KR20140074847A - Hydraulic Vibratory Ripper - Google Patents

Abstract

The present invention relates to a vibration ripper mounted to heavy equipment, such as an excavator. The vibration ripper includes a housing connected to a boom, a vibration unit provided in the housing and having a vibrator, and a ripper blade protruding from the vibration unit. In order to engage the ripper blade with the housing to be able to rotate up and down without having a clearance in a left and right direction, upper and lower link units have a plurality of links, with one end being connected to upper and lower portions of both sides in the housing to be able to rotate, and the other end protruding from the housing and connected to upper and lower portions of the ripper blade to be able to rotate. A booster is installed between the housing and the vibration unit to boost the working force of the ripper blade. The vibration intensity of the vibrator is adjusted by an adjusting member.

Description

{Hydraulic Vibratory Ripper}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hydraulic vibration ripper mounted on heavy equipment such as an excavator, and more particularly, to a hydraulic vibration ripper mounted on a heavy equipment such as an excavator, The present invention relates to a hydraulic vibration ripper.

Generally, an excavator refers to a civil engineering vehicle used for excavating soil, and basically a bucket for lifting up the soil is mounted on the end of the boom.

In addition, a breaker for crushing a rock or a concrete structure or a ripper for raking the soil of the ground may be used instead of the bucket at the end of the boom.

Particularly, such an excavator ripper is mainly used for excavating the soil of the ground or removing the stone buried in the ground from the soil. The vibration ripper is constituted by a hydraulic vibration ripper (hereinafter referred to as "Quot; vibration ripper ").

1, the conventional vibration ripper 1 has a vibrating space 11 inside thereof and a mount cap 12 (not shown) for coupling with the boom frame 2 on the upper side. A vibrating unit 20 disposed in the vibrating space 11 and provided with a vibrator 30 and a ripper blade 10 extending downwardly from the vibrating unit 20, And a plurality of vibration damping rubbers for supporting the vibrating unit 20 in a vibratable manner with respect to the housing 13 so as to support both sides of the vibrating unit 20 and the inner side surfaces of the corresponding housing 13, (40).

The vibration ripper 1 vibrates the vibration unit 20 in the vertical direction by the vibration generated in the vibrator 30 of the vibration unit 20 provided in the vibration space 11 in the housing 13, (10) is vibrated up and down.

At this time, the vibrations in both the left and right directions generated in the vibration unit 20 are absorbed by the plurality of anti-vibration rubber 40 provided between the vibration unit 20 and the housing 13 and are absorbed by the housing 13 and the boom frame 2, Lt; / RTI > is blocked.

However, in such a conventional vibration ripper 1, when excavating the ground with the ripper blade 10 or crushing the rock, the digging resistance of the ground acts in the direction opposite to the operating direction of the ripper blade 10, The operation force of the ripper blade 10 is supported by the plurality of vibration-proof rubber 40 provided between the housing 13 and the vibration unit 20 Excessive deformation of the vibration-proof rubber 40 may be caused by repetitive operation and a large force of the momentarily acting ripper blade 10 and the vibration of the vibration-proof rubber 40 due to the deformation of the vibration- So that the vibration unit 20 continuously collides with the surrounding structure including the housing 13, thereby deteriorating durability.

The vibration ripper 1 according to the related art is used for lifting and lowering the ripper blade 10 due to vibrations generated in the vibrator 30 of the vibration unit 20 to crush the ground or to crush the rock. 1) is generated only by the vibration of the vibrator 30, there is a problem that the vibrating ripper 1 can not double its excavating force (crushing force).

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the above-mentioned problems of the conventional art, and it is an object of the present invention to provide a vibrating unit in which a link unit is formed between a housing and a vibration unit, And an object of the present invention is to provide a hydraulic vibration ripper capable of preventing collision between peripheral structures including a housing and a surrounding structure.

It is another object of the present invention to provide a hydraulic vibration ripper which is provided between a housing and a vibration unit so as to double the excavating force of a ripper blade when a vibration ripper is operated.

The above-described object is achieved by a vibration ripper comprising a housing connected to a boom frame, a vibration unit provided in the housing and having a vibrator, and a ripper blade protruding from the vibration unit, the vibration ripper comprising: One end of each of which is rotatably coupled to both the upper and lower sides of the inside of the housing and the other end of which is protruded from the housing and rotatably coupled to the upper and lower portions of the ripper blade, A boosting unit installed between the housing and the vibration unit to double the operating force of the ripper blade; And adjusting means capable of adjusting the vibration intensity of the vibrator.

