KR200307711Y1 - Cutter and bearing fixing device of shredder axis - Google Patents

Abstract

The present invention relates to a crusher for crushing various wastes, and more particularly, a plurality of cutters installed on the crushing shaft and a bearing supporting the rotational support of both ends of the crushing shaft to apply a strong tightening force so that flow does not occur even during long-term use Cutter and bearing retainer of a shredder shaft without damaging the shaft.

The present invention prevents the occurrence of flow by installing a fastening plate that exerts a strong tightening force so that the cutter, spacer, bearings, etc. installed on the crushing shaft is in close contact with the crushing shaft, and prevents the flow from occurring, The bolt is installed on the support plate spaced apart from the tightening plate by a predetermined distance, and the support plate is made by close contact with the split coater fitted in the cotter groove of the crushing shaft to be fixed so as not to be pushed backward, the tightening plate according to tightening the tightening bolt A strong tightening force is applied to the bearing, the spacer and the cutter can be closely adhered to the flow does not occur.

Description

Cutter and bearing fixing device of shredder axis

The present invention relates to a crusher for crushing various wastes, and more particularly, a plurality of cutters installed on the crushing shaft and a bearing supporting the rotational support of both ends of the crushing shaft to apply a strong tightening force so that flow does not occur even during long-term use Cutter and bearing retainer of a shredder shaft without damaging the shaft.

A general configuration of the shredder 1 for shredding various shredded materials in the form of small particles is that a pair of shredding shafts 3 are disposed on the shredding base 2 to face the shredding shaft 3 as shown in FIG. A plurality of cutters (4) are continuously installed at staggered intervals so as to interlock with the cutter (4) of the other shredding shaft (3) and between the cutter (4) and a constant interval between the cutter (4) A plurality of spacers 5 are installed to hold them, while both ends are rotatably supported by the bearing 6.

Here, the crushing shaft 3 is rotated at high speed due to the characteristics of the crusher, so that the cutter 4, the spacer 5, and the bearing 6 installed on the crushing shaft are flowed along the axis, so that the smooth crushing work is achieved. The key is to fix the cutter 4, the spacer 5 and the bearing 6 to the fracture shaft without flow.

Conventionally, it has been common to fasten a pair of hook nuts on both ends of the crushing shaft 3 as part of a method for fixing them.

However, in this case, due to the high-speed rotation of the crushing shaft (3) and the resistance applied to the cutter during the crushing of the waste, flow occurs in the fastening portion to which the hook nut is fastened, the tightening force is loosened, the loosened crushing shaft is lost or worn Was generated and rust was rusted.

In addition, as the cutter and the spacer flows, the cutter's arrangement interval is changed, so that a collision occurs with the cutter installed on the other pair of crushing shafts that rotate and engage, which causes a problem that the cutter is not broken and the cutter is broken.

The present invention has been devised to eliminate the above problems, to ensure that a strong tightening force is always maintained in the cutter and spacers, bearings installed on the crushing shaft to prevent damage to the crushing shaft and breakage of the cutter due to flow generated It is for the purpose of design.

The present invention for achieving the desired purpose is to install a tightening plate to apply a strong tightening force to the cutter shaft, the spacer, bearings, etc. are installed on the crushing shaft to be extrapolated to the crushing shaft to prevent the flow is generated, the tightening force on the tightening plate A plurality of tightening bolts are provided to install a support plate spaced apart from the tightening plate by a predetermined distance, and the support plate is made by close contact with the split coater fitted in the cotter groove of the crushing shaft to be fixed so as not to be pushed backwards. As the tightening force is applied to the tightening plate, a strong tightening force is applied, so that the flow between the bearing, the spacer, and the cutter can not be generated.

Another method of the present invention for achieving the desired purpose is to screw the flow prevention cap formed on the tightening ring frame to one side of the crushing shaft, the coupling member is fitted to the outer side of the tightening ring frame, the separation prevention cap As the tightening member tightens the tightening frame in order to fix the flow preventing cap without flow as it is tightened with the fastening member, any flow is generated between the bearing, spacer, and cutter by the firm fixing force of the flow preventing cap. There will be no.

