KR101108437B1 - Method for constructing inverted-t shape excavation high-strength earthwire using extendable excavating blade of auger crane - Google Patents

Abstract

PURPOSE: A method of constructing inverted-t shape excavation high-strength stayline using a hydraulic extendable excavating blade for an auger crane is provided to simplify an excavating process for constructing a stay block due to reduction in the excavated amount of soil and sand by a high-strength stay block. CONSTITUTION: A method of constructing inverted-t shape excavation high-strength stayline using a hydraulic extendable excavating blade for an auger crane is as follows. In a state that the extendable excavating blade of an excavating screw is reduced, a block inserting portion(300) is excavated using only a spiral screw. By expanding the extendable excavating of the excavating screw with fluid pressure, a block burying portion(400) is excavated to have a larger inner diameter than the length of a high-strength stay block(100).

Description

Method for constructing inverted-T shape excavation high-strength earthwire using extendable excavating blade of auger crane}

The present invention relates to a high-strength ground root construction method for supporting and fixing electric poles in the case of mechanized dry construction using an expansion excavator of auger crane, and more specifically, even in the first excavation process without auxiliary excavation, it is longer than the excavation diameter. It is possible to install high-strength ground roots, and in particular, it is possible to excavate the cross section of the excavated hole to be inverted T-shaped by expanding the excavation using the hydraulic expansion drill blade of auger crane at the depth to embed the ground roots. Since the ground line is buried on the base surface of the buried ground, it can have strong pulling resistance, so it can effectively show the support of the pole with the facilities in the pole that is strong against natural disasters and weighted by large capacity distribution power facilities. Inverted T Type Excavation Steel Using Auger Crane Hydraulic Telescopic Digging Blade It relates to the branch construction method.

In general, when constructing transmission poles, communication lines, etc. in installing electric poles and wires electric wires and communication cables, the poles are installed to reinforce the unbalanced tension of electric wires and communication cables to prevent the poles from tilting or falling down. In order to install a branch line, excavation work for underground line laying is carried out by manual or mechanical work, and the ground line is buried at the excavation point to connect with Jeonju through the ground rod. I'm doing it.

Such general branch line and branch line construction method is disclosed by Patent No. 710649, Patent No. 727279, Patent No. 740013, and Patent No. 761778 issued by the present applicant.

The ground roots used in modern ground roots construction methods are rectangular roots of 0.7 m and 1.2 m, and round roots of 43 cm in diameter and 62 cm in diameter corresponding to the above values.

Here, the reason for the difference between the standard and the shape of the branch line as described above is for the construction of a facility having an appropriate strength according to the tension according to the design load of the facility installed in Jeonju. This is rapidly increasing, and as the population increases, the power supply facilities are also becoming larger.

In other words, the current distribution system in Korea is equipped with a distribution voltage of 22.9kV, but due to the current flow of expansion of the large-capacity distribution supply capacity, research is being conducted to increase the distribution voltage.

For this reason, in the past, the construction of boosting voltage from 110V to 220V was implemented nationwide. At this time, the distribution voltage of Korea was changed from 6.6kV to 22.9kV.

Here, when the distribution voltage is changed, all the equipment necessary for constructing the electric power facility is changed. The electric pole supporting the electric power facility and the branch wire used to support the electric pole and the ground wire used therein are very important.

In addition, in terms of the transition point of the distribution line, all the equipment and other related equipment installed on the electric pole are all derived from the design load, and the facility is installed in consideration of the load capacity within the range that the branch line can overcome the tension of the line so that the electric pole is not damaged. Because of this, if these problems are solved, it will be possible to accumulate and install more power equipment-related equipment on one track.

For example, if there are areas where electric poles are erected on both sides of the road and the distribution lines are used, it means that heavy load facilities on both sides can be accumulated by using only one side of the road if high-strength branch construction is possible. In addition, the installation of large-capacity power lines to expand the power supply capacity as power demand increases, and the power facilities become more abundant at the point where various problems such as damage to the surrounding environment are brought about by the land occupancy and land occupancy. In light of the increasing trend of power facilities, the development of high-strength ground power is urgently needed.