A support plate formed on the link of the lower link unit and supporting the vibration unit; And a stop damper installed on the support plate and contacting and separating from the vibration unit.

The vibrator may include a plurality of shafts rotatably mounted on the vibrating unit and having a motor connected to one side thereof; Gears fixed to the shafts and engaged with each other; A loader eccentrically installed on both the gears and integrally rotated with the gears; And a weight member detachably coupled to the loader to vary the weight of the loader.

Preferably, the loader is installed on one or both surfaces of the gear.

According to the hydraulic vibration ripper of the present invention, since the vibrating unit is provided between the upper and lower link units provided so as to be in contact with the inner side surface of the vibration space of the housing connected to the boom frame, the vibrating unit is instantaneously and repetitively It is possible to firmly support the vibration unit and to prevent deformation, damage or breakage of the link unit, thereby preventing collision between the vibration unit and the surrounding structure including the housing.

Further, according to the present invention, in addition to the vibration by the vibrator during operation of the vibration unit, the excavating force (crushing force) of the ripple blade is increased by the expansion device by the expansion device, thereby improving the working efficiency.

1 is a view showing a conventional hydraulic vibration ripper.
Fig. 2 is a view showing the hydraulic vibration ripper according to the present invention.
3 is an illustration of a hydraulic vibration ripper according to the present invention.
4 is a sectional view of a hydraulic vibration ripper according to the present invention.
FIG. 5 is a view showing an operating state of a hydraulic vibration ripper according to the present invention, wherein FIG. 5A is a state in which the ripper blade is raised, and FIG. 5B is a state in which the ripper blade is in a lowered state.
6 is a configuration diagram showing the vibration control means of the hydraulic vibration ripper according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 to 6 are views showing a hydraulic vibration ripper according to the present invention.

2 to 4, the hydraulic vibration ripper 100 of the present invention includes a housing 110, a vibration unit 160, a link unit 130 (140 ).

The housing 110 is formed in a box shape including an upper plate and a plurality of side plates and the inside of the housing 110 is formed as a vibration space portion 111. The rear and lower surfaces of the housing 110 facing the driver's seat of the excavator are opened, Is installed so as to protrude through the rear surface and the bottom surface of the housing 110.

A mount cap 120 is formed on the upper portion of the housing 110 so as to be connected to a boom frame. The housing 110 is installed to be movable up and down through a link unit 130 (140) The vibration unit 160 is constituted.

The vibration unit 160 is configured to be movable only in the vertical direction without a left and right clearance in the vibration space 111 inside the housing 110 by the link units 130 and 140 to be described later.

The vibrating unit 160 is implemented through a gear box 161 and a ripper blade 190 is formed on one side of the gear box 161 so as to protrude upward and downward from the gear box 161, A power unit 180 for connecting the gear box 161 to the inner upper surface of the housing 110 is installed on the upper surface of the housing 161.

The power unit 180 includes a mount portion 181 mounted on both the inner upper surface of the housing 110 and the upper surface of the gear box 161 at both ends thereof and a mount portion 181 formed between both mount portions 181, And a stretchable and contractible portion 182. The stretchable and contractible portion 182 is formed of a corrugated tube made of a rubber material (also referred to as a "bellows tube" or "bellows") and is filled with nitrogen gas so that it absorbs vibration while being compressed, 190 in the axial direction.

A support bracket 183 is provided between the lower surface of the power unit 180 and the upper surface of the gear box 161 to compensate the installation height of the power unit 180. The support bracket 183 has an upper plate 183a fixed to the lower surface of the power unit 180 and a lower plate 183b fixed to the upper surface of the gear box 161 and upper and lower plates 183a And a plurality of support ribs 183c radially disposed between the support ribs 183a and 183b. Since the support bracket 183 is installed on the upper surface of the gear box 161 where vibration is directly generated, the support bracket 183 is able to withstand vibration and impact by a plurality of support ribs 183c, . ≪ / RTI > The support bracket 183 may be provided between the upper surface of the power unit 180 and the upper surface of the inner side of the housing 110.

An upper link unit 130 and a lower link unit 140 are rotatably engaged with upper and lower engaging portions 191 and 192 respectively formed on the upper and lower portions of the ripper blade 190 .

3 and 6, the vibrator 170 includes a plurality of shafts 171 (171a, 171a) and a plurality of shafts 171a (171a, 171b) in the gear box 161, And gears 172 and 172a are provided at the center of the outer peripheral surface of the shafts 171 and 171a.

