KR20200067323A - Drum cutter - Google Patents

Abstract

According to the present invention, a surface grinder capable of improving work efficiency comprises: an arm connection portion which has connection bars for connection to an arm of an excavator, and in which a pair of support frames connected by the connection bars is coupled to a disk block; a cutting body having a support block coupled in contact with the disk block of the arm connection portion and a side wall block connected to the support block; a hydraulic drum cutter having a hydraulic motor installed on the side wall block of the cutting body, and having protrusion cutters for surface grinding, which are installed to rotate by the hydraulic motor and provided on the outer circumferential surface thereof; and a main coupling portion which penetrates and couples the disk block of the arm connection portion and the center part of the support block of the cutting body, and allows rotation of the cutting body with respect to the arm connection portion. The disk block and the support block are rotated relatively by the main coupling portion to allow the hydraulic drum cutter to rotate on the center line of the main coupling portion.

Description

Grinding Machine {DRUM CUTTER}

The present invention relates to a chamfering machine, and more particularly, to a chamfering machine used in connection with an arm of an excavator.

In a chamfering machine or drum cutter, cutters for cutting solids such as walls and ground are projected on the drum-shaped cutter body. These chamfering machines are mainly used as attachments detachable to hydraulically operated excavators.

The chamfering machine is installed and used on the arm connected to the excavator's boom. These grinders are used as effective alternatives to hydraulic breakers or bucketing in profiling, trenching, crushing, masonry and demolition.

As such, the chamfering machine is also used for excavation of narrow roads for the laying of pipelines, for wall excavation of tunnels and underground construction, and for leveling of the ground or demolition of building walls.

However, since the existing chamfering machine is installed on the arm of the excavator in the same way as a bucket, the chamfering position is limited according to the rotation angle and the arrangement of the excavator by the operation of the boom and the arm, so the excavation work is performed in response to the moving aspect or arrangement of the excavator. Difficult, due to the large impact due to the front arrangement of the excavator, there was a disadvantage of failure.

The present invention is to provide a chamfering machine capable of increasing work efficiency and flexibility by being appropriately arranged in a work area in response to various aspects or arrangements of the excavator, in addition to the frontal operation of the excavator, and attenuating shock to reduce failure.

The chamfering machine according to the present invention, in the chamfering machine installed on the arm of the excavator, is provided with connecting bars for connecting to the arm of the excavator, a pair of support frames connected by the connecting bars coupled to the disc block Female connection; A cutting body having a support block that is brought into contact with and coupled to a disk block of the arm connection part and a side wall block connected to the support block; A hydraulic drum cutter having a hydraulic motor installed on a sidewall block of the cutting body, and having protrusion cutters for chamfering installed to rotate by the hydraulic motor; And a main coupling portion that penetrates through the central portion of the support block of the cutting body and the disc block of the arm connection portion, and allows the rotation of the cutting body relative to the arm connection portion, wherein the disc block and the support block are the main portion. The relative rotation by the engaging portion allows the hydraulic drum cutter to rotate on the center line of the main engaging portion.

The main coupling portion is disposed on the bottom surface of the support block through the disc block and a main shaft provided with a screw portion for screwing thereon; And a plurality of screw blocks coupled to the threaded portion of the main shaft, a circular slip bearing portion is provided on an upper portion of the disc block, and a rotational coupling portion is installed under one of the plurality of screw blocks, and the rotational coupling is provided. A circular slip groove portion rotatably coupled to the slip bearing portion may be provided in the portion.

A first slip ring is provided on the disk block to block the inflow of foreign substances toward the slip bearing portion and the rotational coupling portion, and the first slip ring may be disposed while surrounding the upper portion of the rotation coupling portion.

The slip bearing portion, an annular block installed in a circle on the disk; And a protruding bearing male and female coupled to the circular slip groove of the rotational engagement portion at the lower inner circumferential wall of the annular block, and the upper inner wall portion of the annular block may be disposed to extend adjacent to the rotational engagement portion.

