KR20140031087A - Crush module for juice - Google Patents

Abstract

The present invention relates to a crushing module for a juicer and, more specifically, to a crushing module for a juicer which prevents a deformation and a shaking of a mesh that separates juice and residues by covering a space where materials are crushed or pressed by a screw. The present invention is characterized by a composition that comprises: a container having residue and juice outlets, a mesh formed inside the container, a screw that is located inside the container and extracts juice from materials, an inlet which is joined to an upper part of the container and where materials are inputted, a cover having a processing guide unit that guides the materials to be crushed formed on a lower part that communicates with the inlet, and a processing unit which is formed on an upper side of the screw to correspond with the processing guide unit and in which a processing blade, which crushes the materials while pushing the materials to the inside of the processing guide unit, is formed. A load on the mesh generated according to conditions of the screw and the materials is reduced as the materials are transformed to be soft simultaneously with being crushed by the processing unit formed on the upper side of the screw and the processing guide unit via the interaction of the processing unit and the processing guide unit before juice is extracted by the screw. Therefore, the present invention obtains effects capable of preventing noise and damage to the mesh by preventing the deformation and the shaking of the mesh simultaneously with preventing a problem of foreign substances being added by preventing an abrasion of the screw and the mesh.

Description

Crushing Module for Juice Liquid {CRUSH MODULE FOR JUICE}

The present invention relates to a fracturing module for a stock solution, and more particularly, to a fracturing module for a stock solution that suppresses deformation and shaking of a mesh that separates juice and dregs by enclosing a space where materials are broken or compressed by screws.

Typically, the stock solution includes a body and a juice module mounted on the body. The juice module includes a container having a juice space, a lid having an inlet for feeding material into the container, a screw for juice of the material in the container, and a mesh separating juice and debris.

The body includes a drive motor for rotating the screw, the shaft of the drive motor is connected to the screw in the juice module. Conventional stock solutions require the material to be cut to a size at which the screw can be juiced.

As an example, Korean Patent Registration No. 10-0793852 discloses a stock solution technology configured to cut or cut material by a screw blade protruding from the central axis of the screw to the top side.

However, this technique is a material that is cut or cut material is crushed and pressed in the space of the mesh, the material is hardened by crushing and juice in the process of pressing or moving to the lower portion by the screw by the screw And the larger the frequency of deformation or shaking of the network is the situation.

Such deformation or shaking of the meshes causes the durability of the meshes to deteriorate from the deformation, or the hollowing of the meshes is deformed, so that no homogeneous juice is obtained. There is a problem with noise.

In addition, Korean Patent Registration No. 10-0966607 discloses a stock solution technology for crushing a material immediately before juice by installing a steel sheet on the entire upper surface of the screw.

However, the crushing using steel sheet has a problem that it must be made by a high speed rather than the inherent low speed of the stock solution, and the inconvenience that the user has to press the material on the steel sheet with a large force to suppress the material from being rotated by the high speed of the steel sheet. have.

Accordingly, the present invention solves the problem of preventing deformation and shaking of the net body generated during crushing and crushing of the screw by crushing hard or large material before crushing to slightly soften and at the same time reducing the size of the material. Let's do the task.

The present invention is formed with a container formed with a discharge outlet and juice discharge port and a mesh located inside the container and a screw located in the mesh to juice the material) and an inlet through which the material is injected, The lower part communicating with the inlet includes a lid having a processing guide for guiding and crushing the material, and a processing portion having a processing blade for crushing while pushing the material into the processing guide, corresponding to the processing guide at the top of the screw. It is to solve the problem.

According to the present invention, through the interaction between the processing portion and the processing guide portion formed on the upper portion of the screw, the material is crushed and smoothly deformed before being squeezed by the screw, and thus, by the state of the screw and the material. As the load of the generated net is reduced, deformation or shaking of the net is suppressed, thereby preventing breakage and noise of the net and at the same time suppressing wear of the screw and the net, thereby preventing the problem of adding foreign substances.

