KR20110007344A - Hammer for digging - Google Patents

Abstract

PURPOSE: An excavating hammer is provided to enhance the efficiency of excavation and to increase the utilization of an excavation ball. CONSTITUTION: An excavating hammer comprises a back head, a case, a bit fixing ring, a bit structure(70), a piston and an inner sleeve. The back head is connected to a ground excavator and is connected to the lower end of a rotary shaft. The case is coupled/fixed to one side of the back head. The bit fixing ring is coupled/fixed to the other side of the case, which is the opposite side of the back head. The bit structure is located in the bit fixing ring and directly excavates the ground through an excavating ball(75). The piston is installed in the case and strikes the bit structure by a lifting action. The inner sleeve is installed between the piston and the back head and supplies air pressure from the back head to the piston to cause the lifting action of the piston.

Description

Hammer for digging

The present invention relates to a drilling hammer, and more particularly to a drilling hammer equipped with a square bit.

In the foundation works such as civil engineering and construction work, work is performed to prevent the settlement of the ground so that the structure built on the ground can be firmly located. Work or drilling is in progress.

In order to drill holes in solid ground or rocks, hammers with strong rotational and propulsive forces are used to support them. Recently, pneumatic hammers using high pressure compressed air are mainly used. The pneumatic hammer receives the rotational force and high-pressure air from the ground excavator and rotates as a whole, while simultaneously hitting the ground to excavate the soil layer and the rock layer.

On the other hand, the bit hitting the ground directly through the excavation ball formed on the bottom surface plays a very important role to perform the excavation effectively. Accordingly, various types of bits have been developed for efficient drilling. However, the conventional bit has a lot of problems, such as the load is not applied to reduce the efficiency of the excavation, easily broken by the rock layer and the like, difficult to use for a long time, the utilization of the drilling ball is not properly.

Therefore, the technical problem to be achieved by the present invention is to provide an excavation hammer equipped with a bit that improves the efficiency of the excavation, not easily broken, can be used for a long time and improves the utilization of the excavation ball and the like.

Excavation hammer of the present invention for achieving the above technical problem includes a back head connected to the excavator, a case coupled to one side of the back head and fixed and a piston installed inside the case to lift. In addition, it is located on the other side of the case opposite to the back head, and has a bottom is provided with a hitting force by the lifting action of the piston having a cross-section of the square shape.

In the hammer of the present invention, the bit may have a square cross section while corners are chamfered and corners may have curvature. In addition, the circumference of the bottom may be divided into a flat portion and an inclined portion inclined in the lateral direction of the bit, the area of the inclined portion may vary depending on the use of the drilling hammer. The size of the excavation ball disposed on the inclined portion is preferably larger than that disposed on the flat portion. Nana, the excavation hammer may be installed a plurality of to form a combination hammer.

According to the excavation hammer of the present invention, by using a bit provided the impact force by the lifting action of the piston while the bottom surface has a square cross-section, to increase the efficiency of the excavation, does not break well, can be used for a long time and drill ball Its performance can be improved by increasing its utilization.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. Embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art.

An embodiment of the present invention will propose a drilling hammer for improving the performance of the drilling by making the shape of the bit rectangular. To this end, first, the role of the bit in the excavation through the excavation hammer equipped with a square bit will be described in detail, and then the features of the square bit will be described in detail. Further, the application will be extended to a combination hammer equipped with a plurality of bits including the square bits of the present invention.

1 is a cross-sectional view showing a drilling hammer equipped with a square bit according to an embodiment of the present invention. As an example of the drilling hammer presented herein, it may be applied to other types of hammers within the scope of the present invention. For example, although described herein with reference to hammers using pneumatics, the present invention can be applied to hammers operated by screws.

Referring to Figure 1, the excavation hammer 100 of the present invention is connected to a conventional ground excavator, the back head (back) (10), which is connected to the lower end of the rotating shaft (not shown) with a screw formed on its outer surface It includes a case 50 is coupled to one side of the head 10, the bit fixing ring 60 is coupled to the other side of the case 50, which is opposite to the back head 10.

