KR101986320B1 - A crusher that is attached on a heavy equipment for destruction of objects and a method for crushing and digging - Google Patents

Abstract

The present invention relates to a crusher mounted on heavy equipment to crush an object, mounted on heavy equipment such as an excavator to crush an object to be crushed without vibration and noise. Moreover, basic hydraulic pressure provided from the heavy equipment to increase crushing power of the crusher is increased by a pressure increasing means unit, and thus the basic hydraulic pressure can be supplied to a hydraulic pressure cylinder unit. In addition, a speed increasing means unit can be applied to increase a crushing speed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a crusher for crushing an object,

The present invention relates to a crusher for crushing and excavating an object by attaching to and connecting to a heavy equipment. More particularly, the present invention relates to a crusher for crushing and excavating an object to be crushed by vibrationless and noiseless equipments mounted on hydraulic equipment such as an excavator.

Further, the present invention is an invention in which the basic oil pressure provided by the hydraulic equipment is increased to increase the crushing power of the crusher to the hydraulic cylinder.

Further, the present invention is an application of a speed increasing means portion to a hydraulic cylinder portion for increasing the crushing speed.

In the 21st century, the development of science and technology in Korea has greatly improved the construction field including civil engineering and architecture. As a result, large-scale buildings and facilities that can not be imagined compared to the past can be built.

In the past 20th century, due to the lack of technology in the construction field, accidents occurred frequently during the construction. Among them, the technology of construction of tunnels was not enough.

Especially, the 'Tangjeong Tunnel' accident occurred during the construction of the Gyeongbu Expressway in the 1970s is a typical tunnel construction accident caused by Korea's poor tunnel construction technology.

However, thanks to the know-how and technology gained through trial and error through such a number of incidents, the tunnel construction technology in Korea has reached the world-class level, and now tunnel incidents are reduced much more than in the past.

On the other hand, tunnel construction method is blasting method using explosives such as dynamite and vibration excavation method which cuts rock into heavy equipment. Blasting method is gradually decreasing due to vibration, noise and stability caused by explosion And the vibration and shear method has a problem that the working time is long and the working efficiency is low.

Therefore, in order to solve these problems, there is a tendency that the vibration-free method of crushing the rock mass directly by inserting the crusher after the construction of a certain depth in the rock and pressurizing the rock by the pressure by the hydraulic pressure is in the spotlight.

The following are conventional prior art related thereto.

1. Korean Laid-Open Patent Publication No. 10-2008-0072128 A rock crusher for heavy equipment 2. Korean Patent Laid-Open Publication No. 10-2012-0013181 Hydraulic circuit device of a hydraulic excavator 3. Korean Patent Laid-Open Publication No. 10-2013-0069286 Rock mass crusher module

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

An object of the present invention is to provide a crusher for crushing an object to be crushed by vibrationless, noise-free operation mounted in a hydraulic equipment such as an excavator.

It is another object of the present invention to increase the crushing force of the crusher by supplying the basic hydraulic pressure provided by the hydraulic equipment and the pressurized hydraulic pressure generated by the increased pressure end to the hydraulic cylinder.

The present invention also aims to increase the crushing speed by using the speed increasing means.

In order to accomplish the above object, the present invention provides a crusher for crushing an object mounted on a heavy equipment,

A mounting means (100) for connecting the crusher (10) to the heavy equipment (20);

The hydraulic cylinder part 200 (see FIG. 1) for advancing or retracting the wedge 310 of the shredding device 300 using the hydraulic pressure having the first hydraulic pressure or the hydraulic pressure having the second hydraulic pressure provided by the booster 400, )Wow;

A crushing means portion (300) including a wedge (310) for moving back and forth to crush an object;

A pressure increase end 400 for providing the hydraulic cylinder 200 with a hydraulic fluid having a first hydraulic pressure or a second hydraulic pressure under the control of the control means 500;

When a control signal for advancing or retracting the wedge 310 is applied, a hydraulic fluid having a first hydraulic pressure or a hydraulic fluid having a second hydraulic pressure provided by the booster 400 is supplied to the hydraulic cylinder 200 A control unit 500 for controlling the booster 400 to control the hydraulic fluid discharged from the hydraulic cylinder 200 to be recovered to the heavy equipment 20 in accordance with the forward or backward movement of the wedge 310;

