KR200317937Y1 - Rock layer breaking device - Google Patents

Abstract

The present invention relates to a rock-breaking device using an excavator that is used to remove rock by being buried in the ground or underground when constructing concrete buildings, concrete structures, etc., and the main bracket detachably mounted on the tip of the excavator boom The main bracket is installed at the bottom of the main bracket so that the angle can be adjusted to the left and right, the guide rod is fixed to the upper and lower ends while being installed in parallel to each other vertically on the inner side of the main body, and can be elevated on the guide rod. The mounted lifting body and the tip of the piston rod which is mounted upside down on the upper end of the inner side of the main body are connected to the supporting protrusions protruding to the rear side of the lifting body to operate the lifting body. Cylinder for lifting and lowering operation, and the output shaft is attached to the upper surface of the tip side of the lifting body to protrude. The hydraulic motor is installed to penetrate toward the bottom, and is installed vertically downward while being fixed to the output shaft end of the hydraulic motor. The hydraulic motor is circular to the rock by the lowering operation of the lifting cylinder and the rotating operation of the hydraulic motor. A rock perforator comprising a cylindrical body for forming a hole;

A pressurized body inserted into the circular hole formed in the rock by the rock drilling machine, a piston performing an emergent operation to apply pressure toward one inner wall surface of the circular hole in a state in which the piston is mounted, and the piston appears. A hydraulic breaker composed of a pressure plate inserted between one side of the pressurized body and a circular hole, and destroying the rock by pushing the pressure plate at the pressure of the piston appearance operation;

A hydraulic pressure feeder comprising an hydraulic booster for amplifying and supplying the hydraulic pressure to the hydraulic breaker, and an engine for driving the hydraulic booster;

The invention is characterized in that it is configured to include.

Description

Rock breaking device using excavator {Rock layer breaking device}

The present invention relates to a rock-breaking device using an excavator used to remove the rock is buried in the ground or underground when civil engineering construction of concrete buildings, concrete structures, and the like.

Generally, an excavator is used to excavate the ground in various civil works.

The excavator has excellent maneuverability even on poor ground, and it is easy to selectively install equipment such as a fork bucket or a breaker that breaks rocks according to working conditions. Excavators are used a lot in construction.

However, if a rock appears in the basement during the excavation work of the ground by mounting the fork bucket on the boom of the excavator, the fork bucket is removed from the tip of the boom and then replaced with a breaker to remove the rock. The breaker is configured to break the rock by reciprocating the pointed cutting tool using the hydraulic pressure, and the blow noise generated when the above-mentioned hitting tool hits the rock is not only very large but also dust (dust) Due to the occurrence of severe vibrations, there is a problem of complaints at sites where buildings are concentrated or at construction sites where livestock farms are close to each other.To solve complaints, noise and vibration generated when using breaker And the installation of additional facilities to reduce dust as much as possible. The problem is so costly addition.

The present invention is designed with the purpose of making it possible to remove the rock while suppressing the occurrence of noise, dust and vibration to the maximum even if the rock appears during the civil engineering process using an excavator as described above.

The present invention as a means for achieving the above object,

The main bracket is detachably mounted to the boom end of the excavator, the main body is installed to the left and right angle adjustment to the bottom of the main bracket, and the upper and lower ends are installed vertically next to each other on the inner side of the main body A fixed guide rod, a lifting body removably mounted to the guide rod, and a tip of a piston rod which moves in a downward direction while being attached upside down to the upper end of the inside of the main body protrude to the rear side of the lifting body. A lift operation cylinder connected to the supporting support piece for lifting and lowering the lifting body, and a hydraulic motor installed so that the output shaft penetrates toward the bottom from the upper surface of the lifting body while protrudingly attached to the upper surface of the tip side of the lifting body. It is fixed to the end of the output shaft of the hydraulic motor is installed vertically downwards to the downward operation of the lifting operation cylinder and the hydraulic motor Rock drilling machines configured for body piercing cylinder cycle so as to form a hole in the rock by the rotation operation and;

A pressurized body inserted into the circular hole formed in the rock by the rock drilling machine, a piston performing an emergent operation to apply pressure toward one inner wall surface of the circular hole in a state in which the piston is mounted, and the piston appears. A hydraulic breaker composed of a pressure plate inserted between one side of the pressurized body and a circular hole, and destroying the rock by pushing the pressure plate at the pressure of the piston appearance operation;

A hydraulic pressure feeder comprising an hydraulic booster for amplifying and supplying the hydraulic pressure to the hydraulic breaker, and an engine for driving the hydraulic booster;

It is characterized in that it is configured to include.

