KR102673901B1 - Insert hammer for direct drilling machines for narrow spaces - Google Patents

Abstract

An insert hammer for a direct drilling machine for narrow spaces is disclosed. The insert hammer of the disclosed woven drilling machine for narrow spaces includes a wear sleeve that is inserted to a predetermined depth inside the upper end of a steel pipe and is detachably fixedly installed on the upper end of the steel pipe; A center tube that is inserted into the wear sleeve, has a lifting hole formed between it and the wear sleeve, and has an air supply hole 121 on a side thereof; It is inserted between the wear sleeve and the center tube and is configured to move up and down along the lifting hole, and moves up and down repeatedly by air flowing into the lifting hole through the air supply hole to impact the inner bottom surface of the wear sleeve, causing the wear sleeve to move up and down. A piston that causes hammering to hit the steel pipe by means of a wear sleeve; A center tube guide coupled to the top of the wear sleeve and having a lower end surrounding the upper outer peripheral surface of the center tube; and an upper guide that is inserted and coupled to the inside of the center tube guide and presses and secures the center tube downward.

Description

Insert hammer for direct drilling machines for narrow spaces}

The present invention relates to a hammer for a straight boring machine that inserts a steel pipe pile at the same time as boring. More specifically, it relates to a hammer for a straight boring machine for narrow spaces that can be installed and used even in narrow spaces where the installation space for the boring machine is insufficient due to the interior of a building or terrain features. It's about the insert hammer.

In civil engineering work, grouting is a method of injecting filler (grout material) into cracks and cavities in the ground to prevent water leaks or stabilize the soil. Steel pipes are installed in the ground. By installing a packer inside the steel pipe and injecting and solidifying the grout material, it serves to unite the steel pipe and the ground and increase the shear strength of the soil and rock. This is a very advantageous method in terms of constructability and economic efficiency because grout material injection is performed inside a steel pipe.

Typically, the steel pipe grouting method consists of drilling the ground (perforated surface), inserting a steel pipe with a strainer installed in the drilling hole, inserting a sealing material between the steel pipe and the drilling hole, and injecting cement while installing the packer. It comes true. Since this method inserts the steel pipe after drilling, it is less practical in soft ground where it is difficult to maintain the drill hole, as it makes insertion of the steel pipe difficult due to the collapse of the drill hole and the mixing of foreign substances.

To solve this problem, a direct perforation method has been proposed in which a steel pipe is inserted simultaneously with perforation.

The straight drilling device is configured at the bottom of the steel pipe and includes a bit that pierces the perforation surface, a shoe that connects the steel pipe and the bit, and a rod that penetrates the steel pipe and is detachably connected to the bit with a pilot. The rod transmits the rotational force generated by the drive device to the bit through the pilot, allowing the bit to rotate. As the bit rotates, it pierces the perforation surface to form a perforation hole, and the steel pipe is inserted into the perforation hole along the bit. When the steel pipe is inserted to the set depth, the pilot is separated from the bit and discharged out of the steel pipe along with the rod.

In this way, the bit is configured at the bottom of the steel pipe, the rod to transmit the power of the driving device is lowered to the bottom of the steel pipe to combine with the bit, and after the work is completed, the rod is raised to the ground again. The work is complicated and there are many device configurations. Therefore, due to the expensive equipment and complexity of workability, drilling work was unfortunately expensive.

Accordingly, depending on conditions such as an environment in which the stratum is easy to drill or the cost of drilling, a rotary penetration method may be applied in which a bit is formed at the bottom of the steel pipe, a rotation power transmission device is connected to the upper end of the steel pipe, and the steel pipe is directly rotated and inserted. do.

Meanwhile, in the case of this rotary penetration method, not only is drilling done by rotating the steel pipe, but hammering is applied by connecting a hammer device to the steel pipe to strike the stratum and insert it. In this case, the hammer device is installed from the top of the steel pipe to the top. I am using it.

However, installing a hammer device on the top of a steel pipe like this requires a lot of installation space, so it is not a problem when working in an outdoor space without obstacles, but it is necessary to drill the floor slab of the lowest floor of a building, such as at a reconstruction site or remodeling site. In ground reinforcement work where steel pipes are inserted into the ground, there is not enough space above and below to install the hammer device. In construction where steel pipes are inserted while drilling rock, etc. in a horizontal direction, if there is an obstacle at the rear, the space on the left and right where the hammer device is installed is insufficient. When direct drilling work was performed in a narrow space, such as a lack of space, there was a problem that it was difficult to proceed with the hammering work because it was impossible to install a hammer device.

