KR102360704B1 - Hydraulic port of A Turning Link Device for Heavy Equipments - Google Patents

Abstract

The present invention relates to a hydraulic port structure of a rotary link connection device for heavy equipment, which has excellently improved work efficiency. The hydraulic port structure of the present invention comprises: a quick coupler (102) for quickly mounting a bucket of an excavator; a rotary link device (104) installed on an upper portion of the quick coupler (102); and an oil quick device (116).

Description

Hydraulic port of A Turning Link Device for Heavy Equipments

The present invention relates to a hydraulic port structure of a rotary link connection device for heavy equipment, and more particularly, it is a device used for heavy equipment such as excavators, buckets, brakes, etc., which is automatically mounted on a bucket, a breaker, etc. and then rotates to work on heavy equipment It is related to the hydraulic port structure of the rotary link connecting device for heavy equipment that can be installed directly from the operating device to the hydraulic port by increasing the degree of freedom at the work site.

In the case of excavators, which are commonly used as heavy equipment, it is composed of a boom and an arm, which are areas directly operated for excavator work. The degree of freedom must increase according to the environment, but in the past, the rotation angle of the bucket or drill mounted on the distal end of the arm did not change arbitrarily. The work process was repeated.

As a representative patent technology, there is an 'agricultural tractor having a 360-degree rotatable articulated arm (Patent No. 10-2017-0035163, hereinafter referred to as Patent Document 1)'.

The technology according to Patent Document 1 relates to an agricultural tractor having a 360-degree rotatable articulating arm, and a 360-degree rotatable articulating arm in the left and right directions together with a cabin to bend forward and lateral as well as various types of rear work It was made so that it could be performed using the arm.

The invention according to Patent Document 1 includes a body having a front wheel and a rear wheel; a cabin rotatably installed 360 degrees on the upper body and having a driver's seat inside; It is installed in a supported form at the front of the cabin so that it can rotate together by the rotation of the cabin, and it is installed on the main body and an articulated arm that allows the working devices to be installed at the tip end to transmit the engine power of the main body to the driven working device. A swivel bearing and a swivel bearing in which an outer ring and an inner ring are coupled to the main body and the cabin, respectively, and gear teeth are formed on the inner circumferential surface of the inner ring for 360-degree rotation of the cabin, including a power take-off device and a traction device installed in front of the main body A drive gear meshed with the inner ring and a hydraulic motor providing rotational force to the drive gear are provided to rotate the cabin by rotation of the inner ring of the swivel bearing.

As another patent precedent, there is a 'rotation shaft assembly for a scissor bucket device and a scissor bucket device having the same (registration number 10-1369900, hereinafter referred to as Patent Document 2)'.

The patented technology according to Patent Document 2 relates to a rotating shaft assembly for a scissor bucket device and a scissor bucket device having the same, and instead of permanently fixing a bearing that rotatably cross-couples a pair of scissor arms to each other by welding, easily By making it removable, if the bearing is damaged, a new one can be replaced without damaging or replacing the scissor arm.

However, in these known prior documents, the degree of gear wear due to the resistance between the rotating links is seriously occurring in structural and design parts, and these link structures are rotated according to the load of the rod (load), so that the work of the excavator is difficult. There was a problem that it was not done precisely.

In addition, heavy equipment devices such as excavators using the existing rotary link are of a type that connects after removing the pin of the rotary link. .

This is because, when the rotary link is coupled and installed, it is difficult to disassemble easily, and after separating the coupled pin, the hydraulic hose must be connected from the outside and the excavator bucket must be installed.

Republic of Korea Patent Publication No. 10-2017-0035163 Republic of Korea Patent Registration No. 10-1369900

The present invention has been devised to solve the above problems, and the present invention is free to attach and detach so that it can be used when the work of the hydraulic port structure of the rotary link connection device for heavy equipment is required, and is detachable and separated when not in use. Its purpose is to provide a hydraulic port structure of a rotary link connection device for heavy equipment that can be stored.

And, it is an object of the present invention to provide a hydraulic port structure of a rotary link connecting device for heavy equipment that is installed so that it is automatically connected using a hydraulic connector unit without connecting a hydraulic hose, and the hydraulic port can be directly connected and used. do it with

The purpose of the present invention and its technical problems are not limited to the technical problems described above. Therefore, other technical problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the following description.