The protruding bearing includes: a base portion connected to the annular block; And a bearing member protruding from the base portion, wherein the bearing member has a shape protruding obliquely toward the inner wall portion of the rotational engagement portion, wherein an upper surface portion and a lower surface portion have the same slope, and an inner wall portion facing the rotational engagement portion is from the top. It may have a shape inclined adjacent to the side of the rotation coupling portion downward.

The upper and lower portions of the bearing member are provided with protruding protruding plates, and the protruding member can crush foreign substances introduced into the slip bearing portion.

A second slip ring is disposed between the original block and the support block, and the second slip ring may surround a lower portion of the original block.

A circular support plate that is supported and coupled to the bottom surface of the support block is provided below the main shaft, and an insertion coupling member that is inserted into and coupled to the support block may be provided on the circular support plate.

The hydraulic cutter drum includes: a drum body in which the hydraulic motor is inserted and disposed; And

Located inside the drum body, including a drum plate coupled to the drive shaft of the hydraulic motor, the projection cutter may be inclined in one direction with respect to the circumferential direction of the drum body.

The present invention described above, as well as the front surface of the excavator is arranged in a suitable working area in response to various aspects or arrangements of the excavator can increase the working efficiency and flexibility and reduce the failure by preventing the impact to reduce the failure Can provide.

1 is a schematic three-dimensional view of a chamfering machine according to an embodiment of the present invention,
Figure 2 is a rear perspective view of Figure 1,
Figure 3 is a right side view of Figure 2,
Figure 4 is a left side view of Figure 2,
5 is a state diagram of the use of the chamfering machine according to an embodiment of the present invention,
6 is a front view of a chamfering machine according to an embodiment of the present invention,
Figure 7 is a right side view of Figure 6,
8 is a plan view of FIG. 6.

Hereinafter, various embodiments of the present invention will be described by specific embodiments illustrated in the accompanying drawings. Differences in the embodiments are not mutually exclusive and should be understood in a complex drawing, without departing from the spirit and scope of the present invention, specific shapes, structures, and properties described in connection with the embodiments are implemented in other embodiments Can be.

The position or arrangement of individual components according to embodiments of the present invention should be understood as a combination of drawings as being changeable, and similar reference numerals in the drawings may indicate the same or similar functions across various aspects, length and area, thickness The specific shape of the lamp may be exaggerated for convenience in description.

Each unit, module, part, member, or any structure in which the sub-elements are not described is assumed to include or include conventional sub-elements for each having a given function, and is limited to the sub-elements or detailed structures shown in the drawings. I don't. Components shown, but whose description is omitted in the general content, should be understood as inherent in the detailed description of the embodiments.

Among various embodiments of the present invention, the practical implementability is high, and the chamfering machine according to one embodiment having high industrial availability is mainly intended to increase the efficiency and flexibility of the working position.

Hereinafter, main components of the chamfering machine according to an embodiment of the present invention will be described based on the drawings.

1 is a schematic three-dimensional view of a chamfering machine according to an embodiment of the present invention, FIG. 2 is a rear three-dimensional view of FIG. 1, FIG. 3 is a right side view of FIG. 2, and FIG. 4 is a left side view of FIG. 2, 5 is a state diagram of the use of the chamfering machine according to an embodiment of the present invention.

Referring to Figures 1 to 5, the chamfer according to an embodiment of the present invention is installed on the end connected to the arm 100 of the excavator, is operated by receiving the hydraulic power of the excavator, the arm of the excavator ( It is possible to perform a rotary excavation operation of a work object within a range of 100).

The chamfering machine is installed on the arm connecting portion 110 connected to the arm 100 of the excavator, the cutting body 130 rotatably coupled to the arm connecting portion 110, and the cutting body 130 to perform rotational excavation by hydraulic operation. It includes a drum cutter to perform, and the main coupling unit 150 to mutually engage while allowing rotation of the drum cutter and the cutting body 130.

The arm connection portion 110 includes connection bars 112 for connecting to the arm 100 of the excavator, and a pair of support frames 111 connected by connection bars 112 are mounted on the disc block 113 It is bound to. The pair of support frames 111 are plate-like members having a thickness, which are mutually coupled by connecting bars 112 of a certain diameter, and are welded to the disc block 113.