1 is a perspective view showing a fracturing module for a stock solution according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing a fracturing module for a stock solution according to an embodiment of the present invention.
3 is a plan view showing the lid of the shredding module shown in FIG.
4 is a cross-sectional view of the lid taken along AA of FIG. 3.
5 is a cross-sectional view of the lid taken along BB of FIG. 3.
Figure 6 is a front view showing a screw integrally provided with a processing unit at the top as part of the shredding module shown in FIG.
7 illustrates another embodiment of the present invention.
8 is a partial longitudinal cross-sectional view taken along line a-a 'and b-b' of FIG.
9 is a partial longitudinal cross-sectional view of c-c 'and d-d' of FIG.
10 illustrates another embodiment according to the present invention.
11 shows yet another embodiment according to the present invention.

The present invention relates to a fracturing module for the stock solution to suppress the deformation and shaking of the mesh surrounding the space in which the material is crushed or compressed to separate the juice and debris by a screw, largely as shown in the accompanying drawings The container 100, the juice discharge port 101 is formed and the net body 200 is located inside the container 100, the screw 300 is located in the net body 200 to juice the material, the container 100 The inlet 410 is coupled to the top and the input material is formed, the lower portion communicating with the inlet 410 is formed with a processing guide 600 for guiding and crushing the lid 400 and the screw 300 Corresponding to the processing guide 600 at the top of the), and comprises a processing unit 500 is formed with a processing blade 510 for crushing while pushing the material into the processing guide 600.

1 is a perspective view showing a fracturing module for a stock solution according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a fracturing module for a stock solution according to an embodiment of the present invention, Figure 3 is a plan view showing the lid of the shredding module shown in FIG. 1 from top to bottom, FIG. 4 is a sectional view of the lid taken along AA of FIG. 3, FIG. 5 is a sectional view of the lid taken along BB of FIG. 3, FIG. 6 is a front view illustrating a screw integrally provided with a processing unit at an upper end as a part of the shredding module shown in FIG. 1, FIG. 7 is a view showing another embodiment of the present invention, and FIG. 8 is of FIG. 7. 9 is a partial longitudinal cross-sectional view of a-a 'and b-b', and FIG. 9 is a partial longitudinal cross-sectional view of c-c 'and d-d' of FIG. 7, and FIG. 10 shows another embodiment according to the present invention. 11 is a view showing another embodiment according to the present invention.

First, an embodiment of the present invention will be described with reference to FIGS. 1 to 6.

The crushing module for the juicer comprises a juice space therein and a container 100 formed with a juice outlet 101 and a residue outlet 102 on one side and the other side of the outer surface, and installed inside the container 100 when juiced. The net body 200 for separating the juice from the generated material residues, the screw 300 is installed inside the net body 200 to juice the material, the inlet 410 is installed on the top of the container 100, the material is injected The lid 400 is formed.

Although not shown, the shredding module may be an opening and closing means for selectively opening and closing the juice outlet 101 of the container 100, a cock valve may be used as the opening and closing means, the cock valve is the juice It is preferable to include a valve body for advancing or retracting the discharge port 101, the tip of the valve body being oriented toward the juice discharge port 101.

In addition, the coke valve may include a juice discharge tap that may be selectively connected to the juice discharge port 101 by a valve body, and various ones may be employed.

The processing unit 500 is formed in the form of narrowing toward the top at the top of the screw 300, the surface is formed with a processing edge 510 extending in the form of spiral while having a width gradually narrowed toward the upper It is configured.

The processing unit 500 is configured to process the side of the material, it is configured to interact with the processing guide 600 to be described below to crush the material.

Meanwhile, a central axis 310 of the screw 300 is formed at the upper end of the processing unit 500, and the central axis 310 merely suppresses shaking of the screw 300 and the processing unit 500. In the present invention, one or more auxiliary processing blades (not shown) may be further formed to help the processing blade 510 to more effectively crush the material.