1 is an exploded perspective view of an embodiment of the present invention

Figure 2 is a longitudinal cross-sectional view of the installation state of the subject innovation

Figure 3 is a side cross-sectional view of the installation state of the inventive split coater

Figure 4 is an exploded perspective view of another embodiment of the present invention

Figure 5 is a longitudinal cross-sectional view of the installation state of another embodiment of the present invention

Figure 6 is a side cross-sectional view of the coupling state and the flow preventing cap of the present invention another embodiment

7 is a plan view of a crusher to which the present invention is applied

[Explanation of symbols on the main parts of the drawings]

1: crusher 3: crushing shaft 4: cutter

6: bearing 10: pushing member 20: transmission member

30: tightening plate 40: support plate 41, 72, 82: bolt hole

50: tightening bolt 60: split coater 70: flow prevention cap

74: tightening ring frame 75: first reducer 80: tightening member

81: second reducer

Referring to the configuration of the preferred embodiment for effectively achieving the object of the present invention is as follows.

First, referring to the schematic configuration of the present invention, as shown in FIG. 7, a plurality of cutters 4 are installed at predetermined intervals on the crushing shaft 3 rotatably supported by both bearings 6, and the cutters (4) In the known crusher (1) provided with a spacer (5) for maintaining a gap therebetween,

Pushing the outermost spacer (5) to the center to prevent the flow of the pushing member 10, the pushing member 20 to transfer the tightening force of the tightening plate 30 to the pushing member 10, and the bearing ( 6) a fastening plate 30 which is installed at the rear and strongly tightens the bearing 6, the spacer 5, and the cutter 4 without flow with a strong fastening force, and is spaced apart from the back of the fastening plate 30 by a predetermined distance. A support plate 40, a tightening bolt 50 that is screwed to the support plate 40 and provides a tightening force to the tightening plate 30 depending on whether the tightening plate, and the crushing shaft (3) while being in close contact with the back of the support plate 40 It is installed in the) consists of a split coater 60 for supporting the support plate 40 so as not to be pushed backward.

It will be described in more detail to enable the present invention made of the schematic configuration.

The pushing member 10 is installed to be inserted to the outside of the crushing shaft 3, and one side is in close contact with the spacer 5 provided on the outermost side to push the spacer 5 to the center to cutter (4) and spacer (5) To prevent the flow of the coupling groove 11 is coupled to the support member (2a) attached to the body side plate (2) on the other side.

The transmission member 20 installed between the pushing member 10 and the bearing 6 serves to transfer the tightening force applied by the tightening plate 30 to the pushing member 10, and the pushing member 10. It is installed to be inserted in the outer side of the crushing shaft (3) in the same way.

The fastening plate 30 for fixing the bearing 6, the spacer 5, and the cutter 4 without flow is installed at the rear of the bearing 6, and a plurality of radially fastening grooves 31 are formed at regular intervals.

The tightening plate 30 pushes the bearing 6 to the center by using the strong tightening force provided by the tightening bolt 50, and the tightening force passes through the bearing 6 to the transfer member 20 and the pushing member 10. By pushing the spacer (5) and the cutter (4) to the center through the () does not even a minute flow occurs.

The tightening bolt 50 that provides the tightening force to the tightening plate 30 is screwed into the bolt hole 41 formed in the support plate 40 is fitted into the tightening groove 31 of the tightening plate 30. Accordingly, as the tightening bolt 50 is tightened, an end of the tightening bolt 50 pushes the tightening plate 30 toward the center to generate a tightening force, and at the rear side of the support plate 40, the tightening bolt 50 is artificially operated. Without the lock, the lock nut 51 is prevented from loosening naturally.

Meanwhile, in order for the tightening force by the tightening bolt 50 to be smoothly provided to the tightening plate 30, the supporting plate 40 on which the tightening bolt 50 is installed should not be pushed backward.

To this end, a split coater 60 is fitted into the coater groove 61 formed in the crushing shaft 3, and the split coater 60 is closely attached to the rear of the support plate 40 to support the tightening bolt 50 despite the manipulation of the tightening bolt 50. 40 is no longer pushed back by the split coater 60.

At this time, the split coater 60 is preferably formed to be divided into a plurality of pieces because it is difficult to install in the coater groove 61 when formed integrally of the cylindrical.

The present invention made of such a configuration is to provide a tightening force to the tightening plate 30 selectively depending on whether the tightening bolt 50 in the state in which the support plate 40 is supported by the split coater 60 and the tightening plate 30 ) Pushes bearings 6, spacers 5 and cutters 4 in sequence using a strong tightening force so that there is no gap between them at all times so that no flow occurs and the tightening force is lowered without artificial action. The tightening part is not loosened.

On the other hand, Figures 4 to 5 relates to another embodiment of the present invention, by this method it is possible to effectively achieve the object of the present invention.

Another embodiment of the present invention is applicable to the case where the screw portion (3a) is formed in the crushing shaft (3) is coupled to the screw portion (3a) flow preventing cap 70 to prevent the flow of the bearing (6) And, coupled to the tightening ring frame 74 of the flow preventing cap 70 is composed of a tightening member 80 to selectively tighten the tightening ring frame 74.

