KR101488588B1 - A grab bucket interlock device for linking the bucket and grab bucket of the hydraulic excavator - Google Patents

Abstract

The present invention relates to a grab linkage device for linking a bucket and a grab of an excavator, and more particularly, to a grab linkage device for increasing the rotation range of a grab by operating the first drive link and the second drive link, And a grab linkage device for interlocking the bucket of the excavator and the grab, which can prevent the oil pressure reverse to the gravity hydraulic cylinder due to the inner rotation of the bucket during the grab operation and prevent damage to the hydraulic line .
A grab linkage device for linking a bucket and a grab of an excavator according to the present invention includes a bucket and a grab, A bucket hydraulic cylinder for operating the bucket, and a grab hydraulic cylinder for operating the grab; and a drive unit including a bucket hydraulic cylinder for operating the bucket and a grab hydraulic cylinder for operating the bucket, And a control unit for controlling the movement of the bucket and the grab.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a grab bucket interlock device for linking a bucket and a grab of an excavator,

The present invention relates to a grab linkage device for linking a bucket and a grab of an excavator, and more particularly, to a grab linkage device for increasing the rotation range of a grab by operating the first drive link and the second drive link, To a grab linkage device for interlocking a bucket of an excavator and a grab that can prevent reverse hydraulic pressure to the grab hydraulic cylinder due to the inner rotation of the bucket during grab operation to prevent damage to the hydraulic line .

Generally, an excavator is a heavy equipment used for crushing a strong ground such as rock by attaching a bucket, digging the ground or attaching a breaker, etc., and the attachment is selectively exchanged depending on the working conditions and circumstances as needed have.

The bucket can be easily mounted on a conventional excavator in order to secure safety of movement by quickly receiving the workpiece and moving it while stably supporting the workpiece and minimizing the volume of the bucket in the normal state, Hydraulic operating structure can be provided with auxiliary grippers that are easy to operate and use.

Conventionally, an excavator having such a clamping device is known from Korean Utility Model Registration No. 0171738, and FIG. 1 shows an excavator having such a clamping device according to the prior art. As shown in Fig. 1, the tongue 10 is gradually enlarged downward and the hydraulic cylinder 20 is connected to the hydraulic controller 22 of the excavator and the hydraulic line 21. Thus, the operation of the tongue 10 is enabled by operating the hydraulic cylinder 20 connected to the hydraulic line 21 through the control of the hydraulic controller 22 mounted on the excavator.

In this case, however, there is a limitation in the pivotal movement of the pliers 10 due to the extension of the hydraulic cylinder 20 rod, so that the pliers body can not be rotated in accordance with the pivotal movement of the bucket 30 on the pivotal area.

In addition, when the bucket 30 rotates inward toward the excavator side, the hydraulic cylinder 20 for transmitting the power to the grab conveys the hydraulic pressure to rotate the grab outwardly. However, the bucket hydraulic pressure Since the force of the cylinder is greater than the force of the hydraulic cylinder 20, there is a problem that the hydraulic line breaks due to the oil pressure reversely flowing into the hydraulic cylinder.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems of the prior art as described above and to further expand the range in which the grab coupled to the lower hinge portion of the boom frame rotates outward by coupling the multi- .

Also, in the present invention, the outer shape of the first driving link among the articulated links for rotating the grab is configured as an 'S' shape so that even when the first driving link rotates downward, So that the outer rotation angle of the first drive link can be further improved by positioning the first drive link so as to correspond to the lower hinge portion of the boom.

The present invention also provides a method of connecting a rod of a grab hydraulic cylinder, which provides power for rotating a grab, to a connecting portion of a first driving link and a second driving link, .

Further, by connecting the rod of the grab hydraulic cylinder, which provides the power for rotating the grab, to the stop of the first driving link, the operation range of the grab hydraulic cylinder rod can be made small, There is another purpose to transmit the pressure of the hydraulic cylinder more effectively.

Further, according to the present invention, when the grab is not used, the grab cylinder can be contracted to the maximum. At this time, by coupling the first safety member of the grab and the second safety member of the second driving link to each other, So that it can not be rotated downward.

Further, in the present invention, when the grab is operated to grasp the workpiece together with the bucket, the grab is rotated in accordance with the rotation of the bucket, thereby enlarging the operation region of the excavator gripping the workpiece, There is another purpose for grasping or moving.

Further, according to the present invention, the grab gripped by the workpiece prevents the reverse hydraulic pressure from flowing into the grab hydraulic cylinder which transmits power to the grab in response to the inner rotation of the bucket, so that the hydraulic line of the grab hydraulic cylinder There is another purpose for preventing damage.

The above object of the present invention is also achieved by a grab linkage device for linking a bucket and a grab of an excavator, the grab linkage device including a bucket and a grab, wherein the bucket and the grab are engaged, A bucket hydraulic cylinder for operating the bucket and a grab hydraulic cylinder for operating the grab; and a control unit for controlling the movement of the bucket and the grab included in the operating unit And a grab linkage device for linking the grab with the bucket of the excavator.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art as described above, and it is an object of the present invention to provide a method of joining a multi-joint link to a grab, There is an effect.