Publication Patent No. 10-2023-0036610 Public Patent No. 10-2024-0044624 Registered Patent No. 10-1131955 Registered Patent No. 10-1919607

The present invention was created to solve the conventional problems as described above, and is configured to enable insertion and installation inside the upper end of the steel pipe, so that it can be inserted into the upper end of the steel pipe even in narrow spaces where installation space for a drilling machine is limited due to the inside of the lowest floor of a building or terrain features. The purpose is to provide an improved insert hammer for a straight drilling machine for narrow spaces that can perform straight drilling work by striking.

However, the purpose of the present invention is not limited to this, and of course, purposes and effects that can be understood from the means of solving the problem or embodiments are also included even if not explicitly mentioned.

The insert hammer of the woven drilling machine for narrow spaces of the present invention for achieving the above object includes a wear sleeve that is inserted to a predetermined depth inside the upper end of the steel pipe and is detachably fixedly installed on the upper end of the steel pipe; A center tube that is inserted into the wear sleeve, has a lifting hole formed between it and the wear sleeve, and has an air supply hole 121 on a side thereof; It is inserted between the wear sleeve and the center tube and is configured to move up and down along the lifting hole, and moves up and down repeatedly by air flowing into the lifting hole through the air supply hole to impact the inner bottom surface of the wear sleeve, causing the wear sleeve to move up and down. A piston that causes hammering to hit the steel pipe by means of a wear sleeve; A center tube guide coupled to the top of the wear sleeve and having a lower end surrounding the upper outer peripheral surface of the center tube; and an upper guide that is inserted and coupled to the inside of the center tube guide and presses and secures the center tube downward.

The center tube has an upper air inlet groove on the upper outer peripheral surface and a lower air inlet groove on the lower outer peripheral surface, and the piston is formed to be long in the vertical and longitudinal direction on the inner peripheral surface, and the air supply hole and the air supply hole are formed according to the vertical movement of the piston. A flow path connecting groove is configured to connect the lower air inlet groove or connect the air supply hole and the upper air inlet groove, and when the air supply hole and the lower air inlet groove are connected by the flow path connecting groove, the air supply hole is connected to the lower air inlet groove. The supplied air flows into the lower part of the lifting hole to cause an upward movement of the piston, and when the air supply hole and the upper air inlet groove are connected by the flow path connection groove according to the upward movement of the piston, the air supply hole is supplied. The supplied air may be configured to flow into the upper part of the lifting hole to cause the piston to move downward.

A bottom air inlet groove may be formed on the lower surface of the piston to allow air introduced into the lower air inlet groove to flow into the lower surface of the piston so that the piston is raised by the air introduced into the lower air inlet groove.

An air outlet groove connected to the bottom air inlet groove is formed on the lower outer peripheral surface of the piston, and the lower part of the wear sleeve is connected to the air outlet groove and flows into the bottom air inlet groove during the upward movement of the piston, causing air to flow into the bottom air inlet groove of the piston. A lower air discharge hole is configured to discharge the air that has performed the upward movement to the outside of the wear sleeve, and the upper part of the wear sleeve is connected to the upper space of the lifting hole when the piston is lowered, so that the upper part of the lifting hole is An upper air discharge hole may be configured to discharge the air that flows into and performs the downward motion of the piston to the outside of the wear sleeve.

The lower air discharge hole and the upper air discharge hole are configured to be located inside the steel pipe, and the air discharged through the lower air discharge hole and the upper air discharge hole is supplied from the upper part of the steel pipe to the lower end of the steel pipe. It can be configured to be discharged through.

It further includes a coupling means for detachably coupling the wear sleeve to the upper end of the steel pipe, wherein the coupling means includes: a socket portion coupled and fixed to the upper outer peripheral surface of the steel pipe by welding; And, the outer peripheral surface is inserted into the inside of the socket portion and coupled by a screw coupling method, the wear sleeve is coupled to the inner peripheral surface by a screw coupling method, and the lower end is configured to be in close contact with the upper end of the steel pipe, so that the piston is connected to the wear sleeve. It may be configured to include a coupling tab that allows the hitting force to be transmitted to the steel pipe when hitting the inner bottom surface.

It may be configured to further include; pressure reducing valve means for supplying some of the air supplied to the center tube through the hollow part of the upper guide to the upper side of the lifting hole to control the striking force of the piston and to control the noise level caused by the striking. You can.

