KR20220001594A - Rock crushing apparatus for excavation - Google Patents

Abstract

In accordance with the present invention, disclosed is a bedrock crushing apparatus for excavation, which can be detachably mounted on construction heavy machinery such as an excavator, and can be provided with an adjustment function and a buffer function of a wedge part to considerably improve working efficiency. In accordance with the present invention, the bedrock crushing apparatus for excavation, which is mounted on construction heavy machinery to crush bedrock, includes: a mount part including a mount pin to be mounted on the construction heavy machinery; a base part connected to the mount part through a tilting cylinder and a tilting connection part; and a crushing part mounted in a lower part of the base part to crush the bedrock. The base part comprises: an upper base connected to the mount part; and a lower base mounted on the upper base to be rotatable around a rotary shaft within a predetermined radius. The lower base also includes at least one vertical buffer member installed to be stood vertically on each of both sides with respect to the rotary shaft.

Description

Rock crusher for excavation {ROCK CRUSHING APPARATUS FOR EXCAVATION}

The present invention relates to a rock crushing device for excavation, and more particularly, to a rock crushing device for excavation that can be installed and used in the middle of construction.

In general, in various civil works such as road construction or tunnel construction in mountainous terrain or downtown areas, various types of rocks protrude and act as an obstacle to the work. Also, in the prior art, various rock crushing methods have been applied to remove such rocks. For example, a method of forming a number of blast holes on the rock using a crawler drill, etc. and inserting an explosive into these blast holes to blast, or a method of continuously hitting and crushing a part of the rock using a separate breaker is being used

This method causes considerable noise and vibration not only in the work place but also in the surrounding environment. In particular, the generated vibration causes cracks in the surrounding buildings or rock walls, or the collapse of buildings or the ground, and also causes civil complaints about the generated noise. There are also problems such as non-stop.

Recently, due to these problems, a method using a non-vibration rock crusher, which is excellent in reducing noise and vibration, is gradually spreading.

When briefly explaining the rock excavation work using the conventional vibration-free rock crusher as follows. First, an insertion hole is drilled in the rock face using a drilling machine, and the crushing blade of the non-vibration rock crusher is inserted into the insertion hole, and then the vibration-free rock crusher is driven to crush the rock. Next, a heavy construction machine such as a fork crane equipped with a breaker on the boom enters and re-crushes the crushed rock. The re-fragmented rock is then excavated with construction equipment that replaces the breaker with a bucket or with a separate construction heavy machine equipped with a bucket mounted on a boom, and a series of operations of loading and unloading in a dump truck are performed continuously, and through this, the rock excavation is performed. work will be done

That is, the sequence of the rock excavation work in general civil engineering work includes the steps of drilling an insertion hole by a drilling equipment; Crushing the rock by inserting a vibration-free rock crusher into the insertion hole; Re-crushing and collecting the crushed rock; And it consists in the order of the step of taking out the collected bedrock.

More specifically, the drilling equipment enters the front of the rock to be crushed and performs the drilling operation. Next, after the drilling equipment is completely withdrawn, a heavy construction machine equipped with a non-vibration rock crusher enters and performs rock crushing work. Next, the heavy construction machinery withdraws and the heavy construction machinery (excavator) equipped with a breaker enters. The excavator re-crushes the crushed rock to a size that can be loaded into a dump truck, etc. using a breaker equipped with it. Next, the breaker mounted on the excavator is replaced with a bucket and mounted, and the re-crushed rock is collected and loaded into a dump truck waiting at the rear. Next, the excavator after completing the work withdraws and the drilling equipment enters again. By repeating such a work process, the rock excavation work is made.

As described above, in order to perform a rock excavation work in an environment with a narrow working space such as a tunnel, it is inevitable to repeat the process of withdrawing and entering the construction equipment at each process step. However, it is self-evident that as the number of shifts of such equipment increases, the construction period becomes longer and work efficiency decreases. Moreover, as the rock excavation work progresses, withdrawal and entry distances increase for each shift of equipment, which increases the time required for shifting equipment.

