KR20170114330A - Shell Grinder - Google Patents

Abstract

It is an object of the present invention to provide a shell crusher having a high separation efficiency of coated yarn and a small load due to coating yarn.
According to an aspect of the present invention, there is provided a vacuum cleaner comprising: a base housing having an upper portion and a lower portion, And a housing-side cover (150) which is located on the housing-side cover (130) side and is coupled to the base housing (110); A punching net 300 having a plurality of discharge holes formed at a lower portion of the housing 100; And is disposed between the screw 530 formed at a constant pitch and the screw 530 so as to be rotatable about the rotation axis 510 at both ends in the inner space of the housing 100 and is equal to the height of the screw 530 A rotary drum 500 having a rib 550 formed in the longitudinal direction of the rotary drum 500; And a guide protrusion 131 having a predetermined pitch, which is opposite to the rotating direction of the screw 530, is provided on the inside of the housing top cover 130.

Description

{Shell Grinder}

The present invention relates to a shell crusher for crushing and separating a crushing object comprising a shell and a coated strand.

A shell crusher is a device for crushing shellfish to collect crustaceans and reusing the remaining shells. The shell is fastened by coated strand. The shell is crushed and recycled as fertilizer, which must be separated from the plastic coated yarn. Conventionally, the operator directly grinds the shell and the coated yarn before crushing the object to be ground. In recent years, a shell crusher has been introduced in order to increase the working efficiency of the crusher, in which the crust is crushed and the coated crust is separated separately without separating the shell and the coated strand at the same time.

However, since the coated yarn can not be separated and discharged after being injected and is moored at the entrance or inside of the shell crusher, further twist or bunch occurs due to entanglement with the applied coated yarn, thereby making it more difficult to separate and discharge, and suddenly, There is a problem that a load is generated in the motor of the shell crusher.

 SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a shell crusher having a high separation efficiency of coated yarn and a small load due to coating yarn.

According to an aspect of the present invention, there is provided a vacuum cleaner comprising: a base housing having an upper portion and a lower portion, And a housing-side cover (150) which is located on the housing-side cover (130) side and is coupled to the base housing (110); A punching net 300 having a plurality of discharge holes formed at a lower portion of the housing 100; And is disposed between the screw 530 formed at a constant pitch and the screw 530 so as to be rotatable about the rotation axis 510 at both ends in the inner space of the housing 100 and is equal to the height of the screw 530 A rotary drum 500 having a rib 550 formed in the longitudinal direction of the rotary drum 500; And a guide protrusion 131 having a predetermined pitch, which is opposite to the rotating direction of the screw 530, is provided on the inside of the housing top cover 130.

Here, the height of the rib 550 of the rotary drum 500 may be lower than the height of the screw 530 in a predetermined section on the inlet side where the loading hopper is located. In addition, the predetermined section may have a plurality of stages and have different heights for each section.

The height of the rib 550 of the rotary drum 500 may be equal to or higher than the height of the screw 530 in a predetermined section on the exit side. In addition, the predetermined section may have a plurality of stages and have different heights for each section.

INDUSTRIAL APPLICABILITY The present invention can enhance the separation efficiency of the coated twisted yarn and reduce the load generated in the motor by the coating twisted yarn.

Further, the separation process by the additional human force is unnecessary, and the cost can be reduced.

In addition, the crushing efficiency can be increased by efficiently pulverizing the shell.

1 is a perspective view according to an embodiment of the present invention;
FIG. 2 is a perspective view of the housing of FIG. 1 with the cover removed. FIG.
3 is an exploded view.
4 is a side view.
5 is a perspective view of a rotary drum.
6 is a perspective view for explaining the inner surface of the housing top cover;
7 is an assembled view of the housing cover and the rotary drum.
8 is a side view of the rotary drum.

Hereinafter, a shell crusher according to the present invention will be described in detail with reference to the drawings.

1 and 2, the shell crusher according to the present invention includes a base housing 110 having a bottom support, a housing cover 130 covering an upper portion of the base housing 110, a housing cover 130, A punching net 300 installed on a lower surface of the base housing 110 and a housing 100 formed of a housing side cover 150 coupled to the base housing 110 by a housing 100, And a rotary drum 500 installed in the inner space.

