KR101369900B1 - Shaft assembly for scissors type bucket apparatus and scissors type bucket apparatus with the same - Google Patents

Abstract

The present invention relates to a rotating shaft assembly for a scissor bucket device and a scissor bucket device having the same, wherein a bearing that rotatably cross-couples a pair of scissor arms can be easily removed instead of permanently fixed by welding, thereby causing damage to the bearing. It can be replaced with a new one without damaging or replacing the Caesar's arm.
The present invention is an installation pipe installed on the first scissors arm; A bearing inserted into the installation pipe; First and second mounting rings respectively provided on one side and the other side of the second scissors arm and having an inner diameter larger than the diameter of the bearing; Third and fourth mounting rings which are respectively provided on the other side and one side of the auxiliary arm and have an inner diameter larger than the diameter of the bearing; A wedge flange having a ring shape installed in the second and fourth mounting rings, respectively; A pair of first bushes interposed between the inner circumferential surface of each of the second and fourth mounting rings and the outer circumferential surface of the wedge flange; A pair of cover flanges respectively installed on the first and second mounting rings; A rotating shaft supported through the inner ring of the bearing and having both ends thereof penetrated through the wedge flange and the cover flange; It consists of a second bushing between the inner circumferential surface of the wedge flange and the outer circumferential surface of the rotating shaft.

Description

SHAFT ASSEMBLY FOR SCISSORS TYPE BUCKET APPARATUS AND SCISSORS TYPE BUCKET APPARATUS WITH THE SAME}

The present invention relates to a scissor bucket device, and in particular, a bearing that rotatably cross-couples a pair of scissor arms so that the bearing can be easily removed instead of permanently fixed by welding, thereby damaging the scissor arm when the bearing is damaged. The present invention relates to a rotating shaft assembly for a scissors bucket device and a scissors bucket device having the same, which can be replaced with a new one without changing or replacing the same.

In general, the Caesars bucket device is a device that is used to move to a certain position after collecting the heavy objects and heavy moving objects such as sand, gravel, waste metals, grains, etc. made of two arms with the bucket is crossed like scissors. It is called.

Such a scissors bucket device has a shorter cycle time than other types of bucket devices, such as a shorter working time and a high efficiency, simple structure, and excellent maintainability. For example, the Caesar's bucket device is used as a facility for unloading raw materials at the raw material pier of POSCO, a representative Korean company.

Thus, Figure 1 is a reference diagram for explaining the scissors bucket device according to the prior art.

As shown, in the scissors bucket device according to the prior art, a pair of scissors arms 22a, 22b provided with buckets 21a, 21b at the lower end thereof are rotatably coupled in an intersecting form.

Here, in order to rotatably couple the pair of Caesar's arms 22a and 22b in an intersecting form, a bearing 12 and the bearing 12 are provided at an intersection between the pair of Caesar's arms 22a and 22b. Rotating shaft 11 penetrating the inner ring of is installed. That is, the outer ring of the bearing 12 is fixed to one of the first scissors arm 22a and the second scissors arm 22b by welding, and the bearing 12 is fixed to the other one of which the bearing 12 is not fixed. The rotating shaft 11 in the state which penetrated the inner ring of was fixed. Alternatively, a bearing 12 is provided on both the first scissors arm 22a and the second scissors arm 22b so that the outer ring is fixed by welding, and the rotary shaft 11 penetrating the inner ring of the bearing 12 is provided. The configuration to be installed was also possible.

In the case of such a scissors bucket device, the load is concentrated on the bearing 12 installed at the center of the cross-linking site and the operating part due to the heavy load of several tens of tons, and the damage occurs periodically. However, the task of separating and replacing only the bearing 12 permanently fixed by welding from the scissors arms 22a and 22b was extremely difficult. Therefore, the damaged bearing 12 was not immediately replaced in the field, and the entire Caesars bucket device was transported to the factory, and the first Scissors arm 22a and the second Scissor arm 22b were damaged in the process of replacing the bearing 12. This inevitable problem has been caused.

