KR101013504B1 - Vertical screw juicer - Google Patents

Abstract

PURPOSE: A vertical screw juicer is provided to prevent the frictional force between a support unit and a rotary shaft or a screw from being increased by restraining the movement of the screw. CONSTITUTION: A vertical screw juicer comprises a main body(400), a container(200), a screw(100), a mesh net(300), a cover(600), and a locking structure. The top of a drive shaft(410) of the main body is protruded. The screw is arranged inside the container. The rotary shaft of the screw is vertically inserted into the drive shaft. The mesh net is arranged inside the container in order to cover the screw. The cover is coupled to the top of the main body. When the drive shaft is rotated with the rotary shaft, the locking structure prevents the screw from ascending.

Description

Vertical Screw Juicer {VERTICAL SCREW JUICER}

The present invention relates to a vertical screw juicer, and more particularly, to improving the juice performance of the vertical screw juicer.

In general, juicers are devices that make juice by processing vegetables or fruits in the form of liquid or juice. Several types of juicers are known that can be conveniently used for home or commercial purposes. Typically, the juicer adopts a method of crushing the blade by rotating the blade at high speed after putting the material into the inlet. However, the conventional juicer's method of crushing the material by the high speed blade has a disadvantage in that it is difficult to make a good juice because it changes the properties of the material in the crushing process.

In this regard, a vertical screw juicer using a slow rotating screw (or auger) has been proposed in the past. This vertical screw juicer is configured to cut and squeeze a material, such as a vegetable or fruit, by slow rotation of a vertically placed screw to produce juice. The technique of the vertical screw juicer as described above is disclosed in the Republic of Korea Patent Registration No. 10-0966607 under the name of "juicer screw and juicer module including the same".

1 is a longitudinal sectional view showing an upper module of a conventional vertical screw juicer, that is, a juicer module.

The conventional vertical screw juicer includes a body in which a motor is built and a juicer module vertically coupled on the body. The juicer module includes a screw 10, a container 20, Net body 30 and lid 50. The screw 10 is disposed in the vessel 20 together with the mesh 30, and the mesh 30 is disposed in the vessel 20 so as to surround the periphery of the screw 10. The lid 50 has a material inlet for injecting the material into the container 20 and is detachably coupled to the upper portion of the container 20. The screw 10 has a rotating shaft 11 at the bottom, which is the drive shaft of the motor that protrudes to the upper portion of the main body 40 when the container 20 is mounted on the main body 400. Connected in a manner fitted to (not shown). Rotation guide 51b is formed in the bottom surface of the lid 50, and this rotation guide 51b is in contact with the upper end of the screw 10 (especially the corner part), and suppresses the shaking of the screw 10. On the other hand, it serves to guide the rotation of the screw (10). In addition, the lid 50 also pushes down the upper end of the net body 30 perpendicular to the bottom of the container 20, and also serves to fix the net body 30 in the container 20.

When a material such as a fruit or vegetable is introduced into the container 20 of the feeding module through the material inlet of the lid 50 and the screw 10 is rotated by the motor of the main body, the material is meshed with the outer surface of the screw 10. It is crushed and squeezed while being moved between the inner faces of 30, whereby juice is made from materials such as vegetables or fruits. Juice passing through the net body 30 is discharged to the outside through the discharge port formed in the container 20, the residue that does not pass through the net body 30 is separated from the juice and the waste discharge port extending from the bottom surface of the container 20 Is discharged to the outside through.

The screw 10 has a shape in which the diameter or cross-sectional area of the middle height part is relatively largest, and the diameter or cross-sectional area becomes smaller as it goes down or up from the height middle part. On the other hand, the net body 30 has a wide top and a narrow bottom under the light for easy fitting of the screw 10 into its interior and for maximizing the juice efficiency by the cooperation of the screw 10 with itself. Take the form of consultation. At any position in the middle of the height of the screw 10, the distance between the outer surface of the screw 10 and the inner surface of the mesh 30 is determined to be the shortest, but as the distance from the position up or down is increased. The distance between the inner side of 30 and the outer side of the screw 10 is longer.

