KR20030065052A - closed hammer bit coming and going by slide type - Google Patents

Abstract

PURPOSE: A closed hammer bit operated in a slide method is provided to prevent a loss of equipment, to make rapid execution possible and to prevent damage by dispersing an impact caused by external force. CONSTITUTION: The closed hammer bit operated in a slide method comprises; a bit housing(30) closing up a sliding wing bit(10) to be slidable and hitting a steel pipe(60) downward; a pilot bit(20) coupled with the lower side of the bit housing(30) to close up the sliding wing bit(10) to be slidable; a sliding wing bit(10) expanding and excavating a boring hole; a locking pin(40) fastened to a fastening hole(34) of the bit housing(30) and a fastening perforated hole(24) of the pilot bit(20); and a spacer(50) fixed with the locking pin(40) made with synthetic resins.

Description

Closed hammer bit coming and going by slide type}

The present invention relates to a hermetic hammer bit configured to slide in and out, and more specifically, even when the bit is opened during excavation, no hole in which soil and stone are introduced does not occur, and thus there is no problem in restoring the bit, resulting in equipment loss. There is no worry of any problem, and even small gaps do not allow soil and stone to be introduced by air pressure, and the external pressure applied from the open bit is applied the same throughout, so that the excavation is faster and the support shaft of the bit slides. The present invention relates to a hermetic hammer bit configured to open and close in a horizontal manner by distributing an impact caused by external force so as to enter and exit in a sliding manner without fear of damage.

In general, boring is the drilling of small diameter holes in the earth's crust to understand the structure and properties of the strata, to gain knowledge of the interior of the earth's crust, or to obtain oil, natural gas, hot springs, and groundwater. It is made to collect the back.

Depending on the purpose of use, there are various scales, ranging from several meters to thousands of meters in length and several millimeters to tens of centimeters in diameter. Today, large-scale drilling of several meters in diameter is carried out for use as a vertical shaft.

According to the excavation method, there are a shock type that impacts the bit and breaks the rock and drills it, and a rotary type that drills by rotating the bit in which the diamond and cemented carbide is inserted into the end of the steel pipe (pipe) with respect to the rock surface. The deepest drilling hole in the world is 8,000 meters perforated in the American oil field.

Since the length of the steel pipe used in such a large one is lengthened by connecting a certain length of the iron pipe in order to extend the length. However, when exchanging bits or inserting a steel pipe called a "casing pipe" into an excavated hole, it is necessary to lift the steel pipe (also called a rod, or steel tube) for various investigations.

To this end, large hoisting towers are to be installed, and around them, power plants or excavation equipment used for the purpose of removing the excavated material and preventing the collapse of the hollow walls are to be arranged. The landscape of the elevated tower seen in the oil field shows that drilling is being done.

Drilling is also an important task in mines against underground deposits. In mines, it may be used as a drainage hole or a ventilation hole, a passage through which ores and waste-rock pass, or for the purpose of passing an electric cable. It is common to conduct drilling for preliminary investigations before exploration of the mines by exploration or advanced drilling of geological or mineral deposits.

Mining drilling is not as large as petroleum drilling, but much has been developed to allow free drilling of holes in any direction, at any angle and at any depth. In the rotary drilling, the rock can be extracted into the core of a thin rod called 'core', so that good results can be obtained for the top yarns such as rock quality, dignity and deposits.

In the impact formula, it is possible to determine the quality and quality of cancer by investigating the powder from the hole during drilling. Core drilling is called core drilling, and core drilling is called bunny drilling. Drilling is also used as a hole for investigating the structure and situation inside the crust because it can insert various measuring measuring instruments and experimental devices. Other uses include dam construction of power plants and basic surveys of buildings.

Excavation hammer bits used for such drilling are to use hammer bits of different specifications and structures according to the purpose or the conditions of the geological (geological) bar, the type of hammer bits for direct digging and indirect digging It is roughly divided into bits.

The hammer bit for the direct excavation method is used in a manner in which the state of the ground layer is good or does not drill deeply, and the ground layer is excavated while the bit housing mounted on the hammer drill rotates without using a steel tube.

