KR200470384Y1 - A clamshell pulverizer - Google Patents

Abstract

An object of the present invention described above is formed with a hopper having a hopper inlet into which a shell line is attached, a lower housing having a plurality of discharge holes is formed thereon, and an upper portion detachably coupled to the lower housing. A grinding housing in which a housing is formed; A spiral blade having a predetermined pitch is formed in a cylinder having an axis that is rotated inside the grinding housing, and is formed at regular intervals along the spiral blade, and a plurality of cutters are formed such that both ends thereof are connected to one spiral blade and the other spiral blade. A pulverizing transfer part in which wing grooves are formed at regular intervals on the outer circumferential side of the spiral wing proximate to the cutter, and cutter cutters are formed in the cutter proximate the wing grooves; A shell mill including a discharge chute installed on the outlet side of the housing and a motor for rotating the grinding conveying unit, the grinding housing being spaced apart from the floor and supported, but inclined in the longitudinal direction, the hopper inlet is inclined downward Located in, can be achieved through the shell mill, characterized in that the inclined support is further installed so that the discharge chute is located in the upper direction of the inclination.

Description

Shell Crusher {A clamshell pulverizer}

The present invention relates to a shell crusher, and more specifically, by providing an inclined structure of the pulverizing housing and the pulverizing conveying unit, even when a large amount of shells are put at a time, since the feed is sequentially made from the lower part of the crushing housing, the motor is overloaded. Is not generated, and the shells that are not crushed by the structure of deep and wide wing grooves have a long time for the large particles to stay below the slope by the law of gravity through the wing grooves. By gradually passing upward through the narrow gap of the blade and the fixed cutter of the housing, the rapid transfer is limited to a shell mill that is crushed into smaller particles in the process.

In general, a shell mill is a device for harvesting shells of fish and shellfish and grinding them to recycle the remaining shells, that is, shells such as oysters, shellfish, and clams. Conventional shell shredders are separated by crushing the shell and the droop, but the work efficiency has decreased due to the separation of the droop and the droop, and in order to improve the work efficiency, the shell has been put together at one time without separating the shell and the droop. Crushing shell mills have been introduced.

Such a shell mill has a spiral blade and a plurality of ribs formed between the blades to push out the foreign matter laminated to the shell outlet through the spiral blade.

However, in the above-described structure, it was not possible to prevent the phenomenon of twisting or agglomeration of the string, and there was a problem such that the shell or the foreign matter could not be pulverized finely and laminated to the shell outlet.

In order to solve the problems of the prior art, the technology for the shredding transfer unit of the shell mill is disclosed through Republic of Korea Registration Room No. 20-0380605.

However, the conventional shell grinder is a horizontal grinder, and since the hopper for the shell input is high, a separate transport device must be provided, and the shell and the droop are rapidly discharged so that the string and the shell are not separated and discharged smoothly. As a result, as the mixture is discharged by mixing with each other, there is a problem in that pulverized particles below an appropriate value cannot be obtained.

The object of the present invention devised to solve the problems of the prior art is to provide the inclined structure of the pulverizing housing and the pulverizing transfer portion, so that even if a large amount of shells are put in at one time, the feed is made from the lower part of the crushing housing in order. The shells, which are not overloaded by the motor and cannot be crushed by the deep and wide wing grooves, have a longer time for large particles to stay below the slope by the law of gravity through the wing grooves. It is only to be passed through the narrow gap between the spiral blade and the fixed cutter of the housing to be gradually conveyed upwards, the rapid transfer is limited to provide a shell mill that is crushed into smaller particles in the process.

Another object of the present invention includes a spiral blade having a constant pitch in the cylinder, and a cutter formed at regular intervals along the spiral blade, the cutter is a wing groove on the outer circumferential side of the spiral wing in close proximity to the cutter and close to the wing groove Cutter groove is formed in the present invention, which can prevent twisting or agglomeration of the string, and also provides a shell crusher that can smoothly transport the pulverized string and simultaneously crush the shell and the string. .