Also, in the present invention, the outer shape of the first driving link among the articulated links for rotating the grab is configured as an 'S' shape so that even when the first driving link rotates downward, The outer rotation angle can be further improved as compared with the first driving link of the straight line by positioning the portion so as to correspond to the lower hinge portion of the boom.

Further, according to the present invention, by connecting the rod of the grab hydraulic cylinder, which provides the power for rotating the grab, to the connecting portion of the first driving link and the second driving link, It is effective.

Further, by connecting the rod of the grab hydraulic cylinder, which provides the power for rotating the grab, to the stop of the first driving link, the operation range of the grab hydraulic cylinder rod can be made small, There is another effect that the pressure of the hydraulic cylinder can be transmitted more efficiently.

Further, according to the present invention, when the grab is not used, the grab cylinder can be contracted to the maximum. At this time, by coupling the first safety member of the grab and the second safety member of the second driving link to each other, Thereby making it possible to prevent a safety accident caused by the grab during the operation of the excavator.

Further, in the present invention, when the grab is operated to grasp the workpiece together with the bucket, the grab is rotated in accordance with the rotation of the bucket, thereby enlarging the operation region of the excavator gripping the workpiece, There is another effect that can be grasped or moved.

Further, according to the present invention, the grab gripped by the workpiece prevents the reverse hydraulic pressure from flowing into the grab hydraulic cylinder which transmits power to the grab in response to the inner rotation of the bucket, so that the hydraulic line of the grab hydraulic cylinder There is another effect that can be prevented from being broken.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing an excavator having a grip device according to the prior art; Fig.
2 is a side view of the grab linkage apparatus according to the first embodiment of the present invention,
3 is a perspective view of a grab operation device according to the first embodiment of the present invention,
4 is an operational side view of the grab linkage apparatus according to the first embodiment of the present invention,
5 is a configuration diagram of a first drive link and a second drive link according to the first embodiment of the present invention,
6 is an exploded perspective view of the grab linkage apparatus according to the first embodiment of the present invention,
7 is a view showing a coupling of a driving link and a grab according to the first embodiment of the present invention,
8 is a view showing a combination of a bucket and a bucket according to the first embodiment of the present invention,
FIG. 9 is a view showing a coupling of the grab linkage device according to the first embodiment of the present invention,
10 is a side view of a grab linkage device according to a second embodiment of the present invention,
11 is a perspective view of a grab operation device according to a second embodiment of the present invention,
12 is an operational side view of the grab linkage apparatus according to the second embodiment of the present invention,
13 is a configuration diagram of a first drive link according to a second embodiment of the present invention,
14 is a view showing a coupling of a driving link and a grab according to the second embodiment of the present invention,
15 is a view showing the combination of a bucket with a bucket according to a second embodiment of the present invention,
16 is a view showing the coupling of the grab linkage device according to the second embodiment of the present invention,
FIG. 17 is a view showing the construction of the safety member of the grab linkage device according to the present invention,
18 is a configuration diagram of the grab linkage apparatus according to the present invention,
FIG. 19 is a diagram showing a relief valve in a grab operation device according to the present invention. FIG.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

Hereinafter, preferred embodiments of the present invention will be described in detail.

FIG. 2 is a side view of the grab linkage apparatus according to the first embodiment of the present invention, FIG. 3 is a perspective view of the grab linkage apparatus according to the first embodiment of the present invention, and FIG. 6 is an exploded perspective view of the grab linkage apparatus according to the first embodiment of the present invention. 2 to 4 and 6, the grab linkage device includes a bucket 310 coupled to the lower hinge portion 322 of the boom frame 320 of the excavator, a lower hinge portion 322 of the boom frame 320, A grab hydraulic cylinder 220 for rotating the grab 330 and a grab hydraulic cylinder 220 for rotating the grab 330 in accordance with the shrinkage and tension of the grab hydraulic cylinder 220. [ The hinge portion 341 is coupled to the upper hinge portion 321 of the boom frame 320 and the other hinge portion 342 of the first driving link 340 is coupled to the grab hydraulic cylinder rod 321. [ The first drive link 340 and the one end hinge portion 352 of the second drive link 350 coupled to the end of the first drive link 340 and the gravity hydraulic cylinder 342 of the first drive link 340, And the other end hinge part 353 of the second driving link 350 is coupled to the end of the rod 221 and includes a second driving link 350 coupled to the grab driving shaft 332.

One end hinge portion 341 of the first drive link 340 is coupled to the upper hinge portion 321 of the boom frame 320 and the other end hinge portion 342 of the first drive link 340 is connected to the grab hydraulic pressure When the grab hydraulic cylinder rod 221 is pulled or contracted as it is coupled to the end of the cylinder rod 221, the first hinge part 321 of the first driving link 340 coupled to the upper hinge part 321 of the boom stand 320, And the first drive link 340 is configured to be rotatable.