Moreover, in some cases only one bearing 12 could not be replaced, so the entire Caesars bucket device had to be replaced with a new one.

Accordingly, the present invention has been proposed to solve the conventional problems as described above, and an object of the present invention is to easily replace the bearings for rotatably cross-coupling a pair of scissor arms, instead of permanently fixing them by welding. The present invention provides a rotary shaft assembly for a scissor bucket device and a scissor bucket device having the same, which can be detached so that a new one can be replaced without damaging or replacing the scissors arm when the bearing is damaged.

In order to achieve the above object, the rotary shaft assembly for a scissors bucket device according to the technical idea of the present invention includes: an installation pipe fixedly installed by drilling the first scissors arm; A bearing inserted into the installation pipe; Respectively installed on one side of the second scissor arm and the other side opposite to the first scissor arm so as to communicate with a through hole formed in the second scissor arm at a position corresponding to the installation pipe; A first mounting ring and a second mounting ring having an inner diameter larger than the diameter of the bearing to allow the bearing to enter and exit; The installation pipe is installed on one side of the other side and the other side of the auxiliary arm and the surface opposite to the first scissor arm so as to communicate with the through hole formed in the auxiliary arm in a position corresponding to the installation pipe, respectively A third mounting ring and a fourth mounting ring which are installed symmetrically with the first mounting ring and the second mounting ring and have an inner diameter larger than the diameter of the bearing to allow the bearing to enter and exit from the center; A pair of wedge flanges each formed in the second mounting ring and the fourth mounting ring so as to block the entrance and exit of the bearing, and formed in a ring shape; A pair of first bushings interposed between the inner circumferential surface of each of the second and fourth mounting rings and the outer circumferential surface of the wedge flange to fix the wedge flange to the second and fourth mounting rings; ; A pair of cover flanges installed in the first mounting ring and the third mounting ring, respectively, fastened to the wedge flange and formed in a ring shape; A rotating shaft supported through the inner ring of the bearing so as to be rotatable, and both ends of which are provided to penetrate the wedge flange and the cover flange; A pair of second bushes interposed between an inner circumferential surface of the wedge flange and an outer circumferential surface of the rotation shaft to couple the second scissor arm and the auxiliary arm to rotate with the rotation shaft with respect to the first scissor arm. It is characterized by its technical configuration.

The wedge flange and the cover flange are provided with a plurality of bolt holes formed at positions corresponding to each other along the circumferential direction so that the wedge flange and the cover flange may be fastened by a nut and a bolt. One side of the cover flange is not located may be characterized in that the bolt head is provided with a bolt head restraining groove that is constrained so that the head of the bolt through the body is not rotated.

In addition, the first bushing and the second bushing may be formed in the shape of a wedge cross-section, the cross-sectional thickness of which gradually increases toward an outer direction in which the cover flange is located.

In addition, both the first bushing and the second bushing may be formed of a combination of two individuals each having a semicircular shape.

In addition, the wedge flange may be formed in the form of a wedge cross-section that gradually decreases in the outward direction where the cover flange is located, the cross-sectional thickness of the circumference portion corresponding to the first bushing and the second bushing.

In addition, the cover flange may cover the first bushing and the second bushing so as not to be separated.

In addition, the bearing is coupled to both ends of the mounting pipe between the mounting pipe and the wedge flange, respectively, the bearing from the inside of the mounting pipe while supporting the bearing inserted into the mounting pipe by contact projections protruding from the inner surface. It may be characterized in that a pair of bearing cover in the form of a ring to prevent the departure more.

In addition, the outer surface of the bearing cover is formed with a recessed groove recessed in the circumferential direction, the ring-shaped collar is inserted into the mounting groove so as not to protrude from the outer surface of the bearing cover to reinforce the strength of the bearing cover The pair may be further provided.

In addition, the inner diameter of the first mounting ring and the third mounting ring may be formed larger than the second mounting ring and the fourth mounting ring.

