RU2448633C1 - Module of juice squeezer and juice squeezer with vertical screw - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: invention relates to a juice squeezer module. The juice squeezer module comprises a juice squeezer container with an open top; the lid which is provided with a loading chute for raw materials in the wall of the lid, and is connected with the upper section of the juice squeezer container; a mesh drum rigidly located inside the juice squeezer container; and a screw located inside the mesh drum, at that the screw is equipped with a spiral portion formed on the lateral surface of the screw, and a rotating shaft which passes through the hole for the shaft of the juice squeezer container. The juice squeezer container comprises a lower inclined surface descending out from the hole for the shaft, and at the lower end of the screw there is a lower inclined surface which is at least partially formed in contact with the said lower inclined surface. The guide rotating section is formed on the upper end of the screw, and the lid is provided with a rotary guide for the direction of rotation of the screw.

EFFECT: invention facilitates cleaning the juice squeezer and the lid, and reliably prevents leakage of liquid out of the container of the juice squeezer, improves effectiveness of juice squeezing.

21 cl, 12 dwg

Description

Technical field

The present invention relates to a juicer module, and in particular to a juicer module, in which a screw connected to the drive shaft of a drive device is used to crush or chop vegetables, fruits, nuts, cereals, etc., thereby producing juices, vegetable juices or other juice products.

State of the art

A juicer is a device for processing vegetables, fruits, etc., to produce liquid or juice products. Various types of juicers have been known that can be conveniently used for domestic and industrial applications. In the most versatile juicers, a scheme was chosen in which the raw material was thrown into the loading chute for the raw material and then crushed by using a high-speed rotating blade. However, this type of juicer had a limitation in grinding hard raw materials such as green vegetables, consisting of stems and leaves, to produce vegetable juices.

Therefore, the juicer has traditionally been improved for crushing vegetables and fruits between a rotating screw and a mesh drum, thereby obtaining juices and extracts (e.g., vegetable juices). In such a juicer, a screw and a mesh drum are arranged inside the open top juicer container, and a lid on which a loading chute for raw materials is formed is connected to the top portion of the juicer container. The shaft socket is formed in the lower portion of the cover, and the shaft, which is rotatably inserted into the shaft socket, is mounted on the upper end of the screw. The feed chute for raw materials is made in a small size in the lid, without overlapping with the shaft socket. The juicer container is mounted on the main body into which the drive unit is integrated, and the screw is connected to a drive shaft of the drive unit located outside the juicer module so that the screw can rotate.

In a traditional juicer, only protruding spiral sections formed on the side surface of the screw are involved in raw material processing schemes, such as squeezing juice and / or grinding together with a juicer or grinding mesh drum. Accordingly, in order for the raw material to be thrown into the feed chute for raw materials to reach the helical sections formed on the side surface of the screw, a sufficient portion of the upper end of the screw has been removed.

In addition, in a traditional juicer, water or moisture can seep where the drive shaft of the main body and the rotary shaft of the screw are connected to each other. A substantially cylindrical protrusion for water tightness is formed around a central lower portion of the juicer container, which is connected to the drive shaft, and a seal is mounted on the upper portion of the cylindrical protrusion. Additionally, a cylindrical recess is formed around a rotating shaft located in the lower portion of the screw, so that the cylindrical protrusion is inserted into the cylindrical recess.

However, the traditional juicer has the disadvantage that it is difficult to clean the surrounding portion of the cylindrical protrusion in the central lower portion of the juicer container and the inside of the cylindrical recess in the lower portion of the screw. Since the juicer is a food processing device requiring exceptional purity, this drawback is very significant. In addition, in order to assemble the screw and the juicer container with each other, the protrusion in the central lower portion of the juicer container must be smoothly inserted into the recess in the lower portion of the screw. Therefore, the size of the cylindrical recess is larger than the size of the cylindrical protrusion. Here, since the rotating shaft of the auger must be supported by a soft seal mounted on the upper portion of the protrusion, the auger is maintained in a state in which it oscillates laterally when mounted on the bottom of the juicer container. Although oscillations of the screw can be prevented by inserting the shaft formed in the upper portion of the screw into the shaft socket formed in the lid according to the most common scheme in the food industry, there is another disadvantage in that the shaft socket formed in the lid may be broken when the unstable assembled condition of the screw. In addition, it is very inconvenient to clean the shaft nest formed in the lid, and this is considered a drawback in a food processing apparatus requiring cleaning.

Disclosure of invention

Technical problem

Accordingly, the present invention addresses the aforementioned problems of the prior art. An object of the present invention is to provide a juicer module in which a cylindrical protrusion and a cylindrical recess in a traditional juicer, which are otherwise located on the inner lower part of the juicer container and in the lower portion of the screw, respectively, can be removed, thereby facilitating the cleaning of the juicer, still resting the auger on the inner bottom of the juicer container, and reliably preventing moisture from leaking out in the juicer container.

Another object of the present invention is to provide a juicer module in which the shaft, which is otherwise located on the upper end of the screw, as well as the shaft socket, which is otherwise located in the cover and into which the shaft is inserted, can be omitted, thereby further facilitating cleaning covers.

An additional objective of the present invention is the provision of a juicer with a vertical screw containing a locking structure, which can prevent vertical movement of the screw, which will cause deterioration in the efficiency of squeezing juice.