One of the shafts 171a and 171a is constituted by a drive shaft 171 directly driven by a motor 177 and the other shaft is driven by gears 172 and 172a by a drive shaft 171 And a driven shaft 171a that is interlocked.

The gears 172 and 172a are keyed and fixed to the shafts 171 and 171a and the gears 172 and 172a are engaged with each other while being engaged with each other.

Loaders 173 and 173a for generating vibrations are provided on both sides of the gears 172 and 172a and the loaders 173 and 173a are provided on both sides of the shafts 172 and 172a in the same manner as the gears 172 and 172a. 171) 171a. The loaders 173 and 173a are formed in a semicircular shape and eccentrically disposed on one side of the gears 172 and 172a in a state of being keyed to the shafts 171 and 171a so that the shafts 171 and 171a The gear box 161 is moved upward and downward while being rotated together with the gears 172 and 172a.

On the other hand, the loaders 173 and 173a are provided with adjusting means for adjusting the vibration intensity of the vibrator 170. [ That is, the adjustment means is provided with stepped mounting grooves 174a and 174a on the surfaces of the respective loaders 173 and 173a, and the mounting grooves 174 and 174a are provided with loaders 173 and 173a, And a weight member 175 (175a) for varying and adjusting the weight member 175 is detachably installed. These mounting grooves 174 and 174a may be formed on both sides of the loader 173 and 173a but may be mounted only on one side of the loader 173 or 173a opposite to the gear 172 or 172a in this embodiment Grooves 174 and 174a are formed.

The weight members 175 and 175a formed in a shape corresponding to the mounting grooves 174 and 174a of the loaders 173 and 173a are formed in a state in which the loaders 173 and 173a are engaged with the gears 172 and 172a, 174a by a bolt that fixes the mounting hole 174a to the mounting groove 174a. It is also possible to apply a magnetic force to the weight members 175 and 175a and to attach and detach them to the mounting grooves 174 and 174a of the loader 173 and 173a by magnetic force.

The vibrating force of the vibrator 170 can be adjusted by varying the weight of the weight members 175 and 175a so that the excavating force of the ripper blade 190 can be adjusted to various strengths.

The link units 130 and 140 are composed of an upper link unit 130 and a lower link unit 140 respectively provided on upper and lower sides of the inside of the housing 110.

The upper and lower link units 130 and 140 are constituted by a plurality of links 132 and 142 rotatably hinged to both inner plates of the housing 110 with one end connected thereto, 132) 142 are rotatably coupled to the upper and lower coupling portions 191, 192 of the ripper blade 190, respectively. Of course, bearings are provided at both ends of the links 132 and 142.

The links 132 and 142 are connected to the coupling parts 133 and 143 of the front end of the hinge parts 131 and 141 while being coupled to both side plates of the housing 110, (190) is moved up and down.

A support plate 144 supporting the lower surface of the gear box 161 of the vibration unit 160 is installed between the links 142 of the lower link unit 140 among the link units 130 and 140 And a stop damper 150 is disposed on the upper surface of the support plate 144 to be in contact with and separated from the lower surface of the gear box 161.

The stop damper 150 includes a mount part 151 fixed to the upper surface of the support plate 144 and a damper part installed on the upper surface of the mount part 151 to absorb the vibration transmitted from the gear box 161 152). Here, it is preferable that the damper part 152 is formed of a compressed rubber material.

The operation of the hydraulic vibration ripper according to the present invention as described above will be described.

The operation of the vibration ripper 100 is controlled such that the drive shaft 171 directly connected to the motor 177 is rotationally driven and the key 176 is connected to the drive shaft 171 when the motor 177 configured in the vibrator 170 is operated, And the loader 173 located on both sides of the drive gear 172 is rotationally driven integrally with the drive shaft 171.

The driven shaft 171a adjacent to the drive shaft 171 is fixedly coupled to the key 176a and is coupled to the drive shaft 171a by a driven gear 172a engaged with the drive gear 172 of the drive shaft 171. [ And the loader 173a coupled to the driven shaft 171a with the key 176a is also rotationally driven integrally with the driven shaft 171a.

Therefore, the vibration is generated by the loader 173 (173a) which is rotationally driven like the shaft 171 (171a), and the gear box 161 of the vibration unit 160 is moved by the vibration of the housing 110 And supported by the link unit 130 (140) in the vertical direction.