As shown in FIG. 3, the base housing 110 has an upper portion and a lower portion that are opened so as to penetrate. The upper opening of the upper portion is formed with a hopper through which the object to be ground is introduced, . The bottom support may be configured to divide the lower surface of the housing 100 so as not to mix the coated twisted yarn separated and discharged from the crushed and discharged shell. In addition, the inlet side surface of the base housing 110 has a through portion so that the rotary shaft 510 of the rotary drum 500 can be inserted.

The housing top cover 130 is coupled to the base housing 110 in such a manner as to cover a portion of the upper portion of the base housing 110 where the input hopper is not formed.

The housing side cover 150 has a penetrating portion through which the rotary shaft 510 of the rotary drum 500 can be inserted and is disposed on the housing upper cover 130 side while being coupled with the base housing 110.

The punching net 300 is formed in a U-shape in cross section so as to cover a predetermined section of the lower portion of the housing 100. Further, a plurality of discharge holes are formed on the surface to discharge the crushed shell by the holes formed.

The rotating drum 500 is installed in an inner space portion provided in the housing 100, and the lower portion is surrounded by the punching net 300. The rotation shaft 510 of the rotary drum 500 is inserted into the penetration portion of the housing side cover 150 and the penetration portion of the side portion of the base housing 110, respectively. After the rotation shaft 510 is inserted, both ends of the rotary drum 500 are coupled to the housing 100 by the bearing kit 700 to be rotatable. One end of the rotary shaft 510 of the rotary drum 500 is coupled with the power unit to receive the rotational force.

As shown in Fig. 4, the lower surface of the base housing 110 is divided into spaces by a floor support. The divided first space is a space in which the coated yarn is discharged from the object to be crushed into the hopper and the second space is crushed into a space in which the shell is crushed and discharged, .

As shown in FIG. 5, the rotary drum 500 has a cylindrical shape having a predetermined outer diameter around the rotary shaft 510. On the outer circumferential surface of the rotary drum 500, a screw 530 for conveying the object to be crushed from the inlet to the outlet along the axial direction is formed. And ribs 550 are formed between the screws 530 and equal in height to the screw 530 and in the longitudinal direction of the rotary drum 500. The ribs 550 serve to crush the object to be crushed to be conveyed toward the outlet by the screw 530. In this case, the rib 550 may have a predetermined angle with the tangential direction of the cylinder of the rotary drum 500 in order to increase the grinding efficiency. The rib 550 has a section in which a portion of the rotating drum 500 is divided by the separating plate 570 so that the screw 530 and the rib 550 are not formed. The position of the separating plate 570 is formed so that the positions of the spaces divided by the bottom support of the base housing 110 coincide with each other.

6 and 7, the housing cover 130 is provided with a guide protrusion 131 having a predetermined pitch opposite to the rotating direction of the screw 530 of the rotary drum 500 . The guide protrusion 131 defines a space between the rotary drum 500 and the housing cover 130 at a predetermined interval. The space partitioned by the guide protrusions 131 is maintained at a predetermined interval between the grinding object inserted first and the grinding object inserted later during the grinding process to minimize the mutual mixing to prevent the coated grits from being bundled or twisted.

As shown in FIG. 8, the height of the ribs 550 formed in the rotary drum 500 may be varied depending on the section.

The amount of the object to be crushed into the hopper is large so that the object to be crushed at the top of the crushing object is pushed by the gravity due to the gravity to rotate the rotary drum 500 along the screw 530 Although moving in the axial direction of the drum 500 is not troublesome, when the latter stage of the pulverization process is reached, the coated pulp having a relatively low density is not allowed to flow into the pulverizer and is pumped into the feed hopper. At this time, the coated coated strand can not continuously flow into the pulverizer, accumulates in the section A where the loading hopper is located, and the accumulated coated strand flows into the pulverizer all at once, causing a problem of sudden load on the motor. In order to solve this problem, the coated strand located on the upper side of the rotary drum 500 is seated inside the rotating rotary drum 500 and moved to the lower side of the rotary drum 500, The height of the rib 550 is made lower than the height of the screw 530 in the section A where the hopper is located. Accordingly, the coated twist is moved in the direction A toward the exit direction of the crusher along the space provided by the rib 550, which is lower than the height of the screw 530.