A valve body portion including the pressure reducing valve means, a pressure reducing passage formed in the center tube guide to be connected to the lifting hole, and a valve passage formed on a side of the upper guide and connecting the inside of the upper guide and the pressure reducing passage. And, it may be configured to include a valve member installed on the valve passage to control the amount of air supplied to the lifting hole through the pressure reduction passage by adjusting the opening and closing degree of the valve passage according to the user's operation.

An air injection hole is formed at the bottom of the wear sleeve through which the air supplied into the center tube is directly injected into the steel pipe, and a blocking member is inserted into the bottom of the center tube to block the air injection hole. there is.

According to the above, the insert hammer of the present invention can be used by inserting it into the upper part of the steel pipe, so when inserting the steel pipe in the horizontal direction inside a building with a narrow upper and lower space, such as the basement of a building, it can be damaged by obstacles such as terrain features. It can be installed even in narrow spaces, such as narrow spaces, so even in narrow spaces, it is effective in carrying out ground reinforcement work easily and efficiently by inserting and installing the steel pipe through rotation and hammering of the steel pipe itself.

In particular, the insert hammer of the present invention has a simple structure to easily control the noise from the piston hitting during hammering work and can also stop the hitting of the piston to temporarily eliminate the noise, so it can quickly respond to complaints from people around the construction site, such as during the day. This has the effect of significantly reducing the number of ongoing civil complaints.

In addition, the various and beneficial advantages and effects of the present invention are not limited to the above-described content, and may be more easily understood in the process of explaining specific embodiments of the present invention.

1 is an illustration of the use of an insert hammer of a woven drill for small spaces according to an embodiment of the present invention;
Figure 2 is a diagram showing the installation state of the insert hammer of the woven drill for narrow space according to an embodiment of the present invention;
Figures 3 and 4 are diagrams showing the combined configuration and operating state of the insert hammer of the woven drill for small spaces according to an embodiment of the present invention;
Figures 5 to 9 are diagrams showing the wear sleeve, center tube, piston, center tube guide, and upper guide of the insert hammer of the woven drill for small space according to an embodiment of the present invention, respectively.

The above objects, other objects, features and advantages of the present invention will be easily understood through the following preferred embodiments related to the attached drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content will be thorough and complete and so that the spirit of the present invention can be sufficiently conveyed to those skilled in the art.

In this specification, when an element is referred to as being on another element, it means that it may be formed directly on the other element or that a third element may be interposed between them. Additionally, in the drawings, the thickness of components is exaggerated for effective explanation of technical content.

Embodiments described in this specification will be described with reference to cross-sectional views and/or plan views, which are ideal illustrations of the present invention. In the drawings, the thicknesses of films and regions are exaggerated for effective explanation of technical content. Therefore, the shape of the illustration may be changed depending on manufacturing technology and/or tolerance. Accordingly, embodiments of the present invention are not limited to the specific form shown, but also include changes in form produced according to the manufacturing process. For example, an etch area shown at a right angle may be rounded or have a shape with a predetermined curvature. Accordingly, the regions illustrated in the drawings have properties, and the shapes of the regions illustrated in the drawings are intended to illustrate a specific shape of the region of the device and are not intended to limit the scope of the invention. In various embodiments of the present specification, terms such as first and second are used to describe various components, but these components should not be limited by these terms. These terms are merely used to distinguish one component from another. Embodiments described and illustrated herein also include complementary embodiments thereof.

The terms used in this specification are for describing embodiments and are not intended to limit the invention. As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context. As used in the specification, 'comprises' and/or 'comprising' does not exclude the presence or addition of one or more other elements.

In describing specific embodiments below, various specific details have been written to explain the invention in more detail and to aid understanding. However, a reader skilled in the art to understand the present invention will recognize that it can be used without these specific details. In some cases, it is mentioned in advance that in describing the invention, parts that are commonly known but are not significantly related to the invention are not described in order to prevent confusion without any reason in explaining the invention.

Hereinafter, the insert hammer 100 of the woven drill for narrow spaces according to an embodiment of the present invention will be described with reference to FIGS. 1 to 9.

The insert hammer 100 of the present invention is used for straight drilling reinforcement work in which a steel pipe 10 is inserted while drilling the ground to reinforce the ground. It can be inserted into the upper end of the steel pipe 10 inserted into the ground. It is designed to be used in narrow spaces with terrain features inside or behind a building.