The one end hinge portion 352 of the second drive link 350 is coupled to the other end hinge portion 342 of the first drive link 340 and the end of the gravity hydraulic cylinder rod 221, When the grab hydraulic cylinder rod 221 is pulled or contracted as the other end hinge portion 353 of the swash plate 350 is coupled to the grab drive shaft 332, And the grip 330 is rotatable about a rotation axis of a position coupled to the shaft 322.

4 (a), when the grab hydraulic cylinder rod 221 contracts to its maximum, the grab hydraulic cylinder rod 221 moves to the inside of the grab hydraulic cylinder 220, The other end hinge portion 342 of the first drive link 340 coupled to the grab hydraulic cylinder rod 221 is connected to the one end hinge portion 342 of the first drive link 340 coupled to the upper hinge portion 321 of the boom frame 320, The first driving link 340 is rotated upward by using the supporting portion 341 as a rotation axis.

The one end hinge portion 352 of the second drive link 350 hinged to the end of the gravity hydraulic cylinder rod 221 and the other end hinge portion 342 of the first drive link 340 is engaged with the gravity hydraulic pressure The second driving link 350 is moved upward in correspondence with the turning radius of the first driving link 340 coupled with the end of the cylinder rod 221 and the grab driving shaft 340 coupled to the other hinge portion 353 of the second driving link 350, (332) upward. On the other hand, the rotation of the graphene 330 is rotated by using the lower hinge portion 322 of the boom frame 320 coupled with the grapple 330 as a rotation axis.

4 (b), when the rod 221 of the grab hydraulic cylinder 220 protrudes to the outside at the maximum, the first driving link (not shown) coupled to the grab hydraulic cylinder rod 221 The first hinge portion 342 of the first driving link 340 coupled to the upper hinge portion 321 of the boom frame 320 rotates the first driving link 340 .

The one end hinge part 352 of the second driving link 350 coupled together with the end of the grab hydraulic cylinder rod 221 and the other end hinge part 342 of the first driving link 340, And moves the grab driving shaft 332 coupled to the other end hinge portion 353 of the second driving link 350 downward. On the other hand, the lower portion of the grapple 330 is pivoted about the lower hinge portion 322 of the boom frame 320 to which the grapple 330 is coupled.

In this way, the feature that the graphene 330 is coupled to the lower hinge portion 322 of the boom frame 320 and that the rod of the grab hydraulic cylinder is connected to the grab drive shaft 332 using the first drive link and the second drive link, Even when the bucket 310 rotates outward to the outside of the excavator due to the feature that the power is transmitted to the bucket 310, the rotation of the grab 330 can be extended toward the bucket 310, .

It is preferable that the width of the graphene 330 between the inner side surfaces of the graphene 330 is larger than the width between the outer side surfaces of both sides of the boom stand 320. As a result, When the swing arm 320 is rotated in the direction of the swing arm 320, the swing arm 320 may be housed inside the swing arm 330.

5 is a configuration diagram of a first drive link and a second drive link according to the first embodiment of the present invention. 5 (a) shows the first driving link 340, and FIG. 5 (b) shows the second driving link.

The first driving link 340 shown in Figure 5A is formed by a hinge part 341 at one end of the first driving link 340 for coupling with the upper hinge part 321 of the boom bridge 320, And a first drive link 340 and a second drive link 340. The first drive link 340 and the second drive link 340 are connected to each other by a hinge It is preferable that it is formed in an H shape in order to be joined to the end of the grab hydraulic cylinder rod 221 and the upper hinge portion 321 of the boom frame 320.

Since the outer shape of the first drive link 340 is in close contact with the lower hinge portion 321 of the boom frame 320 when the grab hydraulic cylinder rod 221 protrudes to the maximum, It is preferable to be made of an S shape.

The second drive link 350 shown in FIG. 5B is connected to the other end hinge portion 353 of the second drive link 350 to be coupled to the grab drive shaft 332, And one end hinge portion 352 of a second driving link 350 for engaging with the other end hinge portion 342 and the end of the gravity hydraulic cylinder rod 221. The width of the second driving link 350 It is preferable that the protrusions are formed in a size that can be inserted into the width between the inner side surfaces on both sides of the graphene 330.

The second driving link 350 is provided with a second safety member 351 protruding in a direction of being inserted into the grab 330 and the second safety member 351 is provided with a first A through hole into which the safety member 333 can be inserted is formed so that when the grab hydraulic cylinder 220 contracts to the maximum, the grab 330 rotates upward and the second driving link 350 is rotated The first safety member 333 can be coupled to the second safety member 351 which is protruded as it is inserted into the first safety member 331. [

FIG. 7 is a view showing a coupling between a grapple and a driving link according to a first embodiment of the present invention, FIG. 8 is a view showing a coupling between a bucket and a boom frame according to the first embodiment of the present invention, and FIG. Fig. 4 is a view showing the coupling of the grab linkage according to the present invention. 7, the grab linkage device for grasping a work using an excavator includes a first driving link 340, a second driving link 350, and a grab 330.

