KR200499201Y1 - Juicer - Google Patents

Abstract

The present invention relates to a juicer, and a juicer according to the present invention comprises: a juice drum having a juice outlet for discharging juice extracted from a juice material and a residue outlet for discharging residue; a screw disposed inside the juice drum and rotating to crush and squeeze the juice material fed into the juice drum between the juice drum and the screw, and having a receiving space provided inside and communicating with the juice outlet, and a gap formed on an outer surface to spatially separate the juice extracted from the juice material from the residue and move it to the receiving space; and a water level indicator unit extending in the height direction from the outer surface of the juice drum and communicating with the juice outlet to visually provide a water level corresponding to the water level of the juice stored in the receiving space of the screw; wherein the water level indicator unit is characterized by including a visible chamber having an opening formed on a lower side and a chamber cover for opening and closing the opening.

Description

JUISER

The present invention relates to a juicer, and more specifically, to a juicer having a juicer structure in which juice separated from juice residue moves into the interior of a screw, and in which the level of juice stored inside the screw can be easily checked.

As interest in health has increased recently, the use of juicers that allow individuals to make juice from vegetables, grains, or fruits at home is increasing.

A juicer generally operates by squeezing juice by pressing the juice target with high pressure, as in the 'juice extractor' of registration number 10-0793852.

A conventional juicer is composed of a screw that receives power from a motor inside a juice drum and rotates to crush and squeeze the juice to be extracted, and a mesh drum that is placed between the juice drum and the screw to separate the juice and the residue. However, since this mesh drum is made of a mesh filter structure with a large number of microscopic holes formed, it has the problem of being difficult to clean.

Accordingly, juicers have been developed recently that do not have a separate drum and instead move the separated juice inside the screw to separate it from the residue. However, these juicers have the problem that the level of the juice contained inside the screw cannot be checked.

Republic of Korea Patent No. 10-0793852

Accordingly, the purpose of the present invention is to solve such conventional problems, and to provide a juicer in which the juice level stored inside the screw can be easily checked in a juice extraction structure in which juice separated from juice residue moves inside the screw.

In addition, the present invention provides a juicer in which a visible chamber indicating the level of juice on the outside of a juice drum can maintain a level corresponding to the level of juice stored inside a screw regardless of changes in the internal pressure of the juice drum.

In addition, the present invention provides a juicer in which the inside of the thorn chamber formed on the outer surface of the juice drum can be opened and closed, thereby making it easy to clean the inside of the thorn chamber.

The above object is achieved by, according to the present invention, by a juicer, which comprises: a juicer drum having a juice outlet for discharging juice extracted from a juice material and a lees outlet for discharging lees; a screw disposed inside the juicer drum and rotating to crush and squeeze the juice material fed into the juicer drum between the juicer drum and the screw, and having a receiving space provided inside and communicating with the juice outlet, and a gap formed on an outer surface to spatially separate the juice extracted from the juice material from the lees and move it to the receiving space; and a water level indicator unit extending in the height direction from the outer surface of the juicer drum and communicating with the juice outlet to visually provide a water level corresponding to the water level of the juice stored in the receiving space of the screw; wherein the water level indicator unit includes a visible chamber having an opening formed at a lower side and a chamber cover for opening and closing the opening.

Here, it is preferable that the water level indicator include a visible chamber at least partially made of a transparent material so that the water level of the juice stored inside can be visually checked.

In addition, it is preferable that one end of the chamber cover be rotatably hinged to the juicing drum.

In addition, it is preferable that a rotation support shaft is formed on one side of the chamber cover, and a rotation joint is formed on one side of the opening of the thorn chamber to which the rotation support shaft is rotatably coupled.

In addition, it is preferable that the water level indicator further includes a first packing interposed between the inner edge of the chamber cover and the edge of the opening of the visible chamber.

In addition, it is preferable that a ventilation hole is formed at the top of the thorn chamber to communicate with the outside of the thorn chamber.