Referring to Figures 1 to 3, the insert hammer 100 of the woven drilling machine for small spaces of the present invention includes a wear sleeve 110, a center tube 120, a piston 130, a center tube guide 140, and an upper guide. It is configured to include (150).

Referring to FIGS. 2, 3, and 5, the wear sleeve 110 is inserted to a predetermined depth inside the upper end of the steel pipe 10 and is detachably fixed to the upper end of the steel pipe 10 by the coupling means 160. It is composed.

At this time, the coupling means 160 is coupled to the socket portion 162, which is fixed to the upper outer peripheral surface of the steel pipe 10 by welding 164, and the outer peripheral surface is inserted into the interior of the socket portion 162, and is coupled by a screw coupling method. , It is configured to include a coupling tab 163 configured to couple the wear sleeve 110 to the inner peripheral surface by a screw coupling method.

The socket portion 162 and the coupling tab 163 are detachably coupled to each other by a first screw coupling portion (s1), and the coupling tab 163 and the wear sleeve 120 are coupled to each other by a second screw coupling portion (s2). It is configured to be separably coupled. That is, a female thread is formed on the inner peripheral surface of the socket portion 162, and a male thread is formed on the outer peripheral surface of the coupling tab 163, so that the socket portion 162 and the coupling tab 163 are separated by the first screw coupling portion s1. It is configured to be capable of being coupled, and a female thread is formed on the inner peripheral surface of the coupling tab 163 and a male screw is formed on the upper outer peripheral surface of the wear sleeve 110, so that the coupling tab 163 and the wear sleeve 110 are connected to the second screw coupling portion ( It is configured to be separably coupled by s2).

The coupling tab 163 is configured such that the lower end is in close contact with the upper end of the steel pipe 10, so that when the piston 130 moves downward and strikes the wear sleeve 110, the striking force applied to the wear sleeve 110 is applied to the steel pipe 10. ) is transmitted to allow the ground of the steel pipe (10) to be inserted.

In addition, a lower air discharge hole 112 and an upper air discharge hole 113 are formed at the upper and lower parts of the wear sleeve 110, respectively. A plurality of lower air distribution holes 112 and upper air discharge holes 113 may be formed in the air sleeve 110 at equal intervals around the circumference.

Referring to FIGS. 2, 3, and 6, the center tube 120 has a tube shape, is inserted into the cylindrical wear sleeve 110, and has a piston 130 between the wear sleeve 110. ) is configured to form a lifting hole (p) that guides the vertical movement.

An air supply hole 121 is formed on the side of the center tube 120, and the air supply holes 121 are formed at predetermined intervals up and down along the longitudinal direction of the center tube 120, and are located at the top and bottom. Each of the air supply holes 121 formed is configured so that a plurality of air supply holes 121 are formed at equal intervals around the circumference on the side of the center tube 120.

In addition, an upper air inlet groove 122 is formed on the upper outer peripheral surface of the center tube 120, and a lower air inlet groove 123 is formed on the lower outer peripheral surface.

Referring to FIGS. 2, 3, and 7, the piston 130 has a cylindrical shape with a hollow portion formed inside, and is inserted between the wear sleeve 110 and the center tube 120 to move up and down along the lifting hole (p). It is configured to be portable. That is, the piston 130 is inserted into the wear sleeve 110, and the center tube 120 is inserted into the inside of the piston 130, so that the piston 130 moves along the lifting hole (p). It is configured to move up and down.

The piston 130 repeats its up and down movement along the lifting hole (p) and strikes the inner bottom surface of the wear sleeve 110 when moving downward, so that the wear sleeve 110 to be hit is connected to the steel pipe (p) through the coupling means 160. ) is configured to perform hammering on the steel pipe (p) by hitting it.

On the inner peripheral surface of the piston 130, a passage connecting groove 132 is formed long in the vertical and longitudinal direction. This passage connecting groove 132 connects the air supply hole 121 and the lower air inlet groove 123 or connects the air supply hole 121 and the upper air inlet groove 122 according to the vertical movement of the piston 130. It is configured to connect. That is, when the piston 130 moves downward, the air supply hole 121 and the lower air inlet groove 123 are connected by the flow path connection groove 132, and when the piston 130 moves upward, the flow path connection groove 132 It is configured to connect the air supply hole 121 and the upper air inlet groove 122.

Additionally, a bottom air inlet groove 133 is formed on the lower surface of the piston 130. A plurality of bottom air grooves 133 may be formed radially on the lower surface of the piston 130.

