KR930006792B1 - Trench excavator - Google Patents

Abstract

No content.

Description

Groove Excavator

1 is a front view of a first embodiment of the present invention.

2 is a cross-sectional view of the embodiment of FIG. 1 along line A-A of FIG.

3 is an explanatory view showing the shape of the groove hole excavated using the groove hole excavator of the present invention.

4 is a front view showing the general structure of the second embodiment of the present invention.

5 is a front view showing another example of the ring cutter arrangement used in the groove hole excavator of the present invention.

6 is a sectional view showing another power mechanism according to the present invention.

* Explanation of symbols for main parts of the drawings

10: excavator body 14: guide

16: rotation drive source 20: horizontal rotation axis

22: drum cutter 26: link cutter

63: reverse axis 70: excavation residual portion

The present invention relates to a groove hole excavator, in particular a groove hole excavator capable of drilling a groove hole of rectangular cross section suitable for an undergroung diaphragm wall.

The underground continuous wall is used for underground structures that replace caissons, rigid foundations such as high-rise buildings, foundations of tower buildings, and underground tank walls. In order to form such a continuous continuous wall, a groove hole is excavated in the ground while filling a stabilizer such as bentonite sewage using a groove hole excavator. Next, reinforcing bars are erected in the excavated groove holes and concrete is poured from the ground to form a wall of one element. This element is then formed in the ground as a continuous wall as a whole. This continuous wall is called underground continuous wall.

In the past, various groove hole excavators have been proposed that can be used to excavate such underground continuous walls. For example, an excavator for arranging a plurality of vertical shafts in parallel, overlapping cutters differently at the lower end of the vertical shaft, and digging a groove hole has been proposed. However, in the conventional grooved hole excavator having such a resin rotating shaft, since the bit rotates in the horizontal plane, both ends of the grooved hole have an arc shape. In the underground continuous wall method without the use of the locking pipe, the adjacent grooved hole is excavated while excavating the end face of the pre-installed concrete foundation after pouring the concrete.However, since the cutter rotates in a horizontal plane, the excavator itself is shaken and the predetermined shape and position There is a disadvantage in that it can not be excavated exactly in the groove hole.

As can be seen from the above description, the groove hole of the rectangular cross section cannot be excavated in the groove hole excavator provided with the vertical axis of rotation. Therefore, in order to eliminate the disadvantages of the conventional excavator, another type of groove hole excavator having a horizontal axis of rotation and a cutter attached to both ends thereof has been proposed. For example, excavators such as Japanese Utility Model Publication No. 50-2242 in 1975 and Japanese Patent Publication No. 56-4692 in 1981 correspond to this, but the grooved-hole excavator described in these publications is provided at both ends of the horizontal rotating shaft. As the gap between the drum cutters is not cut, the remaining portion remains and the resistance during the excavation is high, and the backflow suction port is formed on the drum cutter upper portion, so that the soiling property is bad and the slime remains at the bottom of the groove hole. Since the drum cutters are arranged on both sides of the support of the horizontal axis of rotation, transmission means for rotating the horizontal axis of rotation should be arranged at the center, and at least the drum spaces of both sides of the support space should be arranged to prevent interference between the support and the drum cutter. In order to narrow the gap between the cutters in order to reduce the excavation residue, the space for the transmission means is narrowed, and sufficient power transmission is not possible, and the strength of the support decreases. A gap corresponding to the space should be installed between the cutters, and thus there is a disadvantage in that a large amount of excavation remains. This excavation residual part is not only able to perform the groove hole excavation itself smoothly, but also because the backflow suction port is located on the top of the drum cutter, the efficiency of soil removal is poor, and the excavation residual part is left, so that slime remains at the bottom of the groove hole. In addition, this groove hole excavator also causes a problem that the space of the support is structurally constrained so that the strength of the support is weakened, and thus a thick wall (e.g., 1.5 to 3.2 m thick) that requires a large digging force. It is not suitable for cutting the groove hole for forming the hole.

The present invention aims to eliminate the drawbacks seen in conventional grooved hole excavators in light of this situation. Accordingly, it is a main object of the present invention to provide groove hole cutting capable of forming underground continuous walls having the required strength without leaving excavation residual portions.