In addition, the bit structure by the lifting mechanism in the state installed in the bit structure 70, the case 50 to directly dig the ground through the excavation ball 75 formed on the bottom surface is located inside the bit fixing ring 60 Piston 40 striking the structure 70 and is installed between the piston 40 and the back head 10 to provide an air pressure flowing from the back head 10 to the piston 40 to elevate the piston 40 And an inner sleeve 30 to induce the inner sleeve. The inner sleeve 30 is disposed to be in close contact with the piston 40 in the space of the central portion of the piston 40. Reference numerals 20 and 32 are guides for guiding air pressure flowing from the back head 10 in an appropriate direction, respectively, and sleeve windows for exchanging air pressure. While contacting the bit structure 70 may be attached to a separate fixing ring drilling ball 62 to the exposed portion of the bit fixing ring 60 to protect the bit fixing ring 60 and to make the excavation well.

2A is a perspective view illustrating a bit structure according to an exemplary embodiment of the present invention, and FIGS. 2B to 2C are cross-sectional views taken along lines 2B-2B, 2C-2C, and 2D-2D of FIG. 2A, respectively.

2A to 2D, the bit structure 70 includes a connection portion 71 for connecting with the bit fixing ring 60, a bit shank 72 for supporting the bit 73, and a drilling ball 75. It is configured by. The bit shank 72 and the bit 73 preferably have a rectangular cross section or a rectangular cross section chamfering with a cross section. Here, the rectangular cross section does not refer to a perfect quadrangle but also includes a partially deformed case. For example, the bit shank 72 and the bit 73 can be chamfered at an angle in cross section to be inclined or rounded. In addition, the edges of the bit shank 72 and the bit 73 may also be curved to increase mechanical durability. That is, the rectangular cross section is a concept including a corner or a corner having curvature.

In some cases, a foot valve (not shown) may be installed on the connection portion 71 to control the flow of air pressure. The connecting portion 71 has a shape for connecting with the bit fixing ring 60. A flow path 74 through which air flows is penetrated from the connecting portion 71 to the bit 73. There may be one flow path 74 in the center as shown, but in some cases there may be a plurality of the flow path (74).

The bottom surface of the bit 73, that is, the portion which directly touches the ground and excavates, the shape of the bit 73 extends as it is. Specifically, the bottom surface of the bit 73 may be formed of only the flat portion (a) in the state that the flow path 74 is disposed, and may further include a portion (b) inclined along the circumference. Preferably, as shown, the underside of the bit 73 may be a combination of a flat portion (a) and an inclined portion (b). If the bit 73 is in the chamfered shape, the bottom surface of the bit 73 has the same shape, and the circumference has a portion b inclined in the lateral direction of the bit 73. The inclined portion (b) may vary in area and inclination depending on the use of the hammer of the present invention.

The drilling ball 75 is made of a hard material such as diamond, and is divided into a first drilling ball 75a embedded in an inclined portion (a) and a second drilling ball 75b embedded in a flat portion (a). The size of the first drilling ball (75a) is preferably larger than the second drilling ball (75b). This is because the wear of the first drilling ball (75a) is relatively severe during the excavation process. The number of the first drilling balls 75a may be determined differently according to the area of the inclined portion b.

The corner where the inclined portion (a) meets at an angle may be chamfered in a flat form or a rounding form to plant the first drilling ball 75a or to have a space in which the discharge path 76 is formed. The discharge path 76 is for discharging rocks, etc., generated during the excavation process to the outside of the hammer. By chamfering the corners, the corners can be prevented from being damaged by abrasion or impact, and the efficiency of the excavation can be increased by arranging the first drilling balls 75a in the corners.

The perimeter of the bit 73 except for the chamfer may be bent to have a predetermined curvature. By bending the circumference of the bit 73, it is easy to absorb external impact, and the shape of the bit 73 can be appropriately adjusted according to the intended use. Nevertheless, even if the circumference of the bit 73 is bent, since the portions where the corners meet each other have a constant angle, it can be said that it has a rectangular cross section.

The bit 73 according to the embodiment of the present invention has a larger endurance force of the bit 73 than in the conventional case having a circular cross section or a triangular cross section, so that more load can be applied to the bit 73. In addition, it is possible to prevent the bit 73 from being broken by an external impact by removing the sharply protruding portion through the chamfer. In addition, the first drilling ball (75a) and the second drilling ball (75b) is in contact with the ground and by varying the size thereof, the drilling ball 75 can be used for a long time. Furthermore, if the first drilling ball (75a) is worn or damaged and can not be used, it is easy and economical to replace only the damaged part.