The hammer bit for indirect digging method is used in the method of drilling while embedding the steel pipe in the drilling hole, and after the bit housing and the bit mounted on the hammer drill drill a hole wider than the diameter of the steel pipe, It is taken out.

The indirect digging hammer drill increases the pressure as it goes deep into the ground, and the load caused by a lot of energy interferes with the hammer bit, making the digging work difficult.

In addition, the hammer bit that needs to excavate a hole wider than the diameter of the steel tube being buried is that the steel tube is embedded at the same time as the excavated amount, and if the hole is not widely excavated so that the steel tube can be easily lifted, In addition to the difficulty of embedding the pipe, a lot of load is applied during the excavation, which causes breakage of the hammer bit, and it becomes very difficult to remove the hammer bit after the excavation.

Therefore, in the art, many products have been developed in order to supply a product capable of performing rapid excavation work as well as supplying a stronger hammer bit, and thus, eccentric rotation type and open type products have been known.

In the eccentric rotation type, the excavation bit is eccentrically rotated and excavation is carried out.This product is eccentric in structure, which makes fast excavation impossible and at the same time, the hammer bit is broken even under a small load or the neck of the bit housing is Problems such as breakage have occurred and are not widely supplied.

The open type product is a structure in which two or three multi-drive hammer bits are opened on the bottom of the bit housing, and this product is not only too far between bits but also a support part supporting the bit is excluded. There is a problem that the expensive excavation work because the problem occurs, such as broken even in small shocks do not fulfill the function of.

The price of the hammer bit varies greatly depending on the type and specification of the product, but if it is an indirect digging hammer bit, it is an expensive product that costs at least 5 million won to 2 to 30 million won per bit, so every time you drill one borehole Core supervision will be carried out carefully excavation work. If a bit breakage problem occurs during work, the impact is directly related to the cost of construction.

In view of these problems, the present inventors have applied for a product that can perform high-efficiency excavation even under adverse conditions, and have been granted a patent under Patent Registration No. 303201 (Name: Structure of Excavation Hole Expansion Hammer Bit).

Figure 14 is an exemplary view showing a state of use of the conventional invention, Figure 15 is a cross-sectional view showing a coupling state of the multi-drive bit and the pilot bit, including the bit housing of the conventional invention, Figure 16 is a multi-drive in the bit housing of the conventional invention Bottom view showing the combined state of the bits and the action of the multi-drive bits.

In this conventional invention, the bit plate fitting groove 105 and stepped at equal intervals in the center and bottom of the pneumatic supply holes 106, 208 and the pneumatic discharge holes 107, 205 formed perpendicularly or perpendicularly. Bearing pin grooves 109 and 201 and fastening pins having a multi-drive bit support surface 204 formed on the bottom to form a bottom pin hole 203 and an inner circumference and an outer circumference to form a circular bearing hole and a pin hole. The semi grooves 110 and 202 are formed, and the circular pilot head grooves 112 and the hexagonal pilot bit holes 111 are formed, and the tip discharge paths 114 and 207 and the spline 103 are formed on the outer circumference. ), Five multi-drive bits 400 coupled at equal intervals are to be excavated wider than the diameter of the steel tube 10a to be buried while semi-reversely rotating at an angle of 100 ° (± 10 °).

The conventional drill hole expansion hammer bit is rotated as the hammer drill 12a vibrates, the bit housing 100 and the pilot bit 200 are rotated in the clockwise direction at the same time, five multi-drive When the bit 400 is folded inwardly narrower than the outer diameter of the initial bit housing 100 and the bit housing 100 and the pilot bit 200 are rotated to some extent to reach the ground, the arrow is shown in FIG. 16 simultaneously with the ground contact. In all directions, about 100 ° is rotated about half a turn to form a diameter larger than the diameter of the bit housing 100 and the steel tube (10a) to dig into the basement.