The lid 400 is formed with an inlet 410 into which the material is injected, and communicates with the inlet 410, and is formed to be concave upward from the surface coupled with the container 100 to accommodate the processing unit 500. The guide part 600 is included in the lower surface, and the processing guide part 600 has a shape that is gradually narrowed toward the top apex to correspond to the processing part 500.

The processing guide 600 is inserted into the processing blade 510 of the processing unit 500 to be described below, the material injected through the inlet 410 in cooperation with the processing unit 500 is shredded.

And at the top apex of the processing guide 600 may be formed a shaft hole in which the central axis 310 of the screw 300 is rotatably fitted.

On the other hand, the inner surface of the processing guide 600, in particular, the inner side is gradually from the lower end of the inlet 410 and the processing edge 510 of the processing unit 500 in the direction that the processing blade 510 proceeds. The first processing guide surface 610 formed to be adjacent is configured so that when the material is pushed out by the processing blade 510, the material is blocked by the inner surface of the processing guide 600, and the processing blade 510 is The material is configured to be gradually rolled into the inside of the processing guide 600 while digging into the side of the material, and at the same time, the material is shredded.

That is, by interacting with the cutting edge 510 of the processing unit 500 of the first processing guide surface 610, by forcibly moving the material to the processing blade 510, even if the user does not push the material is automatically crushed processing It is configured to be built.

In addition, as the material is rolled into the processing guide 600, a force for pressing the screw 300 downward is generated, and the upper part of the screw generated by infiltrating the residue between the bottom surface of the screw and the bottom surface of the container. There is also an effect that can suppress movement.

In addition, one or more shredding blades 640 are further formed on the first processing guide surface 610 to further improve the shredding processability, and the shredding blades 640 are spaced apart from each other at the top of the first processing guide surface 610. It may be desirable to form the process blade 510 closer to the processing edge 510 as it extends from the upper side to the lower side.

And one of the inner surface of the processing guide 600 includes an inlet 410 and the material guide surface 620 is formed to be inclined toward the lower side of the center of the processing unit 500, such a configuration is the inlet ( The material introduced into the 410 is moved toward the processing unit 500 by the inclination of the material guide surface 620, so that the side surface of the material is naturally formed by the processing blade 510 of the processing unit 500. ) And the processing edge 510 to perform the function of assisting to occur.

On the other hand, the material guide surface 620 does not extend with the inlet 410, it may be simply formed at the lower end of the inlet to implement the present invention.

According to the present exemplary embodiment configured as described above, the material injected through the inlet 410 formed in the lid 400 is crushed by the interaction between the processing unit 500 and the processing guide unit 600, and then crushed. After being deformed somewhat softly like the pieces and the chopped state, it is moved to the existing screw 300 and configured to be juiced, and the injected material is moved to the processing unit 400 by the material guide surface 620 and thus moved. The side surface of the material is moved by the machining blade 510 along the first machining guide surface 610 into the machining guide 600, but the space between the machining blade 510 and the first machining guide surface 610 gradually decreases. As it narrows, the material is sandwiched between the first machining guide surface 610 and the machining edge 510.

At this time, while rotating the cutting edge 510 is to dig the side of the material while pushing the side of the material into the processing guide 600, to crush a part of the side of the material, the material thus pushed to the first processing guide surface 610 By pressing toward the center of the processing unit 500, the processing blade 510, which comes back again, penetrates the side of the material, and the above-described operation is repeated, so that the crushing processing is performed. Interaction proceeds.

The manipulation of the shredded material is to move naturally to the screw 300 to be juiced.

As described above, according to the present invention, the material is crushed by the interaction between the processing unit 500 and the processing guide 600, and at the same time it is deformed smoothly, the net body 200 generated by the screw 300 and the material state. The load of the bar is reduced, so that deformation or shaking of the mesh 200 is suppressed, so that breakage and noise of the mesh 200 are suppressed, and the wear of the screw 300 and the mesh 200 is also suppressed to prevent the problem of adding foreign substances. It can work.