3A is a partial cross-sectional view schematically showing the configuration of the combination hammer 200 including the excavation hammer 100 and the auxiliary hammer 240 to assist the present invention. 3B is a bottom view of FIG. 3A. The number of excavation hammers 100 and auxiliary hammers 240 employed may vary depending on the use in which the combination hammer 200 is used. Here, the case where the number of the drilling hammer 100 and the auxiliary hammer 240 is one is taken as an example. At this time, the drilling hammer 100 is the same as described with reference to FIG.

3A and 3B, the combination hammer 200 includes a hammer body 220, a joint 210 provided at an upper end of the hammer body 220, and an excavation disposed at regular intervals in the hammer body 220. And a fixing frame 230 including hammers including the hammer 100 and a guide member fixed to an end of the hammer body 220 to hold a circumference of the bits of the hammers.

The joint 210 is fixed to the upper end of the hammer body 220, the rotary shaft and air provided from the rotary shaft (not shown) and air supply means (not shown) provided in a conventional ground excavator to the hammer body 220 Supply. Therefore, the hammer body 220 receives the rotational force and the impact force from the joint 210 to perform the excavation and excavation operation. In the hammer body 220, the drilling hammer 100 and the auxiliary hammer 240 are installed at regular intervals, and the hammers 100 and 240 are supplied with the air delivered from the joint 210, and the air is supplied to the supplied air. By lifting and lowering continuously.

The lower end of the hammer body 220 is combined with a plurality of bits 70 installed in the excavation hammer 100 and the auxiliary bit 245 installed in the auxiliary hammer 240 to form a combination bit 250, combination bits 250 receives an impact force at the time of rising or falling from hammers and exerts an excavation force in the ground direction.

The auxiliary hammer 240 may have the same shape as the excavation hammer 100 of the present invention, and may have a circular or triangular cross section as in the related art. The auxiliary hammer 240 is only different in shape from the excavation hammer 100 of the present invention, the operation method is the same. In the drawings, the combination bit 250 is placed on the same surface, for example, but the auxiliary hammer 240 may be more protruding than the drilling hammer 100. In addition, the size of the auxiliary hammer 240 and the drilling hammer 100 may be different depending on the type of the combination hammer 200.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but many variations and modifications may be made without departing from the scope of the present invention. It is possible.

1 is a cross-sectional view showing a drilling hammer equipped with a square bit according to the present invention.

2A is a perspective view illustrating a bit structure according to the present invention, and FIGS. 2B to 2C are cross-sectional views taken along lines 2B-2B, 2C-2C, and 2D-2D of FIG. 2A, respectively.

Figure 3a is a partial cross-sectional view schematically showing the configuration of a combination hammer including an excavation hammer and an auxiliary hammer to assist the present invention.

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

10; Backhead 20; guide

30; Inner sleeve 40; piston

50; Case 60; Bit retaining ring

70; Bit 71; Connection

72; Beet shank 73; beat

74; Euro 75; Excavation ball

100; Drilling hammer 200; Combination hammer

210; Joint 220; Hammer body

230; Fixed frame 240; Auxiliary hammer

245; Auxiliary bit 250; Combination bits

Claims (6)

A backhead connected to the excavator; A case coupled to and fixed to one side of the back head; A piston installed inside the case and configured to elevate; And Excavating hammer which is located on the other side of the case opposite to the back head, the bottom has a square cross-section and is provided with a striking force by the lifting action of the piston. The hammer of claim 1, wherein the bit has a square cross section while the corner is chamfered and the corner has a curvature. The drilling hammer of claim 1, wherein the circumference of the bottom surface is divided into a flat portion and an inclined portion inclined in the lateral direction of the bit. 4. The excavation hammer according to claim 3, wherein the area of the inclined portion depends on the use of the excavation hammer. 4. The drilling hammer of claim 3, wherein the size of the drilling ball disposed on the inclined portion is larger than that of the drilling ball disposed on the flat portion. The excavation hammer according to claim 1, wherein a plurality of excavation hammers are installed to form one combination hammer.

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