In addition, it is preferable that the ventilation hole is formed so that the thorn chamber communicates with the internal space of the juicing drum.

In addition, it is preferable that the juice discharge port is formed in the chamber cover, and that the juice discharge port is opened and closed by a juice stopper.

In addition, it is preferable that the juice stopper part include an operating lever that is rotatably hinged to the chamber cover, and a sealing valve that is connected to the operating lever and opens and closes the juice discharge port depending on the rotational position of the operating lever.

In addition, it is preferable that the juice stopper part includes a discharge cover that supports the sealing valve and can be brought into close contact with the chamber cover while the operating lever is rotated toward the closing side.

In addition, it is preferable that the chamber cover include a stopper that comes into close contact with an end of the discharge cover and restricts further rotation of the discharge cover when the operating lever is rotated toward the open side.

In addition, it is preferable that guide ribs for guiding the discharge of juice are formed protrudingly on both sides of the surface of the discharge cover facing the chamber cover.

In addition, it is preferable that the juice stopper part includes a discharge cover having a discharge port formed on a plate surface and being movably supported with respect to the chamber cover so that the discharge port selectively communicates with the juice discharge port.

In addition, it is preferable that the chamber cover includes a rail groove formed along the moving direction of the discharge cover, and that the discharge cover includes a slide projection that engages with the rail groove so as to be able to slide within the rail groove.

In addition, it is preferable that the rail home be set to limit further movement of the sliding projection while the discharge port of the chamber cover is in communication with the juice discharge port, and to limit further movement of the sliding projection while the discharge port is completely removed from the juice discharge port.

According to the present invention, a juicer is provided in which juice separated from juice residue moves into the interior of the screw, and the level of juice stored inside the screw can be easily checked.

In addition, a juicer is provided in which a visible chamber indicating the level of juice on the outside of the juice drum can maintain a level corresponding to the level of juice stored inside the screw regardless of changes in the internal pressure of the juice drum.

In addition, a juicer is provided that allows the inside of the thorn chamber to be easily cleaned by opening and closing the thorn chamber formed on the outer surface of the juice drum.

Figure 1 is a perspective view of the juicer of the present invention.
Figure 2 is an exploded perspective view of the juicer of the present invention.
Figures 3 and 4 are exploded perspective views of the juicing drum shown in Figure 2.
Figure 5 is a cross-sectional view showing the assembled state of the juicer drum and screw of the present invention.
Figure 6 is a cross-sectional view showing the state in which the juicer according to the present invention has the juicer drum and inner drum separated.
Figure 7 is an exploded perspective view of the supply unit shown in Figure 2.
Figures 8 and 9 are perspective views of the screw illustrated in Figure 2.
Figures 10 and 11 are exploded perspective views of the screw illustrated in Figure 2.
Figure 12 is an explanatory drawing of a gap formed in a screw of the juicer of the present invention.
Figure 13 is a cross-sectional view showing the operation of the thorn chamber according to the juicer of the present invention.
Figures 14 and 15 are drawings showing the operation of the juice stopper according to the juicer of the present invention.
Figure 16 is a drawing showing the function of the chamber cover according to the juicer of the present invention.
Figures 17 and 18 are exploded perspective views of a juicer according to the second embodiment of the present invention.
Figures 19 and 20 are cross-sectional views showing the opening and closing state of the juicer cap according to the second embodiment of the present invention.
Fig. 21 is a diagram showing the opening and closing operation of the juicer cap according to the second embodiment of the present invention.

Before the explanation, in several embodiments, components having the same configuration will be described representatively in the first embodiment using the same reference numerals, and in other embodiments, configurations different from the first embodiment will be described.

Hereinafter, a juicer according to a first embodiment of the present invention will be described in detail with reference to the attached drawings.

