KR101316913B1 - Grizzly device for crusher with shock absorber - Google Patents

Abstract

Provided is a grinder device of a crusher having a cushioning function to prevent premature wear of the grizzly bar. The grizzly device of the crusher according to the present invention includes a plurality of grizzly bars and a first buffer part for absorbing the drop impact of the sintered ore applied to the grizzly bar by using the elastic force of the buffer spring. The plurality of grizzly bars are spaced apart from each other, are integrally coupled by a shaft, and form a multistage through hole at one end. The first buffer part includes a plurality of protrusions fitted into the multistage through hole, a buffer spring fitted into each of the plurality of protrusions inside the multistage through hole, and a buffer support for fixing the plurality of protrusions under the grizzly bar.

Description

Grizzly device of crusher with cushioning function {GRIZZLY DEVICE FOR CRUSHER WITH SHOCK ABSORBER}

The present invention relates to a grizzly device installed in a crusher, and more particularly, to a grizzly device having a cushioning function to prevent premature wear of the grizzly bar.

In the sintering process of the steel mill, the combined trolleys are loaded with the upper light and the blended raw material while passing through the lower part of the upper light hopper and the surge hopper. And as the trolley advances to the shredder direction, the blended raw material is sintered from the upper surface to the lower side by the suction air volume of the main blower through the wind box.

At the point when the trolley reaches the crusher, the blended raw material is completely sintered to a solid red state, and the temperature of the sintered ore is approximately 1,500 ° C. The sintered ore falls freely from the trolley to the crusher and is collected while colliding with the grizzly bar of the crusher. The sintered ore collected at the grizzly bar is crushed to an appropriate size by the rotation of the rotor, and the sintered ore is discharged to the cooler through the chute and cooled.

However, as the solid red sintered ore continuously hits the grizzly bar, the surface of the grizzly bar is rapidly worn out. In particular, when the coke particle size defect or the compounding ratio defect occurs in the raw material due to poor operating conditions, the strength of the sintered ore rapidly increases with excessive sintering, thereby promoting wear of the grizzly bar. Therefore, when the repair work due to the deterioration of the grizzly bar, the sintering machine stops, as well as the blast furnace is a problem occurs.

An object of the present invention is to provide a grizzly device of a crusher which can prevent premature wear of the grizzly bar due to the drop impact of the red sintered ore and extend the life of the grizzly bar to improve the sintering machine operation rate.

Grizzly device of the crusher according to an embodiment of the present invention, iii) a plurality of grizzly bar spaced apart from each other, integrally coupled by a shaft, forming a multi-stage through hole at one end, ii) multistage And a first buffer portion having a plurality of protrusions fitted into the through hole, a buffer spring fitted into each of the plurality of protrusions inside the multi-stage through hole, and a buffer support for fixing the plurality of protrusions under the grizzly bar.

The plurality of grizzly bars may be spaced apart along the first direction and may form an axial through hole penetrating the grizzly bar along the first direction at an end portion opposite to the multi-stage through hole. The shaft may be fitted into the shaft through-hole and coupled to the plurality of grizzly bars, and bearing blocks may be installed at both ends of the shaft.

The multi-stage through hole is divided into a lower through hole contacting the lower surface of the grizzly bar and an upper through hole contacting the upper surface of the grizzly bar and having a smaller size than the lower through hole, and a thread may be formed on an inner wall of the upper through hole.

The height of the protrusion is greater than the height of the multi-stage through hole, and a thread is formed on the upper outer circumferential surface of the protrusion so that the protrusion is screwed with the upper through hole and coupled to the nut outside the upper surface of the grizzly bar. The plurality of shock absorbing springs may be mounted on the shock absorbing support, and may be fitted to the outside of the protrusion in the lower through hole.

The grizzly device of the crusher may further include: a) a second shock absorber having a plurality of elastic bodies coupled to the lower end of the shock absorber to secondarily absorb a drop shock applied to the grizzly bar and the first shock absorber. Each of the plurality of elastic bodies may form a coupling protrusion, and a plurality of recesses may be formed at a lower end of the buffer support to accommodate the coupling protrusion.

The grizzly device according to the present embodiment having the first buffer part and the second buffer part prevents premature wear of the grizzly bar by mitigating most drop impacts of the sintered ore applied to the grizzly bar, and extends the life of the grizzly bar to increase the operation rate of the sintering machine. It can increase.