A support bar 114 and a buffer spring 115 are disposed on an upper surface of the disk block 113. The support bar 114 supports the shock transmitted from the cutting body 130 to be described later, and the shock absorbing spring 115 serves to cushion the shock.

The connection bar 112 is connected to a plurality of connection portions each having a circular groove in the end portion of the arm 100 of the excavator. Accordingly, a chamfering machine is installed in the excavator.

The cutting body 130 is rotatably coupled to the disc block 113 of the arm connection portion 110.

The cutting body 130 is provided with a support block 131 connected to the disc block 113 of the arm connection portion 110 and a connected side wall block 132 of the support block 131. The support block 131 has a shape corresponding to the disk block 113, and forms a structure such as a sidewall block 132 and "a".

A hydraulic drum cutter 140 for rotary excavation is installed on the side wall block 132 of the cutting body 130.

The hydraulic drum cutter 140 includes a hydraulic motor 143 installed on the side wall block 132 of the cutting body 130, and a projection cutter 145 for chamfering to be rotationally operated by the hydraulic motor 143. These are prepared on the outer periphery.

The hydraulic motor 143 is connected to the excavator and the hydraulic line 147 to operate to rotate the cutter drum, which will be described later, and the projection cutters 145 may perform rotational excavation while rotating together with the cutter drum.

The hydraulic cutter drum includes a drum body 141 in which a hydraulic motor 143 is inserted and disposed, and a drum plate 142 located inside the drum body 141 and coupled to a drive shaft of the hydraulic motor 143. . One side of the hydraulic motor 143 is fixed to the side wall block 132, the drum plate 142 of the drum body 141 is coupled to the plate connected to the drive shaft of the hydraulic motor 143.

The protrusion cutter 145 may be inclined in one direction with respect to the circumferential direction of the drum body 141. The projection cutter 145 is rotated toward the inclined direction, so that excavation can be more certainly performed with respect to the working area. The protrusion cutter 145 may be provided with ultra-high carbon steel or industrial diamond with protrusions in contact with a work object.

The main coupling part 150 penetrates through the central portion of the disc block 113 of the female connection portion 110 and the support block 131 of the cutting body 130, and the cutting body 130 is provided with respect to the female connection portion 110. Is to allow rotation. Accordingly, the disk block 113 and the support block 131 are allowed to rotate relative to each other by the main coupling part 150, thereby allowing the hydraulic drum cutter 140 to line the center of the main coupling part 150 according to the excavation pattern of the work object. It can be rotated smoothly in the phase.

6 is a front view of a chamfering machine according to an embodiment of the present invention, FIG. 7 is a right side view of FIG. 6, and FIG. 8 is a plan view of FIG. 6.

6 to 8, the main coupling part 150 is disposed through the disk block 113 at the bottom of the support block 131 and is provided with a screw part 154 for screwing thereon. It includes a shaft 151 and a plurality of screw blocks 152 and 153 coupled to the threaded portion 154 of the main shaft 151. The main shaft 151 penetrates the support block 131 of the cutting body 130 and is coupled to the plurality of screw blocks 152 and 153 at the upper surface of the disc block 113.

The main shaft 151 is allowed to rotate by the slip bearing unit 120 and the rotation coupling unit 160. A circular slip bearing unit 120 is provided on an upper portion of the disk block 113, and a rotation coupling unit 160 is installed on one of the lower screw blocks 153 of the plurality of screw blocks 152 and 153. A circular slip groove portion 161 rotatably coupled to the slip bearing portion 120 may be provided at the rotation coupling portion 160.

The slip bearing part 120 is supported by a male and female structure in a rotational engagement fitted to the main shaft 151, and forms a bearing structure surrounding the main shaft 151 together with the circular slip groove 161 of the rotational coupling part 160. .

The rotation coupling part 160 has a structure like a "a" with a flange at the top, and another flange is slightly protruded at the bottom to provide a circular slip groove 161.

The slip bearing part 120 is a protruding bearing that is male and female coupled to the circular slip groove part 161 of the rotary coupling part 160 at the lower inner circumferential wall of the annular block 121 and the annular block 121 installed circularly on the disk. (122).