On the other hand, the scissors bucket device according to the present invention is characterized in that it comprises a rotary shaft assembly for the scissors bucket device described above in the technical configuration.

The rotating shaft assembly for the scissors bucket device and the scissors bucket device having the same according to the present invention can be easily installed and detached instead of permanently fixing the bearing by welding, without damaging or replacing the scissors arm when the bearing is damaged. You can replace it with a new one.

In addition, the present invention is provided with a bolt head restraint groove in the wedge flange to block the separation of the bearing on both sides of the bearing is very easy bolt and nut fastening process for the cover flange and the wedge flange.

In addition, the present invention is because the wedge flange and the rotating shaft is fixed to the mounting ring by the interference fitting method of the first bushing and the second bushing can be securely fixed, it can be easily separated if necessary.

In addition, according to the present invention, the first bushing and the second bushing are composed of a combination of two semicircular objects, respectively, so that the stretching of the circumference required in the installation process is naturally performed.

In addition, the present invention is provided with a bearing cover, in addition to the wedge flange, the separation of the bearing is primarily blocked by the bearing cover, and is supported so that the bearing does not move unstable inside the installation pipe.

1 is a reference diagram for explaining the scissors bucket device according to the prior art.
2 and 3 is a state diagram showing a state in which the rotating shaft assembly according to an embodiment of the present invention is installed in the scissors bucket device.
Figure 4 is a cross-sectional view for explaining the configuration of the rotary shaft assembly according to an embodiment of the present invention.
5 is an exploded perspective view of a rotating shaft assembly according to an embodiment of the present invention.
Figure 6 is a reference diagram showing the components coupled to the first scissors arm of the rotary shaft assembly according to an embodiment of the present invention.
7 is an enlarged cross-sectional view of a portion “A” of FIG. 6.
8 is a reference view showing the components coupled to the first scissors arm of the rotary shaft assembly according to an embodiment of the present invention.
9 is an enlarged cross-sectional view of a portion “B” of FIG. 8.

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

2 and 3 is a state diagram showing a state in which the rotating shaft assembly is installed in the scissors bucket device according to an embodiment of the present invention.

As shown, the rotating shaft assembly 100 according to an embodiment of the present invention is the first bucket arm 210b is installed at the end of the first bucket 210a, the second bucket 220a is installed at the end and spaced apart from each other In the scissor bucket device having an outer second scissors arm 220b and an inner auxiliary arm 220c that operate together with each other, the pair of first scissor arms 210b is provided on the left side and the post. It serves to rotatably couple in the inserted state between the scissors arm 220b and the secondary arm 220c.

Here, the rotating shaft assembly 100 according to an embodiment of the present invention, can be easily removed by replacing the bearing which is essentially provided for the rotation operation between the first scissors arm (210b) and the second scissors arm (220b). It is configured to be. As a result, while the load is concentrated during the rotation operation between the first scissors arm 210b and the second scissors arm 220b, a bearing which is frequently damaged compared to other parts can be easily separated and replaced in the field, and the bearing is replaced. In the process of doing so, there is no problem of damaging the first Caesar's arm 210b or the second Caesar's arm 220b or replacing the first Caesar's arm 210b or the second Caesar's arm 220b itself.

Hereinafter, the configuration of the rotary shaft assembly 100 according to an embodiment of the present invention will be described in detail. However, the rotating shaft assembly 100 according to an embodiment of the present invention is provided with two in each one in the symmetrical form on the left side and the post in the bucket device, but will be described below for the convenience of description only one of them.

Figure 4 is a cross-sectional view for explaining the configuration of the rotary shaft assembly according to an embodiment of the present invention, Figure 5 is an exploded perspective view of the rotary shaft assembly according to an embodiment of the present invention. FIG. 6 is a reference view illustrating components coupled to a first scissors arm of a rotating shaft assembly according to an exemplary embodiment of the present invention, FIG. 7 is an enlarged cross-sectional view of part “A” of FIG. 6, and FIG. FIG. 9 is a reference view illustrating components coupled to a first scissors arm of a rotating shaft assembly according to an embodiment, and FIG. 9 is an enlarged cross-sectional view of part “B” of FIG. 8.