5, the first driving link 340 is formed by connecting both sides of the 'S' shape on both sides, and a hole for forming a hinge portion is formed at one end of the 'S' shape and at the other end have.

One end hinge portion 341 of the first drive link 340 is connected to the upper hinge portion formed in the boom stand 320 of the excavator and the other end hinge portion 342 of the first drive link 340 is connected to the grab 330 And is hingedly coupled to the one-end hinge portion 352 of the second drive link 350 connected to the drive shaft 332 of the second drive link 350. [

5, the second driving link 350 includes a second safety member 351 formed to protrude from both sides thereof, and the one-end hinge portion 352 of the second driving link 350 is connected to the second driving link 350, And the other end hinge portion 353 of the second drive link 350 is hinged to the drive shaft 332 of the grab 330. The hinge portion 352 of the second drive link 350 is hinged to the other end hinge portion 342 of the first drive link 340.

2, 3, and 6, the width of connecting the double curved shapes is a width capable of accommodating the boom stand 320, and the double curved surface 330 is formed in a curved shape, And a through hole through which the second safety member 351 formed on the second driving link 350 can be inserted is formed on the area of the area connecting the shapes.

The one end hinge portion 331 of the grapple 330 is formed with a through hole so as to be hinged to the outer side of the lower hinge portion 322 of the boom frame 320, And a through hole is formed so as to be hinged to the hinge portion 353.

Further, it is preferable that one or more projections are formed on the lower end portion of the double-curved shape of the grab 330 where the workpiece can be gripped to firmly grip the workpiece.

8, the excavator is provided with an upper hinge portion 321 and a lower hinge portion 322 for coupling the grab device 320 to the boom platform 320. As shown in FIG. The upper hinge portion 321 and the lower hinge portion 322 of the boom frame 320 are connected to the bucket 310 of the excavator and the end of the rod 211 of the bucket hydraulic cylinder 210, And a supporting member for supporting the supporting member so as to be rotatable.

Therefore, the upper hinge portion 321 and the lower hinge portion 322 of the boom frame 320 for coupling the first driving link 340 and the grab 330 are not separately constructed but are mounted on the boom stand 320 of the excavator The hinge portions previously used are used.

The excavator is provided with a gravity hydraulic cylinder 220 and a gravity hydraulic cylinder rod 221 for transmitting the power to the grab 330 and the end of the grab- The other end hinge portion 342 of the link 340 and the one end hinge portion 352 of the second drive link 350 are hinged together and hinged to the other end hinge portion 353 of the second drive link 350. [ And is configured to transmit power for rotating the grapple 330 via the drive shaft 332. [

As shown in Fig. 9, the grab linkage described with reference to Figs. 7 and 8 includes the upper hinge portion 321, the lower hinge portion 322, and the upper hinge portion 322 of the boom frame 320 provided in the excavator, One end hinge portion 341 of the first drive link 340 and one end hinge portion 331 of the grab 330 and the other end hinge portion 342 of the first drive link 340 are connected to the hydraulic cylinder rod 221, And the one end hinge part 352 of the second driving link 350 are coupled together to move the joint 330 of the first driving link 340 and the second driving link 350 in a wide rotation Area can be provided.

FIG. 10 is a side view of a grab linkage apparatus according to a second embodiment of the present invention, FIG. 11 is a perspective view of a grab linkage apparatus according to the second embodiment of the present invention, and FIG. Figure 3 is an operational side view of the grab linkage. 10 to 12, the first driving link 340 hinged to the upper hinge portion 321 and the lower hinge portion 322 of the boom bar 320 and the grab 330 may be formed in a manner similar to that shown in Figs. Is the same as the first embodiment described in Fig.

However, in the second embodiment of the grab linkage device, the grab hydraulic cylinder rod 221 hinged to the first driving link 340 is not coupled to the other hinge portion 342 of the first driving link 340 And the stop hinge portion 343 formed at the stop of the first drive link 340. [ The engagement of the other end hinge portion 342 of the first drive link 340 and the one end hinge portion 352 of the second drive link 350 is performed in the same manner as in the first embodiment, And the coupling between the hinge portion 353 of the second driving link 350 and the drive shaft 332 of the grab 330 is the same as in the first embodiment.

When the end of the grab hydraulic cylinder rod 221 is hinged to the stopped hinge portion 343 of the first driving link 340 as in the second embodiment of the present invention, Even if the movement of the grapple 330 is shortened, there is an effect that the radius of the graphene 330 is the same as the radius of rotation of the lower hinge portion 322 of the wobble table 320. In the grab hydraulic cylinder 220, There is a characteristic in that the power to be transmitted can be transmitted more effectively.