The present invention includes a quick coupler 102 for quickly mounting the bucket of the excavator; a rotary link device 104 installed on the quick coupler 102 to rotate 360 degrees; It includes an oil quick device 116 for connecting and operating directly using a hydraulic port without being connected to a hydraulic hose installed on the upper portion of the rotary link device 104, wherein the oil quick device 116 includes a frame part 110 , a hydraulic connector part 112 , and a frame jig part 112 , wherein the frame part 110 has a flat base plate 40 formed thereon, and upper left and right side parts of the base plate 40 . Frame bodies 42 and 43 are erected and fixed in a vertical direction, a base plate coupling hole 41 is formed in the center of the base plate 40, and the valve body is formed in the base plate coupling hole 41 The part 108 is coupled and installed, and the hydraulic connector part 112 is provided with a plurality of hydraulic port pipes 82 and the hydraulic port pipes 82 are fitted in the front and rear directions to be firmly fixed and installed. (74) and a hydraulic port unit 118 having a pair of hydraulic port guide blocks 84 that are fixedly installed by slidingly coupled to face each other on both upper ends of the port block 74. do.

The quick coupler 102 includes a pair of low plates 10 and 11 installed in parallel in the vertical direction, and a cover panel that is vertically erected on all of the low plates 10 and 11 to block the front part. It is preferable to include a cover panel (14) and a cover panel (16) which is vertically erected on the rear surface of the low plates (10, 11) and is positioned parallel to and fixed to the cover panel (14).

The rotary link device 106 includes a cylindrical case body 24 having a hollow central portion, and a case upper plate 26 having a flat flange portion formed on the upper surface of the case body 24 to the outside of the hollow hole. The worm unit 28 is installed on the right side of the case body 24, and the motor 30 is coupled to the front of the worm unit 28 to rotate the worm unit 28. It is preferable to operate

The hydraulic port unit 118 includes a pair of left and right lower guide brackets 50 having a rectangular shape and having a support portion 60 formed in the central portion; a pair of left and right upper guide brackets 52 having a rectangular shape and having a pressing portion 58 formed in the central portion; a guide shaft (46) coupled and installed between the upper guide bracket (50) and the lower guide bracket (52); a pair of shaft support bodies installed under the guide shaft 46 and installed inside the lower guide bracket 52 to support the lower outer peripheral surfaces of the left and right ends; It is preferable to provide a position fixing piece 68 which is vertically positioned with respect to the center at the rear of the center of the guide shaft 46 and fixedly installed in the rear direction in the horizontal direction.

As described above, the hydraulic port structure of the rotary link connecting device for heavy equipment of the present invention automatically couples the hydraulic quick coupler of the working device with the connecting body of heavy equipment or industrial machinery, and hydraulic pressure when combining the bucket of an excavator of heavy equipment or industrial machinery There is an effect that it can be used by directly connecting it without connecting the hydraulic hose using the port.

In addition, when the rotary link for heavy equipment such as an excavator is combined, the durability of the equipment is improved by preventing the heavy equipment such as the excavator from being strained, and the flow rate is maintained smoothly and the flow rate is maintained so that the power is saved and the work efficiency is excellently improved. has the effect of being

1 is a perspective view showing the structure of a hydraulic port structure of a rotary link connection device for heavy equipment according to the present invention;
Figure 2 is a partial exploded perspective view showing the structure of the hydraulic port structure of the rotary link connection device for heavy equipment of the present invention
Figure 3 is an exploded perspective view showing the structure of the hydraulic port structure of the rotary link connection device for heavy equipment of the present invention
4 and 5 are perspective views showing a state in which the hydraulic port unit of the present invention is installed;
6 and 7 are perspective views showing the structure of the hydraulic port unit of the present invention;
8 is an exploded perspective view showing the structure of the lead-in port unit of the present invention;

In describing the specific embodiments below, various specific contents have been prepared to more specifically explain and help the understanding of the invention.

However, a person of ordinary skill in the art having enough knowledge in this field to understand the present invention will recognize that it can be used without these various specific details.