According to the present invention, in order to achieve the above object, between a suspension excavator body, a pair of drum cutters having a set clearance in the lower part of the body coaxially and at the same time having a horizontal axis of rotation, and a pair of drum cutters In a groove hole excavator having a ring cutter disposed and a rotation driving source for rotating the pair of drum cutters and the ring cutter, the pair of drum cutters and the ring cutters disposed therebetween form a unit. A groove hole excavator is provided in which a plurality of said units are arranged in parallel with each other at a lower portion of the excavator body.

The present invention will be described in more detail below with reference to the accompanying drawings showing a preferred embodiment of a grooved hole excavator according to the present invention.

First, referring to FIG. 1, the excavator body 10 is configured to be suspended downward from the ground via the lobe 12. A plurality of guides 14 are provided in the up and down direction on the front and side surfaces of the excavator body 10. The excavator main body 10 is equipped with a rotation drive source 16 such as an electric motor or a hydraulic motor. The rotary drive source 16 is a sealed electric motor or the like that can be used underwater.

As shown in FIG. 2, the gear case 18 is formed in the lower part of the excavator main body 10, and the gear case 18 is provided with the horizontal rotating shaft 20 so that pivoting is possible. The horizontal rotating shaft 20 is fixed to a drum type cutter (hereinafter referred to as drum cutter) 22. The drum cutter 22 is formed to a size that can accommodate the gear case 18 therein. The drum cutter 22 has a cutting blade 24 formed on its outer circumferential surface. The drum cutters 22 are arranged at regular intervals as shown in FIG. 2, and in the space formed thereon, a gear case 18a for connecting the gear case 18 and the gear body side gear case to be described later is provided. Will be deployed. The gear case 18 is pivotally mounted with a horizontal rotating shaft 28 of a ring-shaped cutter 26 (hereinafter referred to as a link cutter). A cutting blade 27 is formed on the outer circumference of the ring cutter 26 similarly to the drum cutter 22. It is. The link cutter 26 is formed with a diameter smaller than that of the drum cutter 22, and the horizontal axis of rotation 28, which is its central axis, is eccentrically disposed. That is, as shown in FIG. 1, the horizontal cutting shaft 28 is eccentrically arranged so that the side and bottom of the drum cutter 22 are substantially flush with the side and bottom of the ring cutter 26. As shown in FIG.

As shown in FIG. 2, the gear case 30 of the main body 10 side is provided at the upper portion of the gear case 18A, and the gear cases 30, 18A, 18 are supplied with power from the rotation drive source 16. As shown in FIG. The reduction gear group for transmission is arrange | positioned. That is, a gear 34 is disposed on the output shaft 32 of the rotation drive source 16, and power is transmitted from the gear 34 to the gears 36, 38, 40, 42, 44 arranged in the gear case 30. do. The rotational force of the gear 44 is transmitted to the gear 50 arranged in the gear case 18 via the gears 46 and 48 arranged in the gear case 18A. The rotational force of the gear 50 is divided into gears 54 and 55 provided on both sides of the horizontal rotating shaft 52 and transmitted to the drum cutters 22 on both sides, that is, the rotational force of the gears 54 and 55 is the intermediate gear 56. It is transmitted to the gear 58 of the horizontal rotating shaft 20 via, and rotates the horizontal rotating shaft 20 to rotate the drum cutter (22). In addition, the gear 58 on the left side meshes with the gear 60 fixed to the horizontal rotation shaft 28 via the intermediate gear 59 to rotate the ring cutter 26.

The pair of drum cutters 22 and the ring cutters 26 disposed therebetween are thus arranged in parallel in two units as shown in FIG. 1. When two units are arranged in parallel, the ring cutter 26 has a smaller diameter than the drum cutter 22, so that a large gap is formed on the opposing surface of the unit, and this gap has a bit ( 62) can be arranged. The bite 62 is provided at the lower end of the reverse shaft 63 and is disposed between the ring cutters. The reverse shaft 63 may rotate the bite 62 via the power transmission mechanism 63A branched from the gear transmission means for connecting the rotation drive source 16 and the drum cutter 22. Through the inside of the reverse shaft 63 of the excavation residue by the drum cutter 22, the link cutter 26, and the bite 62, the ground is discharged to the ground. It may be used and a rotation drive source dedicated to reverse shafts may be provided.