In the case of a conventional vertical screw juicer, the inventors have found that there is a problem that the screw 10 is raised in the vertical direction during its operation. This results from the accumulation of debris on the lower surface of the screw 10 during the juicer operation and the existing connection structure between the rotating shaft 11 of the screw 10 and the shaft (not shown) of the motor.

Conventional vertical screw juicers can accumulate debris resulting from processing between the bottom face of the screw 10 and the bottom face of the vessel 20. And, as the rotation of the screw 10 and the processing of the material continue more, a residue accumulation phenomenon occurs in which more debris accumulates on the lower surface of the screw 10. This debris buildup creates pressure (or lift force) that undesirably moves the screw 10 in the vertically upward direction. In the prior art, the guide 51b of the lid 50 is arranged to push down the screw 10, thereby restraining the vertical movement of the screw 10 from freezing, but in severe cases, the screw 10 may be Since it rises up to 50) while bending upwards, there is a limit to solving various problems due to the unwanted rise of the screw (10).

In addition, as the rising height of the screw 10 increases, the space between the bottom surface of the container 20 and the bottom surface of the screw 10 becomes wider, and the accumulation of dregs deepens. Even with the most common construction of the shaft at the top of the screw and the shaft fitted to the lid to support the screw, the buildup of debris from the screw rise still exists, and in addition, the heat of friction between the shaft at the top of the lid and the shaft hole increases. Further problems have arisen, such as the occurrence of contamination in the shaft and the difficulty of cleaning in the shaft.

2 is a view for explaining the connection structure between the rotating shaft of the screw and the shaft of the motor.

As shown in Fig. 2, the rotating shaft 11 of the screw has an approximately hexagonal shaft hole 11a, and the shaft 41 of the motor is hexagonal cross-section 41a fitted into the hexagonal shaft hole 11a. It is provided. The shaft connecting structure by the hexagonal end face 41a and the hexagonal shaft hole 11a can strictly restrict the relative rotation between the rotary shaft 11 and the shaft 41, whereas the shaft 11 in the vertical direction is rotated. ), There is only a sliding surface between the shaft 41 and the rotational axis 11 in the vertical direction with respect to the shaft 41 cannot be prevented.

As described above, the conventional juicer is the shortest distance between the inner surface of the mesh and the outer surface of the screw at the middle of the height of the screw having the largest diameter of the cross section when the screw is moved upward by the accumulation of dregs. Since the length of the screw is longer than before the screw rises, the space between the mesh and the screw becomes wider. As the space between the mesh and the screw increases, the particles of the material to be crushed or crushed become larger, so that the juice rate is significantly lowered. have.

In addition, the prior art increases the frictional heat in the contact portions between the screw and the lid when the screw is raised, ie the rotational guide of the top of the screw and the lid, or the shaft hole of the screw and the shaft hole of the lid, which causes the material to be cut. Conveys juices that occur when they cause problems that destroy nutrients. In addition, since abrasion occurs at the contact portion between the screw and the lid to generate impurities, there is a possibility that the juice may be contaminated by the impurities. In addition, the conventional technology may cause a problem that the overload of the motor occurs to cause a malfunction and stop the rotation of the screw.

In addition, the prior art also raises the lid further due to the rise of the screw, which may lead to an improper fastening state between the lid and the container, whereby the lid cannot be easily removed from the container and at the same time by the lid The crimp fixed mesh may cause unstable shaking. Unstable shaking of the mesh creates an unwanted space between the mesh and the bottom of the container, causing the problem of debris mixing in the outlet of the juice. In addition, the conventional technique is caused by a pressure that accumulates waste into the space between the bottom surface of the container and the screw bottom surface, the packing to seal the shaft and the bottom surface of the container is opened, causing the juice or debris to leak into the motor You can.

Accordingly, the present invention, which solves the problems of the prior art, is intended to prevent unwanted rise of the screw in the container, so that the screw can always process the material at a constant height relative to the container, mesh and lid. The problem is to provide a vertical screw juicer of the structure.

Vertical screw juicer according to one aspect of the present invention, the main body including a drive shaft protruding upward; An upper open container mounted on the main body; A screw disposed in the container, the screw having a rotational shaft fitted in a direction perpendicular to the drive shaft; A net body disposed in said container so as to surround a periphery of said screw; A lid including a material inlet and coupled to an upper portion of the body; And a locking structure that prevents the screw from rising by regulating vertical movement of the screw when the drive shaft and the rotating shaft rotate together.