Another object of the present invention is to provide a shell mill that can minimize the power used during grinding by increasing the grinding efficiency of the shell.

Another object of the present invention is possible to work by the rapid rotation of the grinding conveying unit, thereby increasing the amount of grinding, to obtain fine particles and particles of appropriately sized, and to cleanly discharge the coating yarn Since it can be collected is easy to recycle PVC coating company, and provides a shell mill that the collection rate of waste is increased.

An object of the present invention described above is formed with a hopper having a hopper inlet into which a shell line is attached, a lower housing having a plurality of discharge holes is formed thereon, and an upper portion detachably coupled to the lower housing. A grinding housing in which a housing is formed; A spiral blade having a predetermined pitch is formed in a cylinder having an axis that is rotated inside the grinding housing, and is formed at regular intervals along the spiral blade, and a plurality of cutters are formed such that both ends thereof are connected to one spiral blade and the other spiral blade. A pulverizing transfer part in which wing grooves are formed at regular intervals on the outer circumferential side of the spiral wing proximate to the cutter, and cutter cutters are formed in the cutter proximate to the wing grooves; A shell mill including a discharge chute installed on the outlet side of the housing and a motor for rotating the grinding conveying unit,

The crushing housing is spaced apart from the bottom to support, but inclined in the longitudinal direction, the hopper inlet is located in the lower inclined direction, the shell crusher, characterized in that the inclined support is further installed so that the discharge chute is located in the upper inclined direction Can be achieved.

Here, the depth of the wing groove can be formed to extend to the point where the cylindrical surface meets.

At this time, the cutter formed between the pitch of the spiral blades may be arranged on a straight line in the longitudinal direction.

The present invention according to the above configuration provides the inclined structure of the pulverizing housing and the pulverizing conveying part, so that even when a large amount of shells are put at a time, since the feed is sequentially performed from the lower part of the crushing housing, the motor is not overloaded. Shells that cannot be crushed by the structure of deep and wide wing grooves have a longer time for large particles to stay below the slope due to the law of gravity through the wing grooves. By passing slowly through the narrow gap of the cutter to the top, the rapid transfer is limited to have the effect of being crushed into smaller particles in the process.

In addition, the present invention includes a spiral blade having a constant pitch in the cylinder, and a cutter formed at regular intervals along the spiral blade, the wing groove on the outer peripheral side of the spiral wing in close proximity to the cutter and the cutter close to the wing groove By forming the cutter groove, it is possible to prevent the phenomenon of twisting or agglomeration of the rope, and also to effectively crush the shell and the rope, and at the same time have the effect of smoothly conveying the pulverized rope.

In addition, the above structure has an effect of minimizing the power used during grinding by increasing the grinding efficiency of the shell.

In addition, the shell mill according to the present invention is possible to work by the rapid rotation of the grinding conveying unit, thereby increasing the amount of pulverization, has the effect of obtaining fine particles and particles of a suitable size.

In addition, it is possible to cleanly discharge and collect the coated twisted yarn (drop line), it is easy to recycle the PVC coated yarn, and has an effect of increasing the collection rate of waste.

1 is a schematic configuration diagram of a shell mill according to the present invention.
Figure 2 is a perspective view of the crush feed unit of the shell mill according to the present invention.
3 is a view showing a state in which the cutter of the grinding conveying unit of FIG. 2 is inclined with respect to the spiral blade;

Hereinafter, described in detail with reference to the accompanying drawings for a preferred embodiment of the present invention.

1 is a schematic configuration diagram of a shell mill according to the present invention, Figure 2 is a perspective view of the grinding conveying unit of the shell mill according to the present invention, Figure 3 is a state in which the cutter of the grinding conveyer of Figure 2 is formed to be inclined with respect to the spiral blade Figure is shown.

1 to 3, the grinding conveyance unit 10 according to the present invention, the spiral blades 13, 13 ′ and spiral blades 13 formed at a constant pitch in a cylinder 12 having a shaft 11. A plurality of cutters 14 formed at regular intervals along the ends 13 ', the ends of which are connected to one spiral blade 13 and the other spiral blade 13'.

