KR20230097853A - A hammer-hitting horizontal excavation device that improves straightness - Google Patents

Abstract

The present invention relates to a hammer horizontal excavator with improved straightness, and more particularly, to expand urban infrastructure without destroying or transforming existing structures such as roads and railroads, and extending relatively short lengths in the ground in a non-cutting type. It is a hammer with excellent excavation performance in press-in burial of small-diameter steel pipes horizontally. It reduces construction time for excavation work and improves excavation efficiency in difficult ground by burying pipelines while percussion excavation, especially in the excavation process. It relates to a hammer strike type horizontal excavator with improved straightness that can improve straightness while simply correcting the excavation direction in the forward direction when out of range.

Description

A hammer-hitting horizontal excavation device that improves straightness}

The present invention relates to a hammer horizontal excavator with improved straightness, and more particularly, to expand urban infrastructure without destroying or transforming existing structures such as roads and railroads, and extending relatively short lengths in the ground in a non-cutting type. It is a hammer with excellent excavation performance in press-in burial of small-diameter steel pipes horizontally. It reduces construction time according to excavation work and improves excavation efficiency in the ground where propulsion is difficult by burying pipelines while percussion excavation, especially in the excavation process. It relates to a hammer strike type horizontal excavator with improved straightness that can improve straightness while simply correcting the excavation direction in the forward direction when out of range.

In general, in the pipeline construction of burying water and sewage pipes or communication pipes in downtown areas where various buildings and structures are installed, a non-cutting method is used to press-in and propel steel pipes horizontally by excavating and crushing the ground by the head of the propulsion device.

Steel pipes used in such pipeline construction are buried in various sizes of 200 mm or more in diameter depending on the purpose, and the construction length may be 10 m to 100 m or more.

The conventional method of excavating horizontally and burying a steel pipe by press-in method is a method of directly hitting and press-fitting the steel pipe and discharging the soil inside the steel pipe to the outside, and an excavation device such as a semi-shield, which advances the steel pipe with a hydraulic jack while excavating the ground. There is a technique for pressing.

However, the press-fitting method by directly hitting the steel pipe causes severe noise and vibration and is impossible to construct when the rock is exposed. There is a problem. In particular, if the diameter of the steel pipe is large, manpower is put in to hit the bedrock, but in the case of a steel pipe with a small diameter, manpower cannot be put in, so bedrock work cannot be performed, soil discharge work by manpower cannot be performed, and excavation speed is reduced. There was a problem that it was slow and exposed to safety accidents.

In addition, as in Patent Publication 10-2007-0087933, the steel pipe is inserted while excavating the ground by a metal crane (ring bit) at the tip having a plurality of tips while rotating the steel pipe in a holding state by a pipe opening device, which is a hydraulic rotary device A device for opening a pipeline has also been devised, but this has a problem in that it is difficult to propel the rock during excavation because the strength of the metal crane (ring bit) installed at the tip of the leading propulsion pipe is weak and cannot crush the bedrock.

Therefore, when excavating the rock layer, the hammer excavation method is constructed in which the hammer is rotated and hit to press the steel pipe while crushing the rock mass. It is not easy to excavate with a hammer due to various problems such as bearings and steel pipes that attenuate the impact and vibration of the steel pipe to be press-fitted due to shock and vibration and are damaged without overcoming the impact. In particular, in the case of horizontal excavation with a hammer The hammer and bit rotate clockwise at 3.5 to 13 rpm (rotation per minute) to perform horizontal boring. At this time, since it rotates to the right, it gradually leans toward that direction and moves, and according to the law of gravity, it gradually moves downward by the weight of a heavy hammer and bit of around 1.5 tons and departs from the prescribed burial path, There was a problem that a large error in the end position occurred, and cumbersome work was accompanied by correcting the excavation direction from time to time to solve this problem.