The front end of the piston rod is hinged to both ends of the bottom of the main bracket so that the main body of the rock drilling machine can be vertically upright and inclined to the left and right sides. The body is hinged to the structure is characterized in that the two angular adjustment cylinders are mounted symmetrically to each other,

In addition, the hydraulic breaker is a pressure body having a diameter slightly smaller than the diameter in the drilling cylinder of the rock drilling machine, and is formed in a state in which one side is opened and the other side is closed while being formed parallel to the upper and lower sides in the circumferential direction of the body. The upper and lower cylinder chambers, the upper and lower pistons which are mounted to each of the upper and lower cylinder chambers, and the front and rear hydraulic supply hoses connected to the upper end of the pressurized body to project the upper and lower pistons. And, the hydraulic pressure supplied from the forward hydraulic passage and the hydraulic pressure supplied from the reverse hydraulic supply hose so that the hydraulic pressure supplied from the forward hydraulic supply hose can cause the piston to appear and operate the immersion operation. It is characterized by consisting of a hydraulic passage for the reverse formed in the pressurized body to be able to.

1 is a perspective view of a rock drilling machine that is an essential part of the present invention.

Figure 2 is a rear view of the rock drilling machine of the present invention.

3 and 4 is an operating state of the rock drilling machine of the present invention.

Figure 5 is an exploded perspective view of the hydraulic breaker and the pressure plate which is the main part of the present invention.

6 and 7 are cross-sectional view of the operating state of the hydraulic breaker of the present invention.

Figure 8 is a block diagram of a hydraulic supply is a main part of the present invention.

9 (A) to (F) is a flow chart of breaking the rock of the present invention.

※ Explanation of code for main part of drawing

1A: Rock Drill 1B: Hydraulic Breaker

1C: Hydraulic Feeder 2: Main Bracket

3: main body 4a, 4b: angle adjustment cylinder

20,30: Connecting bracket 21: Pin shaft

31: upper connecting plate 32: lifting body

33: guide rod 34: intermediate support plate

35 cylinder for lifting operation 36 piston rod

37: support protrusion 38: hydraulic motor

39: cheon park body 5: pressurized body

51: pressure plate 52, 53: upper and lower cylinder chamber

54, 55: upper and lower pistons 56, 57: upper and lower nut bodies

58,59: Hydraulic passage for forward and reverse 6a, 6b: Hydraulic hose for forward and reverse

7: cover case 71: engine

72: battery 73: hydraulic booster

74: hydraulic valve R: rock

S: round hole

Embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a rock drilling machine which is the main part of the present invention, Figure 2 is a rear view of the rock drilling machine of the present invention, Figures 3 and 4 is an operating state diagram of the rock drilling machine of the present invention, Figure 5 It is an exploded perspective view of the denier hydraulic breaker and the pressure plate, Figure 6 and Figure 7 is a cross-sectional view of the operating state of the hydraulic breaker of the present invention, Figure 8 is a configuration diagram of the hydraulic supply of the main part of the present invention, Figures 9 (A) ~ ( F) shows a flow chart of breaking the rock of the present invention,

Reference numeral 1A denotes a rock perforator mounted on the boom of the excavator to drill a circular hole in the rock, and 1B denotes a hydraulic breaker inserted into the circular hole formed in the rock by the rock clean air 1B and breaking the rock. Denotes oil pressure supplies for supplying oil pressure at the amplified pressure to the hydraulic breaker 1B.

First, the rock drilling machine 1A will be described.

The rock drilling machine (1A) is composed of a main bracket (2) detachably mounted at the tip of the boom of the excavator and a main body (3) forming a circular hole in the rock.

The main body 3 is connected to the connecting bracket 30 formed at the upper end and the connecting bracket 20 at the bottom of the main bracket 2 are hinged by the pin shaft 21 so that the angle can be adjusted to the left and right sides. Two rear cylinders 4a and 4b are symmetrically connected to both rear rear ends of the main bracket 2 and the rear upper ends of the main body 3, and the two angle cylinders 4a and 4b. Each cylinder body 41 is hinged to the upper connecting plate 31 installed on the rear upper end of the main body 3, the piston rod 42 is hinged to both rear ends of the main bracket (2). Therefore, the piston rod 42 of each of the above-described angle adjustment cylinders 4a and 4b is operated to mutually adjust the distance of the piston rod 42 to move the main body 3 with the pin shaft 22 as the rotational starting point to be fixed vertically and vertically. Or it can be fixed in a state inclined at a certain angle toward the left, right direction.