Technical solution

According to an aspect of the present invention, to achieve these objectives, there is provided a juicer module comprising: an open top juicer container, with a shaft hole formed in a lower central portion of the juicer container; a cover with a loading chute for raw materials in its wall, the cover being connected to the upper portion of the container of the juicer; a mesh drum fixedly located inside the container of the juicer; and a screw located inside the mesh drum, the screw having a spiral portion formed on its side surface and a rotating shaft passing through the shaft opening of the juicer container, the juice extractor container including a lower inclined surface that extends outward from the shaft hole.

According to one embodiment, a lower inclined surface in contact with said lower inclined surface is at least partially formed at the lower end of the screw.

According to another embodiment, the gasket into which the rotating shaft is inserted is installed in a central portion of the lower inclined surface, and the gasket includes an inclined surface extending from the lower inclined surface.

According to another embodiment, the first insertion protrusion is formed below on one side of the lower end of the mesh drum and at least one second insertion protrusion is formed below on the other side of the lower end of the mesh drum, wherein an insertion hole into which the first insertion protrusion is inserted is formed on one side of the lower inclined surface, and at least one insertion chute into which the second insertion protrusion is inserted is formed on the other side of the lower inclined surface the surface.

According to another embodiment, a guide pivot portion is formed at an upper end of the screw, and the lid is provided with a pivot guide for guiding rotation of the screw, the pivot guide being in contact with an edge of the guide pivot portion. Alternatively, a shaft is formed in the upper central portion of the screw, a shaft seat into which the shaft is inserted is formed in the lower side of the cover, and a reinforcing layer is formed in the shaft socket.

According to another embodiment, a blade structure for cutting a raw material thrown into a loading chute for a raw material or for pushing the raw material down is formed at the upper end of the screw.

According to another aspect of the present invention, there is provided a juicer module comprising: an open top juicer container with a shaft hole formed in a lower central portion of a juicer container; a cover with a loading chute for raw materials in its wall, the cover being connected to the upper portion of the container of the juicer; a mesh drum fixedly located inside the container of the juicer; and a screw located inside the mesh drum, the screw having a spiral portion formed on its side surface and a rotating shaft extending through an opening for the shaft of the container of the juicer, the guide rotary portion being formed at the upper end of the screw, and the lid provided with a rotary guide for guiding rotation of the screw, and the rotary guide is in contact with the edge of the guide of the rotary section. Here, it is preferable that the guide pivot portion is ring-shaped to lower the raw material thrown into the feed chute for the raw material.

According to another aspect of the present invention, there is provided a juicer with a vertical screw, comprising: a main body having a drive shaft protruding upward; open top container mounted on the main body; a screw located inside the container, and the screw has a rotating shaft, vertically mounted on the drive shaft; a mesh drum located inside the container to cover the periphery of the screw; a lid connected to the upper portion of the main body, the lid having a feed chute for raw materials; and a locking structure to prevent vertical movement of the screw, to prevent the screw from rising when the drive shaft and the rotating shaft rotate together.

According to one embodiment, the rotary shaft includes a shaft receptacle into which the upper portion of the drive shaft is inserted, and the locking structure includes a locking protrusion formed on the driving shaft and a locking hole formed on the rotating shaft so that the locking protrusion is inserted into a fixing hole when the drive shaft is inserted into the shaft seat. The locking hole includes a lower cavity that is open downward to allow the locking protrusion to enter and exit; a guide portion for providing horizontal movement of the locking protrusion when the drive shaft begins to rotate; and a locking portion to prevent vertical movement of the locking protrusion. The locking hole has a pair of locking sections formed respectively on the right and left sides of the guide section to prevent vertical movement of the rotating shaft with respect to the bi-directional rotation of the drive shaft. The locking protrusion has a circular cross section, and the locking section is made in the form of an arc of a circle corresponding to a circular cross section. The locking hole further has inclined surfaces in the lower portion of the locking hole so as to slide the locking lug into the locking hole. Inclined surfaces are made in the form of an arc that is connected to both sides of the lower cavity. The rotary shaft includes a shaft receptacle into which the upper portion of the drive shaft is inserted, and the locking structure includes a pair of locking projections formed respectively on both diametrically opposite sides of the drive shaft; and a pair of locking holes formed in the rotating shaft, so that the pair of locking tabs is respectively inserted into the locking holes when the drive shaft is inserted into the shaft housing.

According to another embodiment, the lid has a support formed on its lower surface to dampen the vibration of the upper portion of the screw.

According to a further embodiment, the locking protrusion is formed from a pin end inserted laterally and mounted in the drive shaft. Each of the locking holes has an inclined surface for sliding the corresponding locking protrusion into the locking hole, and the inclined surface is made in the form of an arc that is connected to the corresponding locking protrusion.

Preferred Effects

According to the present invention thus made, the following advantages can be expected.

The juicer module according to one embodiment of the present invention adopts a lower structure of the juicer container having a downward inclined surface that gradually descends from the central region of the lower surface of the juicer container through which the rotary shaft of the screw extends to the outer part of the lower surface of the juicer container, so that water does not leak from The juicer container through the main body could be prevented. As such, a cylindrical protrusion to ensure watertightness, which otherwise is formed on the lower portion of the container of a traditional juicer or juicer module, can be omitted, thereby further facilitating cleaning of the lower portion of the container of the juicer. Additionally, in the juicer module according to another embodiment of the present invention, an inclined surface that corresponds to the lower inclined surface of the juicer container is formed on the lower portion of the screw, thereby, resting the screw motionlessly on the lower part of the juicer container. Also additionally, in the juicer module according to another embodiment of the present invention, the guide pivot portion and the pivot guide are formed on the upper end of the screw and the lower portion of the lid, respectively, so that the shaft socket, which would otherwise be formed in the lid of the traditional juicer, could be omitted, thereby allowing cleaning of the lid in a more hygienic and convenient manner.

