KR101213083B1 - The Highest Rod Structure for Providing Water and Air Seperated - Google Patents

Abstract

The present invention relates to a rod structure for separating water supply, and more particularly, to a water separation wall supply structure for forming a water guide wall and a water induction path in the uppermost rod so that the water supplied is automatically separated from the air.
Air separation water supply rod of the present invention is injected into the air and water at the same time, the inner structure of the uppermost rod of the circular tube shape having an inner space formed on the upper, is formed in the inner space, the top diameter is smaller than the lower diameter conical structure An air pipe penetrating through a center of the air pipe to supply the injected air to the lower rod, the air pipe being formed along a length direction of the rod; A water induction wall that guides the injected water to a lower side of the truncated cone structure forming the air pipe; A groove formed at a lower end of the water guide wall in a radial direction perpendicular to the length direction of the rod to temporarily store water guided along the rod outer wall and the water guide wall; The longitudinal upper end is connected to the rod inner space of the truncated conical structure forming the air pipe, the longitudinal lower end is connected to the outside of the rod through the rod outer wall, the longitudinal upper end is above the groove, And a water induction furnace inclined along the longitudinal direction to be positioned at a lower end of the groove in a longitudinal direction, and configured to spray the supplied water to the outside of the rod.

Description

Highest Rod Structure for Providing Water and Air Seperated}

The present invention relates to a rod structure for separating water supply, and more particularly, to a water separation wall supply structure for forming a water guide wall and a water induction path in the uppermost rod so that the water supplied is automatically separated from the air.

In general, underground foundation work or temporary construction is used underground drilling machine as a device for drilling the ground. Such underground perforator is provided with a screw on the rod, such as a rudder or auger provided with a hammer at the end of the rotary drill to rotate it.

In the case of the driven type punching machine 1 as shown in FIG. 1, the down hammer is mounted at the end of the drilling machine to directly hit the ground, and mainly uses pneumatic pressure. At this time, since the end (hammer) and the ground of the perforator is in direct contact with each other, frictional force is generated, and dust is generated due to rock debris or earth and sand, so that water is sprayed at the perforator end to remove dust.

In the prior art as described above, air and water are formed to be spaced apart from each other in order to prevent the air supplied for driving and the water injected for dust removal from being mixed in the rod. Supply each. However, in order to supply air and water through separate supply pipes, there is a problem in that the internal structure of the upper rod becomes quite complicated and the diameter of the rod becomes large.

In addition, when water and air are mixed with each other, there is a fear of causing a failure of the rod.

The present invention has been made in order to solve the above problems, and an object thereof is to separate air from water without installing a separate supply pipe for separating and injecting water and air.

In addition, it aims to effectively remove dust using a simple structure.

In order to achieve the above object, in the present invention, air and water are injected at the same time, and as an inner structure of the uppermost rod of a circular tube shape having an inner space formed thereon, the truncated cone formed in the inner space and having an upper diameter smaller than the lower diameter. An air pipe penetrating the center of the structure, the air pipe being formed along the longitudinal direction of the rod to supply the injected air to the lower rod; A water induction wall that guides the injected water to a lower side of the truncated cone structure forming the air pipe; A groove formed at a lower end of the water guide wall in a radial direction perpendicular to the length direction of the rod to temporarily store water guided along the rod outer wall and the water guide wall; The longitudinal upper end is connected to the rod inner space of the truncated conical structure forming the air pipe, the longitudinal lower end is connected to the outside of the rod through the rod outer wall, the longitudinal upper end is above the groove, The longitudinal lower end is inclined along the longitudinal direction so as to be located at the lower end than the groove, and provides a top rod structure for water separation supply comprising a; water induction furnace formed so that the supplied water is injected to the outside of the rod.

At this time, the lower end of the rod is a socket formed with a thread therein, the upper end of the other rod connected to the lower end of the rod can be screwed with each other and the spigot provided with the thread.

According to the rod structure of this invention, air and water can be isolate | separated without providing each supply pipe separately.

In addition, by controlling the dust generated during the excavation by the water sprayed to the outside of the rod can improve the work efficiency.

1 is a schematic side view showing a conventional underground perforator and rod appearance.
Figure 2 is a schematic side cross-sectional view showing the rod internal structure and the connection structure of the present invention.
Figure 3 is a schematic side view showing the appearance of water is sprayed to the outside in the rod of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately The present invention should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

The uppermost rod 10 of the present invention has a structure in which the water guide wall 12, the water guide path 13, and the groove 14 are formed so that water is automatically separated and supplied from the air. It will be described with reference to FIG.

2 is a schematic side cross-sectional view showing the internal structure of the top rod 10 and the connection structure of the present invention. Hereinafter, the top rod 10 shown in FIG. 2 is located at the top of the rods constituting the rod of the perforator, and water and air are simultaneously injected into the top rod 10 and the top rod 10 The rods below the middle rod 20 of FIG. 2 connected to) are different from the structure of the top rod 10 because the air separated from the top rod 10 is injected and supplied along the air pipe 21. In addition, FIG. 2 illustrates an example in which a hammer bit is connected to a lower structure of the perforator, but the present invention is not limited thereto and may be applied to various types of structures in which fluid and gas are separately supplied.