In some cases, it should be mentioned in advance that parts that are commonly known and not largely related to the invention in describing the invention are not described in order to avoid confusion in describing the invention, which is the right to interact between the components of the invention. will be within range.

The present invention includes a quick coupler 102 for quickly mounting the bucket of the excavator; a rotary link device 104 installed on the quick coupler 102 to rotate 360 degrees; It includes an oil quick device 116 for connecting and operating directly using a hydraulic port without being connected to a hydraulic hose installed on the upper portion of the rotary link device 104, wherein the oil quick device 116 includes a frame part 110 , a hydraulic connector part 112 , and a frame jig part 112 , wherein the frame part 110 has a flat base plate 40 formed thereon, and upper left and right side parts of the base plate 40 . Frame bodies 42 and 43 are erected and fixed in a vertical direction, a base plate coupling hole 41 is formed in the center of the base plate 40, and the valve body is formed in the base plate coupling hole 41 The part 108 is coupled and installed, and the hydraulic connector part 112 is provided with a plurality of hydraulic port pipes 82 and the hydraulic port pipes 82 are fitted in the front and rear directions to be firmly fixed and installed. (74) and a pair of hydraulic port guide blocks (84) fixedly installed by slidingly coupled to face each other on both upper ends of the port block (74).

In addition, the quick coupler 102 includes a pair of low plates 10 and 11 installed in parallel in the vertical direction, and a cover that is erected perpendicular to all of the low plates 10 and 11 and is disposed to block the front part. A panel (14) and a cover panel (16) erected perpendicularly to the rear surface of the low plates (10, 11) and positioned parallel to and fixed to the cover panel (14), the rotary link device (106) is a cylindrical case body 24 having a hollow central portion, and a case upper plate 26 having a flat flange portion formed outside the hollow hole on the upper surface of the case body 24 extending to the outside, and the case body A worm unit 28 is installed on the right side of the worm unit 24, and a motor 30 is coupled to the front of the worm unit 28 to rotate the worm unit 28, and the hydraulic pressure The port unit 118 includes a pair of left and right lower guide brackets 50 having a rectangular shape and a support portion 60 formed in the central portion; a pair of left and right upper guide brackets 52 having a rectangular shape and having a pressing portion 58 formed in the central portion; a guide shaft (46) coupled and installed between the upper guide bracket (50) and the lower guide bracket (52); a pair of shaft support bodies installed under the guide shaft 46 and installed inside the lower guide bracket 52 to support the lower outer peripheral surfaces of the left and right ends; A position fixing piece 68 is provided at the rear of the center of the guide shaft 46, which is vertically positioned with respect to the center and fixedly installed in the rear direction in the transverse direction.

Hereinafter, a specific embodiment according to the hydraulic port structure of the rotary link connecting device for heavy equipment of the present invention will be described.

1 is a perspective view showing the structure of the hydraulic port structure of the rotary link connecting device for heavy equipment of the present invention, Figure 2 is a partial exploded perspective view showing the structure of the hydraulic port structure of the rotary link connecting device for heavy equipment of the present invention, Figure 3 is an exploded perspective view showing the structure of the hydraulic port structure of the rotary link connection device for heavy equipment of the present invention.

And, Figures 4 and 5 are perspective views showing a state in which the hydraulic port unit of the present invention is installed, Figures 6 and 7 are perspective views showing the structure of the hydraulic port unit of the present invention, Figure 8 is the oil supply port unit of the present invention An exploded perspective view showing the structure of

When the hydraulic port structure of the rotary link connecting device for heavy equipment of the present invention is described with reference to FIGS. 1 to 8, first, as shown in FIGS. 1 and 2, the hydraulic pressure of the rotary link connecting device for heavy equipment of the present invention The port structure 100 includes a quick coupler 102 that is connected to the bucket, a rotary link device 104 that is installed on the quick coupler 102 to be rotatably installed, and the rotary link device 104. It includes an oil quick device 116 that is coupled and installed on the upper part of the.

The rotation link device 104 includes a rotation unit portion 106 and a valve body portion 108 .

The frame part 110 includes a hydraulic connector part 112 and a frame jig part 114 .