When the end of the grab hydraulic cylinder rod 221 is hinged to the suspended hinge portion 343 of the first driving link 340, the drive shaft 332 of the grab 330 and the second driving link 350 The position where the other end hinge portion 353 of the boom bar 320 is hinged can be formed away from the position where the one end hinge portion 331 of the grab 330 and the lower hinge portion 322 of the boom stand 320 are engaged, The grab 330 can transmit the power transmitted from the grab hydraulic cylinder 220 to the grab 330 as much as possible so that the grab 330 further increases gripping force for gripping the work together with the bucket 310.

13 is a configuration diagram of a first drive link according to a second embodiment of the present invention. 13, the first driving link 340 in the second embodiment of the present invention is configured to be coupled to the upper hinge portion 321 of the boom frame 320, And the other end hinge portion 342 of the first drive link 340 to be coupled together with the one end hinge portion 341 of the first drive link 340 and the one end hinge portion 352 of the second drive link 350 And an intermediate hinge portion 343 of the first driving link 340 to be hinged to the end of the gravity hydraulic cylinder rod 221 is provided.

The first drive link 340 is hinged to the upper hinge portion 321 of the boom frame 320, the end of the grab hydraulic cylinder rod 221 and the one end hinge portion 352 of the second drive link 350 It is preferable that the structure is formed in a H-shape.

Since the outer shape of the first drive link 340 is in close contact with the lower hinge portion 321 of the boom frame 320 when the grab hydraulic cylinder rod 221 protrudes to the maximum, It is preferable to be made of an S shape.

FIG. 14 is a view showing a coupling between a grapple and a drive link according to a second embodiment of the present invention, FIG. 15 is a view showing a coupling between a bucket and a bucket according to a second embodiment of the present invention, and FIG. Fig. 4 is a view showing the coupling of the grab linkage according to the present invention. 14 to 15, the grab linkage device in the second embodiment of the present invention is configured in the same manner as the first embodiment of the present invention described with reference to Figs. 7 to 9, 340 is further provided with an intermediate hinge portion 343 of the first driving link 340 for connecting the end of the grab hydraulic cylinder rod 221 provided in the grab hydraulic cylinder 220. [

The stop hinge portion 343 of the first drive link 340 is formed with a through hole so that the end of the gravity hydraulic cylinder rod 221 can be hinged to the intermediate portion of the curved surface formed in the 'S' shape on both sides . When the end of the gravity hydraulic cylinder rod 221 is engaged with the stopped hinge portion 343 of the first drive link 340, the power transmitted from the grab hydraulic cylinder 220 can be transmitted more effectively, Since the distance over which the gravity hydraulic cylinder rod 221 of the hydraulic cylinder 220 is operated can be shortened, the length of the gravity hydraulic cylinder can be reduced.

On the other hand, the configurations other than those shown in Figs. 14 to 15 are constructed and combined as in the first embodiment of the present invention.

17 is a view showing the safety member of the grab linkage device according to the present invention. 17, when the grab hydraulic cylinder 220 is contracted to its maximum, the width between the inner side surfaces on both sides of the graphene 330 is larger than the width between the outer side surfaces on both sides of the swash plate 320, It is preferable that a through hole is formed to partially accommodate the workpiece 320, and at least one projection is formed on the grab 330 to firmly support the workpiece.

When the gravity hydraulic cylinder 220 is retracted to the maximum, the first driving link 340 rotates upward and the second driving link 350 moves upward, And is inserted into the inner side surfaces on both sides of the graphene 330. At this time, a second safety member 351 protrudes from the second driving link 350 in a direction to be inserted into the through hole of the graphene 330. The second safety member 351 protrudes from the second driving link 350 and is preferably formed of at least one member. The second safety member 351 is coupled with the grab 330 to form a through hole for fixing the grab.

The first safety member 333 may include a first safety member 333 in the form of a pin and a second safety member 333 inserted in the inner side of both sides of the graphen 330, 351 so that the graphene 330 and the second driving link 350 can be fixed while being rotated toward the boom frame 320 side.

18 is a configuration diagram of a grab linkage apparatus according to the present invention. 18, the grab linkage device includes a driving unit 200 that generates a driving force in response to a command from the control unit 100 and the control unit 100 provided in the driver's seat of the excavator, (Not shown).

The control unit 100 includes a pedal member 110 for generating a movement signal for operating the grab 330, a lever member 120 for generating a turning signal for operating the bucket 310, A control module 130 for receiving the operation signal and the rotation signal of the lever member 120 and generating a bucket control signal and a grab control signal corresponding to each operation and transmitting the bucket control signal and the grab control signal to the hydraulic control member 240 of the driving unit 200 ).

The pedal member 110 generates a movement signal for operating the grab 330 and is provided in a pedal shape and is capable of being pressed in the forward / backward directions about the center of the pedal.

That is, when the pedal of the pedal member 110 is pressed in the forward direction, a movement signal for rotating the grab 330 to the outside of the excavator is generated. When the pedal is pressed in the backward direction, As shown in Fig.