1 is a perspective view showing a grizzly device of a crusher according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of the grizzly device shown in FIG. 1.
3 is a cross-sectional view of the grizzly device shown in FIG. 1.
FIG. 4 is a partially enlarged view of the grizzly device shown in FIG. 3.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

1 is a perspective view showing a grizzly device of a crusher according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the grizzly device shown in FIG. 3 is a cross-sectional view of the grizzly device shown in FIG. 1, and FIG. 4 is a partially enlarged view of the grizzly device shown in FIG. 3.

1 to 4, the grizzly device 100 is located under the crusher 200 that sinters the sintered ore and functions to sort out the sintered ore. The grizzly device 100 is installed at an upper portion of the chute 300 for discharging the sintered ore crushed to a cooler (not shown). The crusher 200 may be configured of a plurality of rotors 202 coupled to the rotation shaft 201.

The grizzly device 100 according to the present exemplary embodiment uses a plurality of grizzly bars 11 and a plurality of buffer springs 21 to first absorb shocks of falling sintered ore applied to the grizzly bars 11. The part 20 and the 2nd buffer part 30 which absorbs the fall shock of the sintered ore applied to the grizzly bar 11 using the some elastic body 31 secondaryly are included.

The plurality of grizzly bars 11 are spaced apart from each other along the first direction (x-axis direction in the drawing), and the wings of the rotor 202 are positioned to correspond to the space between the grizzly bars 11.

The plurality of grizzly bars 11 are integrally coupled by the shaft 12. To this end, an axial through hole 13 penetrating the grizzly bar 11 along the first direction is formed at one end of each grizzly bar 11, for example, at the right end based on the drawing. The shaft 12 is fitted into the shaft through hole 13 and coupled to the plurality of grizzly bars 11. Bearing blocks 14 are provided at both ends of the shaft 12, and the pair of bearing blocks 14 are fixed to the chute 300.

The first buffer unit 20 is directly coupled to the plurality of grizzly bars 11 and primarily absorbs the drop impact of the sintered ore applied to the grizzly bar 11 by using the elastic force of the buffer spring 21.

Multi-stage through hole 15 at the opposite end of each grizzly bar 11, ie, at the end of the grizzly bar 11 away from the shaft 12 (left end relative to the drawing), for engagement with the first buffer part 20. ) Is formed. The multi-stage through hole 15 penetrates the grizzly bar 11 along the height direction of the grizzly bar 11 (the z-axis direction of the drawing and the direction perpendicular to the ground).

The multi-stage through hole 15 has a lower through hole 151 (see FIG. 4) in contact with the lower surface of the grizzly bar 11 and a diameter smaller than the lower through hole 151 in contact with the upper surface of the grizzly bar 11. The upper through hole 152 is formed (see FIG. 4). At this time, a thread is formed on the inner wall of the upper through hole 152.

The first shock absorbing portion 20 is disposed along the first direction in the lower portion of the grizzly bar 11 and the plurality of protrusions 22 fitted into the multi-stage through hole 15 and integrally fixes the plurality of protrusions 22. The buffer support 23, the plurality of shock absorbing springs 21 fitted into the outside of each protrusion 22 inside the lower through hole 151, and the protrusion 22 at the upper surface of the grizzly bar 11. It includes a plurality of nuts 24 to be engaged.

The height of each protrusion 22 is greater than the height of the multistage through hole 15, and a part of the protrusion 22 fitted into the grizzly bar 11 protrudes above the upper through hole 152. Threads are formed on the upper outer circumferential surface of the protrusion part 22. Therefore, the protrusion 22 is screwed to the upper through hole 152, and is coupled to the nut 24 outside the upper surface of the grizzly bar 11 is firmly coupled to the grizzly bar (11).

The buffer support 23 is formed to have a larger width than the protrusion 22 to support the plurality of buffer springs 21. That is, the plurality of shock absorbing springs 21 are fitted to the outside of the protrusion 22 on the shock absorbing support 23, and are located in the lower through hole 151 of the grizzly bar 11. The buffer support 23 is fixed to the chute 300.

One end of the grizzly bar 11 is rotatable about the shaft 12 by the shaft 12 and the pair of bearing blocks 14, and the opposite end of the grizzly bar 11 is a buffer spring ( 21). Therefore, when the sintered red glowing sintered free fall into the grizzly device 100, the plurality of grizzly bars 11 vibrate up and down by the elasticity of the buffer spring 21 about the axis 12.

In the conventional configuration in which the grizzly bar 11 is simply fixedly mounted on the chute 300, there is no device to absorb the drop shock applied to the grizzly bar 11, so that the early wear of the grizzly bar 11 occurs easily. However, in the present embodiment, as the shock absorbing spring 21 absorbs the drop impact of the sintered ore applied to the grizzly bar 11, there is an effect of preventing premature wear of the grizzly bar 11.