An object of the present invention is to solve this conventional problem, and to eccentrically install a large-diameter hammer and a small-diameter hammer having different diameters at the tip of a propulsion pipe, but not installed on the same surface, so that the large-diameter hammer protrudes forward more than the small-diameter hammer. By installing it, it is possible to excavate while simply correcting the path from time to time by pre-excavation by a large-diameter hammer when departing from the buried path, improving straightness and providing a hammer strike type horizontal excavator with improved straightness that enables excavation in a fixed path. is to do

The present invention is a means for achieving this object, a conventional steel pipe propulsion device for holding a steel pipe and rotating it by a hydraulic device, a lead propulsion pipe held and rotated by the steel pipe propulsion device, and an inside of the front end of the lead propulsion pipe. In a hammer strike type horizontal excavation device comprising a plurality of hammers installed and crushing rock by hitting and vibration, the hammer is composed of a small diameter first hammer and a large diameter second hammer, leading each other to the inside of the propulsion pipe. Improves straightness, characterized in that the bit part of is installed eccentrically to protrude, but the small-diameter first hammer and the large-diameter second hammer do not protrude in the same plane, and the large-diameter second hammer is installed so that it protrudes forward than the small-diameter first hammer A hammer strike type horizontal drilling rig is provided.

In addition, the hammers are characterized in that they are installed asymmetrically, each consisting of one or more, but a plurality.

As described above, the present invention has a large-diameter hammer installed eccentrically on the propulsion pipe so that it protrudes forward from the small-diameter hammer, so that the propulsion pipe is rotated while excavating and advancing. Since the excavation direction can be easily corrected in the forward direction by partially proceeding pre-excavation with a hammer, there is an effect of reducing the error between the excavation start point and the excavation end point by improving straightness during horizontal excavation.

1 is an exemplary view of excavation according to an embodiment of the present invention
Figure 2 is an installation structure diagram of a hammer according to an embodiment of the present invention
Figure 3 is a front view of the hammer of Figure 2
Figure 4 is an explanatory example of rotating a large-diameter hammer by 180 °
5 is an exemplary view of inserting a steel pipe according to the present invention

Hereinafter, embodiments of the present invention will be described in detail, focusing on parts necessary for understanding operations and actions according to the present invention with reference to the accompanying drawings.

Since the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention, various modifications that can be substituted for them at the time of the present application It should be understood that there may be

While describing the embodiments of the present invention, descriptions of unnecessary technical details that are well known in the technical field to which the present invention pertains and are not directly related to the present invention are omitted for clearer delivery without obscuring the gist of the present invention.

1 is an exemplary view of excavation according to an embodiment of the present invention, FIG. 2 is an installation structure diagram of a hammer according to an embodiment of the present invention, FIG. 3 is a front view of the hammer of FIG. 2, and FIG. 4 is a large-diameter hammer It is an explanatory example of rotating 180 °, and FIG. 5 is an exemplary view of inserting a steel pipe according to the present invention.

1 to 5, the hammer strike type horizontal drilling rig with improved straightness of the present invention is a conventional steel pipe propulsion device 100 and the steel pipe propulsion device 100 holding a steel pipe and rotating it by a hydraulic device. It includes a lead propulsion pipe 200 that is held and rotated, and a plurality of hammers 300 installed inside the front end of the lead propulsion pipe 200 to crush rock mass with blows and vibrations.

The hammer 300 is composed of a small-diameter first hammer 310 and a large-diameter second hammer 320, and is eccentrically reduced so that the bit portion of the tip protrudes inside the leading propulsion pipe 200, but the small-diameter first It is characterized in that the hammer 310 and the large-diameter second hammer 320 do not protrude in the same plane, and the large-diameter second hammer 320 protrudes forward more than the small-diameter first hammer 310.

In the drawing, reference numeral 210, which is not explained, is a connection pipe connected to the leading propulsion pipe, 50 is a earthing hole, and 51 is a screw that transfers the excavated soil to the rear.

The hammer 300 impact type horizontal drilling device of the present invention holds the lead propulsion pipe 200 in the steel pipe propulsion device 100 and rotates it, while crushing the rock mass by the hammer 300 installed at the tip and excavating the soil. The steel pipe propulsion device 100 is a device that continuously propels the steel pipe forward by sequentially connecting the connection pipe 210 to the rear of the steel pipe while propelling the steel pipe, and since the steel pipe propulsion device 100 has a conventional structure including a hydraulic device, a hydraulic motor, and a holder device, A detailed description is omitted.