The scope of the present invention is not limited to the embodiment described and shown above, but is defined by the appended claims. It is understood that those skilled in the art can make various modifications and changes to it within the scope of the invention defined by the claims. Therefore, the actual scope of the present invention should be determined by the technical nature of the attached claims.

Brief Description of the Drawings

The above and other objects, features and advantages of the present invention will be apparent from the following description of a preferred embodiment given in conjunction with the accompanying drawings, in which:

1 is a sectional view showing a juicer module according to an embodiment of the present invention.

FIG. 2 is an exploded sectional view showing the juicer module shown in FIG. 1 with a pusher separated from the juicer module.

FIG. 3 is a perspective view showing a screw of the juicer module shown in FIGS. 1 and 2.

4 is a view showing an example configuration for rotating the brush when the screw rotates in the juicer module according to an embodiment of the present invention.

5 is a sectional view showing a juicer module according to another embodiment of the present invention.

6 is a longitudinal sectional view showing a vertical screw juicer according to a further embodiment of the present invention.

FIGS. 7 (a) and 7 (b) are views showing a locking structure between the rotary shaft of the screw and the drive shaft of the engine in the vertical screw juicer shown in FIG. 6.

Fig. 8 is a view showing a modification of the fixing structure shown in Fig. 7.

Fig.9 is a view showing another modification of the locking structure shown in Fig.7.

10 is a longitudinal view showing a vertical screw juicer according to another embodiment of the present invention;

11 is a view showing another locking structure according to a further embodiment of the present invention.

The best embodiment of the invention

Below in this document, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described herein are provided by way of example only in order to fully convey the spirit and scope of the present invention to those skilled in the art. Accordingly, the present invention is not limited to the embodiments described below, but may be implemented in various forms. The width, length and thickness of the components can be presented on an enlarged scale for convenience in all drawings. Throughout the description, like elements are denoted by like reference numerals.

FIG. 1 is a sectional view showing a juicer module according to an embodiment of the present invention; FIG. figure 2 is an exploded sectional view showing a juicer module from which the pusher is separated; FIG. 3 is a perspective view showing a screw of the juicer module shown in FIG. 1; and FIG. 4 is a view showing an example of a configuration applied to the juicer module shown in FIG. 1, in which the brush rotates when the screw rotates.

As shown in FIG. 1, the juicer module 1 according to an embodiment of the present invention includes a juicer container 10, a lid 20, an auger 30 and a mesh drum 40. Additionally, the juicer module 1 includes a brush 50 and a pusher 70. The juicer module 1 is used in a juicer for the manufacture of fruit juice, vegetable juice, cereal juice, nut juice or other typical ground products, and the juicer module 1 can be vertically mounted on a main body (not shown) in which the drive bottom device. Since any conventional main body can be used as the main body of the juicer according to the present invention, a specific description and image of the main body will be omitted in the description and drawings of the present invention.

The drive device is provided with a drive shaft that protrudes vertically from the main body so that the drive shaft is removably connected to a rotating shaft 32 located at the lower end of the screw 30. The drive shaft has a generally trapezoidal profile. In this case, the rotary shaft 32 of the screw 30 may be provided with a trapezoidal shaft socket into which the trapezoidal drive shaft is inserted.

The juice extractor container 10 has an open top, and the lid 20 is connected to an upper portion of the juice extractor container 10. In order for the lid 20 to be removably connected to the upper portion of the juicer container 10, the juicer container 10 and the lid 20 are provided with connecting ribs 11 and 21, respectively, which correspond to each other so that the connecting ribs 11 and 21 can be connected to each other due to rotation of the cover 20 in one direction, at the same time they could be disconnected from each other due to the rotation of the cover 20 in the opposite direction.

As described in detail below, the auger 30 and the mesh drum 40, which is substantially adjacent to the outer part of the auger 30, are located inside the juicer container 10, so that the auger 30 and the mesh drum 40 can crush the raw material between them and produce juice or extract from the raw material. The mesh drum for squeezing juice is mainly used as the mesh drum 40, but a grinding mesh drum for grinding other cereals or nuts can be additionally used.

The brush 50 is removably mounted on the outer circumference of the mesh drum 40 and is located between the mesh drum 40 and the inner wall surface of the juicer container 10, so that the brush 50 can rotate itself, mainly to remove raw materials or residual materials adhered to the inner surface of the container wall 10 juicers. The type of mesh drums may vary depending on the raw materials that need to be processed. In this case, one type of mesh drum may be replaced by another type of mesh drum.

The screw 30 is substantially cylindrical in shape, and screw portions 31 that face the mesh drum 40 to crush and guide the raw material are formed on the outer periphery of the screw 30. A wall surface blade to facilitate cutting or grinding of the raw material may be further formed on the mesh drum 40 .