The operation of the embodiment of the groove hole excavator according to the present invention configured as described above is as follows. First, the rotational force from the rotation drive source 16 is transmitted to the drum cutter 22 and the ring cutter 26 via the power transmission mechanism in the gear cases 30, 18A and 18. In this case, as shown in FIG. 1, the drum cutters 22 and the ring cutters 26 of the left and right units are rotated so that their rotation directions are opposite to each other, and are configured to cancel excavation reaction torques. When the excavator main body 10 descends downward in this state, a rectangular drilling hole is formed in the ground.

3 shows a schematic shape of a drilling hole excavated using a groove hole excavator according to the present invention. As shown in FIG. 3, the side surface 66 'of the excavation hole 64 is smoothly formed because the side surfaces of the drum cutter 22 and the link cutter 26 are substantially flush with each other. Also in 68, since the drum cutter 22 and the ring cutter 26 are arrange | positioned so that it may become substantially the same plane, the bottom face of the drilling hole 64 is also formed so that it may become substantially the same surface. In addition, since the bite 62 is arrange | positioned as mentioned above, the excavation remainder 70 formed in the center part of the excavation hole 64 is excavated by this bite 62, and the slime is reversely retracted by a suction pump etc. Through 63 it is discharged to the ground.

In the above embodiment, one bite 62 is provided between the units. However, two bites 62 may be provided and the excavation recoil torque of the bite 62 may be offset by rotating in the opposite direction to each other. That is, as shown in FIG. 4, the byte axis 64 'may be provided on both sides of the reverse axis 63, and the bite 62 may be provided in the lower end of each byte axis 64'. In addition, in the embodiment shown in FIG. 4, the rotation drive source 66 dedicated to the said bite 62 is provided. In addition, each guide 14 is provided with a 14A adjustable forward and backward guide. The adjustable guides 14A may be provided two at the top and bottom of the four sides around the excavator.

In the embodiment shown in FIG. 5, another transmission mechanism is shown. As shown in FIG. 5 and FIG. 6, the drum cutter 22 is attached to the horizontal rotating shaft 28, and the ring cutter 26 is arrange | positioned so that the shaft may be above the horizontal rotating shaft 28. As shown in FIG. Therefore, a space portion is formed in the portion of the link cutter 26, which is biased upward from the drum cutter 22, as shown in FIG. 6, and rotates in the ring cutter 26 and the drum cutter 22 using this space portion. The rotational force from the drive source 16 is transmitted.

Next, a power transmission mechanism for transmitting the same distance from the rotation drive source 16 to the drum cutter 22 and the ring cutter 26 will be described. As shown in FIG. 6, first, the rotational force from the rotation drive source 16 rotates the horizontal rotation shaft 32 via the reduction gear group 30 '. The horizontal rotating shaft 32 is located in the ring cutter 26 from a space formed above the ring cutter 26, and the gear 34 installed on the horizontal rotating shaft 32 is an inner gear formed on the inner circumferential surface of the ring cutter 26. 36). Therefore, the rotational force of the rotation drive source 16 can rotate the ring cutter 26 via the reduction gear group 30 ', the horizontal rotation shaft 32, and the gear 34. In addition, since the gear 34 of the horizontal rotating shaft 32 meshes with the gear 46 of the horizontal rotating shaft 44 ', the horizontal rotating shaft 44' is thereby rotated. The gear 48 is provided in the horizontal rotating shaft 44 ', which meshes with the gear 50 fixed to the horizontal rotating shaft 28 of the drum cutter 22. As shown in FIG. Therefore, the power from the rotation drive source 16 is transmitted to the drum cutter 22 via the reduction gear group 30 ', the gear 46, and the gears 48 and 50.

The pair of drum cutters 22 and the ring cutters 26 disposed between the drum cutters 22, which are transmitted in this manner, are arranged in two units in parallel as shown in FIG.

The groove hole excavator according to the present invention configured as described above has the same operation and effect as the embodiment shown in FIG.

In addition, in the embodiment shown in FIGS. 5 and 6, the link cutter 26 is formed to have a diameter slightly smaller than the diameter of the drum cutter 22, but may be formed to the same diameter as the diameter of the drum cutter 22. FIG. .