On the other hand, in the present invention according to the embodiment as described above, the user does not touch the material having a diameter larger than the radius of the upper portion of the screw 300, which determines the size of the material that can be used in the conventional stock solution. At the same time, smooth juice can be made without cutting, and the lower end of the inlet 410 is one side with respect to the center axis of the screw 300 so that it can be carried out without expanding the radius of the existing screw 300 to cut the material. Formed to be biased, but having a large bottom width (W; or inner diameter) that can be sufficiently injected into a large size of material, the height of the processing unit 500 also has a height to accommodate the input material It is formed to the same or similar size as the bottom width (W) of 410.

This configuration requires that the screw 300 of the existing stock solution has to expand the top radius (or diameter) of the screw 300 in order to use a material larger than the material with the cuttable diameter to increase the area required to install the product. There is a marked difference in that.

That is, while the conventional stock solution has to expand the size of the entire stock solution in order to use a large material, the present invention can be implemented only by expanding only the height of the high portion 500, which is low in manufacturing cost, The installation area of the is not effective to expand.

Hereinafter, another embodiment of the present invention will be described with reference to FIGS. 7 to 9.

7 to 9, unlike the first processing guide surface 610 for pressing the side surface of the material, the processing guide 600, so that the upper portion of the material to be moved to the lower material, the lid 400 The lower space of the circular groove is formed, but protruded inclined spirally from the bottom area of the inlet 410 around the central axis of the processing unit 500 on the lower surface, the same as the rotation direction of the processing unit 500 It is configured to include a second processing guide surface 630 is formed.

The second processing guide surface 630 is formed in the shape of a flat plate, unlike the processing unit 500 having a narrow upper portion and a wide lower portion, and at least one cutting edge 510 is formed on the upper surface to crush the lower portion of the material. In conjunction with the other processing unit 500, when the material is located on the processing unit 500, and interacts with the processing unit 500, such as the first processing guide surface 610, the second processing guide surface ( 630 has the difference of pressing the top of the material.

Such a configuration may be used instead of the first processing guide surface 610 as shown in the drawing, and the present invention may be used in combination with or selectively combined with the first processing guide surface 610 and the material guide surface 620 as shown in FIG. 10. It can be implemented easily.

In addition, the processing guide 600 forms a pressing hole 420 on the side of the lid 400 of the lower region of the inlet 410 in place of the material guide surface 620, and is inserted into the pressing hole 420 to insert the material. It is configured to include a pressing rod 430 that can be pushed into the processing unit 500.

The pressing bar 430 of this configuration is configured to partially sequential crushing by pressing the material injected into the inlet 410 into the processing unit 500, the configuration of the pressing bar 430 and the pressing hole 420 is The present invention can be easily implemented even when used in combination with the first processing guide surface 610 and the second processing guide surface 630 or in combination.

100: container 200: mesh
300: screw 400: lid
420: pressing hole 430: push bar
500: processing part 600: processing guide part
610: first processing guide surface 620: material guide surface
630: second processing guide surface

Claims (12)

