the body part 310, and an insertion hole 401 is formed on the surface of the flare to improve the stability of the penetration motion. Underground permeate.
According to claim 1,
The diameter (D) of the body portion 310 is 15cm ~ 50cm, characterized in that the penetration of the underground permeability improved infiltration movement.

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