As shown, the rotary shaft assembly 100 according to the embodiment of the present invention, including the rotary shaft 130, the installation pipe 211 is fixed to the first scissors arm (210b), and the installation pipe 211 It is provided with a bearing 110 for rotatably supporting the rotating shaft 130, a pair of bearing covers (121a, 121b) and a pair of collars (122a, 122b). In addition, the first mounting ring 221 and the second mounting ring 222, the third mounting ring 223 and the fourth fixed ring symmetrical to the second scissors arm 220b and the auxiliary arm 220c, respectively. A pair installed on the mounting ring 224, the second mounting ring 222 and the fourth mounting ring 224, the first mounting ring 221 and the third mounting ring 223 to support the rotary shaft 130. Wedge flanges 140a and 140b, a pair of cover flanges 170a and 170b, a pair of first bushes 160a and 160b, and a pair of second bushes 150a and 150b.

The rotary shaft assembly 100 according to an embodiment of the present invention is welded to the first scissor arm 210b by permanently fixing the bearing 110 by the configuration including the above components, the installation pipe 211 is inserted into and positioned inside, and the wedge flanges 140a and 140b are detachably installed on both sides of the installation pipe 211 as needed, so that the wedge is immediately on the spot when the bearing 110 is damaged. After the flanges 140a and 140b were separated, the damaged bearing 110 was taken out and replaced.

Hereinafter, the configuration of the rotary shaft assembly 100 according to an embodiment of the present invention with reference to the above components will be described in more detail.

First, the installation pipe 211 serves as a base for the installation of the bearing 110. To this end, the installation pipe 211 is fixed by a method such as welding after drilling the first scissors arm 210b. Here, the installation pipe 211 is made of a pipe shape having an inner hollow so that the bearing 110 can be inserted, the inside is formed of an inner diameter of a size corresponding to the diameter of the bearing 110, The left and right widths are formed so as not to be exposed in the state in which the whole bearing 110 is inserted.

The second mounting ring 222 and the fourth mounting ring 224, the first mounting ring 221 and the third mounting ring 223 are the wedge flange (140a, 140b) and the cover flange (170a, 170b) Acts as a base for installation. To this end, the first mounting ring 221 and the second mounting ring 222 communicate with the through hole formed in the second scissors arm 220b at a position corresponding to the installation pipe 211. It is fixed to one side of the side and the other side of the other side and the other side that is the surface facing the first scissors arm (210b) by welding or the like method. In addition, the third mounting ring 223 and the fourth mounting ring 224 the other side surface of the auxiliary arm 220c to communicate with the through-hole formed in the auxiliary arm 220c at a position corresponding to the installation pipe 211. And a side opposite to the other side and opposite to the first scissors arm 210b by welding or the like. Here, the installation rings (221, 222, 223, 224) are all provided with a through hole (221a, 222a, 223a, 224a) of the inner diameter larger than the diameter of the bearing 110 to allow the bearing 110 to enter and exit. Here, the first mounting ring 221 and the third mounting ring 223 may be installed to cover flanges 170a and 170b having a larger diameter than the wedge flanges 140a and 140b. However, the first mounting ring 221 and the third mounting ring 223 have stepped portions 221b and 223b to have an inner diameter that is partially equal to the inner diameter of the second mounting ring 222 and the fourth mounting ring 224. To cover the cover flanges 170a and 170b.

The bearing 110 is installed in a manner that is simply inserted into the installation pipe 211. At this time, the outer ring 112 of the bearing 110 is supported in close contact with the inner wall of the installation pipe 211, the inner ring 111 rotatably supports the rotating shaft 130 in a state where the rotating shaft 130 is penetrated. do.