A rotating shaft 32, which passes through the central portion of the lower inclined surface 101 of the juicer container 10, is mounted on the lower central portion of the screw 30. The screw 30 is removably connected to a drive shaft located on the upper portion of the main body on which the juicer module 1 is mounted. As described above, the drive shaft is a shaft that is rotationally driven and extends from the drive device in a main body having a motor. The drive device may be configured to rotate the rotating shaft at low speeds or, alternatively, rotate the rotating shaft at medium speeds or high speeds.

Here, it is preferable that the rotary shaft 32 has a trapezoidal shaft socket, and it is preferable that the drive shaft has a trapezoidal shape to fit into the trapezoidal shaft socket.

The lower inclined surface 101 of the container 10 of the juicer is gradually lowered outward from the rotating shaft 32 located in its central part. This shape of the lower inclined surface 101 allows water and moisture in the lower part of the juicer container 10 to be directed to the lower outer region of the juicer container 10, and not to the lower central region of the juicer container 10, which is required to prevent water from leaking around the rotating shaft 32, i.e. through the hole for the shaft in the lower central part of the container 10 of the juicer.

The lower inclined surface 33, which gradually rises from its outer part to its central part, to correspond to the lower inclined surface 101 of the juicer container 10, is formed on the lower portion of the screw 30. The lower inclined surface 33 of the screw 30 is facing the lower inclined surface 101 of the juicer container 10, and the central part of the lower inclined surface 101 is located above. Additionally, the gasket 102 is installed in the central part of the lower inclined surface 101, and the rotary shaft 32 of the screw 30 is inserted into the gasket 102. The inclined surface 102a extending from the lower inclined surface 101 is formed on the upper part of the gasket 102. The inclined surface 102a of the gasket 102 is in close contact with lower inclined surface 33 of the screw 30, so that the leakage of water through the hole for the shaft could be more reliably prevented.

Additionally, the guide pivot section 34 is formed at the upper end of the screw 30. Preferably, the guide pivot section 34 has a flat horizontal upper surface (see FIG. 3). The guide pivot section 34 is movably facing the pivot guide 22 formed on the lower portion of the cover 20. Thus, the pivot guide 22 faces both the upper and lateral surfaces of the guide pivot section 34.

As is well shown in FIG. 3, the guide pivot portion 34 has a ring shape. This is because such a configuration may cause the lowering of the raw material thrown into the feed chute 24 for the raw material of the cover 20. At least one reinforcing rib 37 is connected between the guide rotary section 34 and the housing of the screw 30. Such a reinforcing rib 37 serves to strengthen the guide rotary section 34, in order to prevent separation of the guide rotary section 34 from the screw housing 30. Despite the fact that the guide rotary section 34 and the screw housing 30 are integrally molded according to According to the present embodiment, the guide pivot portion 34 and the screw housing 30 can be made separately and then assembled, for example, according to a connection diagram. In addition, while the guide pivot section 34 causes the lowering of the raw materials, the guide pivot section 34 may have any other shape or configuration other than the ring-shaped configuration.

Due to the pivoting guide 22 of the lid 20 and the pivoting guide portion 34 of the screw 30, a shaft that is otherwise located on the upper end of the screw in a traditional juicer module, or a shaft socket that would otherwise be located in the lid may be omitted.

Returning to FIGS. 1 and 2, the feed chute 24 for raw materials is stretched vertically at the upper end of the lid 20. A portion of the upper end of the screw 30 is made with a blade structure 39 (see FIG. 3) for cutting raw material discharged into the feed chute for raw materials, or pushing raw materials down. In order for the raw material to be thrown into the feed chute for raw materials to be cut using such a blade structure 39, the feed chute 24 for the feed is deflected away from the central part of the lid 20.

In this case, the pusher 70 is used to compress and push the raw materials, namely, such raw materials as fiber-rich fruits or vegetables, into the feed chute 24 for raw materials. If the pusher 70 compresses the feed in the feed feed chute 24, the feed is pushed down to the lower end of the feed feed chute 24 so that the feed can be cut by the blade structure 39 (see FIG. 3) at the upper end of the screw 30 and / or pushed or lowered into the container 10 of the juicer.

2, the feed chute 24 for raw materials has an inner rib 244 formed on the lower inner surface of its wall, and a guide protrusion 242 extending from the upper inner surface of its wall to the inner rib 244. Additionally, the pusher 70 has a side surface in which there is an elongated guide groove 72 corresponding to the guide protrusion 242, and a rib groove 74 corresponding to the inner rib 244. The guide groove 72 and the rib groove 74 are shown in dashed lines. The inner rib 244 can also serve to cut the raw material together with the rib groove 74 of the pusher 70. The shapes of the loading chute 24 for the raw material and the pusher 70, as shown in FIG. 2, are examples described to illustrate the present invention, and therefore, the present invention is not limited to them. As such, the guide groove 72 and the costal groove 74 of the pusher 70 and / or the inner rib 244 and the guide protrusion 242 of the feed feed chute 24 may be omitted.

The mesh drum 40 is kept stationary inside the container 10 of the juicer. If the screw 30 located inside the mesh drum 40 rotates, the mesh drum 40, which faces the screw portions 31 of the screw 30, crushes the raw material thrown into it to produce juices or extracts. Here, if a plurality of elongated edges, that is, a plurality of elongated blades of a wall surface, can be formed on the mesh drum 40 in an upright position, crushing, cutting and squeezing the juice from the raw materials can be improved. The juicer container 10 has a first outlet 14 and a second outlet 12, wherein juices and extracts obtained from the raw materials are discharged through the first outlet 14 from the juicer container 10, while residual raw materials are discharged through the second outlet 12.

