KR102381889B1 - Improvement sleving drive - Google Patents

Abstract

In the present invention, since a tilting reinforcing body is provided inside the revolving drive connected to the connection body of the excavator bucket so that the rotation and tilting operation of the bucket of the excavator are made easily, the external force generated during the tilting operation of the bucket as well as the rotation of the bucket is provided. As the slewing drive can be easily dispersed or damaged, the slewing drive can be used for a long time, and the tilting reinforcing body and the slewing drive can be closely attached to the connection body of the excavator bucket at the same time. The external force generated during operation is not concentrated on the slewing drive, but is supported by the tilting reinforcement, so the external force applied to the slewing drive can be supported and distributed without being concentrated on the slewing drive. Disclosed is an improved slewing drive equipped with a tilting reinforcement that can prevent oil leakage and enable long-term use of excavator equipment.

Description

Improved slewing drive with tilting reinforcement {IMPROVEMENT SLEVING DRIVE}

The present invention relates to an improved slewing drive equipped with a tilting reinforcing body, and more particularly, by distributing and supporting the external force applied by the equipment tilting operation when the equipment is rotated and tilted, cracking, damage, and failure of the slewing drive occur It relates to an improved slewing drive equipped with a tilting reinforcement to prevent

In general, a slewing drive refers to a gearbox designed to transmit torque during rotation and safely withstand radial and axial loads. assembled within.

This slewing drive is coupled to the inner circumferential surface of the outer race to increase durability and lifespan by dispersing the external force even when an external force caused by an abnormal moment generated during the operation of equipment such as an excavator acts, and the rotatable rail along the circumferential direction of the inner race It is provided with a protrusion on both sides, is provided with receiving grooves concave inward on both sides, a plurality of rolling bodies are inserted in both side receiving grooves, and a plurality of rollers are rotatably mounted along the circumferential direction between the outer circumferential surface of the rail and the outer race. It is composed to be arranged in a triangle with the cloud body.

However, in the conventional orbiting drive, since a plurality of rollers are disposed in the gap between the retaining ring and the support ring, when an external force such as an abnormal moment or excessive load is applied to the orbiting drive, the plurality of balls are radially pushed outward. It is relatively vulnerable to force, and there is a problem in that it is not only damaged, but also oil leaks.

In addition, since a plurality of balls and a support structure for preventing their separation are added, the internal structure is relatively complicated, thereby reducing productivity.

Meanwhile, the present applicant has devised a slewing drive, registered Patent No. 10-1719076, in order to solve the problems of the conventional slewing drive, which is that the inner race of the orbital drive is stepwisely coupled to the radial inner surface of the outer race, and the radial inner surface of the outer race and a plurality of balls are inserted and disposed between the radial inner surface of the inner race, and a first sealant is disposed between the radial inner surface of the housing of the swivel driver and the radial outer surface of the outer race, and between the radial outer surface of the inner race and the radial inner surface of the outer race In order to prevent foreign substances from being introduced into the formed gap, the second sealing material is disposed on both sides of the coupling portion, respectively.

The slewing drive devised by the present applicant having such a configuration can greatly improve dust and water resistance, prevent oil leakage, and support axial force and radial force moment when the equipment is driven.

However, the slewing drive devised by the present applicant firmly supports the moment for the rotational motion of the bucket or tongs of the excavator, but fails to properly support the tilting moment for the tilting operation. is occurring frequently.

That is, in the case of the slewing drive devised by the present applicant, the inside is hollow and the supporting force for the rotating operation is made by the slewing bearing provided on the periphery. will not be done at all.

Also, as the inside of the slewing drive is hollowed out, the supporting force for the external force applied to the slewing drive during rotation or tilting of the equipment is concentrated on the outside of the slewing drive, and the connection between the slewing drive and the bucket or tongs of the slewing drive Since only one side is bolted and the other side is not bolted, there is a problem in that one side of the orbiting drive is lifted during the tilting operation of the equipment connected to the orbiting drive.

Patent Document 1: Republic of Korea Patent No. 10-1719076 (registered on March 16, 2017) Patent Document 2: Republic of Korea Patent No. 10-1413040 (Registered on June 23, 2014)

The present invention provides a housing and a tilting reinforcing body in the hollow inner space of a slewing drive comprising a slewing bearing provided inside the housing and having a hollow inner space, so that the rotation of the bucket provided in the excavator as well as the tilting operation occurs In addition to distributing the external force generated by the tilting operation, the bucket is first contacted and supported by the tilting reinforcing body rather than the revolving drive during the tilting operation. There is a purpose.