According to one embodiment, the rotating shaft includes a shaft hole in which the upper portion of the drive shaft is fitted, the locking structure, the locking projection formed in the drive shaft, and the locking projection when the drive shaft is fitted into the shaft hole It includes a step hole formed in the rotating shaft to be fitted.

According to one embodiment, the step hole, the lower space opened to allow the entry / exit of the locking projections, and a linear guide for allowing a horizontal linear movement of the locking projections at the start of rotation of the drive shaft, And a locking portion for locking the locking protrusion to regulate vertical movement of the locking protrusion.

According to one embodiment, the stepped hole includes a pair of engaging portions on both the left and right sides of the linear guide portion so as to restrict the vertical movement of the rotating shaft with respect to the bidirectional rotation of the drive shaft.

According to one embodiment, the locking projection includes a circular cross section, and the locking portion includes an arc shape corresponding to the circular cross section.

According to an embodiment, an inclined surface is formed at the lower portion of the stepped hole to slide the locking protrusion to the inside of the stepped hole.

According to one embodiment, the rotating shaft includes a shaft hole into which the upper portion of the drive shaft is fitted, the locking structure is a pair of engaging projections formed on both sides of the drive shaft in the width direction, and the drive shaft is the shaft hole And a pair of engaging holes formed in the rotating shaft so that the pair of engaging projections are fitted when fitted in the.

According to one embodiment, the bottom of the lid is formed with a support for suppressing the shaking of the upper screw.

According to one embodiment, the locking projection is formed by the end of the pin inserted laterally inserted into the drive shaft.

According to one embodiment, the pair of engaging projections are formed by both ends of the pin penetrating the drive shaft laterally.

The shaft and the rotating shaft are integrally fixed by the coupling means of the present invention, thereby eliminating the problem that the accumulated accumulation phenomenon deepens into the space between the bottom surface of the screw and the bottom surface of the container by the compressed material when the screw rotates. The juice rate is always maintained.

When the rotation of the screw is stopped, the screw can be easily separated through the coupling means, and the movement of the screw is suppressed, thereby increasing the friction between the support and the screw or the rotating shaft.

In addition, even if the engaging projection and the engaging projection of the locking structure do not coincide, by providing the inclined surface to the engaging hole, the engaging projection slides along the inclined surface and can naturally enter the opening.

1 is a longitudinal sectional view showing an upper juicer module of a conventional vertical screw juicer.
2 is a view for explaining the connection structure between the screw shaft and the motor shaft of the conventional juicer shown in FIG.
3 is a longitudinal sectional view showing a vertical screw juicer according to an embodiment of the present invention.
4 (a) and 4 (b) are diagrams for explaining a locking structure between the screw rotating shaft of the screw juicer and the shaft of the motor shown in FIG.
5 is a view for explaining another modified example of the locking structure shown in FIG.
6 is a view for explaining another example of the locking structure shown in FIG.
7 is a longitudinal sectional view showing a vertical screw juicer according to another embodiment of the present invention.
8 is a view for explaining a locking structure according to another modification of the present invention.

With reference to the accompanying drawings will be described in detail the configuration and embodiments of the present invention.

As shown in FIG. 3, the vertical screw juicer according to an embodiment of the present invention includes a main body 400 in which the motor 400a is embedded and a juicer module mounted on the main body 400. The juicer module includes a screw 100, a container 200, a mesh 300, and a lid 600. In addition, the vertical screw juicer, at the time of rotation of the drive shaft 100, at the same time as the power to the shaft 110 of the screw 100 and the shaft 410 of the motor (400a) and the rotation shaft ( And locking structure 500 to block the rise of 110. The order of assembly of the components and the main body of the juicer module may be various, and this does not limit the present invention.