Referring to FIG. 1 , the conventional vibration-free rock crusher includes a binding part 10 connected to a boom in the middle of construction and a fixing pin by a fixing pin, is coupled to the binding part 10 and receives rotational force from the driving motor 21 in the horizontal direction. a rotating part 20 that rotates; A forward and backward transfer unit 30 including a transfer cylinder hinged rotatably to the rotating unit 20, a moving body 32 reciprocating back and forth by the transfer cylinder, and a guide rail 33 on which the moving body 32 slides. Wow; An adjustment cylinder 40 for adjusting the horizontal angle of the forward and backward conveying unit 30 and the rotating unit 20 according to the expansion and contraction of the hydraulic cylinder 31, and a crusher mounting unit 50 hinged rotatably to the lower part of the movable body 32 ) is included.

However, in the conventional vibration-free rock crusher, the wedge portion is often damaged by external force generated due to the discrepancy between the working direction and the drilling direction of the wedge during operation. The work efficiency is low, and improvement is required.

<Prior Document 1>: Republic of Korea Patent Publication No. 10-2004-0001623 (published date: January 07, 2004)

The present invention was devised to solve the above problems, and it can be detachably mounted and used in the middle of construction, such as an excavator. An object of the present invention is to provide a crusher.

According to an embodiment of the present invention for achieving the above object, there is provided a rock crusher for excavation used to crush the rock while being mounted in the middle of construction, the mount unit provided with a mount pin for mounting in the middle of construction; a base part connected to the mounting part via a tilting cylinder and a tilting connection part; and a crusher mounted on the lower part of the base part to crush the rock, wherein the base part includes an upper base connected to the mount part, and a lower base mounted to the upper base so as to be rotatable in a predetermined radius through a pivot axis as a medium. Is configured, and the lower base is provided with a rock crusher for excavation further comprising at least one vertical buffer member installed to stand vertically on both sides with respect to the pivot axis.

It may be made to further include a shredder bracket which is pivotably mounted on a lower portion of the lower base in a horizontal direction and the crusher is mounted.

A reference bar may be installed around the lower base to protrude by a predetermined length in the horizontal direction, and horizontal buffer members may be disposed on both sides of the reference bar on the upper surface of the crusher bracket, respectively.

According to the present invention, by providing a mount structure that can be attached and detached in the middle of construction, such as an excavator, a plurality of excavators for each work unit is not required, thereby improving work efficiency. In addition, when the wedge part is inserted into the drilling hole, the position and angle of the wedge part can be easily adjusted, thereby improving work efficiency. And through the shock absorption and anti-shake structure, it is possible to absorb the load caused by the mismatch between the drilling hole and the wedge during the operation of the excavator.

1 is a configuration diagram showing a conventional vibration-free rock crusher;
2 is a block diagram of a rock crusher for excavation according to an embodiment of the present invention;
Figure 3 is a state diagram showing the installation state of the horizontal buffer member of the rock crusher for excavation according to an embodiment of the present invention;
4 is a perspective view of a rock crusher for excavation according to an embodiment of the present invention;
5 is a perspective view showing the installation state of the vertical buffer member and the horizontal buffer member of the rock crusher for excavation according to an embodiment of the present invention;
Figure 6 is a cross-sectional view showing the internal configuration of the turning part of the rock crusher for excavation according to an embodiment of the present invention, and
7 is a state diagram of an excavator installed with a rock crusher for excavation according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to conventional or dictionary meanings, and the inventor should properly understand the concept of the term in order to best describe his invention. Based on the principle that can be defined, it should be interpreted as meaning and concept consistent with the technical idea of the present invention. In addition, unless otherwise defined in technical terms and scientific terms used, those of ordinary skill in the art to which this invention pertains have the meanings commonly understood. In the following description and accompanying drawings, descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted. The accompanying drawings are provided as examples in order to sufficiently convey the spirit of the present invention to those skilled in the art. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. Also, like reference numerals refer to like elements throughout. It should be noted that the same components in the drawings are denoted by the same reference numerals wherever possible.

Referring to Figure 2, the rock crushing apparatus for excavation of the present invention includes a mount portion consisting of an upper mount 110 and a lower mount 130, a base portion consisting of an upper base 151 and a lower base 152, and a lower portion It includes a crusher body 170 mounted to a lower portion of the base 152 via a crusher bracket 160 .