As a means for achieving the above object, the improved slewing drive equipped with a tilting reinforcement according to the present invention is provided with a housing, a slewing bearing provided inside the housing and having a gear part on an outer circumferential surface, and a worm gear meshing with the gear part of the slewing bearing. It includes a driving part and a rotation support step part provided at the inner center of the slewing bearing and having an open space inside, and is in close contact with the bucket connection body during the bucket tilting operation of the excavator to prevent lifting of the slewing bearing as well as the rotational operation of the bucket of the excavator. In the slewing drive provided with a tilting reinforcement seated on the rotation support stepped portion to be introduced into the open space side of the rotation support stepped portion to disperse and support the external force generated during the tilting operation, the tilting reinforcement includes: a first reinforcing body that is seated and closely adhered to the rotation support step provided on the inside and has a first ball accommodating groove along the inner circumferential periphery; a second reinforcing body provided inside the first reinforcing body and having an outer circumferential surface in close contact with the inner circumferential surface of the first reinforcing body and having a second ball receiving groove positioned to face the first ball receiving groove along the outer circumferential circumference; a rolling ball provided with a plurality of outer surfaces in close contact with the first ball receiving groove of the first reinforcing body and the second ball receiving groove of the second reinforcing body; A wedge-shaped first connector connecting and supporting the upper inner surface of the first reinforcing body and the upper outer surface of the second reinforcing body, and a wedge-shaped second connecting and supporting the inner lower end of the second reinforcing body and the outer lower end of the second reinforcing body Including a connection part, the upper surface of the first reinforcing body is positioned on the same horizontal line as the surface of the orbiting bearing, so that the surface of the orbiting bearing and the upper surface of the first reinforcing body are in close contact with the bucket connection body of the excavator at the same time to tilt the bucket of the excavator The slewing bearing is made to prevent lifting during operation, and the lower surface of the second reinforcing body is drawn into an open space provided inside the rotation support step portion to connect and support the rotation support step portion and the wedge-shaped third connecting portion. It is provided as much as possible.

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Furthermore, the upper surface of the first reinforcing body of the tilting reinforcing body is in close contact with the connecting body of the excavator bucket to prevent the slewing bearing from lifting during the tilting operation of the excavator bucket, and it is easy to distribute the external force generated during the rotating operation of the excavator bucket An adhesion coating layer is provided so as to make it happen.

In the present invention, since a tilting reinforcing body is provided inside the revolving drive connected to the connection body of the excavator bucket so that the rotation and tilting operation of the bucket of the excavator are made easily, the external force generated during the tilting operation of the bucket as well as the rotation of the bucket is provided. As the slewing drive can be easily dispersed or damaged, the slewing drive can be used for a long time, and the tilting reinforcing body and the slewing drive can be closely attached to the connection body of the excavator bucket at the same time. The external force generated during operation is not concentrated on the slewing drive, but is supported by the tilting reinforcement, so the external force applied to the slewing drive can be supported and distributed without being concentrated on the slewing drive. It can prevent oil leakage, and long-term use of excavator equipment is possible.

1 is a perspective view showing an improved slewing drive equipped with a tilting reinforcement according to the present invention.
2 is an exploded perspective view showing the configuration of an improved slewing drive equipped with a tilting reinforcement according to the present invention.
3 is a block diagram showing the configuration of an improved slewing drive equipped with a tilting reinforcement according to the present invention.
4 is an enlarged configuration view of one side showing the configuration of an improved slewing drive equipped with a tilting reinforcement according to the present invention.
5 is an enlarged view of the other side showing the configuration of an improved slewing drive equipped with a tilting reinforcement according to the present invention.
6 is a block diagram showing another embodiment of an improved slewing drive equipped with a tilting reinforcement according to the present invention.
7 is an exploded perspective view of another embodiment of an improved slewing drive equipped with a tilting reinforcement according to the present invention.
8 is a conceptual diagram illustrating a state in which an improved slewing drive equipped with a tilting reinforcement according to the present invention is connected to an excavator bucket.

Hereinafter, in addition to the above object, other objects and features of the present invention will become apparent through the description of the embodiments with reference to the accompanying drawings.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, an improved slewing drive equipped with a tilting reinforcement according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

As shown, the present invention is provided with a housing (1) and a turning bearing (2) provided inside the housing (1) and having a gear part on the outer peripheral surface, and a worm gear meshing with the gear part of the turning bearing (2). It relates to a swing drive having a driving unit (3).

As shown in FIG. 8, the slewing drive of the present invention is connected to the connection body of the excavator bucket to pick up construction materials or wood by the excavator bucket, or transmit torque when the industrial machine rotates and the moment for the applied load to make it stable.

In addition, the present invention includes a rotation support step portion 10 provided at the inner center of the orbiting bearing 2 and having an open space portion 11 on the inside, and an open space portion of the rotation support step portion 10 ( 11) is provided with a tilting reinforcing body 100 that is seated on the rotation support step 10 so as to be drawn in to the side, and is in close contact with the bucket connecting body 5 during tilting operation of the bucket 4 of the excavator and the slewing bearing 2 ), the external force generated during the tilting operation as well as the rotation of the excavator bucket 4 is distributed and supported.