The pedal member 110 has a multi-stage structure in which forward and backward pushing operations are performed to control the power transmitted to the grab 330 through the grab hydraulic cylinder 210, It is possible to control the gravitational force of the grab 330 holding the workpiece together with the bucket 310 through the forward or backward pushing operation of the member 110. [

The lever member 120 is provided in the form of a joystick by generating a turning signal for operating the bucket 310. When the joystick is operated in either the forward direction or the backward direction, The bucket hydraulic cylinder 210 of the bucket hydraulic cylinder 210 is contracted to move the bucket hydraulic cylinder 210 outwardly in the bucket hydraulic cylinder 210 in order to pivot the bucket 310 in the inward direction of the excavator, So that the bucket hydraulic cylinder rod 211 of the bucket is protruded.

The lever member 120 in the form of a joystick may generate a signal for moving the boom belt 320 of the excavator forward or backward and the forward and rearward directions of the lever member 120 may be for rotating the bucket 310 And the left and right sides of the lever member 120 can generate a signal for operating the boom bar 320. [

Further, it is preferable that the lever member 120 is formed in the form of a joystick. However, any configuration may be used in the case of a configuration for generating a rotation signal for rotating the bucket 320.

The control module 130 generates the grab control signal and the bucket control signal in response to the operation signal and the rotation signal generated by at least one of the pedal member 110 and the lever member 120, To the control member (240).

In particular, the control module 130 separates the grab control signal into separate signals so as to differentiate the power of the grab 330 in correspondence with the respective operation signals transmitted through the multi-stage structure of the pedal member 110 Lt; / RTI >

The driving unit 200 includes a bucket hydraulic cylinder 210 and a gravity hydraulic cylinder 220 for transmitting power to the bucket 310 and the grab 330 respectively and is connected to the control module And a hydraulic control member 240 for supplying / withdrawing hydraulic pressure to the respective bucket hydraulic cylinders 210 and gravity hydraulic cylinders 220 corresponding to the bucket control signals and the grab control signals transmitted from the graphed hydraulic cylinders 230 and 130.

When the bucket 310 and the grab 330 are operated and the workpiece is gripped by the bucket 310 and the bucket 310 is gripped by the grab 330, And a relief valve 230 for preventing the reverse hydraulic pressure from being introduced into the grab hydraulic cylinder 220 that provides power to the grab hydraulic cylinder 220.

That is, the bucket hydraulic cylinder 210 of the general excavator is configured to generate a hydraulic pressure larger than the gravity hydraulic cylinder 220, so that the bucket 310 and the grab 330 operate together to grip the workpiece The grab hydraulic cylinder 220 that supplies power to the grabber 300 continuously applies the force to supply the hydraulic pressure when the bucket 310 rotates outward according to the rotation signal of the lever member 120 When the bucket 310 rotates inward according to the rotation signal of the lever member 120, the grab 330 can be rotated in the direction of the outer rotation of the bucket 310, The reverse hydraulic pressure may be generated in the gravity hydraulic cylinder 220 that provides the power, and the hydraulic line may be damaged.

The relief valve 230 is connected to the first hydraulic line for supplying the hydraulic pressure from the hydraulic control member 240 to the gravity hydraulic cylinder 220 and the grab 330 in order to turn the graphene 330 outwardly And is connected to a second hydraulic line for supplying hydraulic pressure to the gravity hydraulic cylinder from the hydraulic control member 240 so as to rotate inward and rotate inward.

The relief valve 230 blocks the hydraulic pressure flowing into the first hydraulic line for operating the grab 330 and the hydraulic pressure flowing into the second hydraulic line for stopping the operation of the grab 330, The first hydraulic line of the grab hydraulic cylinder 220 is pushed to the open first hydraulic line of the grab hydraulic cylinder 220 in accordance with the inner rotation of the bucket 310 while the hydraulic pressure is being supplied from the hydraulic control member 240 to the first hydraulic line for operation of the bucket 310 The relief valve 230 is opened to discharge the hydraulic pressure introduced from the first hydraulic line side to the second hydraulic line side so that the first hydraulic line is connected to the side of the bucket 310 It can be prevented from being damaged by the oil pressure reversely flowing in accordance with the inner rotation.

The hydraulic control member 240 receives the bucket control signal and the grab control signal transmitted from the control module 130 of the control unit 100 and transmits the corresponding hydraulic pressure to the bucket hydraulic cylinder 210 and the grab hydraulic cylinder 320, respectively.

Further, the hydraulic control member 240 adjusts the pressure of the hydraulic pressure to the grab hydraulic cylinder 320 in response to the grab control signal transmitted corresponding to each of the operation signals input from the pedal member 110 of the multi-stage structure The pressure of the hydraulic pressure for transmitting the power to the bucket 310 can be adjusted according to another embodiment.