However, when the multi-drive bit 400 is rotated about the upper surface pin 401 between the lower housing protrusion 115 of the bit housing 100 by rotating the shaft halfway to enter the ground, the top surface of the pilot bit 200 And a hole is formed in the portion before the multi-drive bit 400 is opened between the bottom surface of the and the bit housing 100, that is, the multi-drive bit 400 is folded, and the excavated soil and stone fill this hole. Eventually the hole is tightly filled with dirt and stone.

Accordingly, the multi-drive bit 400 that is open and has a diameter larger than the diameter of the steel tube 10a is folded after excavation of the borehole and is not restored to its original state and thus cannot be taken out through the inside of the steel tube 10a. The bit housing 100 having the multi-drive bits 400 must be left entirely in the ground, resulting in the loss of expensive equipment.

In addition, the multi-drive bit 400 is axially coupled by the bottom pin and the top pin 401 to the pilot bit 200 and the bit housing 100 is axially rotated by the external force when the multi-drive bit 400 is activated. Due to the concentration of the bottom pin and the top pin, there was also a problem that often caused the breakage of the multi-drive bit 400.

The present invention is to solve the conventional problems as described above, even when the bit is open when excavation, there is no problem in the original return of the bit because there is no hole in which dirt and stone is introduced, there is no fear of equipment loss due to this In the small gap, soil and stone are not introduced by the air pressure, and the external pressure received from the bit is applied equally throughout, so that the excavation is faster and the support shaft of the bit is moved horizontally by the slide. An object of the present invention is to provide a closed hammer bit configured to open and close in a sliding manner without fear of damage by dispersing an impact by external force.

In order to achieve the above object, the present invention is provided in the drilling hole expansion hammer bit coupled to the lower end of the hammer drill inserted into the steel tube to supply the pneumatic pressure and excavate the borehole while rotating at the same time;

The upper end is formed with a spline and a ring groove coupled to the lower end of the hammer drill, and a plurality of fastening holes are formed in the middle of the body. A bit housing formed with support protrusions each having an inner guide surface, a fastening recess formed upwardly from a lower center thereof, and a pneumatic supply hole vertically formed at the center of the body;

The upper center has a fastening protrusion which is fitted to the fastening recess of the bit housing, the fastening hole is formed on the extension line, the pneumatic supply hole is formed at the center of the body, and the pneumatic discharge hole is discharged to the lower surface, and the locking protrusion of the bit housing is formed. Sliding long grooves are curved in the clockwise direction from the inner side to the outer outer side at the bottom of the ground, and a plurality of pneumatic discharge holes are formed in the lower direction of the fastening protrusion and the sliding long groove in the vertical direction, and high strength crushing pins are provided at the bottom and the side. A pilot bit in which a plurality of the inserts are inserted to protrude the tip portion;

The upper part is protruded to form a guide protrusion located on the inner side of the bottom of the bit housing, and a pin hole is formed at the lower part to guide the pin to be fastened, and is seated in the sliding long groove of the pilot bit, which slides along the sliding long groove by friction during rotation. And a sliding wing bit which is in situ at the time of reverse rotation;

A locking pin fastened to the fastening hole of the bit housing and the fastening hole of the quick bit by a bar-shaped metal material;

The locking pin is fastened with a bar-shaped synthetic resin material and has a feature of having a spacer filling the remaining portion.

The lower part of the fastening protrusion of the pilot bit has a characteristic that the guide protrusion is formed to slide and guide the inner surface of the sliding wing bit when the sliding movement and the same trajectory with the sliding long groove.

1 is a front view showing a state of the bit housing in an embodiment of the present invention,

2 is a bottom view of FIG. 1;

3 is a front view showing a state of the sliding wing bit in an embodiment of the present invention,

4 is a plan view of FIG.

5 is a bottom view of FIG. 3,

6 is a right side view of FIG. 3;

7 is a front view showing the appearance of the pilot bit in an embodiment of the present invention,

8 is a plan view of FIG.