And supplies the hydraulic fluid having the basic oil pressure supplied from the heavy equipment unit 20 to the booster supply end unit 400. If the basic oil pressure supplied from the heavy equipment unit 20 is lower than a predetermined set hydraulic pressure, To the booster end (400), and when the basic oil pressure supplied from the heavy equipment (20) exceeds a predetermined set oil pressure, the hydraulic oil having a predetermined set oil pressure And a relief portion 600 for providing the pressure increase end portion 400 to the pressure increase end portion 400.

The present invention relates to a crusher for crushing an object to be crushed by vibrationless and noiseless devices mounted on hydraulic heavy equipment such as an excavator. Therefore, there are few delays in construction due to various complaints caused by noise, vibration, It is effective not only to reduce the stress but also to improve the speed of construction work.

The present invention has the effect of increasing the crushing force of the crusher by supplying the basic hydraulic pressure provided by the hydraulic equipment and the pressurized hydraulic pressure at the increased pressure end to the hydraulic cylinder.

The present invention has the effect of shortening the construction time by increasing the crushing speed by using the accelerating unit, and thus the work efficiency is higher than the conventional system.

Fig. 1 is a conceptual diagram of a crusher for attaching to and connecting to a heavy equipment of the present invention,
FIG. 2 is a block diagram of a shredder for attaching to and connecting to a heavy equipment of the present invention,
FIG. 3 is a perspective view of the assembling apparatus according to the present invention, in which a crusher, which is mounted on and connected to a heavy equipment,
Fig. 4 is a detailed configuration diagram of a shredder attached to and connected to a heavy equipment of the present invention,
Fig. 5 is a wedge advancing state of a crusher that is attached to and connected to a heavy equipment of the present invention to crush an object; Fig. 1
Fig. 6 is a wedge advancing state of the crusher which is connected to the heavy equipment of the present invention to crush an object; Fig. 2
Fig. 7 is a view showing a wedge-backward state of a shredder for attaching to and connecting to a heavy equipment of the present invention,
8 is a partially enlarged view and operating state diagram of the direction adjusting means of the crusher which is attached to and connected to the heavy equipment of the present invention to crush an object
9 is a flowchart of a crushing excavation method of a crusher which is mounted on a heavy equipment of the present invention,

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

FIG. 1 is a conceptual diagram of a crusher for crushing an object connected to a heavy equipment of the present invention, and FIG. 2 is a block diagram of a crusher for crushing an object connected to the heavy equipment of the present invention.

1 and 2, a crusher (hereinafter, referred to as 'crusher') mounted on the heavy equipment 20 of the present invention for crushing an object is a crusher for crushing the crush object by being installed in a hydraulic equipment such as an excavator, A hydraulic cylinder 200, a crushing means 300, a booster 400, a control means 500 and a relief portion 600.

The crusher of the present invention may further include a speed increasing means (700), a lubricant supply portion (800), and a direction adjusting means (900).

Specifically, as shown in FIG. 2, the crusher, which is attached to and connected to the heavy equipment and crushes the object,

A mounting means (100) for connecting the crusher (10) to the heavy equipment (20);

The hydraulic cylinder part 200 (see FIG. 1) for advancing or retracting the wedge 310 of the shredding device 300 using the hydraulic pressure having the first hydraulic pressure or the hydraulic pressure having the second hydraulic pressure provided by the booster 400, )Wow;

A crushing means portion (300) including a wedge (310) for moving back and forth to crush an object;

A pressure increase end 400 for providing the hydraulic cylinder 200 with a hydraulic fluid having a first hydraulic pressure or a second hydraulic pressure under the control of the control means 500;

When a control signal for advancing or retracting the wedge 310 is applied, a hydraulic fluid having a first hydraulic pressure or a hydraulic fluid having a second hydraulic pressure provided by the booster 400 is supplied to the hydraulic cylinder 200 A control unit 500 for controlling the booster 400 to control the hydraulic fluid discharged from the hydraulic cylinder 200 to be recovered to the heavy equipment 20 in accordance with the forward or backward movement of the wedge 310;

And supplies the hydraulic fluid having the basic oil pressure supplied from the heavy equipment unit 20 to the booster supply end unit 400. If the basic oil pressure supplied from the heavy equipment unit 20 is lower than a predetermined set hydraulic pressure, To the booster end (400), and when the basic oil pressure supplied from the heavy equipment (20) exceeds a predetermined set oil pressure, the hydraulic oil having a predetermined set oil pressure And a relief portion 600 for providing the pressure increase end portion 400 to the pressure increase end portion 400.