In order to fasten the mesh drum 40 to the juicer container 10 without hesitation, the first and second insertion protrusions 43 and 44 directed downward are formed on one and the other side of the lower end of the mesh drum 40, respectively, while the insertion hole 18 and an insertion chute 19 into which the first and second insertion protrusions 43 and 44 are respectively inserted are formed in the bottom of the juicer container 10. The insertion groove 19 may consist of one or more insertion grooves, and the second exposed protrusion 44 may also consist of one or more second insertion protrusions, depending on the number of insertion grooves.

Here, the first insertion protrusion 43 and the insertion hole 18 may form a channel that extends to the first outlet 14 of the juicer container 10, as shown in FIG.

In this case, the brush 50 serves to continuously remove raw materials or residues of raw materials adhered to the inner surface of the wall of the container 10 of the juicer. The brush 50 has a rotatable brush frame 52, which is substantially cylindrical in shape, and a scraper 54 that is mounted on the brush frame 52. The scraper 54 is made of a flexible material, namely, a flexible plastic or rubber material, and is in close contact with the inner surface of the wall of the container 10 of the juicer. As the brush 50 rotates, the scraper 54 can continuously remove the raw materials or residual materials adhered to the inner wall surface of the juicer container 10.

Many schemes can be selected to rotate the brush 50. According to the present embodiment, the chain of gears, as shown in FIG. 4, causes the brush 50 to rotate accordingly when the screw 30 rotates. As shown in FIG. 4, a round intermediate gear 95 is disposed between a drive gear 35 formed at the lower end of the screw 30 and a driven gear 525 formed at the lower end of the brush frame 52, and such an intermediate gear 95 is engaged with the driving gear 35 and with the driven gear 525. Essentially, if the screw 30 (see FIG. 1) rotates, the joint operation of the gears 35, 95 and 525 causes the brush 50 to rotate (see FIG. 1).

5 is a sectional view showing a juicer module according to another embodiment of the present invention. The juice extractor module 1 according to the present embodiment includes one shaft 301 located in the upper central part of the screw 30, and a shaft socket 201 is formed in the lower central part of the lid 20 located on the upper end of the juice extractor container 10 so that the shaft 301 is inserted into the shaft seat 201 to support rotary auger 30. Here, in order to prevent damage to the shaft socket 201 due to any possible transverse vibrations of the screw 30, a reinforcing layer 210 is formed in the shaft socket 201 by using an insertion scheme or a coating scheme. Since the insertion of the shaft 301 into the shaft seat 201 causes the upper end of the screw 30 to rotate, the pivoting guide at the bottom of the cover and the pivoting guide portion at the top of the screw, as described in the above embodiment, can be omitted. Other configurations are identical to these configurations in the above embodiment, so that descriptions of other configurations will be omitted to avoid redundant descriptions.

An embodiment of the invention

As shown in FIG. 6, a vertical screw juicer according to a further embodiment of the present invention includes a main body 4000 having an engine 4000a integrated therein; and a juicer module mounted on the main body 4000. The juicer module includes a screw 1000, a juicer container 2000, a mesh drum 3000 and a cover 6000. The vertical juicer juicer further comprises a locking structure 5000 that operatively connects the drive shaft 4100 of the engine 4000a with the rotating shaft 1100 of the screw 1000 and at the same time prevents the rotation of the rotating screw 1100 when the drive shaft 4000 rotates. The assembly sequence of the main body and the corresponding components of the juicer module may vary in various ways, and therefore, the present invention should not be limited to the assembly sequence.

The rotating shaft 1100 is integral with the screw 1000, and the rotating shaft 1100 extends to vertically protrude from the bottom of the rotating shaft 1100. The screw 1000 is vertically mounted in the container 2000 of the juicer, and the mesh drum 3000 is installed inside the container 2000 of the juice extractor to accommodate the circumference of the screw 1000. The mesh drum 3000, together with the screw 1000, serves to produce juices from raw materials such as fruits or vegetables, and at the same time serves as a filter to separate juices from the residues of their raw materials. The juicer container 2000 includes a lower inclined surface 2010, which is inclined outward from the central portion or its neighboring portion, and the screw 1000 includes a lower inclined surface, which is formed on the lower part of the screw 1000 and is in contact with the lower inclined surface 2010. Lower the inclined surface 2010 can cause a firm fit of the screw 1000, having its corresponding inclined surface, and at the same time serves to prevent the passage of moisture through the Central part of the lower inclined second surface 2010 that is formed by the connection between the drive shaft and the rotating shaft.

When the juice extractor module is mounted on the main body, the drive shaft 4100 of the engine 4000a is inserted into the juice extractor container 2000 through the lower gasket 2010a of the juice extractor container 2000. The screw 1000 includes a lower cavity that encloses the circumference of its rotating shaft 1100, in which the rotating shaft 1100 of the screw 1000 and the drive shaft 4100 are connected to each other according to the insertion pattern inside the lower cavity. To this end, the rotary shaft 1100 has an elongated circular shaft shaft socket 1100a, while the drive shaft 4100 has a corresponding circular cross section, so that the drive shaft 4100 is inserted into the shaft socket 1100a. As will be described in detail below, the locking structure 5000 is capable of completely damping the relative movement between the drive shaft 4100 and the rotating shaft 1100 in the vertical direction, as well as in the direction of rotation when the drive shaft 4100 rotates. Specifically, the locking structure 5000 completely eliminates the rise of the screw 1000 by restricting the vertical movement of the rotating shaft 1100. Additionally, the locking structure 5000 is configured to provide easy disconnection of the connection between the drive shaft 4100 and the rotating shaft 1100 when the rotation of the drive shaft 4100 is stopped.

