KR20110116647A - Vabratory ripper for heavy equipment - Google Patents

Abstract

The present invention relates to a vibrating nipper for heavy equipment, in which a plurality of gears having an eccentric weight embedded in a vibrating body are arranged in a vertical direction and rotate to generate a vertical vibration. Arranged in the direction so as to be rotatable, each gear is provided with an eccentric body is provided with a vibrating body for generating vibration in the vertical direction during the rotation of the gear, the lower portion of the vibrating body in the nipper blade in the longitudinal direction of the vibrating body When mounted and ground excavation, it provides a vibrating nipper for heavy equipment configured to insert the vibrating body along the nipper blade to the depth of the ground.
According to the present invention, the width of the vibrating body can be made narrower than before, so that the butterfly of the frame can be made narrower, so that even if the nipper blade enters the ground, the vibrating body can be inserted along the nipper blade to the depth of the ground so that the excavation depth It is possible to deepen and to obtain an excellent effect of greatly improving the excavation performance. Furthermore, according to the present invention, even when the nipper blade is excavated from the ground, the nipper blade and the vibrating body are connected to the frame by a link structure which is displaced in the vertical direction even if the nipper blade receives the lateral resistance from the ground. By improving the lateral support structure, the operation of the nipper blade is free, the shock absorbing material supporting the vibration main body is protected and not damaged, and the durability is greatly improved.

Description

Vibration nipper for heavy equipment {VABRATORY RIPPER FOR HEAVY EQUIPMENT}

The present invention relates to a vibrating nipper for heavy equipment equipped with heavy equipment such as excavators, bulldozers and wheel loaders to effectively carry out crushing and excavation work in civil and demolition sites, and more particularly, having an eccentric weight embedded in a vibrating body. A plurality of gears are aligned in the longitudinal direction (up and down direction), and by generating vibration in the vertical direction while rotating, the width of the vibrating body is made narrow, the nipper blade can be inserted to the depth of the ground, and the frame and the vibrating body are connected by a link structure. The operation of the nipper blades is free, and the built-in cushioning material is protected, and the durability relates to a vibrating nipper for heavy equipment greatly improved.

In general, in the construction site, in order to crush a rock, a breaker iron core is mounted on the arm of heavy equipment, and the rock is crushed by hitting the rock.

However, such a conventional breaker hitting method requires a large amount of low noise and high efficiency since noise pollution is generated largely.

In rocky terrain, the rocker must be used to break the rock, but for soft rock, the rocker breaks the rock instead of breaking the rock, so it is not only a rock breaker like a breaker, but also ground like an excavator. It is necessary to equip a type of excavator that can be sold and to break and dig the ground while vibrating up and down like a breaker.

To this end, the applicant of the present invention has developed a "vibrator nipper" of Patent No. 10-0755017, "vibration nipper" of Publication No. 10-2009-0054513 and "vibration nipper" of Patent No. 10-0878296 Therefore, it has proposed a technology that can effectively perform the crushing and excavation work with low noise.

1A and 1B show such a conventional vibrating nipper as an example.

The conventional vibration nipper 1 has a vibration body 20 disposed inside the guide bracket 10 having the mount portion 12 formed thereon, and a hydraulic motor (not shown) inside the vibration body 20. 2) the gear 23 of the drive shaft 22 provided with the eccentric weight 21 and the gear 23 'of the driven shaft 22' provided with the eccentric weight 21 'are horizontally engaged. The vibrator of the shaft is installed.

In addition, the both sides of the vibration main body 20 is mounted by combining the anti-vibration rubber 31, 31 ', 32, 32' and the anti-vibration rubber 31, 31 ', 32, 32' The guide bearings 41 and 42 are installed between the inside of the guide bracket 10 and the outside of the vibration body 20 at upper and lower ends thereof, and the outer circumference of the guide bearings 41 and 42 is the vibration body. It is provided so that a predetermined space | interval is maintained with the outer surface of (20). The nipper blade 50 is bolted to the lower end of the vibration main body 20.