In addition, in the current distribution project, when additional tensions cannot be sustained by one branch line, such as installation of more than two lines of power lines and communication lines, additional branch lines are frequently installed. Since high tension can be given even in construction, it is urgent to develop high-strength ground power because it will be able to cope with the weight of the equipment and the tension of the line according to the distribution facilities and telecommunication line processing facilities that are increased by a single high strength ground power. .

Accordingly, the applicant of the present invention newly manufactured circular branch roots having a diameter of at least 72 cm as shown in Korean Patent No. 0903054, and an excavation unit for embedding the circular branch roots is equipped with a hydraulic expansion drilling screw on the auger crane through hydraulic pressure. The expansion and contraction of the expansion and contraction blades enables the excavation of the ground root buried portion and the ground rod interfering portion to be effectively excavated, and the enlarged circular ground root edge greatly increases the opposing surface area with the landfill soil and improves pull resistance. Excavation process can be mechanized without manual operation by the excavation screw with the hydraulic expansion and contracting blade, so it can be applied to the existing method of circular branch line using manual expander, and it has fast construction time and high quality construction completion. Round branch line and hydraulic expandable features to achieve Hanba complex has proposed a high strength branch geunga construction method using a screw.

However, the ground line construction method as described above is inevitable to weight the ground line roots for the construction, and as a construction method for the construction of the round ground roots, a number of primary excavation and secondary excavation, and expansion excavation for installing the round ground roots By performing the excavation excavation work of the excavation screw over several times, there was a problem of increasing the amount of excavation and hassle in construction.

In addition, the burial soil was buried after the burial of the ground, so that the soil was pulled out to have a pull-out resistance.However, even if the ground was filled after the backfilling, it was disadvantageous in securing the strength of the ground because it could not reach the bearing capacity of the soil. .

The present invention has been made in order to solve the above problems, by forming a long hole-shaped rod insertion hole in the middle of the high-strength ground roots to enable the flow of the ground roots from the ground rods, even in the excavation process for embedding the ground roots Using the first step of excavation of the root insertion part and the expansion and contraction edge of the excavation screw that expands and contracts through hydraulic pressure in the root insertion part, the excavation part is extended and excavated in reverse T-shape. Excavation work is carried out to pick up the excavation hole in the direction to be folded, and the branch line and the branch rod are folded as far as possible so that the rod does not bend using the long slot insert hole. By inserting high strength ground roots, it is possible to reduce the weight of ground roots and to reduce ground excavation. It is possible to simplify the excavation process for construction work. Especially, when the ground wire is buried in the inverse "T" type buried site, both sides of the ground wire are supported on the base surface of the buried ground, so it can have strong pull resistance. An object of the present invention is to provide an inverted T-type excavation high-strength branch construction method using an auger crane hydraulic telescopic drilling rig that enables high-strength support for electric poles having facilities in the electric pole which is weighted. It is.

As a specific means for achieving the above object, the ground near the ground excavation and insertion of ground roots and embedment of earth and sand by an auger-crane-mounted drilling screw having a spiral drilling blade and a spiral screw oozing in the transverse direction by hydraulic pressure In the construction method,

Insertion excavation step of excavating the root portion insertion portion is inserted high-strength branch root using only a screw screw in the state that the expansion and contraction of the drilling screw is reduced;

A buried part excavation step of expanding and digging the buried portion of the buried screw to extend the stretched drilling blade of the digging screw by hydraulic pressure in a state in which the digging screw is not withdrawn after the root portion is inserted;

Ear picking excavation step of excavating the rod withdrawal part by a manpower in a downward slope from the upper end of one side of the root portion inserting state in the state of withdrawing the drilling screw; And

High strength branch roots having branch rods inserted into the long slot inserts, the high strength branch roots are flowed vertically from the branch rods by the rod insertion slots, and then vertically inserted into the excavated root inserts. When located in the buried part, the high-strength branch roots are rotated and flown in the near-floor part, and the high-strength branch roots are inserted into the buried part, and the upper one side is in close contact with the raw surface of the upper part of the near-floor part. It can be achieved by sequentially performing the landfill process of filling the soil generated during the excavation after the rod is seated in the rod withdrawal and withdrawn to the ground.