The operation unit 300 includes a bucket 310 for rotating the lower hinge unit of the boom frame 320 by a power supplied from the bucket hydraulic cylinder 210 of the drive unit 200, A grab 330 for rotating the lower hinge portion of the boom frame 320 about the center axis by using the power supplied from the grab hydraulic cylinder 220 and a hinge portion 330 for coupling the bucket 310 and the grab 330 A boom table 320 having an upper hinge portion and a lower hinge portion and a first drive link 340 for transmitting power generated in the grab hydraulic cylinder 220 of the drive unit 200 through a joint action to the grab 330 And a second drive link 350. The second drive link 350 includes a first drive link 350 and a second drive link 350.

The first driving link 340 and the second driving link 350 each have a hinge at both ends thereof. The first hinge portion of the first driving link 340 is coupled to an upper hinge portion formed at the boom frame 320, The other end hinge portion of the first driving link 340 is coupled to the hinge portion of the one end of the second driving link 350 and the other hinge portion of the second driving link 350 is coupled to the hinge portion of the graphen 330 And one end of the grab 330 is coupled to the lower hinge portion of the boom frame 320. [

3, the end of the grab hydraulic cylinder rod provided in the grab hydraulic cylinder 220 for transmitting the power to the grab 320 is connected to the other end of the first driving link 340, The hinge portion and the second driving link 350 may be coupled to the hinge portion at one end or may be coupled to the hinge hinge portion formed at the end of the first driving link 340 as in the second embodiment of Fig. ). ≪ / RTI >

The grab hydraulic cylinder 220 coupled to the other hinge portion of the first driving link 340 or the hinge portion of the first driving link 340 can move from the boom frame 320 to the first driving link 340 and the second drive link 350 to minimize the loss of power generated through the hydraulic pressure generated in the grab hydraulic cylinder 220, so that the grab 330 can be pivoted.

FIG. 19 is a diagram showing a relief valve in a grab operation device according to the present invention. FIG. 19, the relief valve 230 is located on the side of the gravure hydraulic cylinder 220, and the relief valve 230 is located on the outer side of the grab 330 in accordance with the operation of the grab 330 in the hydraulic control member 240 And is connected to the first hydraulic line A connected to one side of the gravity hydraulic cylinder 220 to supply the hydraulic pressure in response to the rotation of the gravity hydraulic cylinder 220. In accordance with the operation of the grab 330 in the hydraulic control member 240 And is connected to a second hydraulic line B connected to the other side of the grab hydraulic cylinder 220 to supply hydraulic pressure corresponding to the inner rotation of the swing arm 330.

The relief valve 230 recovers the hydraulic pressure reversely flowing into the first hydraulic line A while the relief valve 230 is opened when the hydraulic pressure of the predetermined pressure or higher is reversely introduced into the first hydraulic line A, And is configured to discharge the hydraulic pressure recovered in the line (B).

That is, when the hydraulic pressure supplied from the hydraulic control member 240 flows into the grab hydraulic cylinder 220 in response to the outer rotation of the grab 330, the grab hydraulic cylinder rod 221 of the grab hydraulic cylinder 220 And the grapple 330 rotates outward. At this time, the outer rotating pendulum 330 can grip the work together with the bucket 310.

At this time, the hydraulic pressure of the bucket hydraulic cylinder 210 is larger than the hydraulic pressure of the gravity hydraulic cylinder 220. When the bucket 310 holding the workpiece together with the grab 330 is rotated inward, (330) also performs the inner rotation.

However, since the gravitational force is supplied to the grab 330 due to the hydraulic pressure supplied from the hydraulic control member 240 to the gravure hydraulic cylinder 220, when the bucket 310 is rotated inward , The hydraulic pressure supplied to the first hydraulic line (A) of the grab hydraulic cylinder (220) is reversely introduced. In this case, since the hydraulic pressure is reversely introduced into the first hydraulic line A due to the hydraulic pressure of the bucket hydraulic cylinder 210, the first hydraulic line A collides with the hydraulic pressure supplied from the hydraulic control member 240 to the gravity hydraulic cylinder 220, do.

The relief valve 230 is configured to discharge the hydraulic pressure reversely flowing in accordance with the inner rotation of the bucket 310. The relief valve 230 is not opened to the pressure of the hydraulic pressure flowing into the grab hydraulic cylinder 220, The hydraulic pressure of the bucket hydraulic cylinder 210 is transmitted to reverse the hydraulic pressure of the bucket hydraulic cylinder 210 to discharge the reverse hydraulic pressure to the second hydraulic line B, .

The first hydraulic line A and the second hydraulic line B flowing from the hydraulic control member 240 to the gravity hydraulic cylinder 220 may be installed opposite to each other in accordance with the structure of the excavator, The relief valve 230 connected to the first hydraulic line A and the second hydraulic line B may be reversed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Various changes and modifications will be possible.