9 is a bottom view of FIG. 7;

10 is an enlarged side cross-sectional view of the main part of FIG. 7;

Figure 11 is a side cross-sectional view showing a sliding wing bit is coupled to the sliding wing bit and the pilot bit in the bit housing in an embodiment of the present invention,

12 is a sectional view of the excerpts showing a state in which the sliding wing bit of the present invention in open state,

Figure 13 is a partial cross-sectional view of the excerpt showing the restored state of the sliding wing bit of the present invention,

14 is an exemplary view showing a state of use of the conventional invention,

15 is a cross-sectional view showing a coupling state of a multi-drive bit and a pilot bit, including a bit housing of the prior art;

Figure 16 is a bottom view showing a state in which the multi-drive bit is coupled to the bit housing of the conventional invention and the operating state of the multi-drive bit.

* Description of the symbols for the main parts of the drawings *

10: sliding wing bit 12: pin ball

13: guide pin 14: guide protrusion

20: pilot bit 21: pneumatic supply hole

22: fastening protrusions 24: fastening through holes

25: guide protrusions 26, 26a, 26b: pneumatic discharge hole

28: sliding long groove 29: crushing pin

30: bit housing 31: pneumatic supply hole

32: spline 33: ring groove

34: fastening hole 35: support protrusion

35a: inner guide surface 36: striking jaw

37: tip discharge path 38: jamming projection

39: fastening portion 40: locking pin

50 spacer 60 steel tube

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

The hermetic hammer bit configured to slide in and out of the present invention has a structure in which air pressure is supplied and a connection structure to the structure, and closes the sliding wing bit 10 to be slidably on the upper side and strikes the steel tube 60 downward. The bit housing 30, the sliding wing bit 10 in which the one end surface is operated by sliding pulley in a sealed state to expand and excavate the borehole wide, and the sliding wing bit 10 is coupled to the bottom of the bit housing 30 It is roughly classified into a pilot bit 20 which excavates a sealed and supported sieve.

1 is a front view showing the appearance of the bit housing in an embodiment of the present invention, Figure 2 is a bottom view of Figure 1, the bit housing 30 is a sliding wing bit 10 and the pilot bit 20 coupled state In the fuselage is coupled to a hammer drill (not shown) in the state of being placed inside the steel tube 60 while the protective hole to excavate the borehole, the upper end is narrow and the lower end body is formed in a wide shape.

The upper end of the bit housing 30 is formed with a ring groove 33 and a spline 32 coupled to the lower end of the hammer drill with a spline by inserting a separate ring, and the lower end body has an impact projection protruding outward on the upper portion ( 36 is formed and a plurality of fastening holes 34 are formed in the middle portion, and support protrusions 35 having a locking protrusion 38 and an inner guide surface 35a are formed at the lower portion, respectively. At the outer circumference of the lower body, a tip discharge path 37 is formed in the vertical direction.

The engaging projection 38 is formed in plural and in contact with the sliding wing bit 10 to be described later to push the sliding wing bit 10 in the rotational direction.

The support protrusion 35 is formed to shortly protrude downward between the locking protrusion 38 and the other locking protrusion 38 adjacent thereto, and the inner guide surface 35a is in close contact with the guide protrusion 14 of the sliding wing bit 10. Guide the sliding and the bottom surface is in close contact with the upper surface of the sliding wing bit (10).

In addition, the inner bottom surface of the bit housing 30 is in close contact with the top surface of the sliding wing bit 10 guide protrusion 14 so as to be slidable.

The pneumatic supply hole 31 is formed in the vertical direction in the central axis of the bit housing 30, and the fastening recess 39 is formed upward in the lower center.

Pneumatic pressure supplied through the pneumatic supply hole 31 is supplied at a strong pressure to escape to the outside of the excavation hole through the tip discharge passage 37 and the steel tube 60 together with the tip such as soil or stone generated during excavation do.

Figure 3 is a front view showing a state of the sliding wing bit in an embodiment of the present invention, Figure 4 is a plan view of Figure 3, Figure 5 is a bottom view of Figure 3, Figure 6 is a right side view of Figure 3, the sliding wing bit 10 is coupled between the bit housing 30 and the pilot bit 20 to be described later, the sliding length groove 28 of the pilot bit 20 by the guide pin 13 in accordance with the rotation of the bit housing 30 Sliding and moving on the drilling bore to expand and excavate, the upper end is formed with a guide protrusion 14 which is located on the inner side of the lower end of the bit housing 30 is protruded upward and the pin hole 12 on the center side of the lower end This is formed and the guide pin 13 is fastened and fixed. A plurality of crushing pins 29 to be described later are fastened to the outer side and the lower side.