In addition, the bearing 110 is stably supported so as not to move by a pair of bearing covers 121a and 121b installed at both sides thereof while being inserted into the installation pipe 211. The bearing covers 121a and 121b are coupled by fastening bolts 124 to both ends of the installation pipe 211 between the installation pipe 211 and the wedge flanges 140a and 140b, respectively, The outer ring 112 of the bearing 110 inserted into the installation pipe 211 is contacted and supported. Here, the bolt 124 for fastening is used as having a hexagonal groove for the hexagon wrench, the bearing cover (121a, 121b) is provided with a bolt hole 123 into which the head of the bolt 124 can be inserted do. The bearing covers 121a and 121b having such a structure can prevent the bearing 110 from being separated from the inside of the installation pipe 211 and also suppress unnecessary movement of the bearing 110.

In addition, seating grooves recessed along the circumferential direction are formed on outer surfaces of the bearing covers 121a and 121b. As a result, ring-shaped collars 122a and 122b that reinforce the strength of the bearing covers 121a and 121b may be inserted into the mounting grooves so as not to protrude from the outer surfaces of the bearing covers 121a and 121b.

The wedge flanges 140a and 140b are installed in the second mounting ring 222 and the fourth mounting ring 224 to block entrance and exit of the bearing 110 and to support the rotating shaft 130. Do it. To this end, the wedge flanges 140a and 140b are formed by the first bushings 160a and 160b interposed between the second mounting ring 222 and the fourth mounting ring 224. 222 and the fourth mounting ring 224 is stably coupled, and is formed in a ring shape having a through hole 143 in the center so as to support the rotating shaft 130. Here, the inner circumferential surface 143a and the outer circumferential surface 143b of the wedge flanges 140a and 140b are formed to be inclined to correspond to the first bushings 160a and 160b and the second bushings 150a and 150b so that the cross-sectional thickness of the circumferential portion thereof is increased. It is in the form of a wedge cross-section that gradually decreases toward the outside. According to this configuration, the wedge flanges 140a and 140b are stably fixed to the second mounting ring 222 and the fourth mounting ring 224 by the first bushings 160a and 160b. In the second bushing (150a, 150b) by the rotation shaft 130 can be stably supported.

Meanwhile, the wedge flanges 140a and 140b include a plurality of bolt holes 142 and bolt head restraint grooves 141 along the circumferential direction for coupling with the cover flanges 170a and 170b. The bolt head restraint groove 141 is provided in a circular shape in a circumferential direction on one side of the opposite side on which the cover flanges 170a and 170b are not located, on both sides of the wedge flanges 140a and 140b. 145 is inserted into a width that can be constrained so as not to rotate. As a result, the head of the bolt 145 in a state where the body penetrates the bolt hole 142 of the wedge flanges 140a and 140b is restrained from being seated in the bolt head restraint groove 141 so as not to rotate. In part, the body of the bolt 145 is fastened by the nut 146 in a state passing through the cover flanges 170a and 170b. When the bolt head restraint groove 141 is provided in the wedge flanges 140a and 140b as described above, the head of the bolt 145 can be restrained without a separate fastening part from the inside of the wedge flanges 140a and 140b which are out of reach. do. Therefore, the cover by the work or the nut 146 to be installed in the second mounting ring 222 and the fourth mounting ring 224 in a state where the plurality of bolts 145 penetrate the wedge flanges 140a and 140b. The fastening to the flange (170a, 170b) is made easy.

The cover flanges 170a and 170b are installed to have sizes corresponding to the insides of the first and second mounting rings 221 and 223, and bolts 145 and nuts (opposite to the bearing 110). 146 is coupled to the wedge flanges 140a and 140b to cover the first bushings 160a and 160b and the second bushings 150a and 150b so as not to be separated outward. This ensures that the wedge flanges 140a and 140b do not escape as a result. Here, the cover flange (170a, 170b) is formed in the circumferential direction a plurality of bolt holes 172 through which the bolt 145 penetrates corresponding to the bolt hole 142 provided in the wedge flange (140a, 140b) do. In the center, a through hole 171 is formed to penetrate the end of the rotation shaft 130.