Here, the spiral blades 13 and 13 'are formed in the entire cylinder 12, as shown in Figs. 1 and 2, but the spiral blades 13 and 13 are formed at the lower end where the hopper 21b is located. Not forming ') may be more effective at breaking shells.

On the outer circumferential side of the spiral blade 13 proximate to the cutter 14, wing grooves 13a are formed at regular intervals. At this time, the cutter 14 and the other cutter 14 'with respect to the spiral blade 13 may be formed in a straight line in the longitudinal direction.

In addition, a cutter groove 14a having a chamfer groove may be formed in the cutter 14 adjacent to the wing groove 13a.

In addition, a separate high-strength cutter blade may be formed at the end of the cutter 14 to more effectively crush the shell to be transported.

Here, the cutter 14 is formed at a predetermined angle (45 °) with respect to the normal of the cylinder 12. At this time, the inclination angle is preferably 30 ° to 70 °.

The inclination angle of the cutter 14 shown in FIG. 3 is shown to be around 45 °, but is not limited thereto, and may be formed parallel to the normal, and may be formed higher, lower, or the same as the spiral wings 13, 13 ′. It may be.

Referring to Figure 1, the shell mill according to the present invention, the hopper inlet 21a is formed in the upper portion of the inlet side is located between the bearings 25, 26 installed on both sides and the plurality of discharge holes 22a downward The formed grinding housing 20 and the grinding conveyance unit 10, which is rotated inside the grinding housing 20 and supported by the bearings 25 and 26, both shafts 11 of the cylinder 12 and , A discharge chute 30 installed at the exit side of the grinding housing 20, and a motor (not shown) for rotating the grinding conveying unit 10, wherein the rotating shaft of the motor is organically connected through the chain gear 41. Connected.

In addition, the pulverizing housing 20 is a hopper 21b having a hopper inlet 21a into which a bag with a shell is inserted, a lower housing 22 having a discharge hole 22a, and a lower housing 22. It may be composed of an upper housing 21 detachably coupled to.

When the upper housing 21 and the lower housing 22 are coupled to each other, the upper housing 21 and the lower housing 22 form a cylindrical shape as a whole.

The grinding housing 20 is sealed at both ends thereof with flanges 23 and 24 mounted therein. At this time, the flange 24 on the outlet side is provided with a hole 24a through which a hanger line is discharged, and the hole 24a. Is in communication with the discharge chute (30).

The discharge chute 30 is a place where the remaining drooping line is discharged after the shell is crushed, and the drooping line is discharged through the hole of the flange 24.

Referring to Figure 1, the shell mill of the present invention is supported by the inclined support 50, the grinding housing 20 and the grinding conveying unit 10 is installed in a state inclined in the longitudinal direction.

At this time, the hopper 21b is located at the lower slope, and the discharge chute 30 is located at the upper slope.

Referring to the operation of the shell mill according to the present invention described above are as follows.

First, when the power is applied to the motor and driven, the power is transmitted to the grinding conveyance unit 10 through the chain gear 41 organically connected to the rotating shaft of the motor so that the grinding conveyance unit 10 rotates.

In this state, when the bag with the shell is inserted into the hopper 21b, the shell is transferred into the crushing housing 20 by the spiral blades 12, and at the same time, the shell 14 and 14 'and the spiral are transferred. The shells are crushed by the organic action of the wings 13 and 13 '.

That is, the spiral blades 13 and 13 ′ play a role of pushing up the shell injected into the hopper 21 b toward the discharge chute 30, and the cutters 14 and 14 ′ have a physical impact on the shell. It acts to break up.

The shell and the hanger string crushed through this process are effectively transferred to the discharge chute 30 through the cutter groove 14a formed in the cutter 14 and the wing groove 13a of the helical blade 13.