When the piston 130 descends and moves downward to connect the air supply hole 121 and the lower air inlet groove 123 by the flow path connection groove 132, the air flowing into the lower air inlet groove 123 is the floor air. As it flows between the lower surface of the piston 130 and the inner bottom surface of the wear sleeve 110 through the inflow groove 133, the piston 130 is raised.

Additionally, an air outlet groove 134 connected to the bottom air inlet groove 133 is formed on the lower outer peripheral surface of the piston 130.

When the piston 130 rises, the air outlet groove 134 and the lower air discharge hole 112 are connected, and the air that flows into the bottom air inlet groove 133 and performs the upward movement of the piston 130 flows into the air outlet groove ( 134) and is discharged to the outside of the wear sleeve 110 through the lower air discharge hole 112.

In addition, when the piston 130 is lowered, the upper space of the lifting hole (p) is connected to the upper air discharge hole 113, and the air that flows into the upper part of the lifting hole (p) and performs the lowering motion of the piston 130 is discharged to the outside of the wear sleeve 110 through the upper air discharge hole 113.

Referring to FIGS. 2, 3, and 8, the center tube guide 140 is coupled to the upper end of the wear sleeve 110, and the lower end is configured to surround the upper outer peripheral surface of the center tube 120.

A male thread is formed on the lower outer peripheral surface of the center tube guide 140, and a female thread is formed on the upper inner peripheral surface of the wear sleeve 110, and the center tube guide 140 is inserted into the inside of the wear sleeve 110, thereby engaging the third screw. It is configured to be detachably coupled by a portion s3.

The lower end of the center tube guide 140 is configured to surround the upper end of the center tube 120, and a packing member (k) is interposed between them.

Referring to FIGS. 2, 3, and 9, the upper guide 150 is inserted into the center tube guide 140 using a screw connection method and is configured to press and secure the center tube 120 downward. A female thread is formed on the inner peripheral surface of the center tube guide 140, and a male thread is formed on the lower outer peripheral surface of the upper guide 150, so that the upper guide 150 is separated from the center tube guide 140 by a fourth screw coupling portion (S4). It is configured to be capable of being combined.

The upper guide 150 is configured to have a hollow portion at the inner center so that when the upper guide 150 is screwed to the center tube guide 140, the interior of the upper guide 150 is connected to the interior of the center tube 120. do.

A thread-shaped coupling portion 153 is formed on the upper outer peripheral surface of the upper guide 150 to which a driving device 20 for rotating the steel pipe 10 and moving the piston 130 up and down is coupled. Here, the drive device 20 consists of a rotation drive device for rotating the steel pipe 10 and a compressor, and supplies compressed air to the inside of the center tube 120 through the inside of the upper guide 150 to form a piston 130. ) is provided with a pneumatic driving device that moves it up and down.

Hereinafter, with reference to FIGS. 3 and 4, a striking operation performed while the piston 130 moves up and down by compressed air (hereinafter referred to as “air”) supplied into the upper guide 150 will be described.

As shown in FIG. 3, with the piston 130 located at the bottom of the lifting hole (P), air supplied into the upper guide 150 through a pneumatic driving device such as a compressor is supplied into the center tube 120. The air supplied into the center tube 120 is supplied to the lower surface of the piston 130 and the wear sleeve 110 through the air supply hole 121, the lower air inlet groove 132, and the bottom air inlet groove 133. As it flows between the inner bottom surfaces of the and fills the lower space of the lifting hole (P), the piston 130 moves upward as shown in FIG. 4.

When the piston 130 rises to a predetermined height along the lifting hole (P) in this way, the lower air discharge hole 112 and the air outlet groove 134 are connected and flows into the lower space of the lifting hole (P), thereby forming the piston (130). ) The air that has performed the upward movement is discharged to the outside of the wear sleeve 110 through the lower air discharge hole 112.

In addition, when the piston 130 rises to a predetermined height along the elevation hole (P), the air supply hole 121 and the upper air inlet groove 122 are connected by the flow path connection groove 132, and the center tube 120 The air supplied inside flows into the upper space of the lifting hole (P) through the air supply hole 121 and the upper air inlet groove 122 and fills it, causing the piston 130 to move in a downward motion. The piston 130 performs a striking operation by striking the inner bottom surface of the wear sleeve 110.