A container 100 in which the dregs outlet 102 and the juice outlet 101 are formed;
A net body 200 located inside the container 100;
A screw 300 located inside the mesh 200 to juice the material;
An inlet 410 is formed at the upper end of the container 100 and the material is inserted therein, and a lid 400 in which a processing guide 600 is formed at the lower portion communicating with the inlet 410 to guide and break the material. ) And;
Corresponding to the processing guide 600 on the top of the screw 300, characterized in that it comprises a processing unit 500 is formed with a processing blade 510 for crushing while pushing the material into the processing guide 600 Shredding shredding module for the stock solution.
The method according to claim 1,
The processing guide 600 is formed to be adjacent to the side of the processing unit 500 in the direction in which the processing unit 550 from the inlet 410, the side of the material pushed by the processing unit 500 The shredding crushing module for a liquid crystal, characterized in that it comprises a first processing guide surface 610 to be pressed by the crushing.
The method according to claim 1,
The processing guide 600 protrudes downward from a position corresponding to the processing part 500, and the second processing guide surface is formed to be inclined spirally about the central axis of the processing part 500 so that the upper part of the material is pressed and crushed. The crushing shredding module for a stock solution comprising a 630.
The method according to claim 1,
The processing guide 600 is formed in the lower end of the inlet 410 is formed to be inclined toward the central axis of the processing unit 500 is characterized in that it comprises a material guide surface 620 to move the material in contact with the processing blade 510 Shredding shredding module for the stock solution.
The method according to claim 1,
The processing guide 600 is formed to be adjacent to the side of the processing unit 500 in the direction in which the processing unit 550 from the inlet 410, the side of the material pushed by the processing unit 500 The protrusion is formed on the lower surface of the first processing guide surface 610 and the processing unit 500 and the lid 400 corresponding to the compression and fracture, and the upper portion of the material is pressed in the direction in which the processing unit 550 rotates. The crushing crushing module for a stock solution, characterized in that it comprises a second processing guide surface 630 is formed to form a spiral inclined around the center axis of the processing unit 500.
The method according to claim 1,
The processing guide 600 is formed to be adjacent to the side of the processing unit 500 in the direction in which the processing unit 550 from the inlet 410, the side of the material pushed by the processing unit 500 The material guide surface 620 is formed to be inclined toward the central axis of the processing unit 500 at the lower end of the first processing guide surface 610 and the inlet 410 to be pressed and crushed to move the material in contact with the processing blade 510. The shredding shredding module for a stock solution comprising a.
The method according to claim 1,
The processing guide 600 is projected downward in a position corresponding to the processing unit 500, the second processing guide surface formed to be inclined in a spiral with respect to the central axis of the processing unit 500 so that the upper portion of the material is pressed and crushed 630 and the lower end of the inlet 410 is formed to be inclined toward the central axis of the processing unit 500 is crushed for the stock solution characterized in that it comprises a material guide surface 620 for moving the material in contact with the processing blade 510 Shred Module.
The method according to claim 1,
The processing guide 600 is formed to be adjacent to the side of the processing unit 500 in the direction in which the processing unit 550 from the inlet 410, the side of the material pushed by the processing unit 500 The first processing guide surface 610 and the processing guide part 600 to be pressed and crushed protrude downwardly at a position corresponding to the processing part 500, and the processing part 500 to press and crush the upper part of the material. The second processing guide surface 630 formed to be inclined in a spiral around the central axis of the center and the lower end of the inlet 410 is formed to be inclined toward the central axis of the processing unit 500 to move the material in contact with the processing blade 510 The fracturing shredding module for a stock solution comprising a guide surface (620).
The method according to claim 1, 2, 4 or 5,
Processing unit 500 has a narrow upper portion and the lower portion is wide, one side of the crushing crushing module for a liquid crystal, characterized in that at least one processing blade 510 is formed to crush the side of the material.
The method according to any one of claims 1, 3 and 6 to 8,
Processing unit 500 is formed of a plate material, the upper surface of the crushing crushing module for a stock solution, characterized in that one or more processing blades (510) formed to crush the lower surface of the material is formed.
The method according to claim 2 or 3,
The first processing guide surface 610 and the second guide surface 630 is at least one shredding blade crushing module, characterized in that at least one shredding blade 640 is formed.
5. The method of claim 4,
Stock solution, characterized in that instead of the material guide surface 620, the pressing hole 430 is formed through the pressing hole 420 and the pressing hole 420 formed in the side of the lid 400 at the lower end of the inlet 410 Crushing Crushing Module

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