The first bushings 160a and 160b are mainly interposed between the inner circumferential surfaces of the second mounting ring 222 and the fourth mounting ring 224 and the outer circumferential surfaces 143b of the wedge flanges 140a and 140b, thereby preventing the first bushing 160a and 160b from being disposed. The wedge flanges 140a and 140b are fixed to the second mounting ring 222 and the fourth mounting ring 224. In addition, the second bush (150a, 150b) is interposed between the inner circumferential surface (143a) of the wedge flange and the outer circumferential surface of the rotating shaft 130 to fix the rotating shaft 130 with respect to the wedge flange (140a, 140b) Let it be. Here, the first bushings 160a and 160b and the second bushings 150a and 150b are formed in the shape of a wedge cross section whose cross-sectional thickness gradually increases toward an outer direction in which the cover flanges 170a and 170b are located. As a result, the wedge flanges 140a and 140b and the rotation shaft 130 may be stably supported with respect to the second installation ring 222 and the fourth installation ring 224. In addition, the first bushings 160a and 160b and the second bushings 150a and 150b are each formed of a combination of two semicircular bodies. This is to facilitate the work by allowing the micro-contraction in the circumferential direction to be made naturally in the installation process and the separation process that is fit.

The rotating shaft 130 is supported to penetrate the inner ring 111 of the bearing 110 so as to be rotatable, and both ends thereof are installed to penetrate the wedge flanges 140a and 140b and the cover flanges 170a and 170b. One end of the rotation shaft 130 is fastened to the flanges 181a and 181b of the support bar 180 by bolts 183. To this end, at least one end of both ends of the rotation shaft 130 is provided with a plurality of bolt holes 182 along the circumferential direction.

The assembly and disassembly process of the rotary shaft assembly for the scissors bucket device according to the embodiment of the present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, look at the assembly process of the rotary shaft assembly 100 for the scissors bucket device according to an embodiment of the present invention.

To this end, the bearing 110 is prepared and inserted into the installation pipe 211 which is already fixed to the first scissors arm 210b by welding.

Thereafter, the bearing covers 121a and 121b are fastened to both ends of the installation pipe 211 to prevent the bearing 110 from being detached from the installation pipe 211. When the installation of the bearing covers 121a and 121b is completed, the collars 122a and 122b for strength reinforcement are mounted in the mounting grooves formed on the outer surfaces of the bearing covers 121a and 121b.

The second scissors arm 220b and the secondary arm 220c are then crossed with respect to the first scissors arm 210b. Then, a wedge flange (inside) of the second mounting ring 222 fixed to the second scissors arm 220b by welding and the fourth mounting ring 223 fixed to the auxiliary arm 220c by welding. The operation of fixing the 140a, 140b is in progress.

To this end, first, the body of the bolt 145 is inserted through the bolt hole 142 of the wedge flanges 140a and 140b, and inserted into the outer side to restrain the wedge flanges 140a and 140b formed on the inner surface. The head (hexagonal head) of the bolt 145 is inserted into the groove 141. Then, the bolt 145 is constrained so as not to rotate. As such, when the body of the bolt 145 penetrates through the bolt hole 142 of the wedge flanges 140a and 140b, the wedge flanges 140a and 140b are installed in the second installation ring 222 and the fourth. Located in the mounting ring 224, the first bushing (160a, 160b) is driven between the second mounting ring 222 and the fourth mounting ring 224 and the wedge flange (140a, 140b). Then, the wedge flanges 140a and 140b are fixed to the second mounting ring 222 and the fourth mounting ring 224 by interference fit. This operation is performed on both the second mounting ring 222 and the fourth mounting ring 224 fixed to the second scissors arm 220b and the auxiliary arm 220c. When the wedge flanges 140a and 140b are fixed to the second mounting ring 222 and the fourth mounting ring 224, the bearing cover 121a and 121b and the collar are formed by the wedge flanges 140a and 140b. 122a and 122b and the bearing 110 are supported in a blocked state so as not to be separated or separated from the installation pipe 211.