When the piston 130 moves downward and performs a striking operation in this way, the upper air discharge hole 113 and the upper space of the lifting hole (P) are connected, and the air flows into the upper space of the lifting hole (P), causing the piston 130 to As the air that performed the downward striking operation is discharged to the outside of the wear sleeve 110 through the upper air discharge hole 113, the piston 130 performs one up-and-down stroke movement.

In this way, the piston 130 performs a striking action of repeatedly hitting the inner bottom surface of the wear sleeve 110 while repeatedly moving up and down, and this repetitive hitting action of the piston 130 causes the wear sleeve 110 ) is transmitted to the steel pipe 10 through the coupling means 160, and hammering is performed to strike the steel pipe 10, causing the steel pipe 10 to be inserted into the ground.

As such, the insert hammer 10 of the present invention is a structure that is inserted and installed inside the upper end of the steel pipe 10, and can greatly reduce the height protruding upward from the top of the steel pipe 10, thereby allowing the insert hammer 10 to be installed at the top and bottom, such as the basement of a building. It can be easily installed and used in narrow spaces, such as inside a building where space is limited or at outdoor sites, where there are obstacles behind the space where the steel pipe 10 is horizontally inserted.

In addition, the present invention can significantly reduce costs compared to the existing expensive method of placing the hammer at the inner bottom of the steel pipe and discharging the hammer separately from the steel pipe after use, and by installing the hammer directly at the top of the steel pipe. In the method of directly rotating and hammering the pipe and inserting it into the ground, it is possible to install it by rotating and hitting together even in a narrow space, regardless of location, thereby increasing the efficiency of steel pipe insertion and improving installation workability.

Meanwhile, referring to Figure 3, in the present invention, the lower air discharge hole 112 and the upper air discharge hole 113 are configured to be located inside the steel pipe 10, facing the inner peripheral surface of the upper end of the steel pipe 10. Accordingly, the air discharged through the lower air discharge hole 112 and the upper air discharge hole 113 is configured to be supplied from the upper part of the steel pipe 10 to the lower part and discharged through the lower end of the steel pipe 10.

Typically, in the case of the steel pipe rotation penetration method, which inserts the steel pipe 10 into the ground by rotating and hitting it, compressed air is sprayed to the lower end of the steel pipe 10 when the lower end of the steel pipe 10 penetrates the ground and perforation is made. This makes it easy to insert the steel pipe 10 into the ground while disturbing the ground soil around the lower end of the steel pipe 10. The present invention supplies air to the insert hammer 100 installed at the top of the steel pipe 10 to insert the piston ( 130) is not immediately discharged to the outside of the steel pipe 10 and discarded after being used as a driving source for up and down repetitive movement, but is used as a hammering drive source for the insert hammer 100 to repeatedly move the piston 130 up and down, and then worn. The air discharged from the sleeve 110 is discharged into the steel pipe 10 to disturb the ground soil through discharge from the lower end of the steel pipe 10, thereby improving pneumatic use efficiency and energy use efficiency. You can.

Referring to Figures 3 and 8, the present invention supplies some of the air supplied into the center tube 120 through the inner hollow part of the upper guide 150 to the upper space of the lifting hole (P) to form a piston 130. It may further include a pressure reducing valve means 170 for controlling the striking force and the noise level caused by the striking.

The pressure reducing valve means 170 is configured to include a pressure reducing passage 172, a valve body 173, and a valve member 175.

The pressure reduction passage 172 is configured to penetrate up and down the center tube guide 140 and is connected to the upper space of the lifting hole (P).

The valve body portion 173 is formed on a side part in the middle of the upper and lower length of the upper guide 150, and a valve passage 174 is formed connecting the inside of the upper guide 150 and the pressure reduction passage 172.

The valve passage 174 includes a first valve passage 174a connected horizontally to the inside of the upper guide 150, a second valve passage 174b connected to the pressure reduction passage 172, and first and second valve passages. It connects (174a, 174b) and includes a third valve passage (174c) into which the valve member 175 is inserted to adjust the amount of movement of air transferred from the first valve passage (174a) to the second valve passage (174b). It is configured to do so.

The valve member 175 is installed in the valve passage 174 in a screw-fastening manner and adjusts the opening and closing degree of the valve passage 174 to control the amount of air supplied to the pressure reduction passage 172 and thus through the lifting hole (P). It is configured to control the amount of supplied air.