As described above, the inverted T-type excavation high-strength branch construction method using the present invention Auger-crane hydraulic expansion drilling blade is very high in accordance with the simplification of the excavation process for the ground root construction by reducing the excavation amount of soil by the high-strength branch root that can flow in the excavation section It can bring excellent workability and economic efficiency. Especially, when the ground wire is buried in the inverse "T" type buried site, both sides of the ground wire are firmly supported on the base surface of the buried section, so it has strong pull-out resistance. It is very advantageous to secure, and the high-strength support for the electric pole having facilities in the electric pole to be weighted by this can be obtained.

1 is a perspective view of a high-strength branch root in accordance with the present invention.
Figure 2 is a cross-sectional view of high strength branch roots in accordance with the present invention.
Figure 3 is a close-up insert excavation process diagram according to the present invention.
Figure 4 is a near-floor buried expansion expansion process according to the present invention.
Figure 5 is a picking excavation process diagram of the muscle close insertion portion according to the present invention.
6A and 6C are diagrams illustrating the installation state of high strength branch lines for embedding the high strength branch lines according to the present invention;
Figure 6a is a process chart showing a state in which the high-strength branch root is inserted into the muscle close insertion portion according to the present invention.
Figure 6b is a process chart showing the rotational return state of the indentation and branch line roots in the root portion buried portion through the high-strength branch root value insert portion according to the present invention.
Figure 6c is a process chart showing a state where the high-strength branch root support buried in the buried portion according to the present invention.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

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

1 is a perspective view of a high-strength branch root value in accordance with the present invention, Figure 2 is a cross-sectional view of a high-strength branch root value in accordance with the present invention, Figure 3 is a process diagram of excavation of the root portion insertion according to the present invention, Figure 4 is a muscle value according to the present invention 5 is a process diagram of the buried portion expansion excavation, Figure 5 is a ear picking excavation process diagram of the root portion insertion portion according to the present invention, Figure 6a and Figure 6c is a branch line root installation state diagram for embedding branch line roots according to the present invention.

6A and 6C are diagrams illustrating the installation state of high strength branch lines for embedding the high strength branch lines according to the present invention;

As shown in FIG. 1, the high-strength branch root 100 used in the branch root construction method of the present invention is configured to have a constant length, and a long hole-type rod insertion hole 110 is formed at the center thereof, and the rod insertion hole 110 is The branch rod 120 is inserted and the lower end of the inserted branch rod 120 is configured to be finished by a closing member such as a bolt in order to prevent falling back from the rod insertion hole (110).

That is, the high-strength branch roots 100 are configured in a downwardly inclined type in which both lower portions thereof become gradually narrower, and the rod insertion hole 110 forms a vertical portion 110a from one side from the top as shown in FIG. The side is composed of a rectangular triangular long hole shape that forms an inclined portion (110b) of approximately 45 degrees slope gradually widening from the top to the bottom.

That is, the high-strength branch root 100 is a rotational flow in the inclination angle range of the vertical portion 110a and the inclined portion 110b of the rod insertion hole 110 with the branch rod 120 inserted into the rod insertion hole 110 as an axis. This is possibly configured.

As described above, the high-strength branch root 100 is provided with an auger crane mounting hydraulic drilling screw 200 having elastic drilling blades 220 and 220 'and a spiral screw 210, which are laterally oriented by hydraulic pressure. By excavating the ground where telephone pole was installed by and embedding high strength ground roots

At this time, the high-strength branch root construction process, the insertion part excavation process for excavating the root portion insertion portion 300 that can enter and exit the high-strength branch roots 100, and the root portion buried portion 400 in which the high-strength branch roots 100 are embedded What is necessary is to sequentially perform the burial part excavation process to excavate, the ear picking excavation process to excavate the rod withdrawal unit 500 from the upper end of the muscle value inserting part 300, and the muscle value embedding process.