The lid 6000 is removably connected to the upper portion of the juicer container 2000 and has a support 6100 formed on the lower surface of the lid 6000 to prevent vibration of the screw 1000. Preferably, the support 6100 has a rotational support element that is adjacent to the upper edge of the screw 1000 to direct the rotation of the screw 1000 wherein the rotational support member may have a plurality of guide members that periodically come into contact with the upper edge of the screw 1000. The screw 1000 includes a helical rib formed on the side surface screw 1000, to grind, cut or crush the raw material, while the spiral rib is adjacent to the inner surface of the mesh drum 3000.

The locking structure 5000 includes a pair of locking protrusions 5020 and 5020, respectively, provided on both diametrically opposite sides of the drive shaft 4100. A pair of locking protrusions 5020 and 5020 can be formed by a pin that extends through the drive shaft 4100. The pin is inserted into the hole for the pin of the leading the shaft 4100 according to the interference fit pattern so that both ends of the pin protrude from the side surface of the drive shaft 4100 in a diametrically opposite direction, thereby forming a pair of locking protrusions 5020 and 5020, as described above. The locking structure 5000 further includes a pair of locking holes 5040 and 5040 formed on the rotary shaft 1100 and corresponding to the locking protrusions 5020 and 5020. In the state where the drive shaft 4100 is inserted into the socket 1100a of the rotating shaft 1100, the locking protrusions 5020 and 5020 may be located inside the fixing holes 5040 and 5040, respectively. Additionally, as will be described below, when the drive shaft 4100 rotates, the locking protrusions 5020 and 5020 are kept closed in the respective locking holes 5040 and 5040 so that the screw 1000 and thus its rotating shaft 1100 can rotate together with the drive shaft 4100.

Fig. 7 (a) depicts a state in which the working connection between the rotary shaft 1100 and the drive shaft 4100 can be disconnected, while Fig. 7 (b) depicts another position in which the rotary shaft 1100 and the drive shaft 4100 are operatively connected .

As shown in FIGS. 7 (a) and 7 (b), each locking protrusion 5020 is in the shape of a round cylinder, and its corresponding locking hole 5040 is shaped to allow vertical insertion of the locking protrusion 5020, horizontal linear direction of the locking protrusion 5020, and vertical extraction of the locking protrusion 5020. That is, a lower cavity 5040a that is open downwardly is formed at the bottom of the locking hole 5040 to allow the locking protrusion 5020 to enter and exit; a linear guide portion 5040b is formed in the upper center portion of the locking hole 5040 to allow horizontal and linear movement of the locking protrusion 5020 when the drive shaft 4100 begins to rotate; and locking protrusions 5040c into which the locking protrusion 5020 is closed when the drive shaft 4100 and the screw rotating shaft 1100 rotate in a mutual engagement pattern are formed to the right and left of the linear guide portion 5040b, each locking protrusion 5040c having a substantially circular arc shape. The lower portion of each locking portion 5040c has a shape capable of preventing the locking protrusion 5020 from coming out downward, i.e., the mold extending inwardly. Therefore, even if an upwardly directed force for raising the screw 1000 is created during the rotation of the screw 1000 (see FIG. 6), the screw 1000 is prevented from lifting since the locking protrusion 5020 is engaged with the locking portion 5040c. Furthermore, in order for the locking protrusion 5020 to more reliably contact the inner surface of the fixing portion 5040c of the fixing hole 5040, it is preferable that the circular cross-sectional shape of the locking protrusion 5020 corresponds to the circular arc shape of the locking portion 5040c. More preferably, the radius of the locking protrusion 5020 is substantially identical to the radius of curvature of the circular arc shape of the locking portion 5040c. Although a pair of locking protrusions 5020 and 5020 and a pair of locking holes 5040 and 5040 are respectively provided on the drive shaft 4100 and the rotating shaft 1100 in the present embodiment, the locking structure 5000, as shown in FIG. 8, in which a single locking protrusion 5020 and a single locking hole 5040 are formed on the drive shaft 4100 and the rotating shaft 1100, respectively, should be considered within the scope of the present invention.