FIG. 7 is a front view showing a pilot bit in an embodiment of the present invention, FIG. 8 is a plan view of FIG. 7, FIG. 9 is a bottom view of FIG. 7, and FIG. 10 is an enlarged side sectional view of the main part of FIG. 7. The pilot bit 20 is a sliding wing bit 10 to scrape the inner peripheral surface of the excavation hole to dig a wider drilling hole, whereas the pilot bit 20 is to dig a deep drilling hole in the underground direction It has a function, the top end is formed of a circular fastening protrusion 22, the upper end of the lower fastening protrusion 22 is formed with a guide protrusion 25 protruding to the outside at the same interval as the sliding long groove 28 of the stop.

The sliding field groove 28 of the middle portion is curved in a clockwise direction from the inner side to the outer side so that when the sliding wing bit 10 is opened, the projected area of the sliding wing bit 10 protruding outwards is horizontally shifted without the left and right bias. Since the area is protruded, the area in contact with the external force is not only concentrated on one side but is spread evenly over the entire surface and is evenly absorbed by dispersing the external impact so that the sliding wing bit 10 is not damaged.

In addition, since the external impact proceeds at the same time in three places where the sliding wing bit 10 is formed, the high speed rotation is possible because the load is uniformly applied without the force being applied to the one or the load.

11 is a side cross-sectional view showing a sliding wing bit coupled to the bit housing in the embodiment of the present invention, the sliding wing bit is opened in the bit housing, Figure 12 is a state in which the sliding wing bit of the present invention is open Fig. 13 is a sectional view of the lumbar extract, and Fig. 13 is a sectional view of the lumbar extract showing a state in which the sliding wing bit of the present invention is restored.

The combined bit housing 30 is a sliding wing bit 10 while the bit housing 30 and the pilot bit 20 are rotated as pneumatic pressure is supplied to the lower end of the hammer drill inserted into the steel tube 60. 13 is folded inwardly narrower than the outer diameter of the initial bit housing 30, but when the bit housing 930 and the pilot bit 20 are rotated to some extent to contact the ground, the outer surface is in contact with the ground to generate frictional force. When the sliding wing bit 10 is to be rotated slowly.

At this time, since the pilot bit 20 and the bit housing 30 is rotated faster than the sliding wing bit 10, the guide pin 13 of the sliding wing bit 10 is the locking projection 38 of the bit housing 30 The sliding wing bit 10 slides outward on the sliding field groove 28 of the pilot bit 20 by means of a protruding force, and only one end thereof protrudes to the outside.

In this state, the sliding wing bit 10 forms a diameter larger than the diameter of the bit housing 30 and the steel tube 60 to dig into the basement.

At this time, the sliding wing bit as shown in Figure 11 is the upper cross section is in close contact with the inner bottom surface of the bit housing 30 and the inner guide surface (35a) of the support protrusion 35 and the bottom surface of the support projection (35). Closed, the inner surface of the sliding wing bit 10 is in close contact with the guide protrusion 25 of the pilot bit 20 so as to be slid and closed, the bottom surface of the sliding wing bit 10 is the pilot bit 20 The upper surface and the sliding length of the sliding groove (28) is in close contact with the closed state, only one side only protrudes slightly to the outside, the other portion of the lower portion of the bit housing 30 and the pilot bit (20) It is tightly closed and tightly closed so that only sliding is possible by the upper surface and the side cross section of the bar), and only the sliding protrusion 38 of the bit housing 30 slides, and a strong pressure is provided in the gap of the less closed part. Outside air pressure Soil or stone powder generated during the excavation because it is being called as is closed without being able to flow into the sliding wing bit 10 at all.