Among the attached drawings, FIG. 1 is a perspective view of the juicer of the present invention, FIG. 2 is an exploded perspective view of the juicer of the present invention, FIGS. 3 and 4 are exploded perspective views of the juicer drum illustrated in FIG. 2, FIG. 5 is a cross-sectional view showing the assembled state of the juicer drum and screw of the juicer of the present invention, FIG. 6 is a cross-sectional view showing the juicer drum and inner drum of the juicer of the present invention separated, and FIG. 7 is an exploded perspective view of the supply unit illustrated in FIG. 2.

The juicer of the present invention as shown in the drawing above may be configured to include a juice drum (100), a water level indicator (200), and a screw (300).

The above-mentioned juicing drum (100) accommodates a screw (300) inside and functions to crush and compress the juicing target through interaction with the screw (300).

The above-mentioned juicing drum (100) includes a cylindrical side wall portion (101) that surrounds the side of the juicing space and a lower plate portion (102) that is arranged at the lower end of the side wall portion (101) and closes the lower part of the juicing space.

A waterproof cylinder (103) is formed in the center of the upper surface of the lower plate (102) with a drum hole (103a) extending in the vertical direction, and a ring-shaped guide projection (104) is formed protruding on the outer surface of the upper surface of the lower plate (102) so as to be concentric with the waterproof cylinder (103), have a relatively larger diameter than the waterproof cylinder (103), and support the lower end of the screw (300) so as to be rotatably supported.

On the outer side of the lower part of the above-mentioned juicing drum (100), a juice discharge port (105) for discharging the juice separated by juicing and a residue discharge port (106) for discharging the remaining residue are respectively spaced apart.

In addition, a juice discharge hole (105a) is formed in the area between the waterproof cylinder (103) and the guide jaw (104) on the lower plate (102) to guide the juice flowing into the screw (300) to the juice discharge port (105), and a residue discharge hole (106a) is formed in the area between the guide jaw (104) and the side wall (101) on the lower plate (102) to guide the residue remaining after juice extraction between the juicing drum (100) and the screw (300) to the residue discharge port (106).

The above waterproof cylinder (103) extends upward from the lower part (102) of the juicing drum (100) and prevents juice, etc. located inside the juicing drum (100) from leaking out through the drum hole (103a).

The screw (300) accommodated inside the juicing drum (100) can be rotatably supported on a guide projection (104) formed on the lower plate (102) of the juicing drum (100), and can be coupled with a driving shaft of a driving body part disposed at the lower part of the juicing drum (100) through the drum hole (103a), thereby receiving driving force from the driving shaft of the driving body part and thereby rotating.

The juice target that is fed into the juice extraction space of the juice extraction drum (100) is crushed and compressed between the screw (300) and the juice extraction drum (100) by the rotation of the screw (300) arranged in the internal juice extraction space of the juice extraction drum (100), and is separated into juice and residue. The juice extracted moves toward the inside of the screw (300) through the gap (G, see FIG. 12) formed on the outer surface of the screw (300), is spatially separated from the residue, and is then discharged to the outside of the juice extraction drum (100) through the juice discharge port (105). The residue remaining on the outside of the screw (300) can be discharged to the outside of the juice extraction drum (100) through the residue discharge port (106).

The above water level indicator (200) includes a visible chamber (210) that extends in the height direction from the outer surface of the juice drum (100) and communicates with the juice discharge port (105) to indicate a water level corresponding to the water level of the juice contained inside the screw (300). At least a portion of the visible chamber (210) can be made of a transparent material so that the water level of the juice stored inside can be visually confirmed.

Specifically, the thorn chamber (210) may be formed in a form that extends in the height direction from the outer surface of the juicing drum (100) and is surrounded by a plurality of walls. In addition, in the drawing of the present embodiment, the thorn chamber (210) is illustrated as being formed integrally with the juicing drum (100), but is not limited thereto, and may be configured to be detachably assembled to the outer surface of the juicing drum (100) as needed.