As shown in Figure 2, the uppermost rod 10 of the present invention, although water and air are injected at the same time, the air flows into the air pipe 11 formed in the center of the rod inner space, the water flows separated from the air along the inner surface of the outer wall It is sprayed to the outside along the induction furnace 13. Specifically, the rod shown in the upper part of FIG. 2 is generally the uppermost rod 10 into which water and air are injected, and inside the cylindrical outer wall, an air tube 11 penetrating the center of the truncated conical structure whose upper diameter is smaller than the lower diameter. Is formed. The outer wall of the air pipe 11 forms a water guide wall 12.

The water injected together with the air into the uppermost rod flows along the inner surface of the outer wall instead of the space inside the uppermost rod 10 as shown in the ① path of FIG. It is separated automatically from the flowing air. ① The water flowing along the path is supplied to the outside of the rod through the water induction path 13 connected to the outside through the outer wall and may be temporarily stored in the groove 14 before being supplied to the water induction path 13. In addition, when the water temporarily stored in the groove 14 is filled with a large amount of supply of water, the filled water flows down along the water guide wall 12, which is the side surface of the truncated cone, as shown in the ② path of FIG. , ② The water flowing along the path is supplied to the water induction furnace (13). As a result, both the water flowing along the inner wall (① path) and the water flowing along the water guide wall 12 (② path) are supplied to the outside of the rod along the water induction path 13 connected to the outside through the outer wall. .

The water induction path 13 passes through the outer wall and connects the rod 10 inner space with the rod outside, and has one longitudinal end formed in the upper rod 10 inner space being the upper end and the other end in the longitudinal direction formed outside the rod. The lower portion is inclined so that water is injected into the lower portion.

On the other hand, the groove 14 formed at the bottom of the water guide wall 12 may be temporarily stored in the water guided along the ① path as described above, when the water is continuously supplied, the water level of the water stored in the groove 14 The water stored in the grooves 14 is increased and injected into the water induction furnace 13, and when the amount of water is a little, the filled water flows down the water induction wall 12 and is injected into the water induction furnace 13. . At this time, the inner space formed by the water guide wall 12 and the outer wall inner surface of the uppermost rod, the groove 14 serves to temporarily store the water is formed to accommodate the water of sufficient capacity so that the water is excessively injected In this case, water can be prevented from flowing back to the air pipe 11.

The rods installed in the perforator are connected with a plurality of unit rods screwed together so as to have a predetermined length according to the drilling depth. As shown in the lower structure of the uppermost rod 10 of FIG. The lower part is a socket 15 which is a truncated groove, and a thread is formed therein. In addition, as shown in FIG. 2, the upper structure of the intermediate rod 20 is a spigot 25 corresponding to the socket 15 formed at the lower end of the uppermost rod 10, and on the outside of the spigot 25. The thread is formed, and screwed with the socket 15 formed in the lower portion of the top rod (10). In particular, the air pipe 21 is also formed in the intermediate rod 20, wherein the air pipe 21 communicates with the air pipe 11 of the top rod 10 when the air pipe 21 is connected to the top rod 10. It is preferable that it is formed in the position to become.

Figure 3 is a schematic side view showing the appearance of water is sprayed to the outside in the rod of the present invention. As shown, in the uppermost rod of the present invention, the water injected through the water induction path 13 formed to pass through the outer wall is injected downward along the longitudinal direction of the rod, thereby controlling dust generated at the lower end of the rod (shear). do. The water pressure of the water to be injected may vary depending on the amount of water supplied, and the cross sectional diameter of the water induction furnace 13 may be variously determined according to the amount of water to be sprayed and the injection force.

10 Top Load 11 Air Line 12 Water Guide Wall
13 water induction furnace 14 groove 15 socket
20 intermediate rod 21 air pipe 25 spigot

Claims (2)

Air and water are injected at the same time, the inner structure of the uppermost rod 10 of the circular tube shape having an inner space on the top,
The air pipe 11 is formed in the inner space, the upper diameter penetrates the center of the truncated conical structure smaller than the lower diameter, and is formed along the longitudinal direction of the rod 10 to supply the injected air to the lower rod 10. ;
A water guide wall 12 that guides the injected water to the lower side of the truncated cone structure forming the air pipe 11;
A groove formed at a lower end of the water guide wall 12 in a radial direction perpendicular to the longitudinal direction of the rod 10 to temporarily store water guided along the rod 10 outer wall and the water guide wall 12 ( 14);
The longitudinal upper end is connected to the inner space of the rod 10 outside the truncated conical structure forming the air pipe 11, the longitudinal lower end is connected to the outside of the rod 10 through the outer wall of the rod 10, The longitudinal upper end is inclined along the longitudinal direction so as to be located at the upper end than the groove 14, the longitudinal lower end is located below the groove 14, the water supplied is formed to be sprayed to the outside of the rod 10 Water induction furnace 13;
Top rod structure for separation of water supply comprising a.

The method of claim 1,
The lower end of the rod 10 is a socket 15 having a thread formed therein, and formed with the spigot 25 provided with an upper thread of the other rod 20 connected to the lower end of the rod 10 and provided with a thread. Top rod structure for radix separation supply, characterized in that the screw coupling.

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