FIG. 3 is a perspective view of a shredder connected to the heavy equipment of the present invention and connected to the heavy equipment, FIG. 4 is a detailed view of the shredder connected to the heavy equipment of the present invention, Fig. 6 is a wedge advancing state 2 of a crusher which is attached to and connected to a heavy equipment of the present invention to crush an object, Fig. 7 is an exploded perspective view of a crusher according to the present invention Of the crusher to be connected to the heavy equipment of the crusher.

The crusher (10) of the present invention is a crusher to which a vibration-free rock crushing method is applied. The crusher (10) is less susceptible to construction delays due to various complaints caused by noise and vibration, The present invention relates to a crusher (10) that improves the speed of construction work.

Particularly, although the crusher 10 of the present invention has various kinds of objects to be crushed, it can be effectively used for rock crushing.

Referring to FIG. 3, the crusher 10 of the present invention is mounted on a hydraulic equipment 20 such as an excavator through a mounting means 100, and is used by a user operating the hydraulic equipment 20 The wedge 310 of the shredder 10 moves forward or backward to break the shredding object.

In the present invention, the heavy equipment 20 provides a hydraulic fluid having a basic hydraulic pressure to the crusher 10, and the basic hydraulic pressure provided by the heavy equipment 20 is generally in the range of 220 to 350 bar .

The hydraulic cylinder part 200 is connected to the crushing means 300 (300) using the hydraulic fluid having the first hydraulic pressure or the hydraulic fluid having the second hydraulic pressure provided by the booster 400 under the control of the control part 500 The wedge 310 is moved forward or backward.

Specifically, the hydraulic cylinder 200 has a piston reciprocating motion space, a piston reciprocating motion space is filled with a hydraulic fluid, and the piston reciprocating motion space is divided into a first space 211 and a second space 211 by a piston 220. [ And a second space 212. The wedge 310 is connected to the wedge 310 and is reciprocated by hydraulic pressure supplied to the hydraulic cylinder 200 to rotate the wedge 310 forward, And a piston 220 for moving backward.

The first space 211 and the second space 212, which are the internal spaces of the cylinder body 210, are basically filled with hydraulic fluid.

Particularly, the piston 220 is moved forward or backward by the flow rate and hydraulic pressure of the hydraulic fluid flowing into the first space 211 and the second space 212 inside the cylinder body 210. In addition, the wedge 310 of the crushing unit 300 connected to the piston 220 during forward movement also advances to generate a crushing force for crushing the object.

Referring to FIGS. 4 and 5, the crushing unit 300 is configured to crush an object. The crushing unit 300 is advanced by a piston 220 reciprocating by hydraulic pressure and hydraulic pressure supplied to the hydraulic cylinder 200 And a wedge liner 320 formed on one side and the other side of the wedge 310 and widened or retracted by advancing or retracting the wedge 310 to break the object.

That is, the wedge 310 is connected to the piston 220 so as to move forward or backward as the piston 220 is advanced or retracted. The wedge liner 320 is wedged by advancing or retracting the wedge 310, And the object is returned to its original state, and a crushing force is applied to the object to crush the object.

More specifically, a plurality of wedge liners 320 are formed on one side and the other side of the wedge 310, and when the wedge 310 is advanced, as in the lower end enlargement of FIG. 5, As shown in FIG. 7, when the wedge 310 is retracted, the wedge liner 320 is returned to its original state. When the wedge liner 320 is expanded, And crushing force is applied to crush the object.

On the other hand, if only the hydraulic fluid having the basic hydraulic pressure provided by the heavy equipment 20 is used, the object with high strength may not be crushed.