In addition, since the slewing bearing 2 and the tilting reinforcement 100 are simultaneously connected to the bucket connecting body 5 by the tilting reinforcement 100, the external force generated during rotation is the slewing bearing 2 and the tilting reinforcement ( 100) and is distributed rather than concentrated only on the slewing bearing 2, the load applied during the rotational operation of the slewing bearing 2 can be minimized, and oil leakage of the slewing drive equipped with the slewing bearing 2 can be prevented. can

The tilting reinforcing body 100 of the present invention includes a first reinforcing body 110 and a second reinforcing body 120, and the first reinforcing body 110 is provided inside the orbiting bearing 2 It is seated and closely adhered to the rotation support step portion 10, and the first ball receiving groove 111 is provided along the inner circumferential circumference.

As the first reinforcing body 110 is provided in a state in which the outer peripheral surface of the first reinforcing body 110 is in close contact with the rotating support step 10 provided inside the slewing bearing 2 as shown in FIG. 3 , the excavator When the bucket 4 is rotated or a tilting operation is made, the first reinforcement body 110 is firmly supported by the rotation support step portion 10 so that the dispersion of the external force can be easily made, and the first reinforcement body 110 The second reinforcing body 120 connected to can not only be firmly supported, but also the supportability for the rotational operation of the first reinforcing body 110 is improved.

The second reinforcing body 120 is provided inside the first reinforcing body 110 , and the outer circumferential surface 122 is in close contact with the inner circumferential surface 112 of the first reinforcing body 110 and faces the first ball receiving groove 111 . A second ball receiving groove 121 positioned so as to be viewed is provided along the circumference of the outer circumferential surface 122 .

In addition, a plurality of rolling balls 130 are provided so that the outer surface is in close contact with the first ball receiving groove 111 of the first reinforcing body 110 and the second ball receiving groove 121 of the second reinforcing body 120 .

In the present invention made in this way, as the first reinforcing body 110 with respect to the second reinforcing body 120 can be easily rotated by the plurality of rolling balls 130, the excavator bucket 4 rotates. When the first reinforcing body 110, the second reinforcing body 120, and the slewing bearing 2 of the slewing drive are all closely connected to the excavator bucket 4, the rotation operation can be made, so that the The external force applied during rotation is easily dispersed, so that problems such as oil leakage as well as failure of the orbiting drive that occur when external force is applied only to the slewing bearing 2 can be solved.

That is, when the connecting body 5 of the excavator bucket 4 is connected to the orbiting bearing 2 and the first reinforcing body 110 and the second reinforcing body 120 of the tilting reinforcing body 100, the first reinforcement Since the upper surface 113 of the sieve 110 is positioned identically to the surface 2a and the horizontal line a of the slewing bearing 2 as shown in FIG. 3, the bucket 4 connection body of the excavator ( 5), as the surface 2a of the slewing bearing 2 and the upper surface 113 of the first reinforcement 110 are in close contact at the same time, the slewing bearing 2 is prevented from lifting during the tilting operation of the excavator bucket 4 The external force applied when lifting, tilting, or rotating construction materials or wood having a heavy load by the excavator bucket 4 can As the external force transmitted simultaneously to 120 and applied can be dispersed, it is not concentrated only on the slewing bearing 2 of the slewing drive, thereby preventing breakage, damage and damage of the slewing bearing 2, as well as failures such as oil leakage occurrence can be prevented.

The connection between the first reinforcing body 110 and the second reinforcing body 120 of the present invention is the upper end of the inner circumferential surface 112 of the first reinforcing body 110 and the upper end of the outer circumferential surface 122 of the second reinforcing body 120 . A wedge-shaped first connector 140 for connecting and supporting the (150).

In this way, without welding the first reinforcement body 110 and the second reinforcement body 120, the first reinforcement body 110 and the second reinforcement body 110 by the wedge-shaped first connection part 140 and the wedge-type second connection part 15 The reason for connecting the upper end and the lower end of the reinforcing body 120 is to allow the first reinforcing body 110 to be easily rotated by the plurality of rolling balls 130 with respect to the second reinforcing body 120 .

Accordingly, the external force applied when the construction material or wood having a heavy load is rotated by the excavator bucket 4 is simultaneously applied to the slewing bearing 2 as well as the first reinforcing body 110 and the second reinforcing body 120 As the transmitted and applied external force is distributed, the rotation of the slewing bearing 2 and the first reinforcing body 110 can be easily rotated with respect to the second reinforcing body 120 of the excavator bucket 4 Rotational operation can be made easily and can be firmly supported.