The quick coupler 102 is made to quickly and fixedly couple the bucket of the equipment for the excavator, and the rotation link device 104 is rotatably installed on the top of the quick coupler 102 to rotate the bucket of the excavator.

And the oil quick device 116 installed on the upper part of the rotary link device 104 is provided to be firmly installed by being mounted on the end of the arm of the excavator boom and to be installed quickly using a hydraulic port.

3, the quick coupler 102 of the present invention includes a pair of low plates 10 and 11 installed in parallel in the longitudinal direction, and the low plates 10 and 11. A cover panel (14) which is erected perpendicular to the front and arranged to block the front part, and a cover panel (14) which is erected perpendicularly to the rear part of the low plates (10, 11) and fixed by being positioned parallel to the cover panel (14) ( 16) is provided.

At this time, the low plates 10 and 11 and the cover panels 14 and 16 are combined to form a square box, and a plurality of support panels 18 and 19 are coupled and fixed to the inner corners thereof.

The support panels 18 and 19 are fixed to the front, rear, left, right, and right sides of the inner surface of the low plates 10 and 11, respectively, and firmly support the cover panels 14 and 16 and the low plates 10 and 11 .

The low plates 10 and 11 are curved in a backward direction to form an arm hook part 12 , and a coupling groove 13 is symmetrically formed in an upper portion of the arm hook part 12 . A mounting pin of an excavator bucket (not shown) is coupled and fixed to the coupling groove 13 .

And all of the low plates 10 and 11 extend vertically in the downward direction and a smooth coupling part 15 is formed in a loud shape, and a coupling groove 17 is concavely formed on the right side of the coupling part 15, An anchor pin of an excavator bucket (not shown) is coupled and fixed to the coupling groove portion 17 .

A flat low body 20 is coupled to the upper portions of the low plates 10 and 11 formed as described above, and a shaft coupling hole 22 is vertically penetrated in the central portion of the low body 20 to form. do.

Subsequently, a rotary link device 104 is installed on the upper portion of the quick coupler 102, and the rotary link device 104 has a cylindrical case body 24 having a hollow central portion, and the case body On the upper surface of 24, a case upper plate 26 having a flange portion of a flat plate formed outside the hollow hole is extended to the outside, and a worm unit 28 is installed on the right side of the case body 24, and the worm unit A motor 30 is coupled to the front part of 28 to rotate the worm unit 28 .

And a coupling hole 29 is formed in the central portion of the case body 24 .

A valve body 108 is coupled to the coupling hole 29 .

The valve body part 108 includes a valve body 30 made of a cylindrical shape and both surfaces cut vertically in a plane, and a valve rotation shaft 32 formed to extend and protrude vertically from a lower portion of the valve body 30 . and a valve bracket 34 formed on the upper surface of the valve body 30 .

The valve bracket 34 has a concave-convex shape, and a seating portion 36 having a plurality of coupling holes 38 is formed on both side surfaces thereof.

On the other hand, an oil quick device 116 is installed on the upper portion of the rotary link device 104 , and the oil quick device 116 includes a frame part 110 , a hydraulic connector part 112 , and a frame jig part 112 . includes

In the frame part 110, a flat base plate 40 is first formed, and frame bodies 42 and 43 are erected and fixed to the upper left and right side surfaces of the base plate 40 in a vertical direction.

A base plate coupling hole 41 is formed in the central portion of the base plate 40 . The valve body 108 is coupled to the base plate coupling hole 41 .

An upper wing 44 having a wave shape in the upward direction is formed in the middle portion of the frame body 42 and 43, respectively, and pin holes are formed in the front and rear portions.

A guide shaft 46 is coupled and fixed to the pin hole formed in the front of the frame body 42 and 43, and the guide shaft 48 is inserted into the pin hole formed in the rear portion.

In addition, lower guide brackets 50 are fixed to both sides of the lower outer circumferential surface of the guide shaft 46 so as to surround the lower outer circumferential surface of the guide shaft 46 , and upper guide brackets are also provided on the upper outer circumferential surface of the guide shaft 46 . 52 are respectively installed and are in close contact with the upper surface of the lower guide bracket 50 so that the upper guide bracket 52 is installed to surround the guide shaft 46 and is fixed in contact with each other at the same time.