To this end, the booster end 400 of the present invention provides a hydraulic cylinder portion 200 with a hydraulic fluid having a first hydraulic pressure or a second hydraulic pressure under the control of the control means portion 500.

At this time, the hydraulic fluid having the first hydraulic pressure provided by the booster pressure end portion 400 to the hydraulic cylinder portion 200 is supplied from the heavy equipment 20 and is supplied to the relief portion 600, , And the hydraulic fluid having the second hydraulic pressure provided by the pressure-increasing end portion 400 to the hydraulic cylinder portion 200 is supplied to the pressure increasing end portion 400 at a predetermined pressure-increasing ratio provided by the relief portion 600 And is characterized by being a hydraulic fluid having a pressurized oil pressure.

That is, the hydraulic cylinder part 200 is provided with the hydraulic fluid supplied from the heavy equipment 20 and having the basic oil pressure (first oil pressure) provided by the relief part 600 through the increased pressure end part 400, (Second hydraulic pressure) in which the pressure-increasing end portion 400 is increased by a predetermined pressure-increasing ratio, the hydraulic pressure having a predetermined hydraulic pressure provided by the pressure increasing / reducing valve 600 is provided.

4, the booster 400 is configured to include a plurality of auxiliary pistons 410 for generating a second hydraulic pressure (booster pressure), and a relief portion 600 is provided using an auxiliary piston (Pressure increase hydraulic pressure).

The relief part 600 supplies the hydraulic fluid having the basic oil pressure supplied from the heavy equipment 20 to the pressure increase end part 400. The basic oil pressure supplied from the heavy equipment 20 is set to a preset hydraulic pressure The pressure increase end portion 400 is provided with the oil pressure having the basic oil pressure supplied from the relief portion 600 to the pressure increase end portion 400 as it is, When the basic hydraulic pressure supplied from the heavy equipment 20 exceeds the preset hydraulic pressure set in advance, the hydraulic pressure is supplied to the hydraulic cylinder unit 200, (In this case, the pressurized water end portion 400 is provided with a hydraulic pressure having a hydraulic pressure which is increased to a predetermined pressure-increasing ratio, The meaning of hydraulic pressure with a second hydraulic pressure) Providing a hydraulic cylinder 200)

More specifically, the basic oil pressure provided by the heavy equipment 20 is 220 to 350 bar. Of course, there may be a heavy equipment 20 that provides a basic hydraulic pressure of at least 350 bar.

In the present invention, the pressure increase end portion (400) increases the basic oil pressure supplied from the heavy equipment (20) to a set pressure increase ratio for increasing the crushing force. Of course, the pressure-increasing ratio can be set as needed, but it is preferably 1: 3.

For example, if the basic oil pressure supplied from the heavy equipment 20 is 250 bar and the booster pressure is increased to the set pressure ratio (for example, 1: 3), a high pressure of 750 bar acts on the crusher, : Hydraulic valve or hydraulic pipe) may be damaged by high pressure.

In order to prevent this, the relief unit 600 sets a preset hydraulic pressure (for example, 130 bar) and controls the basic hydraulic pressure supplied from the heavy equipment 20 when the basic hydraulic pressure supplied from the heavy equipment 20 is lower than the set hydraulic pressure (In this case, the pressure-increasing end portion 400 provides the hydraulic fluid having the basic hydraulic pressure supplied from the relief portion 600 to the hydraulic cylinder portion 200 as it is) (For example, 130 bar) to the booster end 400 when the basic oil pressure supplied from the heavy equipment 20 exceeds the set oil pressure (in this case, Provides the hydraulic cylinder portion 200 with a hydraulic pressure having a hydraulic pressure (for example, 390 bar) in which the hydraulic pressure having the supplied hydraulic pressure is increased to a predetermined pressure-increasing ratio)

In this way, regardless of the value of the basic oil pressure provided by the heavy equipment 20, the problem does not occur even when the pressure is increased to a predetermined pressure increase ratio.

For example, if the basic hydraulic range provided by the heavy equipment 20 is 0 to 250 bar for crushing the object, the heavy equipment 20 starts at the initial 0 bar to gradually increase the hydraulic pressure to the final 250 bar To the crusher.