When the valve member 175 is rotated counterclockwise, that is, in the screw loosening direction, the opening degree of the valve passage 174 increases, thereby increasing the amount of air supplied to the lifting hole (P) through the pressure reduction passage 172, Conversely, when rotating clockwise, that is, in the screw-fastening direction, the opening degree of the valve passage 174 is lowered or completely blocked, thereby reducing or completely blocking the amount of air supplied to the lifting hole (P) through the pressure reduction passage 172. It can be.

When the valve member 175 is completely tightened to completely block the valve passage 174, no air is supplied to the lifting hole (P) through the pressure reduction passage 172, and all air supplied through the upper guide 150 is not supplied. Since it is supplied to the center tube 120 and moves the piston 120 up and down, the striking force of the piston 120 is maximized.

On the other hand, when the valve member 175 is released and the valve passage 174 is opened to a predetermined opening degree, some of the air supplied through the upper guide 150 is supplied to the center tube 120, and the rest is supplied to the pressure reduction passage 172. It is supplied to the upper space through the lifting hole (P) and the upward force that pushes the piston 120 upward is reduced, so that the piston 120 cannot rise high and then falls, thereby reducing the striking force of the piston 120.

That is, the rising height of the piston 120 can be adjusted by adjusting the opening degree of the valve passage 174 through manipulation of the valve member 175, and the striking strength of the piston 120 can be adjusted accordingly. In particular, the piston 120 can be adjusted. (120) may not be raised at all so that no striking action is performed at all.

In this way, the present invention can adjust the striking force of the piston 120 through the pressure reducing valve means 170, and will be able to quickly respond to complaints about noise generation during ground reinforcement construction by inserting a steel pipe.

Meanwhile, referring to FIG. 3, the present invention has an air injection hole 115 at the bottom center of the wear sleeve 110 that allows the air supplied to the center tube 120 to be directly injected into the inside of the steel pipe 10. may be formed, and in this case, a blocking member 180 that blocks the air injection hole 115 may be inserted into the lower end of the center tube 120. Depending on whether the blocking member 180 is installed, the air supplied to the center tube 120 is prevented from being directly injected into the interior of the steel pipe 10, and all of the air supplied to the center tube 120 is blown through the air supply hole ( 121), or some of the air supplied to the center tube 120 is directly injected into the steel pipe 10 through the air injection hole 115, and the rest is supplied with air. It can be supplied to the piston 130 through the hole 121.

In addition, in the present invention, the blocking member 180 may be configured with a ventilation passage penetrating upward and downward at the center, and in this case, a plurality of blocking members 180 each having ventilation passages of different sizes are provided to meet the needs. Accordingly, the amount of air to be directly injected into the interior of the steel pipe 10 through the air injection hole 115 can be adjusted.

Meanwhile, the present invention is inserted into the spring receiving groove 154 formed at the bottom of the upper guide 150 to elastically pressurize the center tube 120, so that the lower end of the center tube 120 is pressed to the inner bottom surface of the wear sleeve 110. It may further include elastic means 190 for close contact. In this case, when the center tube 120 is pressed downward by the elastic force of the elastic means 190, the lower end of the center tube 120 not only comes into close contact with the inner bottom surface of the wear sleeve 110, but also the center tube guide 140. The packing member (K) sandwiched between the inner step and the outer step of the center tube 120 is also press-fitted, thereby improving the sealing force between the center tube guide 140 and the center tube 120.

Although the present invention has been shown and described in connection with preferred embodiments for illustrating the principles of the present invention, the present invention is not limited to the configuration and operation as shown and described. Rather, those skilled in the art will be able to understand that many changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all such appropriate changes, modifications and equivalents shall be considered to fall within the scope of the present invention.

110...wear sleeve
112...lower air discharge hole
113...Upper air discharge hole
115...air injection hole
120...center tube
121...Air supply hole
122...Upper air inlet groove
123...lower air inlet groove
130...piston
132...Euro connection home
133...Bottom air inlet groove
134...Air outlet groove
140...Center tube guide
150...Upper guide
160...Combining means
161...Socket part
163...Combined tab
170...pressure reducing valve means
171...pressure relief flow path
173...Valve body part
174...Valve passage
175...valve member
180...blocking member