Thereafter, the rotating shaft 130 is prepared and coupled to the support bar 180, and the rotating shaft 130 passes through the bearing 110 and the wedge flanges 140a and 140b in the state. Then, the operation of fixing the rotating shaft 130 with respect to the wedge flange (140a, 140b) is in progress. To this end, the second bushes 150a and 150b are driven between the wedge flanges 140a and 140b and the rotation shaft 130 while the rotary shaft 130 penetrates the bearing 110 and the wedge flange. Then, the rotation shaft 130 is fixed to the wedge flanges 140a and 140b by interference fit. This operation is performed on both the wedge flanges 140a and 140b installed on the second scissors arm 220b and the auxiliary arm 220c.

Thereafter, the cover flanges 170a and 170b are positioned inside the first bushings 160a and 160b to the wedge flanges 140a and 140b, the first bushings 160a and 160b and the second bushings 150a and 150b. Pad. In this process, a part of the body of the bolt 145 protruding outward through the wedge flanges 140a and 140b penetrates through the bolt hole 172 of the cover flanges 170a and 170b and protrudes outward. Then, the plate spring washer 147 is first inserted into a part of the body of the bolt 145 protruding to the outside of the cover flanges 170a and 170b and then the nut 146 is fastened to cover the cover flanges 170a and 170b. To wedge flanges 140a and 140b. This operation is performed on both the cover flanges 170a and 170b installed on the second scissors arm 220b and the auxiliary arm 220c.

Thus, the assembly process of the rotary shaft assembly 100 for the scissors bucket device according to an embodiment of the present invention is completed.

On the other hand, if the bearing 110 is damaged during the operation of the scissors bucket device, the rotary shaft assembly 100 is assembled by the above process, the process of separating to replace the damaged bearing 110 may proceed as follows. .

First, when the nut 146 fixing the cover flanges 170a and 170b from the outside is released from the bolt 145 to release the fastening, the cover flanges 170a and 170b can be easily removed.

Subsequently, the operation of separating the rotating shaft 130 is performed. This operation simply strikes the rotating shaft 130 or between the second bushing 150a and 150b between the rotating shaft 130 and the wedge flanges 140a and 140b. This is done simply by subtracting from.

Thereafter, the work of separating the wedge flanges 140a and 140b fixed by the first bushings 160a and 160b from the second mounting ring 222 and the fourth mounting ring 224 is performed. This operation hits the wedge flanges 140a and 140b or moves the first bushings 160a and 160b between the second mounting ring 222 and the fourth mounting ring 224 and the wedge flanges 140a and 140b. This is done simply by subtracting from. As such, when the wedge flanges 140a and 140b are separated from the second mounting ring 222 and the fourth mounting ring 224, the bearing covers 121a and 121b and the collar 122a coupled to the mounting pipe 211 are provided. 122b) is exposed to the outside.

Thereafter, the bearing covers 121a and 121b and the collars 122a and 122b are separated through the inner through holes 221a, 222a, 223a and 224a of the second mounting ring 222 and the fourth mounting ring 224. Pull it out. Then, the damaged bearing 110 inserted into the installation pipe 211 can be simply taken out and separated.

As such, the present invention provides a damaged bearing 110 in the field without damaging the first scissor arm 210b or the second scissor arm 220b and the auxiliary arm 220c in a manner that separates the components of the rotary shaft assembly 100. It is possible to simply replace.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be suitably modified and applied in the same manner. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

110: bearing 121a, 121b: bearing cover
122a, 122b: collar 130: rotating shaft
140a, 140b: Wedge flange 141: Restraint groove
150a, 150b: First bush 160a, 160b: Second bush
170a, 170b: cover flange 180: support bar
210a: First bucket 210b: First Caesars arm
220a: second bucket 220b, 220c: second scissors arm, auxiliary arm

Claims (10)