At this time, if the set hydraulic pressure is set to 130 bar, the relief unit 600 can be operated to maintain the hydraulic pressure supplied from the heavy equipment 20 at the hydraulic pressure range of 0 to 130 bar provided by the heavy equipment 20 And the pressure increase end 400 is provided as it is. When the basic oil pressure supplied from the heavy equipment 20 exceeds 130 bar, the hydraulic pressure having the pressure of 130 bar is supplied to the pressure increase end 400, When the set pressure increase ratio of the end portion 400 is 1: 3, the pressure increase end 400 is provided with a pressurized fluid having a pressure of 390 bar to the hydraulic cylinder portion 200 to crush the object.

As a result, the relief part 600 is capable of increasing the versatility of mounting the crusher of the present invention to the heavy equipment 20, which provides a wide range of basic hydraulic pressure, and the pressure increase of the boosted pressure end part 400, It is assumed that the configuration is considered.

5, when the control signal for advancing or retracting the wedge 310 is applied, the control unit 500 controls the hydraulic pressure of the hydraulic fluid having the first hydraulic pressure provided by the pressure increase end 400, And the hydraulic fluid discharged from the hydraulic cylinder unit 200 is discharged from the heavy equipment unit 20 in accordance with the forward or backward movement of the wedge 310. The hydraulic cylinder unit 200, .

Hereinafter, a control process of the control unit 500 for advancing the wedge 310 will be described in detail with reference to FIG.

When the control signal for advancing the wedge 310 is applied, the control unit 500 may control the flow of the hydraulic fluid having the first hydraulic pressure, which is provided primarily by the pressure increasing end 400 as shown in the lower end of FIG. 5, When the first hydraulic pressure supplied to the hydraulic cylinder unit 200 reaches a predetermined set hydraulic pressure, the control unit 200 controls the booster control unit 400 to control the booster control unit 400 so that the booster control unit 200 controls the booster unit 400 to be provided in the first space 211 of the hydraulic cylinder unit 200, And controls the booster end 400 so that a hydraulic fluid having a second hydraulic pressure, which is provided by the boosting end portion 400, is provided in the first space 211 of the hydraulic cylinder portion 200.

In this case, the piston 220 in the hydraulic cylinder 200 advances in the advancing direction (the direction from the first space to the second space).

A predetermined amount of hydraulic fluid filled in the second space 212 of the hydraulic cylinder 200 is discharged according to the advancement of the piston 220. At this time, 2 space 212 to be recovered to the heavy equipment 20. [0050]

 Next, a control process of the control unit 500 for moving back the wedge 310 will be described in detail with reference to FIG.

When the control signal for the backward movement of the wedge 310 is applied, the control means 500 determines that the hydraulic fluid having the first hydraulic pressure provided by the booster end 400 is supplied to the hydraulic cylinder portion 200 to provide the second space 212 of the pressurized end.

In this case, the piston 220 inside the hydraulic cylinder 200 moves backward in the backward direction (direction from the second space to the first space).

A predetermined amount of hydraulic fluid filled in the first space 211 of the hydraulic cylinder 200 is discharged according to the backward movement of the piston 220. At this time, 1 space 211 to be recovered to the heavy equipment 20. [0050]

On the other hand, in order to improve the crushing force, when the pressure increase end 400 provides the hydraulic pressure having the second hydraulic pressure in the first space 211 of the hydraulic cylinder 200, the phenomenon that the advancing speed of the wedge 310 is slowed Lt; / RTI >

At this time, the slowing down of the advancing speed of the wedge 310 (that is, the advancing speed of the piston) means that the working speed is slowed. Therefore, it is necessary to improve the advancing speed of the wedge 310 which is slowed down. The configuration is the speed increasing section (700) of the present invention.

That is, the present invention may further include an accelerating portion 700. The accelerating portion 700 may be configured such that the hydraulic fluid having the second hydraulic pressure is supplied to the first space 211 of the hydraulic cylinder 200 The hydraulic fluid discharged from the second space 212 of the hydraulic cylinder 200 is fed back to the first space 211 of the hydraulic cylinder 200 without being recovered by the heavy equipment 20 to advance the wedge 310 Thereby preventing the speed from being slowed down.