As shown in FIG. 1B, the conventional vibration nipper 1 is horizontally engaged by horizontally engaging gears 23 and 23 ′ rotated by a hydraulic motor in the vibration body 20. The width W of the vibrating body 20 is relatively wide, and the wide width W of the vibrating body 20 may not enter the ground even if the nipper blade 50 enters the ground. . Therefore, the conventional technique in which the gears 23 and 23 'are disposed in the transverse direction in the vibrating body 20 as described above has a problem in that the ground cannot be deeply excavated.

And the conventional vibrating nipper 1 is subjected to the excavation resistance of the ground in the opposite direction that the nipper blade 50 moves, that is, the direction (A) in Figure 1a when the nipper blade 50 excavates the ground, In order to support this force, the conventional vibrating nipper 1 has a means of adding a plurality of friction support structures 41 and 42 or installing a plurality of reinforced anti-vibration rubbers. There was a problem that the vibration-resistant rubber (31) (31 ') (32) (32') is easily torn or the buffering capacity of the anti-vibration rubber is lowered due to excessive lateral deformation due to the lack of excessive transverse direction.

Therefore, when the digging force is increased easily breakage and durability is degraded, it takes a lot of time to maintain the maintenance.

The present invention is to solve the conventional problems as described above, the object is that the built-in gears and eccentric weights vibrate in the vertical direction, the excavation of the ground even in the state of producing a narrow width of the vibrating body of the hydraulic motor In this case, the vibrating main body along the nipper blade can be inserted deep into the ground to provide a vibrating nipper for heavy equipment that greatly improves the excavation performance.

Another object of the present invention is that when the nipper blade excavates the ground, the nipper blade and the vibrating main body are connected to the frame by a link structure in which the nipper blade and the vibrating body are displaced in the vertical direction with respect to the frame even when the nipper blade receives the resistance in the lateral direction from the ground. The present invention provides a vibration nipper for heavy equipment that greatly buffers the directional resistance and frees the operation of the nipper, and protects the shock absorbing material that supports the vibration agent, thereby greatly improving its durability.

In order to achieve the above object, the present invention, in the vibrating nipper which is mounted on the arm of heavy equipment such as excavators, bulldozers and wheel loaders to perform the crushing and excavation at the same time in civil engineering and demolition site,

Gears that are rotated by a hydraulic motor are arranged to be rotatable in the vertical direction therein, each gear is provided with an eccentric body is provided with a vibration body for generating vibration in the vertical direction during the rotation of the gear, the vibration body The lower portion of the vibrating body is equipped with a nipper blade in the longitudinal direction of the ground, when the ground provides a vibrating nipper for heavy equipment configured to be inserted into the ground depth along the nipper blade to the ground.

And the present invention preferably the vibration body is aligned three gears therein in the vertical direction, the eccentric weight rotation moment size of the center gear relative to the rotation moment size of the eccentric weights connected to the upper and lower gears is 2: 1 When the gears are rotated, the lateral centrifugal force generated from the eccentric weights of the upper and lower gears and the lateral centrifugal force generated from the eccentric weights of the central gear are formed to have the same magnitude in opposite directions and cancel each other out. In the vertical direction, centrifugal force overlaps each other to provide a vibration nipper for heavy equipment that generates vibration.

In addition, the present invention preferably wherein the gear is connected to the hydraulic motor to operate as a drive gear, the central gear is rotated in the opposite direction to the rotation direction of the upper gear, the lower gear by rotating in the opposite direction of the center gear When the eccentric weights of the upper and lower gears are positioned in the lateral direction, the eccentric weights of the central gear are disposed in the opposite lateral directions so that the centrifugal force of each other is canceled, and when the eccentric weights of the upper and the lower gears are positioned in the upper and lower directions, The eccentric weight of the center gear is disposed in the same up and down direction as the eccentric weights of the upper and lower gears to provide a vibration nipper for heavy equipment that overlaps centrifugal force and generates vertical vibration.

And the present invention preferably the vibration main body is formed in the form of a four-section link by the upper and lower edges of the front and the link through the pin, respectively, to the transverse excavation resistance transmitted from the ground through the nipper blade. The vibration main body provides an oscillating nipper for up and down vibration, which is supported by the lever movement of the link while being effectively supported.