In addition, a ventilation hole (211) is formed at the top of the thorn chamber (210) to communicate with the outside of the thorn chamber (210) so that the inside of the thorn chamber (210) is not sealed. It is preferable that this ventilation hole (211) be formed so that the inside space of the juicing drum (100) and the thorn chamber (210) communicate with each other.

That is, since the thorn chamber (210) is connected to the internal space of the juicing drum (100) by the ventilation hole (211), even when the pressure in the internal space of the juicing drum (100) increases or decreases while the internal space is sealed, the water level corresponding to the water level of the juice stored inside the screw (300) can be maintained.

The above-mentioned thorn chamber (210) is configured in a form in which the lower part is open for washing, and the opening of the above-mentioned thorn chamber (210) can be configured to be opened and closed using a chamber cover (220).

For example, the chamber cover (220) may be rotatably connected at one end to the juicing drum (100) to open and close the opening of the thorn chamber (210) depending on the rotational position. To this end, a rotational support shaft (221) may be formed at one end of the chamber cover (220), and a rotational coupling part (212) may be formed at one side of the opening of the thorn chamber (210) of the juicing drum (100) to be rotatably connected to the rotational support shaft (221).

At this time, a first packing (222) may be interposed between the inner edge of the chamber cover (220) and the opening edge of the thorn chamber (210). For example, the first packing (222) may be coupled to the inner edge of the chamber cover (220) and may be in close contact with the opening edge of the thorn chamber (210) to secure watertightness. Meanwhile, a packing groove may be formed on the open front edge of the thorn chamber (210) to allow the end of the first packing (222) to be seated, thereby further enhancing the sealing effect.

Meanwhile, although not shown in the drawing, it would be desirable to have a locking part that can fix the position of the chamber cover (220) while the opening of the thorn chamber (210) is closed using the chamber cover (220).

The juice discharge port (105) may be formed in the chamber cover (220), and the juice discharge port (105) may be opened and closed by a juice stopper (230).

Specifically, the juice discharge port (105) is formed through the chamber cover (220) to discharge juice inside the thorn chamber (210) to the external space, and can be extended to a predetermined length to ensure smooth discharge of the juice.

The above juice stopper (230) includes an operating lever (231), a sealing valve (232) that opens and closes the juice discharge port (105) according to the positional movement of the operating lever (231), and a discharge cover (233) that supports the sealing valve (232) and is placed below the juice discharge port (105) when the operating lever (231) is rotated toward the closing side.

Specifically, the operating lever (231) is arranged at the front of the thorn chamber (210), the discharge cover (233) is arranged below the juice discharge port (105), and the operating lever (231) and the sealing valve (232) are formed in a form in which one end is connected to each other. The portion where the operating lever (231) and the discharge cover (233) are connected is rotatably hinged to a hinge portion (223) provided on one side of the juice discharge port (105) of the chamber cover (220) so as to be rotatable to the open side or the closed side, and it is preferable that it is elastically supported to the closed side by an elastic body (not shown).

When the operating lever (231) of the juice stopper (230) is rotated toward the closing side, the discharge cover (233) is in close contact with the lower surface of the chamber cover (220) and further rotation is restricted, so that the closing side rotation position of the juice stopper (230) can be guided.

In addition, a stopper (224) is formed on the chamber cover (220) to which an end of the discharge cover (233) is closely supported when the operating lever (231) is rotated toward the open side. Accordingly, when the operating lever (231) of the juice stopper (230) is rotated toward the open side, the end of the discharge cover (233) is closely contacted by the stopper (224) to limit further rotation, so that the open-side rotation position of the juice stopper (230) can be guided.

As the operating lever (231) of the juice stopper (230) rotates toward the open side, the discharge cover (233) rotates around the hinge part (223) together with the operating lever (231) and is inclinedly positioned at the bottom of the juice discharge port (105). At this time, the discharge cover (233) can perform the function of a guide that guides the discharge direction of the juice discharged through the juice discharge port (105).