The excavation hole is not only wider than the diameter of the bit housing 30, but also excavated wider than the steel tube 60, so that the steel pipe 60 easily enters the excavation hole as it goes down to the ground layer, and soil or stone powder generated by excavation at this time The tip of the is discharged to the outside of the excavation hole by the air pressure that is continuously supplied.

Particularly, the sliding wing bit 10 protruding between the bit housing 30 and the pilot bit 20 does not provide a space or a gap into which dirt or dust is to be dug into the inside, and has a strong pressure as a small gap. Since the air pressure is continuously discharged through the pneumatic discharge holes 26, 26a and 26b, the soil and the stone powder are pushed outwards.

In addition, after the bit housing 30 and the pilot bit 20 are fastened by the locking pin 40 to be fixed, the extra space is filled with a spacer 50 such as a synthetic resin to prevent soil or stone from entering. Soil or stone powder should be prevented from inflowing at the source.

After the drilling is completed, if the hammer drill is rotated in reverse, the bit housing 30 and the pilot bit 20 are reversely rotated, and the sliding wing bit 10 opened by the friction force is the sliding long groove 28 of the pilot bit 20. And the guide protrusion 25 is folded to its original position and the bit housing 30 can be easily taken out from under the steel tube 60 to the outside.

As described above, the drilling hole expansion hammer bit structure of the present invention does not generate a hole in which soil and stone powder flows even when the bit is opened during excavation, so there is no problem in returning the bit, so there is no fear of equipment loss. Soil and stone are not introduced by the air pressure in the gap, and the external force received from the bit is applied equally throughout the opening, so that the excavation is faster and the support shaft of the bit is opened by horizontal movement by the slide. By disperse | distributing the impact by external force, there exists an effect that there is no fear of damage.

Claims (2)

In the drill hole expansion hammer bit coupled to the lower end of the hammer drill inserted into the steel tube while supplying air pressure and excavating the borehole while vibrating rotation; The upper end is formed with a spline 32 and a ring groove 33 are coupled to the lower end of the hammer drill, and a plurality of fastening holes 34 are formed in the middle of the body, and an impact jaw protruding outward from the outer periphery of the upper body ( 36 is formed and a support protrusion 35 having a locking projection 38 and an inner guide surface 35a protruding downward is formed at the bottom, respectively, and a fastening recess 39 is formed upward from the bottom center and is perpendicular to the body center. A bit housing 30 in which a pneumatic supply hole 31 is formed; The upper center has a fastening protrusion 22 formed to be fitted to the fastening recess 39 of the bit housing 30, and a fastening through hole 24 is formed on an extension line of the fastening hole 34. 21 is formed, the pneumatic discharge hole 26 is discharged to the lower surface is formed and the sliding field groove 28 from the inner side to the outer clockwise on the upper outer surface where the lower surface of the engaging projection 38 of the bit housing 30 is grounded. A plurality of pneumatic discharge holes (26b) (26a) are formed in the vertical direction at the lower end of the fastening protrusion (22) and the sliding field groove (28), and the high crushing pins (29) are provided on the lower and side surfaces. A pilot bit 20 which is inserted into a plurality and formed so as to protrude from the tip; The top is protruded to form a guide protrusion 14 located on the lower inner surface of the bit housing 30, the pin hole 12 is formed at the lower end of the guide pin 13 is fastened and the sliding length groove of the pilot bit 20 ( 28 and a sliding wing bit (10) is seated in the sliding slide along the sliding field groove (28) by friction during rotation and reopened in the reverse rotation; A locking pin 40 fastened to the fastening hole 34 of the bit housing 30 and the fastening hole 24 of the quick bit 20 by a bar-shaped metal material; Sealing hammer bit configured to enter and exit the slide method characterized in that the locking pin 40 is fastened with a bar-shaped synthetic resin material and has a spacer 50 for filling the remaining portion. The method of claim 1; In the lower part of the fastening protrusion 22 of the pilot bit 20, the guide protrusion 25 slidingly guides the inner side of the sliding wing bit 10 and protrudes in the same trajectory as the sliding long groove 28 is further formed. Sealed hammer bit configured to enter and exit the slide method characterized in that formed.