In addition, the present invention is preferably the vibration main body is supported by a plurality of cushioning materials each of which the front and rear edges are built into the frame, the shock absorbing material is mounted on the inside of both sides of the plate made of iron plate vibration-resistant rubber vibration Provided is a vibrating nipper for heavy equipment configured to dampen.

According to the present invention, the gears are arranged in the vertical direction of the vibration body so as to be rotatable, and each gear is equipped with an eccentric shaft to generate vibration in the vertical direction during the rotation of the gear, thereby making the width of the vibration body narrower than before. I can make it.

Therefore, the frame of sufficiently strong structure (b) can be configured in a narrow form, so that the frame does not become an obstacle during excavation work can be inserted along the nipper blade to the depth of the ground can deepen the excavation depth, greatly digging performance An improved effect can be obtained.

According to the present invention, the upper and lower edges of the front surface of the vibrating body are connected to the frame surrounding the vibrating body through a link and a pin so as to be displaced in an up and down direction, so that the nipper blade is ground when the nipper blade excavates the ground. Nipper blades and the vibrating body are connected to the frame in a vertically displaced link structure even when a lateral digging force is applied to the frame, so that the lateral digging resistance of the nipper blade can be sufficiently supported so that strong excavation can be achieved. Since the vertical motion is free, the shock absorbing material for supporting the vibration main body is protected and not damaged, and the durability is greatly improved.

Figure 1a is a perspective view of a vibrating nipper according to the prior art.
1B is an explanatory diagram illustrating a process of operating a plurality of gears and eccentric weights mounted in a transverse direction to a vibrating nipper according to the related art.
Figure 2 is a perspective view showing a vibration nipper for heavy equipment according to the present invention.
Figure 3a is a side view showing a vibration nipper for heavy equipment according to the present invention.
Figure 3b is a longitudinal sectional view of the vibration nipper for heavy equipment according to the present invention.
Figure 4 is a side cross-sectional view showing a structure in which the three gears and the eccentric weights provided in the vibration nipper for heavy equipment according to the present invention arranged in the longitudinal direction (up and down direction).
Figure 5a is an exploded perspective view showing a structure in which the front edge of the vibrating body in the vibration nipper for heavy equipment according to the present invention is mounted so as to be displaced vertically in the frame by pins and links.
FIG. 5B is an explanatory diagram showing a trajectory of a pin and a link connecting the vibrating main body and the frame shown in FIG. 5A.
Figure 6a is a perspective view showing a shock absorbing material provided in the vibration nipper for heavy equipment according to the present invention.
6B is a cross-sectional view illustrating a structure in which a plurality of shock absorbing materials provided in the vibration nipper for heavy equipment according to the present invention are provided in the upper and lower portions of the frame.
7a to 7d is a gear and the eccentric weights provided in the vibration nipper for heavy equipment according to the present invention, the centrifugal force is oscillated in the longitudinal direction (up and down direction), and the horizontal centrifugal force is canceled with each other and vibration does not occur It is explanatory drawing which showed the situation step by step.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

Vibration nipper 100 for heavy equipment according to the present invention is a device that can be mounted on the arm of heavy equipment such as excavators, bulldozers and wheel loaders to perform the crushing and excavation at the same time in civil and demolition site.

Vibration nipper 100 for heavy equipment according to the present invention as shown in Figure 2 as a whole, the upper mounting bracket 110 is formed with an arm fastening hole 112 connected to the arm of the heavy equipment is formed, the mounting ( Frame 120 is connected to the lower side of the 110 in a roughly "∩" shape, the vibration body 130 is located inside the frame 120, the nipper blade 135 is mounted on the bottom.

As shown in FIGS. 3B and 4, the vibrating body 130 rotates with the gears 142a, 142b, and 142c rotated by the hydraulic motor 140 vertically aligned therein. Each of the gears 142a, 142b, and 142c is equipped with eccentric weights 144a, 144b, and 144c on one side, and the gears 142a, 142b, and 142c are rotated. It is a structure that generates vibration in the vertical direction.

That is, the vibration body 130 is coupled to the three gears (142a, 142b, 142c) aligned in the vertical direction, that is, the longitudinal direction therein, as shown in Figure 3a through such a structure. The width w1 of the frame 120 and the vibrating body 130 may be formed to be significantly smaller than the existing width W.