The rotating shaft 110 is integrally formed in the screw 100, and the rotating shaft 110 protrudes perpendicularly to the lower portion of the screw 110. The screw 100 is vertically installed in the container 200, and the mesh 300 is installed in the container 200 to surround the screw 100. The mesh 300 cooperates with the screw 100 to produce juice from a material such as a fruit or vegetable, and at the same time serves as a filter for separating juice and residues. The container 200 includes a bottom surface 201 inclined outward from its center or its vicinity, and a lower portion of the screw 100 includes an inclined surface in surface contact with the inclined bottom surface 201. do. The inclined bottom surface 201 enables stable mounting of the screw 100 having a corresponding inclined surface and at the same time serves to block moisture with respect to the center of the bottom surface 201 where the shaft is coupled.

When the juicer module is mounted to the main body, the drive shaft 410 of the motor 400a is inserted into the inside of the container 200 through the bottom packing 201a of the container 200. The screw 100 includes a lower space surrounding its own rotational axis 110, in which the rotational axis 110 of the screw 100 and the drive shaft 410 are connected in such a way that they are inserted relative to each other. do. To this end, the rotary shaft 110 has an elongated circular cross section shaft hole 110a, and the drive shaft 410 includes a circular cross section inserted into the shaft hole 110a. As will be described in detail below, the locking structure 500 is configured to completely suppress the relative motion between the drive shaft 410 and the rotation shaft 110 in the vertical direction and the rotation direction when the drive shaft 410 rotates. . In particular, the locking structure 500 completely suppresses the rise of the screw 100 by regulating the vertical movement of the rotation shaft 110. In addition, the locking structure 500 is configured to easily release the connection between the drive shaft 410 and the rotation shaft 110 in a state where the rotation drive of the drive shaft 410 is stopped.

The lid 600 is detachably coupled to the upper portion of the container 200, the support surface 610 is formed on the bottom to suppress the shaking of the screw 100. The support part 610 is preferably a rotation guide structure that guides the rotation of the screw 100 in contact with the upper edge of the screw 100, the rotation guide structure is intermittently at the upper edge of the screw 100 It may include a plurality of guide pieces in contact. Ribs for crushing, cutting or pressing the material are formed spirally on the side of the screw 100, which ribs are located close to the inner surface of the mesh 300.

The locking structure 500 includes a pair of locking protrusions 502 and 502 provided opposite to the width direction of the drive shaft 410. The pair of engaging projections 502, 502 may be formed by pins that laterally penetrate the drive shaft 410. Both ends of the pin are inserted into the pin hole of the drive shaft 410 in a fitting manner, and both ends of the pin protrude in a direction opposite to approximately 180 degrees from the side of the drive shaft 410, such that The engaging projections 502 and 502 are formed. In addition, the locking structure 500 includes a pair of engaging holes 504 and 504 formed in the rotation shaft 110 to correspond to the pair of engaging protrusions 502 and 502. In a state where the drive shaft 410 is fitted into the shaft hole 110a of the rotation shaft 110, the pair of engaging protrusions 502 and 502 may be located in the pair of engaging holes 504 and 504. have. Further, as will be described in detail below, when the drive shaft 410 rotates, the engaging projections 502 and 502 are held in step by the stepped holes 504 and 504, whereby the screw 100 and The rotating shaft 110 belonging to it may rotate integrally with the drive shaft 410.

4 (a) shows a state in which the power connection between the rotating shaft 110 and the drive shaft 410 is releasing, Figure 4 (b) is the rotation shaft 110 and the drive shaft 410 is power connected to each other Show status