As shown in FIGS. 6 and 7 (a) and (b), when the fixing structure 5000 is used as described above, the juicer module, in which the screw 1000, the juicer container 2000 and the mesh drum 3000 are assembled, is vertically pressed down and mounted to the main body 4000, from which the drive shaft 4100 protrudes, thereby the drive shaft 4100 can be inserted into the socket 1100a of the rotating shaft 1100. Alternatively, in the state where the juicer container 2000 is mounted on the main body 4000, the drive shaft 4100 can be inserted into the socket 1100a shaft by simply of the first step of pressing down the screw 1000 to the drive shaft 4100 or only by means of the weight of the screw 1000. Additionally, only through the operation of the engine 4000a integrated in the main body 4000, the locking protrusion 5020 provided on the drive shaft 4100 rotates and then spontaneously engages in the locking portion 5040c of the locking holes 5040 so that the drive shaft 4100 is operatively connected to the screw 1000 and its rotary shaft 1100. Here, as shown in Fig. 7 (b), since the fixing portion 5040c of the fixing hole 5040 strictly prevents vertical By moving the locking protrusion 5020, the auger 1000 can rotate reliably in its main position, without lifting upward, even if the upward force for lifting the auger 1000 can be formed due to the rotation of the auger 1000 and / or accumulation of residual raw materials. In addition, when the screw 1000 needs to be separated after stopping the rotation of the screw 1000, after the screw 1000 only rotates slightly and then rises, the locking state between the locking protrusion 5020 and its corresponding locking hole 5040 is released from the position as shown in FIG. 7 ( b) to a position as shown in FIG. 7 (a) so that the screw 1000 can be more easily separated.

In addition, the locking hole 5040 has inclined surfaces 5040d that are located on the lower portion of the locking hole 5040 and gradually extend into the locking hole 5040, more specifically, the locking sections 5040c. Even if the locking protrusion 5020 and its corresponding locking hole 5040 are not aligned with each other, the inclined surfaces 5040d will allow the locking protrusion 5020 formed on the drive shaft 4100 to spontaneously slide along the inclined surfaces 5040d so that the locking protrusion 5020 can spontaneously move into the locking hole 5040 Since it is difficult for the user to determine the relative position between the fixing protrusion 5020 and its corresponding fixing hole 5040 with the naked eye, the inclined surfaces and 5040d are very useful for easy connection between the rotating screw shaft and the drive shaft of the motor.

In addition, as shown in FIG. 9, since the inclined surfaces 5040d have an arc shape that respectively extends on both sides of the lower cavity, the locking protrusion 5020 can spontaneously move into its corresponding locking hole 5040 above the inclined surface 5040d, even if the locking protrusion 5020 can snuggle down in some position.

10 is a longitudinal view showing a juicer with a vertical screw according to another embodiment of the present invention.

As shown in FIG. 10, the rotating shaft 1100 passes through the central part of the screw 1000 and thus protrudes upward above the upper portion of the screw 1000 in the juicer with a vertical screw according to the present embodiment. The upper portion of the rotating shaft 1100 has a smaller diameter than its other sections, and is inserted into the socket 6100a of the shaft formed in the cover 6000. Since the upper portion of the rotating shaft 1100 of the screw 1000 is inserted into the socket 6100a of the shaft and rotatably supported, the vibrations of the screw 1000 can be canceled to some extent during the rotation of the screw 1000. The configuration of the upper portion of the screw 1000 and the shaft socket 6100a replaces the guide support 6100 (see FIG. 6) shown in the aforementioned embodiment. Since the vertical screw juicer according to the present embodiment has substantially the same configuration as the aforementioned embodiments, with the exception of the support element in the upper part of the screw, by the shaft socket 6100a and the upper portion of the rotating shaft 1100, a description for the same configuration will be omitted. to avoid redundant descriptions.

11 depicts a modified locking structure to prevent the screw from rising.

The locking structure 5000, as shown in FIG. 11, includes a first pin hole 5060 provided in the drive shaft 4100; a second pin hole 5070 provided in the rotating shaft 1100; and a locking pin 5020 ', which is simultaneously inserted in both the first pin hole 5060 and the second pin hole 5070 when the drive shaft 4100 is inserted into the socket 1100a of the rotary screw shaft 1100. To this end, the first pin hole 5060 is formed to laterally pass through the drive shaft 4100, and the second pin hole 5070 is formed to laterally pass through the rotary screw shaft 1100 at the location where the shaft socket 1100a is located.

According to the present invention thus made, the following advantages can be expected.

The juicer module according to one embodiment of the present invention adopts a lower structure of the juicer container having a downward inclined surface that gradually descends from the central region of the lower surface of the juicer container through which the rotary shaft of the auger extends to the outer part of the lower surface of the juicer container so that water is leaked from the container juicers through the main body could be prevented. An essentially cylindrical protrusion to provide watertightness, which would otherwise be formed on the lower portion of the container of a traditional juicer or juicer module, may be omitted, thereby further facilitating cleaning of the lower portion of the juicer container. Additionally, in the juicer module according to another embodiment of the present invention, an inclined surface that corresponds to the lower inclined surface of the juicer container is formed on the lower portion of the screw, thereby, resting the screw motionlessly on the lower part of the juicer container. Also additionally, in the juicer module according to another embodiment of the present invention, the guide pivot portion and the pivot guide are formed on the upper end of the screw and the lower portion of the lid, respectively, so that the shaft socket, which would otherwise be formed in the lid of the traditional juicer, can be omitted thereby allowing cleaning of the lid in a more hygienic and convenient manner.

Industrial applicability

The scope of the present invention is not limited to the embodiment described and shown above, but is defined by the appended claims. It is understood that those skilled in the art can make various modifications and changes to it within the scope of the invention defined by the claims. Therefore, the actual scope of the present invention should be determined by the technical nature of the attached claims.