The nipper blade 135 is mounted to the lower portion of the vibrating body 130 in the longitudinal direction of the vibrating body 130. As described above, the present invention provides a small width w1 of the frame 120 and the vibrating body 130. Due to this, the width of the frame (w2) can be sufficiently increased, and thus, the frame of sufficiently strong structure can be formed in a narrow form of the butterfly (b), so that the width of the frame is not an obstacle in the ground excavation, so that the vibration main body 130 is Along the nipper blade (135) can be inserted to the depth of the ground, thereby increasing the excavation performance.

Meanwhile, the three gears 142a, 142b, and 142c embedded in the vibration body 130 may be used to determine the rotation moment magnitude of the eccentric weights 144a and 144c connected to the upper and lower gears 142a and 142c. The magnitude of the rotation moment of the eccentric weight 144b of the center gear 142b is 2: 1.

That is, when the gears rotate, centrifugal force is generated by the rotation moments of the eccentric weights 144a, 144b, and 144c, respectively, in the three gears 142a, 142b, and 142c. The lateral centrifugal force generated from the eccentric weights 144a and 144c of the 142c and the lateral centrifugal force generated from the eccentric weight 144b of the central gear 142b are formed to have the same magnitude in the opposite direction to each other. It is configured to cancel each other, and centrifugal forces overlap each other in the vertical direction to generate vibration.

As shown in FIG. 3B, the three gears 142a, 142b, and 142c embedded in the vibration main body 130 are connected to the hydraulic motor 140 to operate as a drive gear. The center gear 142b engaged at the lower side of the upper gear 142a rotates in a direction opposite to the rotational direction of the upper gear 142a, and the lower gear 142c engaged at the lower side of the upper gear 142a is formed of the center gear 142b. It will rotate in the opposite direction.

Through this structure, the eccentric weights 144a and 144c of the upper and lower gears 142a and 142c rotate in the same direction, and the eccentric weights 144b of the central gear 142b rotate in opposite directions. Structure.

And the vibration nipper 100 for heavy equipment according to the present invention, as shown in Figure 5a, the front lower edge 132a of the vibration body 130 through the link 162a and the pins 164a (164b) vibration body It is connected to the frame 120 surrounding the 130, the front upper edge 132b is connected to the frame 120 in the form of a four-section link mechanism through links 162b and pins 164c and 164d.

Therefore, when the ground is excavated through the nipper blade 135, a strong lateral excavation resistance is applied to the nipper blade 135 from the ground, and the lateral excavation resistance at this time is an up and down link connected to the vibration main body 130 ( When the vibration main body 130 is supported by the frame 120 through the 162a and 162b and the vibration body 130 vibrates by the vibrating force of the eccentric weight, the vertical movement is performed by the lever movement of the up and down links 162a and 162b. It is displaced by drawing an arc.

That is, the vibrating body 130 has a front lower edge 132a connected to one side of the link 162a through a pin 164a, and the other side of the link 162a surrounds the vibrating body 130. 120 is connected via a pin 164b, the upper front edge 132b of the vibration body 130 is connected with one side of the link 162b through the pin 164c, and the other side of the link 162b is the pin 164d. By connecting to the frame 120 through the vibration body 130, the frame 120, the links 162a, 162b form a four-section link mechanism, when the nipper blade 135 excavates the ground When the nipper blade 135 receives the excavation resistance in the lateral direction from the ground, as shown in FIG. 5B, the vibration main body 130 has the nipper blade 135 and the vibration main body 130 with respect to the frame 120. It is possible to move in a circular arc in the vertical direction through the links 162a, 162b and the pins 164a, 164b, 164c, and 164d to support the action of the force in the transverse direction A. Can vibrate up and down.

In addition, as shown in FIG. 3A, the front edge 138a and the rear edge 138b of the vibrating body 130 are supported by a plurality of buffer members 170 embedded in the frame 120, respectively. As shown in FIG. 6A, the same cushioning material 170 has a structure in which anti-vibration rubber 174 is mounted inside both side plates 172a and 172b each made of iron plates.

In addition, as shown in FIG. 6B, the shock absorbing materials 170 are provided in a plurality of pairs in the upper and lower sides of the frame 120 to effectively cushion the vibration generated by the vibration main body 130.