The upper and lower link units 130 and 140 are connected to the housing 110 by the hinge portions 131 and 141 at one end thereof, The coupling parts 133 and 143 are rotated up and down as shown in the seesaw and the ripper blade 190 coupled to the coupling parts 133 and 143 at the other end of the upper and lower link units 130 and 140, As shown in FIG. 5A and FIG. 5B, the soil in the ground is moved or the stone buried in the ground is removed from the soil.

5A, when the ripper blade 190 is lifted up, the stretchable and contractible portion 182 of the booster 180 is compressed to absorb the vibration, and as shown in FIG. 5B, When the ripper blade 190 is lowered, the stretchable and contractible portion 182 of the booster 180 is stretched to double the excavating force of the ripper blade 190.

5A and 5B, the gear box 161 of the vibration unit 160, which moves the ripper blade 190 up and down during operation of the ripper blade 190, Is operated in a state of being firmly supported by the link units 130 and 140 in the housing 110 without left and right clearances so that the gear box 161 is moved only in the vertical direction and not in the right and left directions.

Up and down vibrations of the gear box 161 when the gear box 161 is moved up and down are absorbed by the stopper 150 at the lower portion of the gear box 161 and the power unit 180 at the upper portion of the gear box 161.

That is, the booster 180 connects the inner upper surface of the housing 110 with the upper surface of the gear box 161 to absorb the vibration while being compressed by the upward movement of the gear box 161, and the stop damper 150, And is disposed on the upper surface of the support plate 144 of the unit 140 to selectively contact the lower surface of the gear box 161 to thereby absorb vibration as well as to prevent transmission of vibration in advance. 5A, the stop damper 150 is disengaged from the lower surface of the gear box 161 so that the gear box 161 is engaged with the gear box 161. In this case, It is possible to prevent the vibration from being transmitted to the lower link unit 140 in advance and to prevent the vibration of the lower link unit 140 when the ripper blade 190 is lowered The stop damper 150 contacts the lower surface of the gear box 161 to absorb the vibration of the gear box 161. [

In order to control the intensity of vibration during operation of the vibration ripper 100 as described above, a loader 173 (see FIG. 1) coupled to both gears 172 (172a) of the shafts 171 and 171a 173a are separated from the shafts 171 and 171a and then the weight members 175 and 175a are fixedly engaged with the mounting grooves 174 and 174a of the loaders 173 and 173a, The weight members 175 and 175a coupled to the mounting grooves 174 and 174a of the driving shaft 173a are separated and adjusted to adjust the weight of the loaders 173 and 173a.

At this time, it is preferable that the weight members 175 and 175a are installed and separated in the same manner in all the loaders 173 and 173a.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the same is by way of illustration and example only and is not to be construed as limiting the present invention. It is obvious that the modification or improvement is possible.

It is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

100: vibration ripper 110: housing
111: vibration space part 120: mount cap
130, 140: Link unit 131, 141:
132.142: Link 133, 143:
144: Support plate 150: Stop damper
151: mount part 152: damper part
160: vibration unit 161: gear box
170: Vibrator 171,171a: Shaft
172, 172a: gears 173, 173a:
174, 174a: mounting groove 175, 175a: weight member
176, 176a: key 177: motor
180: power assist device 181: mount part
182: extensible portion 183: support bracket
183a: upper plate 183b: lower plate
183c: Support rib 190: Ripper blade
191, 192:

Claims (4)

A vibration ripper comprising a housing connected to a boom frame, a vibrating unit provided in the housing and having a vibrator, and a ripper blade protruding from the vibrating unit,
One end of which is rotatably coupled to both the upper and lower sides of the inside of the housing and the other end of which is protruded from the housing so as to be rotatable about the upper and lower sides of the ripper blade, And an upper and a lower link unit having a plurality of links each rotatably coupled to a lower portion thereof,
A booster provided between the housing and the vibration unit to multiply the operating force of the ripper blade; And
And adjustment means for adjusting the vibration intensity of the vibrator.
The method according to claim 1,
A support plate formed on a link of the lower link unit to support the vibration unit; And
And a stop damper installed on the support plate and contacting and separating from the vibration unit.
The method according to claim 1 or 2,
The vibrator includes: a plurality of shafts rotatably mounted on a vibrating unit and having a motor connected to one side;
Gears fixed to the shafts and engaged with each other;
A loader eccentrically installed on both the gears and integrally rotated with the gears; And
And a weight member detachably coupled to the loader to vary the weight of the loader.
The method of claim 3,
The loader is mounted on one or both surfaces of the gear, respectively.

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