In detail,

The insertion part excavation process,

As shown in FIG. 3, the high strength branch root 100 is inserted to excavate the root portion inserting part 300, wherein the drilling screw 200 is in a state in which the expansion and contraction blades 220 and 220 'are reduced. Using only the screw 210 of the spiral is excavation of the root portion inserting portion 300 is inserted into the high strength branch root 100.

Then, the buried part excavation process is carried out continuously,

The buried part excavation process,

As shown in FIG. 4, the high-strength branch line is extended after the expansion and contraction blades 220 and 220 'of the drilling screw 200 are hydraulically expanded without the drilling screw 200 being withdrawn from the root portion inserting part 300. It is necessary to expand and excavate the root value embedding part 400 to have an inner diameter larger than the length of 100, and when the root value embedding part 400 is excavated, the root value inserting part 300 and the root embedding part 400 are inverse T-shaped in cross section. The close value insertion unit 300 and the close value embedding part 400 is formed.

At this time, in the expansion excavation process of the buried value buried part 400, the excavation pressure applied to the hydraulic drilling screw 200 is very strong depending on the state of the ground or the geological and gravel layer, the auger crane and the drilling screw 200 In order to prevent the overload is applied, it is desirable to perform the excavation while gradually expanding the expansion and contraction blades 220 and 220 '.

When the excavation of the near-floor buried portion 400 is completed as described above, the expanded expansion and contraction drilling blades 220 and 220 'may be reduced by hydraulic pressure, and the drilling screw 200 may be withdrawn.

Then, the ear picking excavation process is performed,

Ear picking excavation process,

As shown in FIG. 5, the rod extracting part 500 is formed to be inclined downward from the upper end of one side of the root value inserting part 300 in a state in which the drilling screw 200 is withdrawn. When the buried to remove the interference between the insert portion 300 and the branch rod 120.

At this time, the rod withdrawal unit 500 to be excavated is preferably performed by a manpower.

After that, the labor price embedding process is performed,

The process of embedding the strength, the high-strength branch root 100 is inserted into the root portion inserting portion 300, the circular return of the inserted high-strength branch root 100, and the high-strength branch root value 100 to the root embedding portion 400 This is done by installing and backfilling the soil.

At this time, the high strength branch root 100 is inserted, as shown in Figure 6a the first high strength branch root 100 has a length larger than the diameter of the root portion insertion portion 300 is not possible to insert. Thus, the high strength branch root 100 is rotated from the branch rod 120, and then the entire width thereof is reduced to be inserted vertically from the top into the inner side insertion section 300 to be positioned in the root embedding section 400. .

That is, the high-strength branch root 100 is formed with a right-angled triangular rod insertion hole 110 is inserted into the branch rod 120, at this time, the high strength around the branch rod 120 by the rod insertion hole 110 Rotating the branch roots 100 to rotate the inclined portion (110b) of the rod insertion port 110 to form a vertical line with the branch rods 120 to reduce the width of the high strength branch roots 100, the root insert portion 300 ) Can be inserted smoothly.

In addition, the branch rod 120 is inserted at the same time when the high-strength branch root 100 is inserted is the interference is removed when inserted by the rod seating portion 500 excavated when inserted.

Subsequently, the circular return of the high-strength branch roots 100 is performed when the high-strength branch roots 100 enters the muscle burial portion 400 through the muscle inserting unit 300 as shown in FIG. 6B. In contrast to the insertion process of the), the high strength branch roots 100 may be rotated and flown.

That is, the high strength branch root 100 rotates about the branch rod 120 so that the vertical portion 110a of the rod insertion port 110 rotates in a vertical line with the branch rod 120 so that the high strength branch root 100 is rotated. With the expansion of the width, the high-strength branch root 100 and the branch rod 120 is to form a right angle, at this time, the high-strength branch root 100 is back to the root portion inserting portion 300 due to the expansion of the width To be prevented.