The main body 3 is formed in a rectangular frame shape in which the front and rear sides are open and the upper, lower, left and right sides are blocked, and guides the lifting of the lifting body 32 on one side thereof, that is, the front side. Two guide rods 33 are vertically side by side fixed.

The lifting body 32 is moved up and down by the lifting operation cylinder 35 which is located on the opposite side of the guide rods 32 on both sides and is fixedly installed in an upside down state between the upper end of the main body 3 and the intermediate support plate 34. Will be performed. That is, the piston rod 36 of the lifting and lowering operation cylinder 35 passes through the intermediate support plate 34 and the tip thereof is connected to the supporting protrusion piece 37 protruding from the rear of the lifting body 33 so that the lifting body 33 It is configured to move up and down.

In the above-described lifting operation cylinder 35 is attached to the protrusion 3a protruding upward on the upper end of the main body 3, the protrusion 3a is the main body when the main body 3 itself is adjusted to the left and right angles. By forming the bracket at a height not to reach the bracket 2, the left and right angles of the main body 3 can be adjusted, and the length of the cylinder 35 for the lifting operation cylinder 35 accommodated in the projecting portion 3a can be as large as that of the rock. It is possible to reduce the overall height of the perforator 1A itself.

The hydraulic motor 38 is mounted on the front end side of the lifting body 33, and the output shaft of the hydraulic motor 38 passes through the lifting body 33 to rotate the drilling cylinder 39. It is configured to be.

The drilling cylinder 39 is connected to the output shaft of the hydraulic motor 28 in the closed state of the upper end, the lower end is a plurality of tips (39a) for drilling a circular hole in the rock in the open state Attached.

Further, several supporting rods 311 are attached to the bottom corner portion of the main body 3 to stably support the rock drilling machine 1A on the rock.

Next, the hydraulic breaker 1B will be described.

The hydraulic breaker (1B) is a pressing body (5) having a diameter smaller than the drilling cylinder (39) of the rock drilling machine (1A) to make a circular hole in the rock and the pressure plate formed in a state separated from the pressing body ( 51), and the upper and lower cylinder chambers 52 and 53 are formed in the pressurized body 5 horizontally and vertically. The upper and lower cylinder chambers each have one side opening. The other side is formed in the closed state.

Each of the upper and lower cylinder chambers 52 and 53 has upper and lower pistons 54 and 55 mounted therein so that the upper and lower pistons 54 and 55 can be sunk, and each of the upper and lower pistons 54 and 55 has a head portion. The rod part is inserted in the closed state to the side, and the rod part is configured to be indented and operated through a guide hole formed in the center of the upper and lower nut bodies 56 and 57 which are assembled to the opening side of the upper and lower cylinder chambers. The outer circumference of the head portion of each of the upper and lower pistons 54 and 55 and the inner circumferential surface of the upper and lower nut bodies 56 and 57 are provided with packings to prevent hydraulic leakage.

The front and rear hydraulic hoses 6a and 6b for supplying the hydraulic pressure are connected to the upper end of the pressurized body 5, and the internal and external hydraulic hoses for the forward and reverse pressure are connected to the pressurized body 5, respectively. A forward hydraulic passage 58 and a reverse hydraulic passage 59 for advancing and reversing the upper and lower pistons 54 and 55 are respectively formed.

A handle 5a is formed at the upper end of the pressing body 5, and a handle 511 is formed at the upper end of the pressing plate 51.

Next, the hydraulic feeder 1C will be described.

The hydraulic pressure supply 1C is driven by the engine 71 capable of generating power in the case 7, the battery 72 supplying power to the engine, and the power of the engine to amplify the amount of hydraulic pressure supplied. The hydraulic booster 73 is supplied to the hydraulic breaker 1B, and the hydraulic booster 73 and the hydraulic breaker 1B are connected to the forward and backward hydraulic hoses 6a and 6b. The hydraulic valve 74 of the hydraulic booster 73 to which the above-mentioned forward and backward hydraulic hoses 6a and 6b are connected is automatically moved forward and backward as the operator operates the forward and backward valve switches (not shown). One of the hydraulic hoses 6a and 6b is selected to supply the hydraulic pressure. At this time, the hydraulic hose that is not supplied with the hydraulic pressure through the hydraulic valve 74 of the hydraulic booster 73 has an upper portion of the pressure body 5. The hydraulic pressure recovered from the lower cylinder chambers 52 and 53 is recovered.

Referring to the operation of breaking the rock (R) with the present invention configured as described above are as follows.