Referring to (a) and (b) of Figure 4, the locking projection 502 is formed in a circular shape, the engaging hole 504 is inserted in the vertical direction of the circular locking projection 502, the locking projection ( It includes a straight guide in the horizontal direction of the 502 and the shape that allows the engaging projection 502 to fall out in the vertical direction. That is, a lower space 504a opened downward to allow entry / exit of the locking protrusion 502 is formed at the lower portion of the engaging hole 504, and a drive shaft 410 is formed at the upper center of the engaging hole 504. The linear guide portion 504b is formed to allow a horizontal linear movement of the locking projection 502 at the start of rotation of the rotating shaft. The driving shaft 410 and the rotating shaft of the screw are formed on both left and right sides of the linear guide portion 504b. When the 110 rotates in conjunction with each other, an approximately arc-shaped locking portion 504c on which the locking projection 502 is stepped is formed. The lower portion of the locking portion 504c has a shape that can prevent the locking protrusion 502 from falling down, that is, protruded inwardly, so as to lift the screw 100 during the rotation of the screw 100 (see FIG. 3). Even if this occurs, the locking projection 502 is caught by the locking portion 504c, so that the rise of the screw 100 is suppressed. In addition, the circular shape of the locking protrusion 502 and the circular arc of the locking portion 504c may be more reliably in close contact with the inner surface of the locking portion 504c of the engaging hole 504. It is preferable that the shapes correspond to each other, and the radius of curvature of the locking projection 504 and the radius of curvature of the arc shape of the locking portion 504c are approximately equal. In this embodiment, a pair of engaging projections 502 and 502 and a pair of engaging holes 504 and 504 are provided in each of the drive shaft 410 and the rotation shaft 110, but as shown in FIG. The locking structure 500 formed with one locking protrusion 502 and one stepping hole 504 and 504 in each of the drive shaft 410 and the rotating shaft 110 is also within the scope of the present invention.

Referring to FIGS. 3 and 4 (a) and (b) together, in the case of using the above-described locking structure 500, a screw module 100, a container 200, and a mesh module 200 are assembled to drive the juicer module. Simple operation of pressing the shaft 100 against the drive shaft 410 while pressing the vertically to the upper portion of the main body 400 protruding from the shaft 410 or mounting the container 200 to the main body 400. Alternatively, the drive shaft 410 may be inserted into the shaft hole 110a of the screw rotation shaft 110 only by the load of the screw 100. In addition, only by driving the motor 400a embedded in the main body 400, the locking protrusion 502 provided in the drive shaft 410 rotates to the locking portion 504c of the engaging hole 504. Naturally caught, the drive shaft 410 is in power communication with the screw 100 and its rotating shaft 110. At this time, as shown in FIG. 4B, since the vertical movement of the locking protrusion 502 is strictly regulated by the locking portion 504c of the engaging hole 504, the screw 100 is rotated. And even if the lift force is generated due to the accumulation of the residue, it can be reliably rotated in the original position without being raised upward. In addition, when the rotation of the screw 100 is stopped and the screw 100 needs to be separated, the step of the locking projection 502 and the stepping hole 504 is merely lifted by slightly rotating the screw 100. It is released from the position shown in (b) of FIG. 4 to the position shown in (a) of FIG. 4, so that the screw 100 can be removed more easily.

In addition, an inclined surface 504d is formed in the lower part of the engaging hole 504, which is gently connected to the inside of the engaging hole 504, in particular, to the engaging portion 504c. Even when the engaging projection 502 and the stepping hole 504 are misaligned, the inclined surface 504d allows the engaging projection 502 formed in the drive shaft 410 to naturally slide on the inclined surface 504d, thereby The locking projection 502 allows for natural movement to the interior of the stepping hole 504. The inclined surface 504d is very useful for easy connection between the rotating shaft of the screw and the drive shaft, in that it is difficult for the user to visually confirm the position of the locking projection 502 and the stepping hole 504.

In addition, as shown in Figure 6, the inclined surface 504d is formed in an arc shape connected to both sides of the lower space so that the locking projection 502 is inclined surface 504d even if the locking projection 502 is pressed at any position. It can be naturally moved to the interior of the step hole 504 by riding.

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

Referring to FIG. 7, in the vertical screw juicer according to the present embodiment, the rotation shaft 110 protrudes upward through the center of the screw 100. The upper end of the rotating shaft 110 has a smaller diameter than the other portion and is inserted into the shaft hole 610a formed in the lid 60. Since the upper end of the rotating shaft 110 of the screw 100 is inserted into the shaft hole 610a and is rotatably maintained, the shaking of the screw 100 may be suppressed to some extent during the rotation of the screw 100. The configuration of the top of the shaft 110 and the shaft hole 610a replaces the guide type support 610 (see FIG. 3) of the previous embodiment. The vertical screw juicer according to the present embodiment has the same configuration as the juicer of the previous embodiment, except for the upper support structure of the screw by the upper end of the rotating shaft 110 and the shaft hole 610a. Explanation is omitted.