Claims (21)

1. A juice extractor module comprising:
an open top juicer container with a shaft hole formed in a lower central portion of the juicer container;
a cover with a loading chute for raw materials in its wall, the cover being connected to the upper portion of the container of the juicer;
a mesh drum fixedly located inside the container of the juicer; and
a screw located inside the mesh drum, and the screw has a spiral section formed on its side surface, and a rotating shaft passing through the hole for the shaft of the container of the juicer,
wherein the juicer container includes a lower inclined surface extending outward from the shaft hole, and a lower inclined surface contacting said lower inclined surface at least partially formed at the lower end of the screw. 2. The juicer module according to claim 1, wherein the gasket into which the rotating shaft is inserted is installed in a central portion of the lower inclined surface, and the gasket includes an inclined surface extending from the lower inclined surface. 3. The juicer module according to claim 1, in which the first insertion protrusion is formed below on one side of the lower end of the mesh drum and at least one second insertion protrusion is formed below on the other side of the lower end of the mesh drum, and in which an insertion hole into which a first insertion protrusion is inserted, formed on one side of the lower inclined surface, and at least one insertion groove into which the second insertion protrusion is inserted, is formed on the other side of the lower inclination th surface. 4. The juicer module according to claim 1, wherein the guide pivot section is formed at the upper end of the screw, and the lid is provided with a pivot guide to guide the rotation of the screw, the pivot guide being in contact with the edge of the guide pivot section. 5. The juicer module according to claim 1, wherein the shaft is formed in the upper central portion of the screw, the shaft socket into which the shaft is inserted is formed in the lower side of the lid, and a reinforcing layer is formed in the shaft socket. 6. The juicer module according to claim 1, wherein the blade structure for cutting the raw material thrown into the loading chute for the raw material, or pushing the raw material downward, is formed at the upper end of the screw. 7. A juicer module comprising:
an open-top juicer container with a shaft hole formed in a lower central portion of the juicer container;
a cover with a loading chute for raw materials in its wall, the cover being connected to the upper portion of the container of the juicer;
a mesh drum fixedly located inside the container of the juicer; and
a screw located inside the mesh drum, the screw having a spiral portion formed on its side surface and a rotating shaft passing through an opening for the shaft of the container of the juicer, the lid provided with a pivoting guide for guiding the rotation of the screw. 8. The juicer module according to claim 7, wherein the guide pivot section is formed at an upper end of the screw and the pivot guide is in contact with an edge of the guide pivot section. 9. The juicer module of claim 8, in which the guide rotary section has the shape of a ring for lowering the raw materials abandoned in the loading chute for raw materials. 10. The juice extractor module of claim 8, wherein the rotary guide comprises a plurality of guide elements in contact with the guide rotary section, wherein at least one cavity is provided between adjacent guide elements and allows the input of juice juice inserted through it. 11. A juicer with a vertical screw, containing:
a main body having a drive shaft protruding upward;
open top container mounted on the main body;
a screw located inside the container, and the screw has a rotating shaft, vertically mounted on the drive shaft;
a mesh drum located inside the container to cover the periphery of the screw;
a lid connected to the upper portion of the main body, the lid having a feed chute for raw materials; and a locking structure for restricting the vertical movement of the screw to prevent the screw from rising when the drive shaft and the rotating shaft rotate together. 12. A juicer with a vertical screw according to claim 11, in which the rotating shaft includes a shaft socket in which the upper portion of the drive shaft is inserted, and the locking structure includes a locking protrusion formed on the driving shaft and a locking hole formed on the rotating the shaft so that the locking protrusion is inserted into the locking hole when the drive shaft is inserted into the shaft housing. 13. The vertical screw juicer of claim 12, wherein the fixing hole includes a lower cavity open downward to allow the locking protrusion to enter and exit;
a guide portion for providing horizontal movement of the locking protrusion when the drive shaft begins to rotate; and a fixing portion for restricting vertical movement of the locking protrusion. 14. A juicer with a vertical screw according to item 13, in which the fixing hole has a pair of locking sections formed respectively on the right and left sides of the guide section to prevent vertical movement of the rotating shaft relative to the bi-directional rotation of the drive shaft. 15. The juicer with a vertical screw according to item 13, in which the locking protrusion has a circular cross section, and the locking section is made in the form of an arc of a circle corresponding to a circular cross section. 16. The juicer with a vertical screw according to item 13 or 14, in which the fixing hole further has inclined surfaces on the lower portion of the fixing hole so as to slide the locking lug into the fixing hole. 17. A juicer with a vertical screw according to clause 16, in which the inclined surfaces are made in the form of an arc, which is connected to both sides of the lower cavity. 18. The vertical screw juicer of claim 11, wherein the rotating shaft includes a shaft seat into which the upper portion of the drive shaft is inserted, and the locking structure includes a pair of locking protrusions formed respectively on both diametrically opposite sides of the driving shaft; and a pair of locking holes formed in the rotating shaft so that the pair of locking tabs is respectively inserted into the locking holes when the drive shaft is inserted into the shaft housing. 19. A juicer with a vertical screw according to claim 11, in which the lid has a support formed on its lower surface to dampen vibration of the upper portion of the screw. 20. A juicer with a vertical screw according to item 12, in which the locking protrusion is formed from the end of the pin inserted laterally and installed in the drive shaft. 21. A juicer with a vertical screw according to claim 17, wherein each of the fixing holes has an inclined surface for sliding the corresponding locking protrusion into the locking hole, and the inclined surface is made in the form of an arc that is connected to the corresponding locking protrusion.

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