The lower surface 123 of the second reinforcing body 120 of the present invention is introduced into the open space 11 provided on the inside of the rotation support stepped portion 10, and the rotation support stepped portion 10 and the wedge-shaped product are introduced into the inner side. It is provided so as to be connected and supported by three connecting parts 160 .

As described above, as the lower surface 123 of the second reinforcing body 120 is firmly connected and supported by the wedge-shaped third connecting portion 160 to the rotation support step 10, when the first reinforcing body 110 is rotated It not only firmly supports the second reinforcing body 120 , but also prevents the second reinforcing body 120 from being separated from the lower side of the open space 11 .

The upper surface 113 of the first reinforcing body 110 of the tilting reinforcing body 100 of the present invention is in close contact with the connecting body 5 of the excavator bucket 4 to turn during the tilting operation of the excavator bucket 4 The adhesion coating layer 170 is provided to prevent the bearing 2 from lifting and to facilitate the distribution of external force generated during the rotational operation of the excavator bucket 4 .

The adhesion coating layer 170 may be made of a Teflon coating layer that prevents rust and corrosion or scratches on the surface. It is possible to prevent rust and corrosion of the 110, and the sliding on the upper surface of the first reinforcement 110 can be improved by the adhesion coating layer 170, so that the first reinforcement during the rotational operation of the excavator bucket 4 The rotation operation of 110 can be easily made.

As described above, in the present invention, specific matters such as specific components, etc., and limited embodiments and drawings have been described, but these are only provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. Various modifications and variations are possible from these descriptions by those of ordinary skill in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims described below, but also all of the claims and equivalents or equivalent modifications will fall within the scope of the spirit of the present invention.

10: rotation support step part 11: open space part
100: tilting reinforcement 110: first reinforcement
111: first ball receiving groove 112: first reinforcement body inner peripheral surface
113: upper surface of the first reinforcement 120: the second reinforcement
121: second ball receiving groove 122: second reinforcement body outer peripheral surface
123: second reinforcement body 130: cloud ball
140: wedge-shaped first connection part 150: wedge-shaped second connection part
160: wedge-shaped third connection part 170: adhesion coating layer

Claims (3)

A housing (1), a turning bearing (2) provided inside the housing (1) and having a gear part on an outer peripheral surface, and a driving part (3) provided with a worm gear meshing with the gear part of the turning bearing (2); The bearing (2) is provided in the center of the inner side and includes a rotating support step portion (10) having an open space (11) on the inside, and is in close contact with the bucket connecting body (5) during tilting operation of the bucket (4) of the excavator and is a turning bearing (2) to prevent the lifting of the excavator bucket 4, as well as to support the external force generated during the tilting operation as well as the rotational operation of the excavator bucket 4 so as to be introduced into the open space 11 side of the rotation support step 10. In the turning drive provided with the tilting reinforcement body 100 to be seated on the rotation support step 10,
The tilting reinforcement 100 is,
a first reinforcing body 110 that is seated and closely adhered to the rotation support step 10 provided inside the orbiting bearing 2 and has a first ball receiving groove 111 along the inner circumferential circumference thereof;
A second ball receiving groove ( 121) a second reinforcing body 120 provided along the outer peripheral surface 122 periphery;
a rolling ball 130 provided with a plurality of outer surfaces to be in close contact with the first ball receiving groove 111 of the first reinforcing body 110 and the second ball receiving groove 121 of the second reinforcing body 120;
A wedge-shaped first connector 140 connecting and supporting the upper end of the inner circumferential surface 112 of the first reinforcing body 110 and the upper end of the outer circumferential 122 of the second reinforcing body 120 and the first reinforcing body 110 It includes a wedge-shaped second connection part 150 for connecting and supporting the lower end of the inner circumferential surface 112 and the lower end of the outer circumferential surface 122 of the second reinforcing body 120,
The upper surface 113 of the first reinforcing body 110 is positioned on the same horizontal line as the surface 2a of the slewing bearing 2, and the slewing bearing 2 surface is connected to the bucket 4 connecting body 5 of the excavator. (2a) and the upper surface 113 of the first reinforcing body 110 are closely contacted at the same time to prevent the slewing bearing 2 from lifting during the tilting operation of the excavator bucket 4,
The lower surface 123 of the second reinforcing body 120 is introduced into the open space 11 provided inside the rotation support step 10, and the rotation support step 10 and the wedge-shaped third connection part ( 160), an improved slewing drive provided with a tilting reinforcement, characterized in that it is provided to be connected and supported. delete The method of claim 1,
On the upper surface 113 of the first reinforcing body 110 of the tilting reinforcing body 100, it is in close contact with the connecting body 5 of the excavator bucket 4, and a slewing bearing ( 2) An improved slewing drive with a tilting reinforcing body, characterized in that the adhesion coating layer 170 is provided to prevent this lifting and to easily distribute the external force generated during the rotational operation of the excavator bucket (4).

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