Then, the hydraulic connector part 112 is installed to be positioned inside the upper surface of the base plate 40 of the frame part 110 and is connected and fixed to the guide shaft 46 to transmit hydraulic force.

The frame jig part 114 is formed in a flat plate shape, and both ends are branched in the form of a wiser (Y). An upper guide bracket 54 is fixedly installed on the lower surface of the rear end.

Meanwhile, an oil pipe cover 51 having a dig-shaped (c) shape is fixedly installed on one side of the frame body 42 .

When the low plate 10 of the quick coupler 102 is installed and the rotation link device 104 capable of 360 degree rotation is installed on the top of the quick coupler 102, the oil quick The device 116 is to be installed.

4 and 5 are perspective views showing a state in which the hydraulic port unit of the present invention is installed, FIGS. 6 and 7 are perspective views showing the structure of the hydraulic port unit of the present invention, and FIG. 8 is the structure of the oil supply port unit of the present invention. As an exploded perspective view showing, as shown in FIGS. 4 and 5, first, a pair of frame bodies 42 and 43 facing each other are installed, and guide shafts ( 46) is installed in the horizontal direction, and the guide shaft 48 is installed in parallel to the rear of the frame bodies 42 and 43 in the horizontal direction.

Lower guide brackets 50 are installed on the lower left and right sides of the guide shaft 46 to support the outer periphery of the lower surface of the guide shaft 46 in a semicircular shape, and the lower guide bracket 50 is a pair of left and right. is done

In addition, upper guide brackets 52 and 54 in the form of a square block are mounted on the upper left and right both ends of the guide shafts 46 and 48 to be installed, respectively.

On the upper surfaces of the upper guide brackets 52 and 54 installed as described above, the aforementioned flat plate-shaped frame jig plate 56 is coupled and installed.

At this time, a hydraulic port unit 118 is installed under the frame jig plate 56, and the hydraulic port unit 118 includes a hydraulic port guide block 84, and the guide block 84 is It is fixedly installed under the frame jig plate 56 .

Subsequently, as shown in FIGS. 6 and 7 , the hydraulic port unit 118 includes a guide shaft 46 , a lower guide bracket 50 installed on the left and right lower ends of the guide shaft 46 , and the lower An upper guide bracket 52 installed symmetrically to the guide bracket 50 , a pair of shaft support bodies 62 supporting the lower portion of the guide shaft 46 , and a middle portion of the guide shaft 46 . A position fixing piece 68 for supporting the guide shaft 46 and a pair of hydraulic port guide blocks 80 fixedly installed on the lower surface of the frame jig plate 56, and the hydraulic port guide A port block 74 fixed to the lower end of the block 84, a hydraulic port pipe 82 fitted to the port block 74, and a hydraulic port fixed to the lower portion of the port block 74 It includes a lower block (90).

More specifically, the cylindrical guide shaft 46 is installed in the transverse direction, and lower guide brackets 50 are installed on the left and right lower surfaces of the guide shaft 46 .

The lower guide bracket 50 is formed in a rectangular shape, and a semi-circular support portion 60 is formed in the central portion.

The support part 60 is formed concave to support the side end of the guide shaft 46 and penetrates up and down in the front and rear to be fixed by fixing means such as fixing bolts, nuts, pieces, rivets, etc. not shown. A fixing hole is formed, and the fixing hole is in contact with the upper guide bracket 52 and the upper and lower portions, and is fitted between the upper guide bracket 52 and the lower guide bracket 50 to be coupled and installed.

A pair of shaft support bodies 62 are installed below the guide shaft 46 , preferably inside the lower guide bracket 50 , to support the guide shaft 46 .

In the central rear portion of the guide shaft 46 , a positioning piece 68 is installed to protrude in the rear direction perpendicular to the guide shaft 46 , and is installed to be coupled to the entirety of the positioning piece 68 .

A port block 74 is fixed to the lower portion of the rear end of the position fixing piece 68 by being fitted, and a plurality of hydraulic port pipes 82 are installed in the lower portion of the port block 74, and the On the upper part, a pair of hydraulic port guide blocks 84 are coupled to the left and right portions, respectively.