As described above, according to the groove-hole excavator according to the present invention, since the cutter is provided on the horizontal rotating shaft, a rectangular groove can be formed, and the pre-arranged concrete cross section can be easily excavated. In addition, the grooved hole excavator according to the present invention arranges a pair of drum cutters at a predetermined interval on the horizontal rotating shaft, and also arranges a ring cutter between the drum cutters, and transmits the rotational force from the rotation drive source to the drum cutters and the ring cutters, Since the cutter is excavated by a link cutter, the excavation residual portion conventionally generated does not occur.

In addition, since the link cutter is provided between the drum cutters, it is possible to provide a lot of space for the supporting member, so that a wall hole with a thick hole is possible, and at the same time, the backflow inlet can be placed close to the bottom of the hole, so that the backing effect can be increased. Can be formed.

However, it should be recognized that the present invention is not limited to the above-described special forms, and that the present invention includes all changeable embodiments, structures, etc., which fall within the scope and spirit of the present invention as set forth in the claims below.

Claims (6)

Downward-suspendable excavator body 10, a pair of rotary drive source mounted to the excavator body 10 and the lower portion of the excavator body 10 coaxially disposed at a predetermined interval from each other and having a horizontal axis of rotation 20 Cylindrical ring cutter 26 disposed between the pair of drum cutters 22 and having a drum cutter 22 and a horizontal axis of rotation 28 eccentrically disposed downwardly in parallel with the horizontal axis of rotation 20 of the drum cutter. And a power transmission mechanism (63A) for transmitting power from the rotation drive source (16) by a space formed between opposing surfaces of the pair of drum cutters (22), wherein the drum cutter ( The pair of pairs 22) and the link cutter 26 disposed therebetween form one unit, and a plurality of such units are arranged in parallel to each other in the lower part of the excavator body 10 and in a space formed between the units. Is provided with a reverse axis (63) , The groove hole diggers, characterized in that the two side portions, the pair of bytes including a byte axis 62 in a lower portion of each of the reverse shaft 63 is provided. 2. The grooved hole excavator of claim 1, wherein a diameter of the link cutter (26) is smaller than a diameter of the pair of drum cutters (22). 2. The grooved hole excavator according to claim 1, wherein the rotary drive source (16) is an electric motor operable in water. 2. The grooved hole excavator according to claim 1, wherein said rotary drive source (16) is a hydraulic motor operable in water. A pair having a downwardly suspending excavator body 10, a rotary drive source 16 mounted to the excavator body 10, and a coaxially arranged coaxially arranged at a lower portion of the excavator body 10 and having a horizontal axis of rotation 20. Cylindrical ring cutter 22 having a drum cutter 22 and a horizontal rotating shaft 28 eccentrically disposed downwardly parallel to the horizontal rotating shaft 20 of the drum cutter 22. 26. A groove hole excavator having a power transmission mechanism (63A) for transmitting power from the rotary drive source (16) by a space formed between opposing surfaces of the pair of drum cutters (22). The pair of cutters 22 and the link cutters 26 disposed therebetween form one unit, and a plurality of such units are disposed in parallel to each other at the bottom of the excavator body 10, and formed between the units. With bytes 62 in space Groove hole diggers, characterized in that the front barrel 63 is provided. A pair having a downwardly suspending excavator body 10, a rotary drive source 16 mounted to the excavator body 10, and a coaxially arranged coaxially arranged at a lower portion of the excavator body 10 and having a horizontal axis of rotation 20. Cylindrical ring cutter 22 having a drum cutter 22 and a horizontal rotating shaft 28 eccentrically disposed downwardly parallel to the horizontal rotating shaft 20 of the drum cutter 22. 26 and a groove provided with a power transmission mechanism 63A for transmitting power from the rotation drive source 16 to the ring cutter 26 and the drum cutter 22 through the space in the ring cutter 26. In a hole excavator, the pair of drum cutters 22 and the ring cutters 26 engraved therebetween form one unit, and a plurality of such units are arranged in parallel with each other under the excavator body 10. In the space formed between the unit Groove hole diggers, characterized in that the reversing shaft (63) having a root (62) is provided.

Images