In a scissors bucket device having a first scissors arm provided with a first bucket at the end, and an outer second scissors arm and an auxiliary support arm provided at the end and spaced apart from each other, the first scissors A rotating shaft assembly for rotatably engaging an arm inserted between said second scissors arm and an auxiliary arm,
An installation tube provided by fixing the first scissors arm;
A bearing inserted into the installation pipe;
Respectively installed on one side of the second scissor arm and the other side opposite to the first scissor arm so as to communicate with a through hole formed in the second scissor arm at a position corresponding to the installation pipe; A first mounting ring and a second mounting ring having an inner diameter larger than the diameter of the bearing to allow the bearing to enter and exit;
The installation pipe is installed on one side of the other side and the other side of the auxiliary arm and the surface opposite to the first scissor arm so as to communicate with the through hole formed in the auxiliary arm in a position corresponding to the installation pipe, respectively A third mounting ring and a fourth mounting ring which are installed symmetrically with the first mounting ring and the second mounting ring and have an inner diameter larger than the diameter of the bearing to allow the bearing to enter and exit from the center;
A pair of wedge flanges each formed in the second mounting ring and the fourth mounting ring so as to block the entrance and exit of the bearing, and formed in a ring shape;
A pair of first bushings interposed between the inner circumferential surface of each of the second and fourth mounting rings and the outer circumferential surface of the wedge flange to fix the wedge flange to the second and fourth mounting rings; ;
A pair of cover flanges installed in the first mounting ring and the third mounting ring, respectively, fastened to the wedge flange and formed in a ring shape;
A rotating shaft supported through the inner ring of the bearing so as to be rotatable, and both ends of which are provided to penetrate the wedge flange and the cover flange;
A pair of second bushes interposed between an inner circumferential surface of the wedge flange and an outer circumferential surface of the rotation shaft to couple the second scissor arm and the auxiliary arm to rotate with the rotation shaft with respect to the first scissor arm. Rotary shaft assembly for the scissors bucket device is configured. The method of claim 1,
The wedge flange and the cover flange is provided with a plurality of bolt holes formed at positions corresponding to each other in the circumferential direction so that the fastening of the wedge flange and the cover flange can be made by nuts and bolts,
Rotating shaft for the scissors bucket device, characterized in that the one side of the wedge flange is not located the cover flange is provided with a bolt head restraint groove that is constrained so that the head of the bolt penetrated through the body in the bolt hole does not rotate assembly. The method of claim 1,
The first bushing and the second bushing shaft assembly is characterized in that the cross-sectional thickness is formed in the form of a wedge cross-section gradually increases toward the outer direction in which the cover flange is located. The method of claim 3,
Both the first bushing and the second bushing is a rotating shaft assembly for the scissors bucket device, characterized in that each consisting of a combination of two semi-circular. The method of claim 3,
The wedge flange has a rotary shaft assembly for the scissors bucket device, characterized in that the thickness of the circumferential portion of the wedge cross-section gradually decreases toward the outer side where the cover flange is located so as to correspond to the first bushing and the second bushing. The method of claim 3,
The cover flange is a rotation shaft assembly for the scissors bucket device, characterized in that the cover so that the first bush and the second bush is not separated. The method of claim 1,
The bearings are coupled to both ends of the mounting pipe between the mounting pipe and the wedge flange, respectively, and are supported by bearings inserted into the mounting pipe by contact protrusions protruding from the inner side, thereby preventing the bearing from being separated from the inside of the mounting pipe. A rotating shaft assembly for a scissor bucket device, characterized in that a pair of bearing cover is further provided to prevent a ring. 8. The method of claim 7,
A seating groove recessed along the circumferential direction is formed on the outer surface of the bearing cover, and a pair of collars having a ring shape inserted into the mounting groove so as not to protrude from the outer surface of the bearing cover to reinforce the strength of the bearing cover is further included. Rotary shaft assembly for scissors bucket characterized in that it is provided. The method of claim 1,
The inner diameter of the first mounting ring and the third mounting ring is larger than the second mounting ring and the fourth mounting ring, the rotating shaft assembly for the scissors bucket. Claims 1 to 9 of the scissors bucket device, characterized in that it comprises a rotary shaft assembly for the scissors bucket device.

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