When the hydraulic port unit 118 installed as described above will be described in detail with reference to FIG. 8 , first, a guide shaft 46 having a cylindrical or round bar shape is formed, and both ends of the guide shaft 46 have more diameters. A large boss portion 47 is formed, and an upper guide bracket 50 and a lower guide bracket 52 are fixedly installed to face each other in the vertical direction and to be coupled to the upper and lower portions of the boss portion 47, respectively.

The lower guide bracket 50 has a rectangular shape, and a support part 60 formed in a concave semicircle shape is formed in the upper middle portion, and a press in the middle lower portion of the upper guide bracket 52 is formed in a concave semicircular shape. A portion 58 is formed.

The boss portion 47 is firmly coupled between the support portion 60 and the pressing portion 58 formed as described above, and the upper guide bracket 52 and the lower guide bracket 50 are fixed means, not shown. It has a structure in which the left and right ends are fixed and installed by

At the lower end of the guide shaft 46, a shaft support body 62 is installed on the left and right sides, respectively, and the shaft support body 62 is formed in the shape of a niche (b), and the shaft support body in the transverse direction ( A side support body 64 formed by being bent upward is formed on the entirety of 62), a support part 66 is formed on the upper surface of the side support body 64, and the support part 66 is concave downward. It is formed in a round shape to have the same diameter or a larger diameter as that of the lower outer peripheral surface of the guide shaft 46 while being gently formed.

The intermediate portion of the guide shaft 46 is placed on the support portion 66 of the shaft support body 62 formed as described above to support the guide shaft.

Subsequently, a position fixing piece 68 is installed at the rear of the middle portion of the guide shaft 46, and the position fixing piece 68 has a triangular body, and the lower surface is fitted with a digit (c) shape. The groove 70 is formed in an open shape at the bottom, and the support part 72 which is recessed to the right and formed in a semicircular shape is formed on the front surface.

The support portion 72 is coupled to the outer peripheral surface of the rear of the guide shaft 46 to firmly fix the guide shaft 46 not to be pushed in the rear direction.

A port block 74 is fitted into the fitting groove 70 of the positioning piece 68, and a hydraulic port pipe 82 is connected to the port block 74 to connect a plurality of hydraulic lines.

The port block 74 has a rectangular body and a plurality of port holes 76 are formed in the front and rear directions, and a hydraulic port pipe 82 is coupled to the port hole 76 from the rear direction to the front direction, and the A hydraulic port cap 78 is coupled to the forward portion to couple and fix the hydraulic port pipe 82 .

The hydraulic port pipe 82 includes a main hydraulic port pipe 80 installed so that a plurality of hydraulic pipe lines are formed and a sub hydraulic port pipe 81 fitted to the outside of the main hydraulic port pipe 80 .

On the other hand, a pair of hydraulic port guide blocks 84 coupled to face each other and installed on the left and right sides of the rectangular port block 74 are coupled and installed from the upper surface.

A pair of the hydraulic port guide block 84 has a rectangular body, one surface of the body is formed with a support part 86 so as to protrude downward, and the lower surface is coupled to open downward in the shape of a digit (c). A rail portion 88 is formed.

The port block 74 is coupled to the coupling rail part 88 .

At this time, the upper surface portion of the port block 74 coupled to the coupling rail portion 88 is in contact with the lower surface portion of the hydraulic port guide block 84 , and the side portion of the port block 74 is formed by the support portion 86 . The frame jig plate 56 is positioned above the hydraulic port guide block 84 and is firmly fixed so as not to be moved or shaken by being supported and firmly fixed by fixing means such as bolts, nuts, pieces, rivets, etc. not shown. By being installed, the hydraulic port guide block 84 holds the port block 74 so as not to be shaken, and the hydraulic port pipe 82 is firmly installed in the port hole 76 of the port block 74 to flow the hydraulic pressure. It is installed so that it is smooth, fast, and directly connected to the hydraulic operation.

A plate-shaped hydraulic port lower block 90 is fixedly installed on the lower surface of the port block 74 installed in this way, and a plurality of conduits 92 are formed to pass through the hydraulic port lower block 90 in the front-rear direction.

The pair of hydraulic port guide blocks 84 are slidably coupled to the left and right sides.