Thereafter, the installation of the high-strength branch root 100, the high-strength branch root 100 is rotated together with the branch rod 120 in the root portion buried portion 400, as shown in Figure 6c, the lower high-strength branch root 100 The upper one side of the) is to be supported in close contact with the raw surface of the near-floor buried portion 400, the branch rod 120 is seated in the rod withdrawal part 500 formed by the ear picking excavation process and drawn out to the ground It becomes a state.

Thereafter, the backfill process is usually performed, the backfill process is a high-strength branch by backfilling the soil generated during excavation of the root insert portion 300, the root embed portion 400, the rod withdrawal portion 500 Construction of the muscle 100 is to be finished.

As described above, the inverted T-type excavation high strength branch construction method using the auger crane hydraulic expansion and contraction blade of the present invention can simplify the construction process, and not only the soil excavation amount is reduced, but also the backfill is used even when the light weight of the high strength branch root is small. It is possible to have support for wires and poles that have a heavy weight because it can have a strong pull-out resistance in terms of the support of the soil surface, which is much better than the ground.

100: high strength branch line 110: rod insertion hole
110a: vertical portion 110b: inclined portion
120: branch rod 200: drilling screw
210: screw 220,220 ': telescopic drilling edge
300: muscle value insertion portion 400: muscle value buried portion
500: rod withdrawal unit

Claims (3)

Excavation and insertion of ground roots and burial of the soil by the auger-crane-mounted drilling screw 200 having the elastic drilling blades 220 and 220 'and the spiral screw 210 which are sunk in the transverse direction by hydraulic pressure. In the branch line construction method,
Insertion for excavating the root portion inserting portion 300 into which the high-strength branch root 100 is inserted using only the spiral screw 210 in a state where the expansion and contraction blades 220 and 220 'of the drilling screw 200 are reduced. Secondary excavation process;
After excavation of the root portion insertion portion 300, the expansion and contraction blades 220, 220 'of the excavation screw 200 by hydraulic expansion in the state that does not withdraw the drilling screw 200 than the length of the high strength branch root 100 Buried part excavation process for expanding the excavated buried portion 400 to have a large inner diameter;
Ear picking excavation step of excavating the rod withdrawal part 500 by the manpower in a downward inclined form from the upper end of one side of the root portion insertion portion 300 in the state of withdrawing the excavation screw 200; And
It has a high-strength branch root 100 is inserted into the long branch rod insertion hole 110, the high-strength branch root 100, the high-strength branch root 100 flows from the branch rod 120 in the vertical direction by the rod insertion hole 110 After inserting and vertically inserted into the excavated muscle value insertion unit 300, when the high-strength branch roots 100 are located in the root embedding portion 400, the high-strength branch roots 100 in the root portion buried portion 400 is a rotational flow To be embedded in the root embedding portion 400, and the embedded high-strength branch root 100 is rotated so that the upper one side is in close contact with the raw surface of the upper surface of the root embedding portion 400, and the branch rod 120 draws the rod. Inverted T-type excavation high-strength branch construction method using the auger crane hydraulic expansion-type drilling rig blade, characterized in that to perform sequentially;
The method of claim 1,
Buried excavation process,
Reverse T using an auger crane hydraulic telescopic drilling edge, characterized in that the expansion drilling blades 220, 220 'are gradually expanded to prevent overloading of the telescopic drilling edges 220 and 220'. Excavation high strength branch wire construction method.
The method of claim 1,
High strength branch roots 100,
The lower side is gradually configured to be inclined downward inclined, the rod insertion hole 110,
One side from the top forms a vertical portion (110a), the other side is configured to form an inclined portion (110b) gradually widening from the top to the bottom, branch line rod 120 is inserted into the rod insertion hole 110 of high strength branch roots (110) Inverted T-type excavation high-strength branch construction method using the auger crane hydraulic expansion-type drilling rig blade, characterized in that the rotating flow in the inclined range of the inclined portion (110b) of the rod insertion port (110).

Images