100: control unit, 110: pedal member,
120: lever member, 130: control module,
200: drive unit, 210: bucket hydraulic cylinder,
211: Bucket hydraulic cylinder rod, 220: Grab hydraulic cylinder,
221: Grab hydraulic cylinder rod, 230: Relief valve,
240: hydraulic control member, 300: operating portion,
310: Bucket, 320: Boom,
321: upper hinge portion, 322: lower hinge portion,
330: Grab, 331: Grab Once the Hinji Branch,
332: grab drive shaft, 340: first drive link,
341: first drive link hinge portion, 342: first drive link hinge portion,
343: first drive link stop hinge portion, 350: second drive link,
351: second safety member, 352: second drive link hinge portion,
353: second drive link hinge portion

Claims (17)

A grab linker for linking a bucket and a grab of an excavator,
An operating portion including the bucket and the grab, the operating portion combining the bucket and the grab to allow the bucket and the grab to rotate respectively;
A driving unit including a bucket hydraulic cylinder for operating the bucket and a grab hydraulic cylinder for operating the grab; And
A control unit for controlling the movement of the bucket and the grab included in the operating unit;
Wherein the control unit comprises: a lever member for inputting a turning signal of the bucket; a pedal member for generating a movement signal for transmitting power to the grab; And a control module for controlling the bucket hydraulic cylinder or the grab hydraulic cylinder by receiving any one or more of the operating signals, wherein when the control module receives the rotation signal through the lever member, And a bucket control signal for operating the hydraulic control member of the excavator is transmitted to the hydraulic control member of the drive unit.
The method according to claim 1,
The operation unit
A bottom hinge portion for hinging the bucket and the grab on the same axis;
A first drive link, the hinge portion of which is connected to the upper hinge portion of the boom frame; And
And the other end hinge portion is connected to the interruption of the grab,
Wherein the hinge portion of the first driving link and the hinge portion of the second driving link are connected to each other by a link linkage between the buckle of the excavator and the grab.
3. The method of claim 2,
And a rod of the grab hydraulic cylinder is coupled to the other end hinge portion or the suspended hinge portion of the first drive link.
3. The method of claim 2,
Wherein the first driving link is formed in a curved surface of an 'S' shape, and a concave curved surface of the first driving link encloses the lower hinge portion when the grab rotates to the maximum outward. Grab linkage for linking bucket and grab of
3. The method of claim 2,
Wherein the grab is formed with a receiving groove for partially accommodating the boom frame between the inner side surfaces of both sides of the grab when the grab cylinder is contracted to the maximum. Interlocking device.
6. The method of claim 5,
Wherein a through hole is formed in the grab so that a second safety member formed on the second driving link between the inner side surfaces of the grab when the grab cylinder shrinks to the maximum can be inserted therein Grab linkage for linking the grab.
The method according to claim 6,
Wherein the grab is provided with a first safety member coupled to the second safety member to fasten the grab to the boom frame when the grab cylinder shrinks to the maximum, A grab interlocking device for interlocking the grab.
delete delete The method according to claim 1,
Wherein the control module transmits a grab control signal for operating the grab to the hydraulic control member of the driving unit when receiving the operation signal through the pedal member. Grab interlocking device to make.
The method according to claim 1,
Wherein the pedal member is pushed forward and backward from the center and either the front or rear produces a grab control signal that causes the rod of the grab hydraulic cylinder to move out and the other produces a load of the grab hydraulic cylinder And a grab control signal for causing the bucket of the excavator to move inside the grab.
12. The method of claim 11,
Wherein the pedal member is formed in a multi-stage structure to stepwise adjust the gravitational force of the grab. The grab operator interlocks the bucket of the excavator with the grab.
The method according to claim 1,
The driving unit includes a hydraulic control member for supplying hydraulic pressure to the bucket hydraulic cylinder and the grab hydraulic cylinder; And
A relief valve for returning to the hydraulic pressure control member a hydraulic pressure reversely flowing in the backward movement of the rod of the grab hydraulic cylinder,
And a grab linkage for connecting the bucket and the grab of the excavator.
14. The method of claim 13,
Wherein the hydraulic control member has two lines for supplying hydraulic pressure to the grab hydraulic cylinder, the first hydraulic line supplying hydraulic pressure for moving the rod of the grab hydraulic cylinder to the outside, and the second hydraulic line And a hydraulic pressure for moving the rod of the grab hydraulic cylinder inside is supplied to the grab hydraulic cylinder.
15. The method of claim 14,
Wherein the relief valve includes an inlet connected to the first hydraulic line and an outlet connected to the second hydraulic line.
16. The method of claim 15,
Wherein the relief valve interrupts the hydraulic pressure supplied from the second hydraulic line and the hydraulic pressure reversely introduced into the first hydraulic line by the inner rotation of the bucket opens the inlet to return the hydraulic pressure to the inlet, And a grab linkage device for linking the bucket and the grab of the excavator.
17. The method of claim 16,
Wherein the hydraulic pressure of the grab hydraulic cylinder is smaller than the hydraulic pressure of the bucket hydraulic sealer.

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