The vibration nipper 100 for heavy equipment according to the present invention configured as described above is operated so that the vibration body 130 mounted inside the frame 120 vibrates up and down, and the vibration is suppressed in the horizontal direction or the left and right directions during its operation. do.

That is, as shown in Figure 7a, before the vibration main body 130 operates, the upper and lower eccentric weights (144a, 144c) connected to the upper and lower gears (142a, 142c) located therein, and the center The central eccentric weights 144b formed in the gear 142b are disposed downward by their own weight.

When the hydraulic motor 140 operates in such a state, the upper gear 142a rotates clockwise as shown in FIG. 7B, and the upper eccentric weight 144a rotates in the same direction, and the upper portion The central gear 142b meshed with the gear 142a rotates in the opposite direction, and also rotates the central eccentric weight 144b in the opposite direction to the upper eccentric weight 144a.

In addition, the lower gear 142c meshed with the center gear 142b rotates in the opposite direction to the center gear 142b, and the lower eccentric weight 144c also rotates in the opposite direction to the center eccentric weight 144b.

Therefore, when the gears 142a, 142b, and 142c rotate as described above, centrifugal force is generated by the eccentric weights 144a, 144b, and 144c mounted on the gears. The rotation moment of is to maintain a 2: 1 rotation moment ratio corresponding to twice the rotation moment of each of the upper and lower eccentric weights (144a, 144c), so that the rotation moment of the central eccentric weight (144b) The centrifugal forces directed to the right cancel each other by the centrifugal forces directed to the left in the rotation moments of the upper and lower eccentric weights 144a and 144c, respectively, and do not generate vibration in the transverse direction.

When the gears 142a, 142b, and 142c rotate in this state, as shown in FIG. 7C, the eccentric weights 144a and 144c of the upper and lower gears 142a and 142c are all. Located in the upper direction, the eccentric weight 144b of the central gear 142b is also located in the upper direction, so that the centrifugal forces due to the rotation moments of the upper and lower eccentric weights 144a and 144c and the central eccentric weights 144b overlap each other. It generates a vibration to push up the vibration body 130 in the upper direction.

In addition, when the gears 142a, 142b, and 142c rotate in this state, as shown in FIG. 7D, centrifugal forces directed to the right in the rotation moments of the upper and lower eccentric weights 144a and 144c, respectively. In the central eccentric weight 144b, the centrifugal force toward the right of the size corresponding to the leftward centrifugal force generated by the upper and lower eccentric weights 144a and 144c is generated by the rotational moment thereof so that these centrifugal forces are mutually different. Cancels and thus does not generate vibration in the transverse direction.

Meanwhile, when the gears 142a, 142b, and 142c rotate in this state, as shown in FIG. 7A, the upper and lower eccentric weights 144a and 144c and the central eccentric weights 144b are both lower. The centrifugal force due to the rotation moment of the upper and lower eccentric weights (144a) and (144c) and the central eccentric weights (144b) are overlapped with each other in the downward direction to push down the vibration body (130) downward. Generate.

Therefore, the vibration nipper 100 for heavy equipment according to the present invention generates vibration by offsetting the centrifugal force in the horizontal direction, that is, the left and right directions while the gears 142a, 142b, and 142c rotate continuously by the hydraulic motor 140. The vibration main body 130 and the nipper blade 135 mounted on the lower portion of the vibration body 130 are continuously vibrated by overlapping the centrifugal force in the vertical direction to generate the vibration in the vertical direction.

When the vibrating body 130 is configured as described above, the width w1 of the frame 120 and the vibrating body 130 is greater than the width W of the conventional vibrating body in which gears are disposed in the existing transverse direction. As the size becomes smaller, the butterfly can narrow the frame having a structure that is strong in supporting the lateral excavation resistance, and when the ground is excavated, the vibration main body 130 can be inserted along the nipper blade 135 to the depth of the ground, and the excavation performance Will increase.

And when the vibrational nipper 100 for heavy equipment according to the present invention vibrates in this way, when excavating the ground through the nipper blade 135, the nipper blade 135 from the ground, as shown in Figure 2 and 3a, Excavation resistance in the lateral direction (A) is applied, the vibration body 130 has a front upper and lower edges (132a, 132b) of the pins (164a, 164d) on one side of the link (162a, 162b) By being connected through the vibration body 130 is moved in a circular arc in the vertical direction with respect to the frame 120.