In the section B where the hopper is not located, the height of the rib 550 is increased to prevent the relatively heavy shell from proceeding toward the outlet, thereby increasing the crushing efficiency of the shell. At this time, the coated lightweight yarn relatively lighter than the shell is moved toward the exit direction by the guide protrusion 131 provided on the housing cover 130 covering the upper portion of the section B. The heights of the ribs 550 may be different from each other in order to improve the grinding efficiency.

As a result, in the section A, along the space provided by the ribs 550 lower than the height of the screw 530, in the section B, along the guide protrusion 131 provided on the housing cover 130 covering the upper part, .

In addition, the section A may be further divided into sections C so that the height of the ribs 550 may be different. The section C located at the entrance side is made higher than the height of the rib 550 of the section A. The section C is a section preceding the start point of rotation of the screw 530 and can not affect the movement of the coated yarn in the exit direction. Therefore, the grinding efficiency can be improved without affecting the movement of the coated strand.

The concrete operation of the components of the shell crusher will be described below.

When power is applied to the motor, the power is transmitted to the rotary drum 500 through the chain coupling connected to the rotary shaft 510 of the motor to rotate the rotary drum 500. When the object to be ground including the shell and the coated yarn is put into the feed hopper, the object to be ground is transported by the screw 530 into the interior of the shell crusher, and the shell is crushed by the rib 550. At this time, the coated yarn which is to be separated and discharged without being pulverized moves to the outlet portion along the inner space of the rotary drum 500 partitioned by the screw 530 at the inlet portion of the rotary drum 500, The guide protrusion 131 provided at the inner side of the housing cover 130 moves to the outlet portion and is separated and discharged. Therefore, the coated twist yarn is not moored by various structures provided inside the pulverizer, but is sequentially discharged, so that no load is applied to the motor. Also, the height of the ribs 550 is different according to the section, and the crushing efficiency is further increased.

As described above, the shell crusher according to the present invention not only increases the crushing efficiency of the shell without the load caused by the coated yarn, but also increases the separation efficiency of the coated yarn, so that the shell crusher can perform additional processing, And the pulverizing and separating process of the object to be ground including the coated yarn can be completed.

100: Housing
110: Base housing
130: housing phase cover
131: Guide projection
150: housing side cover
300: punching net
500: rotary drum
510:
530: Screw
550: rib
531: Starting point of rotation
570: Separation plate
700: Bearing kit

Claims (5)

A shell crusher for crushing and separating a crushing object comprising a shell and a coated strand,
A base housing 110 having an upper portion and a lower portion and having a hopper for introducing a grinding object into a part of an upper portion thereof, a housing cover 130 covering an upper portion of the base housing 110, And a housing-side cover 150 coupled to the base housing 110;
A punching net 300 having a plurality of discharge holes formed at a lower portion of the housing 100;
And is disposed between the screw 530 formed at a constant pitch and the screw 530 so as to be rotatable about the rotation axis 510 at both ends in the inner space of the housing 100 and is equal to the height of the screw 530 A rotary drum 500 having a rib 550 formed in the longitudinal direction of the rotary drum 500;
And a guide protrusion (131) formed at an inner side of the housing top cover (130) and having a predetermined pitch opposite to the rotating direction of the screw (530).
The method according to claim 1,
Wherein the height of the ribs 550 of the rotary drum 500 is lower than the height of the screw 530 in a predetermined section on the inlet side where the loading hopper is located. The method according to claim 1,
Wherein the height of the ribs (550) of the rotary drum (500) is equal to or higher than the height of the screw (530) in a predetermined section of the outlet side. 3. The method of claim 2,
Wherein the predetermined section is multi-tiered and has different heights for each section. The method of claim 3,
Wherein the predetermined section is multi-tiered and has different heights for each section.

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