The second shock absorbing portion 30 is coupled to the first shock absorbing portion 20 and further reduces the impact of the sintered ore applied to the grizzly bar 11 and the first shock absorbing portion 20 by using the elastic force of the elastic body 31. Absorb.

The second buffer part 30 is composed of a plurality of elastic bodies 31 positioned below the buffer support 23. The elastic bodies 31 may be provided in pairs and positioned one by one at both ends of the buffer support 23 in the first direction. The elastic body 31 is made of a conventional elastic member such as rubber, and is fixedly mounted on the chute 300.

The elastic body 31 forms a coupling protrusion 32 at an upper end thereof so as to be coupled to the buffer support 23, and a recess 33 is formed at the lower end of the buffer support 23 to accommodate the coupling protrusion 32. Can be. A thread is formed on the outer circumferential surface of the coupling protrusion 32 and the side wall of the recess 33 so that the coupling protrusion 32 may be screwed to the recess 33. The coupling structure of the elastic body 31 and the buffer support 23 is not limited to the illustrated example, various coupling methods may be applied.

Although the shock absorbing spring 21 of the first shock absorbing portion 20 primarily absorbs the drop impact applied to the grizzly bar 11, the free-falling sintered ore has a weight as large as about 6 tons, so that the first shock absorbing portion 20 There is also considerable drop impact on itself. Therefore, the plurality of elastic bodies 31 absorb the drop shocks applied to the grizzly bar 11 and the first shock absorbing portion 20 secondly, thereby effectively reducing the impact applied to the grizzly bar 11.

Thus, the grizzly device 100 of this embodiment provided with the 1st buffer part 20 and the 2nd buffer part 30 alleviates the drop shock of the sintered ore applied to the grizzly bar 11, and the grizzly bar 11 is carried out. Preventing premature wear and extending the life of the grizzly bar 11 can increase the operating rate of the sintering machine.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

100: grizzly device 200: shredder
300: Suit part 11: Grizzly bar
12: shaft 13: shaft through hole
14: bearing block 20: first buffer portion
21: buffer spring 22: protrusion
23: buffer support 24: nut
30: 2nd buffer part 31: elastic body
32: engaging projection 33: recessed portion

Claims (8)

A grizzly device for screening crushed sintered ore located in the lower part of the crusher to sinter the sintered ore,
A plurality of grizzly bars spaced apart from each other along a first direction, integrally coupled by an axis, and configured to form a multistage through hole at one end thereof; And
A first protrusion having a plurality of protrusions fitted into the multistage through hole, a buffer spring fitted into each of the plurality of protrusions inside the multistage through hole, and a buffer support for fixing the plurality of protrusions under the grizzly bar. Buffer
Including;
And each of the plurality of grizzly bars forms an axial through hole penetrating the grizzly bar along the first direction at an opposite end portion away from the multistage through hole. delete The method of claim 1,
And the shaft is coupled to the shaft through-hole and coupled to the plurality of grizzly bars, and a bearing block is installed at both ends of the shaft. A grizzly device for screening crushed sintered ore located in the lower part of the crusher to sinter the sintered ore,
A plurality of grizzly bars spaced apart from each other, integrally coupled by a shaft, and configured to form a multistage through hole at one end thereof;
A first protrusion having a plurality of protrusions fitted into the multistage through hole, a buffer spring fitted into each of the plurality of protrusions inside the multistage through hole, and a buffer support for fixing the plurality of protrusions under the grizzly bar. Buffer unit; And
A second shock absorbing part having a plurality of elastic bodies coupled to a lower end of the shock absorbing support to secondarily absorb a drop shock applied to the grizzly bar and the first shock absorbing part;
Grizzly device of the crusher comprising a. 5. The method of claim 4,
And each of the plurality of elastic bodies forms a coupling protrusion, and a lower end of the buffer support is provided with a plurality of recesses for receiving the coupling protrusion. The method according to any one of claims 1 and 3 to 5,
The multi-stage through hole is divided into a lower through hole contacting the lower surface of the grizzly bar and an upper through hole contacting the upper surface of the grizzly bar and having a smaller size than the lower through hole, and a thread is formed on an inner wall of the upper through hole. Grizzly device of the crusher being. The method according to claim 6,
The height of the protrusion is greater than the height of the multi-stage through hole, the screw thread is formed on the upper outer peripheral surface of the protrusion so that the protrusion screwed to the upper through hole, the grizzly device of the crusher coupled to the nut outside the upper surface of the grizzly bar . The method according to claim 6,
The plurality of shock absorbing spring is mounted on the buffer support, the grizzly device of the crusher fitted into the outside of the protrusion in the lower through hole.

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