First, the main bracket (2) of the rock drilling machine (1A) is mounted on the tip of the boom of the excavator, and then exposed surface of the rock (R) to remove the main body (3) of the rock drilling machine (1A) by means of operating the boom The body 3 is installed according to the angle of inclination of the exposed surface of the rock. That is, when the exposed surface of the rock R is inclined forward and backward, the main body 3 is installed to be inclined forward or rearward according to the front and rear inclination angles of the rock as a means of operating the excavator's boom forward and backward. When the exposed surface of the rock R is inclined to the left and right sides, the cylinders for adjusting the angle of both sides provided at both rear ends of the main bracket 2 of the rock drilling machine 1A and upper rear ends of the main body 3 are provided. The mounting angle of the main body 3 is adjusted using (4a) (4b). At this time, the hydraulic pressure supplied to the cylinder for adjusting both angles is used the hydraulic pressure of the excavator itself.

A support rod protruding from the bottom corner of the main body 3 while adjusting the installation angle of the main body 3 of the rock drilling machine 1A by using the boom of the excavator and the cylinders 4a and 4b for adjusting the angle as described above. When the 311 is supported on the exposed surface of the rock R, the main body 3 is stably seated on the exposed surface of the rock, and in this state, the lifting cylinder 35 and the hydraulic motor 38 are operated. By making a circular hole (S) in the rock (R), at this time, the hydraulic pressure supplied to the lifting operation cylinder 35 and the hydraulic motor 38 also uses the hydraulic pressure of the excavator itself.

As the piston rod 36 starts the emergence operation toward the downward direction by the operation of the lifting operation cylinder 35 as described above, the lifting body 32 is lowered along the guide rod 33, and the cylindrical body for drilling ( 39 is also lowered toward the rock (R) and at the same time rotated by the drive of the hydraulic motor 38, the plurality of tips (39a) formed on the lower end of the drilling cylinder 39 that rotates while falling in this way When the rock (R) starts to penetrate from the moment it reaches the rock and the drilling cylinder 39 penetrates to the desired depth as shown in FIG. 9 (A), the piston rod 36 of the lifting operation cylinder 35 To the immersion operation to relax the drilling cylinder 39 in the rock (R), at which time the hydraulic motor 38 continues to drive even when removing the drilling cylinder 39 from the rock (R) The loosening operation of the common cylindrical body 39 becomes smooth.

When the cylindrical cylinder 39 for drilling is removed from the rock R as described above, a ring-shaped space S ₁ is formed in the rock as shown in FIG. 9B, and then tools such as tongs prepared in advance. When (not shown) is inserted into the ring-shaped space (S ₁ ) and the tongs are applied to the tongs (R ₁ ) located inside the ring-shaped space (S ₁ ) and separated from the rock (R) is cut, When the circular column R ₁ thus cut is taken out from the rock R as shown in FIG. 9C using a forceps, a circular hole S is formed in the rock.

As described above, the pressurized body 5 of the hydraulic breaker 1B is inserted into the circular hole S formed in the rock R. At this time, the upper and lower pistons 54 and 55 as shown in FIG. The pressure plate 51 is inserted into the space on which the pressure plate 51 is to be formed, and then the pressure plate 51 is inserted as shown in FIG. 9E.

After inserting the pressure plate 51 as described above, the front and rear hydraulic hoses 6a and 6b drawn out from the hydraulic supply 1C prepared in advance around the work site are placed on the upper end of the pressure body 5. When the engine 71 is driven in the state of being connected to each of the formed forward and backward hydraulic passages 58 and 59, the hydraulic booster 73 is operated, and then before and after the hydraulic supply unit 1C is installed, When operating the switch for supplying the hydraulic pressure to the forward hydraulic hose (6a) of the reverse switch (not shown), the hydraulic valve 74 is the hydraulic pressure amplified by the hydraulic booster 73 to the forward hydraulic hose (6a) It is supplied to the forward hydraulic passage 58 to push out the head portion of the upper and lower pistons 54 and 55 at the same time, the upper and lower pistons 54 and 55 start the pressing (advancing) operation while pressing plate ( 51), while the upper and lower pistons start the emergence operation, the head and the upper, The hydraulic pressure present in the upper and lower cylinder chambers 52 and 53 between the side nut bodies 56 and 57 flows backward through the reverse hydraulic passage 59 and is recovered to the hydraulic booster 73 while the upper and lower hydraulic pressures are recovered. The pistons 54 and 55 push the pressure plate 51 to the side with a strong pressure. At this time, the upper and lower pistons 54 and 55 which push the pressure plate 51 appear and operate at about 10 cm. Similarly, from the moment when the pressing plate 51 pushed out by the emergence operation of the upper and lower pistons comes into contact with the circular hole S, the pressing plate 5 and the pressing body 5 are operated by the principle of reaction action. Since it is in a state of pushing both sides at the same pressure, the rock R is broken as shown in FIG. 9 (F) with the circular hole S as the center.