The upper inner wall portion of the annular block 121 may be disposed to extend adjacent to the rotation coupling portion 160 side. Since the upper inner wall portion of the annular block 121 is extended, it is possible to block intrusion of dust or foreign substances generated in the working area toward the protruding bearing 122 at the lower portion.

The protruding bearing 122 includes a base 123 connected to the annular block 121, and a bearing member 124 protruding from the base 123.

The bearing member 124 is a shape protruding obliquely toward the inner wall portion of the rotary coupling portion 160, and the upper surface portion and the lower surface portion form the same inclination, and the inner wall portion facing the rotary coupling portion 160 rotates from top to bottom It may have a shape inclined adjacent to the (160) side.

The bearing member 124 is disposed in correspondence with a structure such as an "a" with an upper flange of the rotation coupling portion 160 at the upper end of the inclined aspect.

On the upper and lower surfaces of the bearing member 124, a protruding protruding plate 125 is provided, and the protruding member can crush foreign substances introduced into the slip bearing part 120.

When the intrusion material is accumulated between the annular block 121 and the upper portion of the rotation coupling part 160, it hardens or increases friction. The protruding plate 125 can prevent the intrusion by breaking the hardened state of the intrusion material or by rotating it relative to the rotation coupling part 160 to bounce out the intrusion material and discharge it.

A first slip ring 171 is provided on the disk block 113 to block the inflow of foreign substances toward the slip bearing unit 120 and the rotation coupling unit 160, and the first slip ring 171 is a rotation coupling unit ( 160) may be disposed while surrounding the upper portion. The first slip ring 171 blocks the intrusion of foreign substances between the slip bearing portion 120 and the upper gap of the rotation coupling portion 160.

The second slip ring 172 is disposed between the original block 113 and the support block 131, and the second slip ring 172 may surround the lower portion of the original block 113. The second slip ring 172 makes a smooth rotation of the disc block 113 and the support block 131, and blocks the intrusion of foreign substances between the gaps.

On the other hand, the lower portion of the main shaft 151 is provided with a circular support plate 155 that is supported and coupled to the bottom surface of the support block 131, and on the circular support plate 155 is inserted into the support block 131 to be inserted and coupled The member 156 may be provided.

The main shaft 151 is supported by a circular support plate 155 on the bottom surface of the support block 131, and the insertion coupling member 156 is inserted into the support block 131 to rotate to the support block 131 laterally when rotated. Can be supported.

Hereinafter, the operation state of the chamfering machine according to an embodiment of the present invention will be described in detail.

1 to 5, the chamfering machine according to an embodiment of the present invention is located in the working area in a state installed in the arm 100 of the excavator and moves with the excavator or moves the working area according to the operation of the arm You can proceed with rotary excavation.

Since the hydraulic drum cutter 140 of the cutting body 130 is installed on the cutting body 130, it is possible to rotate with respect to the disc block 113 of the arm connection portion 110 together with the cutting body 130.

The working area can be inclined to the side or various curved surfaces. The drum main body 141 of the hydraulic drum cutter 140 is brought into contact with the working area, and the projection cutter 145 is in contact with the working area.

The drum body 141 is pressurized to the working area by the arm 100 of the excavator, and is rotated by the hydraulic motor 143 on the side wall block 132 of the cutting body 130 to perform rotary excavation for the working area. Will proceed.

In this rotational excavation operation, the surface portion of the work area is not constant, but the yaw rotation by the main shaft 151 intersecting with respect to the rolling rotation of the drum body 141 is allowed, so that the drum body 141 is rotated left and right to work area. It can be arranged corresponding to the shape of the smooth rotation excavation can proceed.

In the above, if the rotation of the hydraulic motor 143 with respect to the center line of the drive shaft is a rolling rotation, the rotation with respect to the center line of the main shaft 151 may be a yaw rotation.

As described above, according to an embodiment of the present invention, the hydraulic drum cutter 140 is disposed to be suitable for a work area in response to various aspects or arrangements of the excavator, in addition to the frontal operation of the excavator, thereby increasing work efficiency and flexibility and impact. It is possible to provide a chamfering machine that can prevent and reduce the failure.