The speed increasing unit 700 may include a bypass unit 710 and an intermittent valve 720 as shown in FIG.

6, when the hydraulic fluid having the second hydraulic pressure is supplied to the first space 211 of the hydraulic cylinder part 200, the bypass means 710 may be disposed in the second space of the hydraulic cylinder part 200, And the hydraulic oil discharged from the first space 212 is fed back to the first space 211.

The control valve unit 720 is formed at one side of the bypass means 710 and the hydraulic fluid having the second hydraulic pressure is supplied to the first space The hydraulic oil discharged from the second space 212 of the hydraulic cylinder part 200 is released to be fed back to the first space 211. [

That is, the control valve 720 is controlled by the control means 500 such that the hydraulic pressure discharged from the second space 212 of the hydraulic cylinder 200 is fed back to the first space 211, .

The hydraulic fluid discharged from the second space 212 of the hydraulic cylinder part 200 and fed back to the first space 211 of the hydraulic cylinder part 200 through the bypass means 710 is supplied to the increased pressure end part 400 And is fed back to the first space 211 of the hydraulic cylinder part 200 by joining to the hydraulic fluid having the second hydraulic pressure provided to the first space 211 of the hydraulic cylinder part 200 .

Referring to FIG. 4, the crusher 10 of the present invention further includes a lubricant supply portion 800 for supplying lubricant to the crushing means portion 300.

The lubricant supply unit 800 includes a lubricant tank 810 and a power unit 820. The lubricant tank 810 includes a constricted portion 811 of a bellows type, The lubricating oil is stored in the bellows type shrinking portion 811 and the lubricating oil stored in the shrinking portion 811 during shrinking is supplied to the wedge liner 320 of the shredding means portion 300, Type shrinkable portion 811. [0064]

Particularly, the wedge liner 320 is provided with a lubricating oil flow passage through which the supplied lubricating oil flows, and a lubricating oil discharge port is formed on the surface of the wedge liner 320. The lubricating oil flowing into the lubricating oil passage is discharged through the lubricating oil discharge port To the surface of the wedge liner 320.

The wedge 310 is smoothly moved forward and backward with respect to the wedge liner 320 when the wedge 310 is moved back and forth by the lubricating oil flowing out to the surface of the wedge liner 320.

8 is a partially enlarged view and an operating state view of a direction adjusting means of a crusher which is attached to and connected to a heavy equipment of the present invention to crush an object.

Referring to FIG. 8, the crusher 10 of the present invention further includes direction adjusting means 900 capable of adjusting the working direction of the crusher.

Here, the direction adjusting unit 900 includes a horizontal adjusting unit 910 for adjusting the horizontal working direction of the crusher, and a vertical adjusting unit 920 for adjusting the vertical working direction of the crusher.

8, the horizontal adjusting unit 910 adjusts the horizontal working direction of the crusher 10, and the vertical adjusting unit 920 rotates the crusher 10 (see FIG. 8) ) In the vertical direction.

Hereinafter, a crushing excavation method using the crusher 10 of the present invention will be described.

The crusher used in the crushing excavation method of the present invention is characterized by being the crusher of the present invention having the above-mentioned characteristics.

Specifically, as shown in FIG. 9, in the fracture excavation method of the present invention,

(S100) for forming an insertion hole on the crushing excavation surface using a perforator;

A heavy equipment entering step (S200) of placing a heavy equipment equipped with the crusher according to any one of claims 1 to 10 near a crushing excavation surface;

A first crushing step (S300) of inserting the wedge liner (320) of the crusher into the insertion hole and advancing the wedge (310) by using the first hydraulic pressure to crush the crushing excavation surface near the insertion hole;

A second crushing step (S400) of advancing the wedge (310) using a second hydraulic pressure to crush the crush excavation surface near the insertion hole;

(S500) of collecting the shredded rock mass and taking it out to the outside,

The first hydraulic pressure is a hydraulic pressure supplied from the heavy equipment 20 and is a basic hydraulic pressure provided to the hydraulic cylinder unit 200 by the pressure increase end 400 of the crusher 10,

The second hydraulic pressure is a hydraulic pressure provided to the hydraulic cylinder 200 by the pressure increase end 400 in a predetermined pressure increase ratio provided by the relief part 600 of the crusher 10 do.