Therefore, it is possible to effectively support the force in the transverse direction (A), in this process a plurality of shock absorbing material 170, the front edge 138a and the rear edge 138b of the vibration body 130 is built into the frame 120 Since it is supported by each) can be effectively dampened vibration generated by the vibration main body 130.

As such, the vibration nipper 100 for heavy equipment according to the present invention can be manufactured to have a narrower width w1 of the frame 120 and the vibration main body 130 than before, even when the nipper blade 135 enters the ground. The main body 130 may be inserted along the nipper blade 135 to the depth of the ground to deepen the excavation depth, and to further improve the excavation performance.

In addition, in the present invention, the upper and lower edges 132a and 132b of the vibration body 130 are connected to the vibration body 130 through the links 162a and 162b and the pins 164a, 164b, 164c, and 164d. It is connected so as to be displaced by drawing an arc in the vertical direction to the frame 120 surrounding the, so that when the nipper blade 135 excavates the ground, the nipper blade 135 receives a large excavation resistance in the transverse direction (A) from the ground Even if the nipper blade 135 and the vibrating body 130 are displaced in the up and down arc direction by the lever movement of the links 162a and 162b with respect to the frame 120, the lateral direction A of the nipper blade 135 is excavated. Since the support of the nipper blade 135 is free to operate, the shock absorbing material 170 for supporting the vibration body 130 is protected and not damaged, and durability is greatly improved.

As described above, optimal embodiments have been disclosed in the drawings and the specification. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 ...... Conventional vibration nipper 10 ...... Guide bracket
12 ..... Mount 20 ...... Vibration Body
21,21 '...... Eccentric weight 22 ...... Drive shaft
22 '...... Drive 23,23' ...... Gear
31,31 ', 32,32' .... Anti-vibration rubber 41,42 ...... Guide bearing
50 ...... Nipper blades 100 ...... Vibration nippers for heavy machinery
110 ..... Mount 112 ...... Arm fastener
120 ..... Frame 130 ...... Vibrating Body
132a ...... front lower corner 132b ...... front upper corner
135 ..... Nipper blades 138a, 138b ..... front and rear corners
140 ...... Hydraulic motors 142a, 142b, 142c ...... gear
144a, 144b, 144c ..... eccentric weight 162a, 162b ...... link
164a, 164b, 164c, 164d ..... Pin 170 ...... Buffer
172a, 172b ...... Side plate 174 ...... dustproof rubber
A ...... transverse W ..... conventional width
w1 ...... width of the vibrating body W2 .... frame width

Claims (3)

In vibrating nippers mounted on the arm of heavy equipment such as excavators, bulldozers and wheel loaders to simultaneously carry out crushing and digging at civil and demolition sites,
Gears that are rotated by a hydraulic motor are arranged to be rotatable in the vertical direction therein, each gear is provided with an eccentric body is provided with a vibration body for generating vibration in the vertical direction during the rotation of the gear, the vibration body The lower portion of the vibration nipper for heavy equipment, characterized in that the vibration body is configured to be inserted to the depth of the ground along the nipper blade when the ground excavation, by mounting the nipper blade in the longitudinal direction of the vibration body. According to claim 1, wherein the vibrating body aligns the three gears therein in the vertical direction, the eccentric weight rotation moment of the central gear relative to the rotation moment size of the eccentric weights connected to the upper and lower gears is 2: 1 When the gears are rotated, the lateral centrifugal force generated from the eccentric weights of the upper and lower gears and the lateral centrifugal force generated from the eccentric weights of the central gear are formed to have the same magnitude in opposite directions and cancel each other out. Vibration nipper for heavy equipment, characterized in that the centrifugal force overlapping each other in the vertical direction to generate a vibration. According to claim 1, wherein the upper and lower edges of the vibrating body is connected to the frame surrounding the vibrating body through the links and pins, forming a four-section link shape and drawing an arc by lever movement of the upper and lower links Vibration nipper for heavy equipment, characterized in that connected up and down displacement.

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