On the other hand, on both sides of the coupling lay portion 88 formed in the lower portion of the hydraulic port guide block 84, the downwardly protruding side coupling projections 89 are formed, and the side coupling projections 89 are the port blocks 74. ) to prevent the port block 74 from moving or shaking in the front-rear direction by supporting the front and rear surfaces.

The present invention described as described above is not limited to the preferred embodiment as described above, and it is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims of the present invention. It will be said that those skilled in the art are able to carry out deformations in various materials and shapes, of course, and such modifications are within the scope of the claims described as key elements of the present invention.

10,11: low plate 12: arm hook
13: coupling groove 14, 16: cover panel
18,19: support panel 20: low body
22: shaft coupling hole 24: case body
26: case upper plate 28: worm unit part
30: valve body 32: valve rotation shaft
34: valve bracket 36: seating part
38: coupling hole 40: base plate
42, 43: frame body 44: upper wing
46,48: guide shaft 50: lower guide bracket
52,54: upper guide bracket 56: frame jig plate
58: press part 60: support part
62: shaft support body 64: side support body
66: support portion 68: position fixing piece
70: fitting groove 72: support part
74: port block 76: port ball
78: hydraulic port cap 80: main hydraulic port pipe
81: sub hydraulic port pipe 82: hydraulic port pipe
84: hydraulic port guide block 86: support
88: coupling rail unit 90: hydraulic port lower block
92: pipeline
100: rotary link connection device 102: quick coupler
104: rotation link device 106: rotation unit unit
108: valve body part 110: frame part
112: hydraulic connector part 114: frame jig part
116: oil quick device 118: hydraulic port unit

Claims (4)

And a quick coupler 102 for quickly mounting the bucket of the excavator;
a rotary link device 104 installed on the quick coupler 102 to rotate 360 degrees;
It includes an oil quick device 116 for connecting and operating directly using a hydraulic port without connecting to a hydraulic hose installed on the upper portion of the rotary link device 104,
The oil quick device 116,
It includes a frame part 110 , a hydraulic connector part 112 , and a frame jig part 114 , wherein the frame part 110 has a flat base plate 40 formed thereon and is an upper portion of the base plate 40 . Frame bodies 42 and 43 are erected and fixed in the vertical direction on the left and right sides,
A base plate coupling hole 41 is formed in the central portion of the base plate 40, and the valve body part 108 is coupled and installed in the base plate coupling hole 41,
The hydraulic connector part 112 includes a plurality of hydraulic port pipes 82, and a port block 74 for firmly fixing and installing the hydraulic port pipes 82 by fitting them in the front and rear directions, and the port block ( 74) including a hydraulic port unit 118 having a pair of hydraulic port guide blocks 84 that are fixedly installed by slidingly coupled to face each other on both ends of the upper portion,
The quick coupler 102,
A pair of low plates 10 and 11 installed in parallel in the vertical direction, a cover panel 14 standing perpendicular to all of the low plates 10 and 11 and arranged to block the front part, and the low plate (10, 11) having a cover panel (16) erected perpendicularly to the rear portion of the cover panel (14) and fixed by being positioned in parallel,
The rotary link device 104,
A cylindrical case body 24 having a hollow central portion, and
On the upper surface of the case body 24, a case upper plate 26 having a flange portion of a flat plate formed on the outside of the hollow hole is extended to the outside, and a worm unit 28 is installed on the right side of the case body 24, A motor 30 is coupled to the front portion of the worm unit 28 to rotate the worm unit 28,
The hydraulic port unit 118,
a pair of left and right lower guide brackets 50 having a rectangular shape and having a support portion 60 formed in the central portion;
a pair of left and right upper guide brackets 52 and 54 formed in a rectangular shape and having a pressing portion 58 formed in the central portion;
a guide shaft 46 coupled and installed between the upper guide brackets 52 and 54 and the lower guide bracket 50;
a pair of shaft support bodies installed under the guide shaft 46 and installed inside the lower guide bracket 50 to support the lower outer peripheral surfaces of the left and right ends;
The hydraulic port structure of a rotary link connecting device for heavy equipment, characterized in that it has a position fixing piece (68) that is vertically positioned with respect to the center at the rear center of the guide shaft (46) and fixedly installed in the rear direction in the horizontal direction.




delete delete delete

Images