The concrete features of the crusher used in the crushing excavation method are the same as those of the crusher described above, and a detailed description thereof will be omitted.

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. In addition, it is a matter of course that various modifications and variations are possible without departing from the scope of the technical idea of the present invention by anyone having ordinary skill in the art.

10: Crusher
20: Heavy Equipment
100:
200: Hydraulic cylinder part
300: crushing means
400: Increase pressure end
500:
600: relief part
700:
800: Lubricant supply part
900: Direction adjusting means

Claims (11)

A shredder attached to and connected to a heavy equipment for shredding an object,
A mounting means (100) for connecting the crusher (10) to the heavy equipment (20);
The hydraulic cylinder part 200 (see FIG. 1) for advancing or retracting the wedge 310 of the shredding device 300 using the hydraulic pressure having the first hydraulic pressure or the hydraulic pressure having the second hydraulic pressure provided by the booster 400, )Wow;
A crushing means portion (300) including a wedge (310) for moving back and forth to crush an object;
A pressure increase end 400 for providing the hydraulic cylinder 200 with a hydraulic fluid having a first hydraulic pressure or a second hydraulic pressure under the control of the control means 500;
When a control signal for advancing or retracting the wedge 310 is applied, a hydraulic fluid having a first hydraulic pressure or a hydraulic fluid having a second hydraulic pressure provided by the booster 400 is supplied to the hydraulic cylinder 200 A control unit 500 for controlling the booster 400 to control the hydraulic fluid discharged from the hydraulic cylinder 200 to be recovered to the heavy equipment 20 in accordance with the forward or backward movement of the wedge 310;
And supplies the hydraulic fluid having the basic oil pressure supplied from the heavy equipment unit 20 to the booster supply end unit 400. If the basic oil pressure supplied from the heavy equipment unit 20 is lower than a predetermined set hydraulic pressure, To the booster end (400), and when the basic oil pressure supplied from the heavy equipment (20) exceeds a predetermined set oil pressure, the hydraulic oil having a predetermined set oil pressure And a relief portion (600) for providing the pressure increase end (400)

The hydraulic cylinder part (200)
And the reciprocating motion space of the piston is divided into the first space 211 and the second space 212 by the piston 220. In this case, A cylinder body 210,
And a piston 220 connected to the wedge 310 and reciprocating by the hydraulic pressure supplied to the hydraulic cylinder 200 to move the wedge 310 forward and backward.

The control means (500)
When a control signal for advancing the wedge 310 is applied, a hydraulic fluid having a first hydraulic pressure, which is provided primarily by the pressure increasing end portion 400, is provided in the first space 211 of the hydraulic cylinder portion 200 When the first hydraulic pressure supplied to the hydraulic cylinder portion 200 reaches a predetermined set hydraulic pressure, the second hydraulic pressure provided by the boosting end portion 400 has a second hydraulic pressure The pressure increase end 400 is controlled so that the hydraulic pressure is supplied to the first space 211 of the hydraulic cylinder 200 and the hydraulic pressure discharged from the second space 212 of the hydraulic cylinder 200 is transmitted to the heavy equipment 20,
When the control signal for the backward movement of the wedge 310 is applied, the hydraulic fluid having the first hydraulic pressure provided by the pressure increase end portion 400 is supplied to the second space 212 of the hydraulic cylinder portion 200, Controls the hydraulic cylinder unit (400) so that the hydraulic fluid discharged from the first space (211) of the hydraulic cylinder unit (200) is recovered to the heavy equipment unit (20)