After breaking the rock R by the action of the pressure body 5 and the pressure plate 51 of the hydraulic breaker 1B as described above, the reverse switch (not shown) of the hydraulic supply 1C is operated to operate the upper and lower parts. The pistons 54 and 55 are immersed (reversed) into the upper and lower cylinder chambers 52 and 53, and the pressure body 5 and the pressure plate 51 are recovered, and a rock drill machine mounted on the boom of the excavator ( After dismantling 1A), the existing breaker or bucket is mounted on the boom and the broken rock fragment is excavated to remove the rock on the ground or underground during the excavation.

According to the present invention as described above, when there is a rock embedded in the ground or the ground when the ground excavation construction using an excavator, replace the rock drilling machine on the boom of the excavator, and then the circular hole in the rock with the sky drilling body of the rock drilling machine And breaks the rock by the operation sequence of supplying hydraulic breaker to the hydraulic breaker by inserting the hydraulic breaker and the pressure bar into the circular hole one by one, and hitting the rock by the blow tool of the breaker as in the prior art. Compared to cracking, it is possible to minimize the occurrence of noise, dust, and vibration, and such effect is to remove rock from the construction site in the urban area where the buildings are concentrated or the construction site in the rural area where the barns are adjacent. Can remove rock without generating noise, dust and vibration It is possible to cut off factors that are subject to complaints from building owners, residents, and farmers around the site, without having to install various subsidiary facilities that need to be installed in preparation for civil complaints. It is a useful design that provides the advantage of allowing the construction to proceed smoothly and shorten the air.

Claims (3)

The main bracket is detachably mounted to the boom end of the excavator, the main body is installed to the left and right angle adjustment to the bottom of the main bracket, and the upper and lower ends are installed vertically next to each other on the inner side of the main body A fixed guide rod, a lifting body removably mounted to the guide rod, and a tip of a piston rod which moves in a downward direction while being attached upside down to the upper end of the inside of the main body protrude to the rear side of the lifting body. A lift operation cylinder connected to the supporting support piece for lifting and lowering the lifting body, and a hydraulic motor installed so that the output shaft penetrates toward the bottom from the upper surface of the lifting body while protrudingly attached to the upper surface of the tip side of the lifting body. It is fixed to the end of the output shaft of the hydraulic motor is installed vertically downwards to the downward operation of the lifting operation cylinder and the hydraulic motor Rock drilling machines configured for body piercing cylinder cycle so as to form a hole in the rock by the rotation operation and; A pressurized body inserted into the circular hole formed in the rock by the rock drilling machine, a piston performing an emergent operation to apply pressure toward one inner wall surface of the circular hole in a state in which the piston is mounted, and the piston appears. A hydraulic breaker composed of a pressure plate inserted between one side of the pressurized body and a circular hole, and destroying the rock by pushing the pressure plate at the pressure of the piston appearance operation; A hydraulic pressure feeder comprising an hydraulic booster for amplifying and supplying the hydraulic pressure to the hydraulic breaker, and an engine for driving the hydraulic booster; Rock breaking device using an excavator, characterized in that configured to include. The method of claim 1, The front end of the piston rod is hinged to both ends of the bottom of the main bracket so that the main body of the rock drilling machine can be vertically upright and inclined to the left and right sides, and the cylinder body is connected to both rear sides of the main body. Rock-breaking device using an excavator, characterized in that the hinge is coupled to each other symmetrically mounted two angle adjustment cylinders. The method of claim 1, The hydraulic breaker is a pressure body having a diameter slightly smaller than the diameter in the drilling cylinder of the rock drilling machine, and is formed in a state in which one side is opened and the other side is closed while being formed parallel to the upper and lower sides in the circumferential direction of the body. Upper and lower cylinder chambers, upper and lower pistons which are mounted to each of the upper and lower cylinder chambers, and a front and rear hydraulic supply hoses connected to an upper end of the pressurized body to project the upper and lower pistons. The hydraulic pressure supplied from the forward hydraulic supply hose and the forward hydraulic passage formed in the pressurized body to enable the hydraulic pressure supplied from the forward hydraulic supply hose to actuate the piston may be immersed in the piston. Rock bed using an excavator, characterized in that the hydraulic passage for the reverse is formed inside the pressurized body Breaking device.