The feature of the present invention is to change the installation structure of the hammer 300 differently from the normal structure, and when the hammer 300 is used to change the excavation direction when departing from the buried path during the excavation process, the path is corrected and the steel pipe is routed to the specified buried path. It is characterized in that it can be inserted.

Describing the action and effect of the hammer 300 according to the present invention, the hammer 300 eccentrically installed in the leading propulsion pipe 200 is divided into two small-diameter first hammers 310 and large-diameter second hammers 320, The two hammers 300 are inserted into the leading propulsion pipe 200, so that the large-diameter second hammer 320 protrudes forward more than the small-diameter first hammer 310, so the steel pipe propulsion device ( 100), in the process of rotating and propelling the steel pipe, the large-diameter second hammer 320 that protrudes forward first performs pre-excavation, and then the small-diameter first hammer 310 located at the rear performs post-excavation while excavating as a whole. Thus, a conduit is opened by inserting a steel pipe and connecting the connection pipe 210.

Meanwhile, in this process, the two hammers 300 eccentrically installed in the leading propulsion pipe 200 rotate clockwise while performing horizontal boring, so they move gradually leaning toward that side, and the heavy weight of the hammer 300 By gradually descending, the predetermined path is deviated, and the path deviation is confirmed by monitoring by the detection sensor installed in the leading propulsion pipe (200).

Therefore, if such path deviation is confirmed, the path is corrected. At this time, the leading propulsion tube 200 is rotated in the opposite direction of the tilt, that is, in the direction to be switched, so that the large-diameter second hammer 320 is positioned, and then shown in FIG. 4 The pre-excavated part is pre-excavated by first excavating by rotating 180 ° left and right reciprocally, and then rotating the leading propulsion pipe 200 360 ° to rotate the entire small-diameter first hammer 310 located at the rear In , since the small-diameter first hammer 310 is idling and no load is applied, the direction is naturally changed to the pre-excavated direction and the path is corrected.

Here, in the two hammers 300, even if hammers 300 having the same diameter are used instead of hammers 300 having different diameters, as shown in the embodiment shown in the drawing, one hammer 300 is the other hammer 300. Although the path can be corrected even when it protrudes beyond the hammer 300, as in the embodiment of the present invention, the small diameter and the large diameter are configured differently and the pre-excavation as the large diameter second hammer 320 is more effective in directional conversion. The effect can be obtained, and the number of small-diameter first hammers 310 and large-diameter second hammers 320 is not limited to the illustrated embodiment, and each one or more can be implemented, and in this case, they must be installed asymmetrically to change direction effect can be obtained.

As described above, the present invention does not install hammers 300 having different diameters on the same surface, but installs one of them protruding forward so that there is a step difference, thereby reducing the load by performing pre-digging using the protruding hammer 300 when the path is deviating. Since the direction can be easily changed by the method of doing so, it is possible to excavate along the set burial path, which has the effect of improving straightness.

50: earthwork 51: screw 100: steel pipe propulsion device 200: leading propulsion pipe 210: connection pipe 300: hammer 310: small diameter first hammer 320: large diameter second hammer

Claims (2)

A general steel pipe propulsion device 100 holding a steel pipe and rotating it by a hydraulic device, a lead propulsion pipe 200 held and rotated by the steel pipe propulsion device, and a rock that is installed inside the front end of the lead propulsion pipe 200 In the hammer (300) impact type horizontal drilling device including a plurality of hammers (300) for crushing by impact and vibration, the hammer (300) includes a small-diameter first hammer (310) and a large-diameter second hammer (320). ), and are eccentrically reduced so that the bit part of the tip protrudes inside the leading propulsion pipe 200, but the small-diameter first hammer 310 and the large-diameter second hammer 320 do not protrude in the same plane, and the large-diameter hammer 2 Hammer striking type horizontal excavation apparatus with improved straightness, characterized in that the hammer 320 is installed so as to protrude forward than the small-diameter first hammer 310. According to claim 1, The small-diameter first hammer (310) and the large-diameter second hammer (320) is composed of one or more, but a hammer impact type horizontal excavator with improved straightness, characterized in that they are installed asymmetrically.

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