Claims (9)

a wear sleeve inserted to a predetermined depth inside the upper end of the steel pipe and detachably fixed to the upper end of the steel pipe;
A center tube that is inserted into the wear sleeve, has a lifting hole formed between it and the wear sleeve, and has an air supply hole 121 on a side thereof;
It is inserted between the wear sleeve and the center tube and is configured to move up and down along the lifting hole, and moves up and down repeatedly by air flowing into the lifting hole through the air supply hole to impact the inner bottom surface of the wear sleeve, causing the wear sleeve to move up and down. A piston that causes hammering to hit the steel pipe by means of a wear sleeve;
A center tube guide coupled to the top of the wear sleeve and having a lower end surrounding the upper outer peripheral surface of the center tube;
An insert hammer for a woven drilling machine for narrow spaces, comprising: an upper guide that is inserted and coupled to the inside of the center tube guide to pressurize and secure the center tube downward.
According to claim 1,
The center tube has an upper air inlet groove on the upper outer peripheral surface and a lower air inlet groove on the lower outer peripheral surface,
The piston is formed to be long in the vertical longitudinal direction on the inner peripheral surface, and is configured with a flow connection groove that connects the air supply hole and the lower air inlet groove or connects the air supply hole and the upper air inlet groove according to the vertical movement of the piston. Became,
When the air supply hole and the lower air inlet groove are connected by the flow connection groove, the air supplied through the air supply hole flows into the lower part of the lifting hole to cause the piston to move upward,
When the air supply hole and the upper air inlet groove are connected by the passage connecting groove according to the upward motion of the piston, the air supplied to the air supply hole flows into the upper part of the lifting hole to cause the downward motion of the piston. An insert hammer for a straight drill for narrow spaces, characterized in that:
According to claim 2,
A narrow bottom air inlet groove is formed on the lower surface of the piston to allow air introduced into the lower air inlet groove to flow into the lower surface of the piston so that the piston is raised by the air introduced into the lower air inlet groove. Insert hammer for space woven drilling machine.
According to claim 3,
An air outlet groove connected to the bottom air inlet groove is formed on the lower outer peripheral surface of the piston,
At the bottom of the wear sleeve, when the piston rises, it is connected to the air outlet groove and flows into the bottom air inlet groove, and the air that performed the piston's upward movement is discharged to the outside of the wear sleeve. This is composed,
The upper air outlet is connected to the upper space of the lifting hole during the lowering operation of the piston at the upper part of the wear sleeve, and causes the air that flows into the upper part of the lifting hole to perform the lowering operation of the piston to be discharged to the outside of the wear sleeve. An insert hammer for a woven drill for narrow spaces, characterized by a hole.
According to claim 4,
The lower air discharge hole and the upper air discharge hole are configured to be located inside the steel pipe, and the air discharged through the lower air discharge hole and the upper air discharge hole is supplied from the upper part of the steel pipe to the lower end of the steel pipe. An insert hammer for a direct boring machine for narrow spaces, characterized in that it is configured to be discharged through.
According to claim 1,
It further includes coupling means for detachably coupling the wear sleeve to the upper end of the steel pipe,
The coupling means is,
A socket portion coupled and fixed to the upper outer peripheral surface of the steel pipe by welding; and,
The outer circumferential surface is inserted into the inside of the socket portion and coupled to the wear sleeve by a screw coupling method, and the wear sleeve is coupled to the inner circumferential surface by a screw coupling method, and the lower end is configured to be in close contact with the upper end of the steel pipe, so that the piston is connected to the inner bottom surface of the wear sleeve. An insert hammer for a woven drill for narrow spaces, characterized in that it includes a coupling tab that allows the striking force to be transmitted to the steel pipe when struck.
According to claim 1,
It further includes a pressure reducing valve means for supplying a portion of the air supplied to the center tube through the hollow part of the upper guide to the upper side of the lifting hole to control the striking force of the piston and to control the noise level due to the striking. Insert hammer for straight drilling machine for narrow spaces.
According to claim 7,
The pressure reducing valve means,
A pressure reduction passage formed in the center tube guide to be connected to the lifting hole,
A valve body portion formed on a side of the upper guide and having a valve passage connecting the inside of the upper guide and the pressure reducing passage;
A valve for narrow space, characterized in that it includes a valve member installed on the valve passage and adjusting the opening and closing degree of the valve passage according to the user's operation to control the amount of air supplied to the lifting hole through the pressure reduction passage. Insert hammer of a drilling machine.
According to claim 1,
An air injection hole is formed at the bottom of the wear sleeve through which air supplied into the center tube is directly injected into the steel pipe,
An insert hammer for a direct drilling machine for narrow spaces, characterized in that it further comprises a blocking member inserted at the bottom of the center tube to block the air injection hole.

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