The hydraulic fluid having the first hydraulic pressure provided by the pressure increase end portion 400 to the hydraulic cylinder portion 200 is a hydraulic fluid having a basic hydraulic pressure supplied from the heavy equipment 20 and provided by the relief portion 600,
The hydraulic fluid having the second hydraulic pressure provided by the pressure increase end portion 400 to the hydraulic cylinder portion 200 is supplied to the pressure increase end portion 400 at a predetermined pressure increase ratio, ) Is pressurized to a hydraulic pressure having a hydraulic pressure, and is attached to and connected to a heavy equipment to crush an object.
delete delete The method according to claim 1,
The crushing means (300)
A wedge 310 which is advanced or retracted by a reciprocating piston 220 due to oil pressure and hydraulic pressure supplied to the hydraulic cylinder 200,
And a wedge liner (320) formed on one side and the other side of the wedge (310) for widening or returning to the original state by advancing or retracting the wedge (310) A shredder for shredding objects.
The method according to claim 1,
The increased pressure end (400)
And a plurality of auxiliary pistons (410) for generating a second hydraulic pressure, wherein the auxiliary piston (410) is connected to the heavy equipment.
The method according to claim 1,
The speed increasing means 700 for preventing the advancing speed of the wedge 310 from being slowed as the hydraulic pressure having the second hydraulic pressure is provided in the first space 211 of the hydraulic cylinder 200 ,
The speed increasing unit 700 is configured to discharge the hydraulic fluid having the second hydraulic pressure from the second space 212 of the hydraulic cylinder 200 when the hydraulic fluid is supplied to the first space 211 of the hydraulic cylinder 200 Wherein the hydraulic cylinder unit (200) is fed back to the first space (211) without returning the hydraulic fluid to the heavy equipment unit (20).
The method of claim 6,
The speed increasing unit (700)
When the hydraulic fluid having the second hydraulic pressure is supplied to the first space 211 of the hydraulic cylinder 200, the hydraulic fluid discharged from the second space 212 of the hydraulic cylinder 200 flows into the first space 211 (710) for guiding the signal to be fed back,
A hydraulic fluid having a second hydraulic pressure is released upon provision of the first space 211 of the hydraulic cylinder portion 200 under the control of the control means portion 500, And an intermittent valve (720) for interrupting the hydraulic fluid discharged from the second space (212) of the cylinder part (200) so as to be fed back to the first space (211) crusher.
The method of claim 7,
The hydraulic fluid which is discharged from the second space 212 of the hydraulic cylinder part 200 and fed back to the first space 211 of the hydraulic cylinder part 200 through the bypass means 710 is supplied to the increased pressure end part 400, Is fed to the first space (211) of the hydraulic cylinder part (200) by means of the hydraulic cylinder part (200) and fed back to the first space (211) of the hydraulic cylinder part And is connected to the crusher to crush the object.
The method according to claim 1,
And a lubricant supply part (800) for supplying lubricant to the crushing part (300)
The lubricating oil supply unit (800)
A lubricant tank 810 for storing lubricating oil in the bellows type constricted portion 811 and supplying the lubricant stored in the constricted portion 811 to the wedge liner 320,
And a power means (820) for generating a power for shrinking the bellows type shrinkage portion (811), wherein the shredding portion (811) is attached to the heavy equipment.
The method according to claim 1,
Further comprising a direction adjusting means (900)
The direction adjusting means (900)
A horizontal adjustment unit 910 for adjusting the horizontal working direction of the crusher,
And a vertical adjustment unit (920) for adjusting the vertical working direction of the crusher.
A crushing excavation method using a crusher connected to a heavy equipment for crushing an object,
(S100) for forming an insertion hole on the crushing excavation surface using a perforator;
A heavy equipment entering step (S200) of placing a heavy equipment equipped with the crusher according to any one of claims 1 to 10 near a crushing excavation surface;
A first crushing step (S300) of inserting the wedge liner (320) of the crusher into the insertion hole and advancing the wedge (310) by using the first hydraulic pressure to crush the crushing excavation surface near the insertion hole;
A second crushing step (S400) of advancing the wedge (310) using a second hydraulic pressure to crush the crush excavation surface near the insertion hole;
(S500) of collecting the shredded rock mass and taking it out to the outside,
The first hydraulic pressure is a hydraulic pressure supplied from the heavy equipment 20 and is a basic hydraulic pressure provided to the hydraulic cylinder unit 200 by the pressure increase end 400 of the crusher 10,
The second hydraulic pressure is a hydraulic pressure provided to the hydraulic cylinder 200 by the pressure increase end 400 in a predetermined pressure increase ratio provided by the relief part 600 of the crusher 10 Lt; / RTI >

Images