Specifically, a pair of mount pins 111 are mounted on the upper mount 110 , and the mount pins 111 serve as a mounting element for mounting in a heavy construction period such as an excavator. In addition, between the upper mount 110 and the lower mount 130 is connected to the upper pivot 120 . Accordingly, the lower mount 130 can be rotated in a predetermined radius with respect to the upper mount 110 . In addition, the upper base 151 is mounted on the lower part of the lower mount 130 via the tilting cylinder 112 and the tilting connection part 115 . Accordingly, the upper base 151 can be tilted at a predetermined inclination angle with respect to the lower mount 130 .

At this time, on the upper base 151, a control valve 114 and a hydraulic control unit 113 for adjusting the hydraulic pressure are installed, and on the lower surface of the lower mount 130, a rotation driving unit for adjusting the rotation angle of the upper turning unit 120 140 is mounted. In addition, both ends of the tilting cylinder 140 are connected by a connecting shaft 131 to facilitate the adjustment of the tilting angle, and similarly, the tilting connecting portion 115 is also connected via the connecting shaft 132 in the middle to facilitate the adjustment of the tilting angle. do.

On the other hand, the upper base 151 is connected to the lower base 152 and the pivot shaft 153 as a starting point to pivot (flow) left and right. At this time, a plurality of pairs of vertical buffer members 150 are installed on the upper surface of the lower base 152 with respect to the pivot axis 153 to be erected. In addition, a horizontal buffer member 180 is installed in the crusher bracket 160 connected to the lower base 152 .

In addition, a crusher is mounted on the lower portion of the crusher bracket 160. Specifically, the crusher has a middle of the crusher body 170 connected to the pivoting connection part 175 of the crusher bracket 160, and one end of the crusher body 170 is a crusher. It is fixed to the bracket 160 , and a lower rotation motor 161 is mounted on the crusher bracket 160 . At this time, the lower rotation motor 161 serves to drive the rotating part 173 connected to the end of the crusher body 170 . On the other hand, a wedge portion 171 is installed at the tip of the crusher body 170 , and a pair of wing pieces 172 are installed outside the wedge portion 171 .

In addition, between the lower base 152 and the crusher bracket 160 is connected through the lower turning portion 117, the crusher bracket 160 is capable of turning a certain radius in the horizontal direction.

3 to 5 , a pivot plate 154 provided with a pivot shaft 153 is formed on the lower base 152 (see FIG. 5 ). In addition, a first vertical shock absorber 150a and a second vertical shock absorber 150b are installed on both sides of the pivot axis 153 to stand up, respectively.

The first and second vertical shock absorbers 150a and 150b formed in this way are formed when the lower base 152 flows by a predetermined width in the vertical direction with respect to the upper base 151 due to vibration during rock crushing, the vibration is the first The vertical shock absorber 150a and the second vertical shock absorber 150b may cushion the lower surface of the upper base 151 as they collide.

In addition, at one edge of the lower base 152, a reference bar 185 is extended by a predetermined length in the horizontal direction, and on the upper surface of the crusher bracket 160, horizontal buffering is provided at positions adjacent to both sides based on the reference bar 185, respectively. Members 180a and 180b are installed. At this time, the lower portion of the lower base 152 becomes movable by a certain radius (θ ₁ ) in the horizontal direction via the crusher bracket 160 and the lower turning part 117 (see FIG. 3 ). That is, the crusher bracket 160 is pivotable by a predetermined width in the horizontal direction with respect to the lower base 152 .

Therefore, the reference bar 185 protruding with a predetermined width from the edge of the lower base 152 is buffered in the left and right directions by a pair of horizontal buffering members 180a and 180b installed on the upper surface of the crusher bracket 160. . That is, when the crusher body 170 flows in the horizontal direction (left and right direction) by vibration generated during rock crushing, a pair of horizontal buffers disposed close to both sides of the reference bar 185 installed in the lower base 152 The impact may be alleviated by the members 180a and 180b.

Meanwhile, referring to FIG. 6 , the lower pivot 117 has a lower base connecting end 117a formed on the lower surface of the lower base 152 and a bracket connecting end 117b formed on the upper surface of the crusher bracket 160 ball bearing member with each other. (119) is connected as a medium, so that it is easily installed in a horizontal direction.