The flow preventing cap 70 is screwed to the threaded portion (3a) formed on the crushing shaft (3) and a plurality of bolt holes 72 are formed radially in the flange portion 71 on one side and the flange portion 71 In close contact with the bearing 6, the bearing 6 is pushed to the center to prevent the flow.

On the other side of the flange portion 71, the tightening ring frame 74 is formed integrally with the flange portion 71 is formed in the cutting groove 73 at equal intervals and the outer diameter of the tightening ring frame 74 to the outer circumference gradually The first reducer 75 which becomes small is formed.

On the other hand, the fastening member 80 is fitted on the outer side of the tightening ring 74, the second reducer 81 is formed in close contact with the first reducer 75 is formed a plurality of bolt holes 82 radially By being formed at regular intervals, the tightening ring frame 74 is selectively tightened depending on whether the tightening bolt 50 is screwed to the bolt holes 72 and 82.

That is, when the tightening bolt 50 is tightened, as shown in FIG. 5, the second reducer 81 formed to be inclined while transferring the tightening member 80 to the center presses the first reducer 75 of the tightening ring 74. The tightening ring 74 tightens the threaded portion 3a with a strong tightening force while the diameter thereof is reduced by the incision groove 73, so that the flow preventing cap 70 does not generate any flow so that the bearing 6 can be fixed without flow. Will be.

The present invention can be applied to the electronic fixing device (A) as shown in Figs. 1 to 2 when the screw portion (3a) is not formed on the shredding shaft (3), the screw portion (3a) When formed, the latter fixing device B as shown in FIGS. 4 to 5 may be applied to fix the bearing 6, the spacer 5, and the cutter 4 in a state of being always in close contact.

The present invention applies a strong tightening force to a plurality of cutters and spacers installed on the crushing shaft of the crusher and bearings that support both ends of the crushing shaft to maintain strong adhesion to each other, so that no loosening occurs due to no flow in the tightening region even during long-term use. There will be no.

Therefore, it is possible to prevent damage to the crushing shaft due to loosening of the tightening part, and smooth crushing work is performed.

Claims (3)

A crusher having a plurality of cutters 4 installed at regular intervals on the crushing shaft 3 on which both sides are rotatably supported by the bearings 6, and a spacer 5 for maintaining a space between the cutters 4 therebetween. In (1), Pushing member 10 for extrapolating to the crushing shaft 3 and pushing the spacer 5 in close contact with one side to the center to prevent flow; A transmission member 20 installed between the pushing member 10 and the bearing 6 to transfer the tightening force of the tightening plate 30 to the pushing member 10; The bearing 6 is installed in the rear and a plurality of radially fastening grooves 31 are formed at regular intervals, and the bearing 6, the spacer 5, and the cutter 4 flow with a strong tightening force by the fastening bolt 50. Fastening plate 30 to be in close contact with, A support plate 40 having a plurality of bolt holes 41 installed at a predetermined distance from the back of the tightening plate 30 and radially tightening the bolts 50 to which the tightening bolts 50 are screwed; Tightening bolt 50 is screwed into the bolt hole 41 of the support plate 40 and the end is fitted into the tightening groove 31 to selectively provide the tightening force to the tightening plate 30 depending on whether the tightening plate (30), Cutter and bearing of the crusher shaft, characterized in that made of a split coater 60 in close contact with the back of the support plate 40 and fitted into the coater groove 61 formed on the crushing shaft 3 to support the support plate 40 so as not to be pushed backward. Fixture. The method according to claim 1, Tightening bolt 50 is a cutter and bearing fixing device of the crusher shaft, characterized in that the lock nut (51) is screwed to prevent natural loosening. The method according to claim 1, One side of the crushing shaft (3) is the flow preventing cap 70 is screwed and the flow preventing cap 70 is radially in close contact with the flange portion 71 formed with a plurality of bolt holes 72 at regular intervals ( 6) to the center to prevent the flow and tightening ring frame 74 is formed integrally in the flange portion 71 formed in the cutting groove 73 at equal intervals and the outer circumference of the tightening ring frame 74 to the outside The first reducer 75 which becomes smaller is formed, A fastening member 80 is fitted to the outer side of the tightening ring 74, but the fastening member 80 is formed with a second reducer 81 in close contact with the first reducer 75 and a plurality of bolt holes radially. Cutter and bearing of the shredder shaft 82 is formed at regular intervals and selectively tightens the tightening ring frame 74 depending on whether the tightening bolt 50 is screwed to the bolt holes (72) (82) Fixture.