At this time, the cutters 14 and 14 'formed between the pitches of the spiral blades 14 are arranged in a straight line along the longitudinal direction.

At this time, through the cutter groove (14a) of the cutter 14 and the wing groove (13a) of the helical blade (13) is transported through the discharge chute 30 is discharged through the chute.

As shown in FIG. 1, the shell mill of the present invention is supported by the inclined support 50, and the grinding housing 20 and the grinding conveyance unit 10 are installed in a state inclined in the longitudinal direction.

At this time, the hopper 21b is installed in the lower slope, the discharge chute 30 is installed in the upper slope.

According to the inclined structure as described above, since the position of the hopper 21b is low, there is an advantage that it can be easily added without the need for a separate feeding device for shell injection, even when a large amount is put in a pulverization at a time Since the inclined structure of the housing 20 is supplied sequentially from the bottom, the motor has an advantage that the overload does not occur.

In such an inclined structure, the law of gravity increases the time for large particles to stay below the slope, and after the small particles are crushed, they are gradually transported upward through the narrow gap of the wing groove 13a, thereby limiting the rapid transfer. In this process, the particles are pulverized into smaller particles, and the pulverized particles are smoothly discharged through the discharge holes 22a of the lower housing 22.

At this time, the coating yarn that is not crushed by the cutters 14 and 14 ′, that is, the hanger string and the like, is attracted to the wing groove 13a and the cutter groove 14a and the chute and agglomeration of the string is prevented while the discharge chute 30 Are transported and discharged).

The present invention also includes a spiral blade 13 having a predetermined pitch in the cylinder 12, and cutters 14 and 14 'formed at regular intervals along the spiral blade 13, and the cutter 14 ( The blade groove 13a is formed on the outer circumferential side of the spiral blade 13 proximate to 14 ') and the cutter groove 14a is formed in the cutter proximate the wing groove 13a. It is possible to prevent, and also to crush the shell and the rope more effectively and at the same time smoothly transport the crushed rope.

And, by increasing the grinding efficiency of the shell by the above structure, it is possible to minimize the power used during grinding.

10: grinding feed unit 11: shaft
12: cylinder 13, 13 ': spiral wing
13a: wing groove 14, 14 ': cutter
14a: cutter groove 20: grinding housing
21: Upper housing 21a: Hopper inlet
21b: Hopper 22: Lower housing
22a: outlet holes 23, 24: flange
25, 26: bearing 30: discharge chute
40: recovery container 50: inclined support

Claims (3)

A hopper 21b having a hopper inlet 21a into which a shell is attached is formed, and a lower housing 22 having a plurality of discharge holes 22a is formed at the bottom thereof, and the lower housing 22 is formed. A grinding housing 20 in which an upper housing 21 is detachably coupled to the grinding housing 20; Spiral vanes 13 and 13 'having a predetermined pitch are formed in the cylinder 12 having the shaft 11 rotated inside the grinding housing 20, and along the spiral vanes 13 and 13'. A plurality of cutters 14 are formed at regular intervals so that both ends thereof are connected to one spiral blade 13 and the other spiral blade 13 ', and the spiral blades 13 adjacent to the cutter 14 are formed. The outer circumferential side of the blade groove (13a) is formed at regular intervals, the cutter 14 is close to the blade groove (13a) in the cutter conveying portion 10 is formed with a cutter groove (14a); As a shell mill including a discharge chute 30 installed on the outlet side of the housing 20 and a motor for rotating the grinding conveying unit 10,
The grinding housing 20 is supported by being spaced apart from the floor, and inclined in the longitudinal direction, and the hopper inlet 21a is positioned below the inclined direction, and the inclined support 50 so that the discharge chute 30 is located above the inclined direction. ) Are installed,
Cutter cutter (14) (14 ') formed between the pitch of the spiral blades (13) (13') are arranged in a straight line along the longitudinal direction.
The method of claim 1,
Shell crusher, characterized in that to extend the depth of the wing groove (13a) to the point meeting the surface of the cylinder (12).
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