As described above, the embodiments of the present invention have been described, but on the basis of this, those skilled in the art can add or change the components within the scope not departing from the essential technical spirit of the present invention described in the claims. , The present invention may be variously modified and changed by deletion, addition, or the like, and this is also included within the scope of the present invention.

100: excavator arm 110: arm connection
111: support frame 112: connecting bar
113: Disc block 114: Support bar
115: buffer spring 120: slip bearing
121: annular block 122: protruding bearing
123: base 124: bearing member
125: projecting plate
130: cutting body 131: support block
132: side wall block 140: hydraulic drum cutter
141: drum body 142: drum plate
143: hydraulic motor 145: turning cutter
147: hydraulic line
150: main coupling 151: main shaft
152, 153: screw block 155: circular support plate
156: insertion coupling member 160: rotation coupling
161: circular slip groove 171: first slip ring
172: second slip ring

Claims (9)

In the surface machine installed on the arm of the excavator,
An arm connecting portion provided with connecting bars for connecting to the arm of the excavator, wherein a pair of support frames connected by the connecting bars are coupled on the disk block;
A cutting body having a support block that is brought into contact with and coupled to a disk block of the arm connection portion and a side wall block connected to the support block;
A hydraulic drum cutter having a hydraulic motor installed on a sidewall block of the cutting body, and having protrusion cutters for chamfering installed to rotate by the hydraulic motor; And
The arm connecting portion of the original block and the cutting body through the center portion of the support block through the coupling, the arm connecting portion includes a main coupling portion that allows the rotation of the cutting body,
The disk block and the support block are relatively rotated by the main coupling portion, so that the hydraulic drum cutter is allowed to rotate on the center line of the main coupling portion. According to claim 1,
The main coupling portion is disposed on the bottom surface of the support block through the disc block and a main shaft provided with a screw portion for screwing thereon; And
It includes a plurality of screw blocks coupled to the screw portion of the main shaft,
A circular slip bearing portion is provided on an upper portion of the disk block, and a rotation coupling portion is installed on one lower portion of the plurality of screw blocks,
The rotary coupling part is provided with a circular slip groove portion that is rotatably coupled to the slip bearing portion. According to claim 2,
A first slip ring is provided on the disk block to block the inflow of foreign substances to the slip bearing portion and the rotational coupling portion,
The first slip ring is a chamfer that is disposed while surrounding the upper portion of the rotating coupling. According to claim 2,
The slip bearing portion,
An annular block installed in a circle on the disc; And
It includes a protruding bearing male and female coupled to the circular slip groove portion of the rotary coupling portion in the lower inner peripheral wall of the annular block;
The chamfering machine is disposed to extend adjacent to the upper inner wall portion of the annular block toward the rotation coupling portion. According to claim 4,
The protruding bearing,
A base portion connected to the annular block; And
It includes a bearing member protruding from the base,
The bearing member has a shape protruding obliquely toward the inner wall portion of the rotating coupling portion, and the upper surface portion and the lower surface portion have the same slope, and the inner wall portion facing the rotating coupling portion is inclined adjacent to the rotating coupling portion from top to bottom. A chamfer with a shape. The method of claim 5,
The protruding plate member is provided on the upper and lower surfaces of the bearing member,
The protruding member is a chamfering machine comprising crushing foreign substances introduced into the slip bearing portion. The method according to any one of claims 3 to 6,
A second slip ring is disposed between the original block and the support block,
The second slip ring is a chamfering machine surrounding the lower portion of the disk block. According to claim 2,
A lower surface of the main shaft is provided with a circular support plate that is supported and coupled to the bottom surface of the support block, and on the circular support plate is provided a surface inserter that is inserted into and coupled to the support block. According to claim 1,
The hydraulic cutter drum,
A drum body in which the hydraulic motor is inserted and disposed; And
Located inside the drum body, and includes a drum plate coupled to the drive shaft of the hydraulic motor,
The protruding cutter is a chamfering machine that is inclined in one direction with respect to the circumferential direction of the drum body.

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