Referring to FIG. 7 , the upper mount 110 is connected to the mounting part of the heavy construction machine P, such as an excavator, so that the rock crusher for excavation can be mounted. In this state, by aligning the wedge 171 to match the perforated hole formed in the perforated wall (W), the crushing of the rock is made through the diameter expansion and the excavation operation of the perforated hole. At this time, in some cases, when the rock crusher for excavation is located close to the ground (G) and the position of the arm of the excavator is changed, the rock crushing operation is performed while changing the posture of the rock crushing device for excavation accordingly.

As such, the present invention is a rock crushing device for mounting an excavator, which is rotated in various postures while being mounted on an arm in the excavator to enable work. That is, it is possible to work by turning the rock crusher at various angles with respect to the perforated hole of the lower part of the perforated wall (W) and the perforated hole of the upper part. At this time, by buffering the swing impact of the rock crusher through the vertical buffer member 150 and the horizontal buffer member 180, it is possible to alleviate the swing impact leading to the load of the device during operation. In addition, the present invention can more precisely set the working angle of the wedge 171 through the tilting cylinder 153, so that the alignment of the perforated hole of the perforated wall W and the wedge 171 can be performed more easily. .

In addition, in the present invention, the crusher can be rotated according to the free surface of the bedrock by the lower rotary motor 161 installed in the crusher bracket 160, so that the work performance can be further improved.

In addition, the present invention is when the vertical buffer member 150 and the horizontal buffer member 180 are arranged in a state close to the lower surface of the upper base 151 and the reference bar 185, respectively, to adjust the crusher to various postures when crushing the rock. , it is possible to prevent excessive load on the device by minimizing the shaking of the wedge portion 171 . In addition, by providing a hydraulic adjustment unit 113, it is possible to adjust the excavation strength of the crusher according to the strength of the bedrock.

In the above, the present invention has been illustrated and described with respect to specific embodiments, but the present invention is not limited to the above-described embodiments, and those of ordinary skill in the art to which the present invention pertains will The invention may be implemented with various changes without departing from the spirit of the invention.

110: upper mount
111: mount pin
112: tilting cylinder
113: hydraulic adjustment unit
114: control valve
115: tilting connection
117: lower pivot
117a: lower base connection end
117b: bracket connection end
119: ball bearing member
120: upper pivot
130: lower mount
131: connecting shaft
132: connecting shaft
140: rotation drive unit
150: vertical buffer member
151: upper base
152: lower base
153: pivot axis
160: crusher bracket
161: lower rotation motor
170: crusher body
171: wedge
172: wings
173: rotating part
175: slewing connection
180: horizontal buffer member
181: first horizontal buffer member
181a: first post
182: second horizontal buffer member
182a: second post
185: reference bar

Claims (5)

A rock crusher for excavation that is installed in the middle of construction and used to crush rock,
a mount unit provided with a mount pin for mounting in the middle of construction;
a base part connected to the mount part via a tilting cylinder and a tilting connection part; and
and a crusher body mounted on the lower part of the base to crush the rock;
The base part is composed of an upper base connected to the mount part, and a lower base mounted to the upper base so as to be pivotable in a predetermined radius via a pivot axis,
Rock crushing apparatus for excavation, characterized in that the lower base further comprises at least one vertical buffer member installed to stand vertically on each side with respect to the pivot axis. According to claim 1,
It is mounted to the lower part of the lower base so as to be able to rotate at a certain radius in the horizontal direction,
Rock crusher for excavation, characterized in that it further comprises a crusher bracket to which the crusher body is mounted. 3. The method of claim 2,
A reference bar is installed on one side of the lower base to protrude by a certain length,
Rock crusher for excavation, characterized in that horizontal buffer members are disposed on both sides of the upper surface of the crusher bracket, respectively, based on the reference bar. A rock crusher for excavation that is installed in the middle of construction and used to crush rock,
a mount unit provided with a mount pin for mounting in the middle of construction;
a base part connected to the mount part via a tilting cylinder and a tilting connection part; and
It is mounted on the lower part of the base and includes a crusher body for crushing the rock,
The base part rock crusher for excavation, characterized in that provided with a buffer member to be able to flow within a certain range according to the operation of the crusher body. 5. The method of claim 4,
The base portion, an upper base connected to the mount portion, and
It is composed of a lower base mounted to the upper base so as to be pivotable in a predetermined radius through a pivot shaft,
The lower base is rock crushing apparatus for excavation, characterized in that it further comprises at least one vertical buffer member installed to stand vertically on both sides with respect to the pivot axis.

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