8 shows a modified structure of locking structure that can prevent lifting of the screw.

The locking structure 500 illustrated in FIG. 8 includes a first pin hole 506 provided to the drive shaft 410, a second pin hole 507 provided to the screw rotation shaft 110, and the drive shaft ( When the 410 is fitted to the shaft hole (110a) of the rotating shaft 110 of the screw, it includes a locking pin 502 'that is fitted to the first pin hole 506 and the second pin hole 507 at the same time. . To this end, the first pin hole 506 is formed so as to penetrate the drive shaft 410 in the lateral direction, the second pin hole 507 is the position where the shaft hole (110a) the screw rotation shaft 110 It is formed to penetrate laterally in the.

100: screw 200: container
300: mesh 500: locking structure
600: lid 502: step hole
504: hanging projection

Claims (11)

delete A main body including a drive shaft protruding upward;
An upper open container mounted on the main body;
A screw disposed in the container, the screw having a rotating shaft fitted in a direction perpendicular to the drive shaft;
A net body disposed in the container so as to surround the screw;
A lid including a material inlet and coupled to an upper portion of the body; And
It includes a locking structure for preventing the rise of the screw by regulating the vertical movement of the screw when the drive shaft and the rotary shaft rotates together,
The rotating shaft includes a shaft hole into which an upper portion of the drive shaft is fitted, and the locking structure includes a locking protrusion formed in the driving shaft and the locking protrusion to be fitted when the driving shaft is fitted into the shaft hole. And a stepped hole formed in the vertical screw juicer. The method of claim 2, wherein the engaging hole is a lower space opened to allow the entry / exit of the locking projections, a linear guide for allowing the horizontal movement of the locking projections at the start of rotation of the drive shaft, and the locking Vertical screw juicer comprising a locking portion for regulating the vertical movement of the projection. The vertical screw juicer according to claim 3, wherein the stepped hole includes a pair of engaging portions on both left and right sides of the linear guide portion so as to restrict vertical movement of the rotating shaft with respect to bidirectional rotation of the drive shaft. The vertical screw juicer according to claim 3, wherein the locking projection includes a circular cross section, and the locking portion includes an arc shape corresponding to the circular cross section. The vertical screw juicer according to claim 3 or 4, further comprising an inclined surface that slides the locking protrusion to the inside of the locking hole at a lower portion of the locking hole. The vertical screw juicer according to claim 6, wherein the inclined surface is formed in an arc shape connected to both sides of the lower space. A main body including a drive shaft protruding upward;
An upper open container mounted on the main body;
A screw disposed in the container, the screw having a rotating shaft fitted in a direction perpendicular to the drive shaft;
A net body disposed in the container so as to surround the screw;
A lid including a material inlet and coupled to an upper portion of the body; And
It includes a locking structure for preventing the rise of the screw by regulating the vertical movement of the screw when the drive shaft and the rotary shaft rotates together,
The rotating shaft includes a shaft hole into which an upper portion of the drive shaft is fitted, and the locking structure includes a pair of engaging protrusions formed at both sides in the width direction of the drive shaft, and when the driving shaft is fitted into the shaft hole, And a pair of stepping holes formed in the rotating shaft so that the pair of engaging projections are fitted therein. A main body including a drive shaft protruding upward;
An upper open container mounted on the main body;
A screw disposed in the container, the screw having a rotating shaft fitted in a direction perpendicular to the drive shaft;
A net body disposed in the container so as to surround the screw;
A lid including a material inlet and coupled to an upper portion of the body; And
It includes a locking structure for preventing the rise of the screw by regulating the vertical movement of the screw when the drive shaft and the rotary shaft rotates together,
The bottom surface of the lid vertical screw juicer, characterized in that it comprises a support for suppressing the shaking of the upper portion of the screw. The vertical screw juicer according to claim 2, wherein the engaging projection is formed by an end of a pin inserted laterally inserted into the drive shaft. The method of claim 8, wherein the pair of stepped holes include an inclined surface for guiding the locking projection to the inside of the stepped hole, the inclined surface comprises a pair of steps formed in the shape of an arc connected to each other Vertical screw juicer.

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