In addition, since guide ribs (234) are formed protrudingly on both sides of the surface of the discharge cover (233) facing the chamber cover (220), juice guided through the discharge cover (233) can be prevented from flowing down to both sides of the discharge cover (233).

In addition, the chamber cover (220) is formed with a rib receiving groove (225) into which the guide rib (234) can be inserted when the discharge cover (233) is in close contact with the chamber cover (220). That is, when the juice stopper (230) is rotated toward the closed side, the guide rib (234) of the discharge cover (233) is engaged with the rib receiving groove (225) of the chamber cover (220), so that the position of the discharge cover (233) can be stably maintained.

The juicer of the present embodiment may further include a supply unit (400) capable of cutting and supplying the juice material into small pieces from the upper side of the juice drum (100).

As illustrated in FIG. 7, the supply unit (400) may include a drum cover (401) detachably assembled to the upper side of the juicing drum (100), a hopper housing (402) that supplies juice material into the juicing drum (100) through an opening formed in a plate surface of the drum cover (401) on the upper side of the drum cover (401), a hopper cover (403) that opens and closes the upper opening of the hopper housing (402), a cutting blade (404) that rotates together with the screw (300) inside the hopper housing (402) and cuts the juice material supplied into the hopper housing (402), and a second packing (405) that is arranged on the lower edge of the hopper cover (403) and interposed between the hopper and the juicing drum (100). Here, the opening formed on the plate surface of the drum cover (401) is formed to a size that allows passage of juice material of a size that can be juiced within the juice drum (100).

Accordingly, in the case of having the supply unit (400) as described above, a large lump of juice material can be cut into small pieces by a cutting blade (404) inside the hopper housing (402) and fed into the juice drum (100) through an opening formed in the plate surface of the drum cover (401), so that the user can omit the process of cutting the juice material before feeding it to the juicer, thereby further improving the convenience of use.

The configuration of the screw (300) and the juice drum (100) for squeezing and crushing the juice material is as follows.

A screw thread (330) is formed on the outer surface of the screw (300), and a plurality of rib protrudingly formed on the inner surface of the juice drum (100).

The above screw thread (330) performs the function of moving the juice material downward, and the rib jaw performs the function of providing frictional resistance to the screw (300) to prevent the juice material from rotating together with the screw (300).

The juice material fed into the juice drum (100) through the upper opening of the juice drum (100) is compressed and crushed while moving downward between the inner surface of the juice drum (100) and the outer surface of the screw (300) by the screw thread (330) and the rib jaw.

The juice extracted through squeezing and crushing of the juice material is separated from the residue through a gap (G) formed on the outer surface of the screw (300), stored in the internal storage space (301) of the screw (300), and discharged through a juice discharge port (105) formed on one side of the lower portion of the juicing drum (100), and the residue separated from the juice can be discharged to the outside through a residue discharge port (106) formed on the other side of the lower portion of the juicing drum (100).

Below, the crushing structure of the juice drum (100) and screw (300) will be described in detail.

First, looking at the juicing drum (100), a plurality of first rib jaws (110) can be formed protruding on the inner surface of the juicing drum (100) to press and crush the juicing material.

The first rib jaws (110) are arranged spaced apart from each other along the inner circumference of the juicing drum (100), and each first rib jaw (110) may be formed to extend along the longitudinal direction of the juicing drum (100) or may be formed to extend at a slight angle with respect to the longitudinal direction of the juicing drum (100). It is preferable that the first rib jaws (110) are formed over the entire longitudinal section of the juicing drum (100).

The first rib jaw (110) enables the pressing and crushing of the juice target to be performed more efficiently through interaction with the screw (300). The first rib jaw (110) acts as a kind of catch jaw, increasing the frictional force on the inner surface of the juice drum (100) to smoothly move the juice target, thereby preventing the juice target from stagnating and going down under the juice drum (100).

The first rib jaw (110) also enables a large pressing force and crushing force to be generated for the juicing target. The juicing target can be crushed and crushed by interaction with the rotating screw thread (330) while the juicing target is hung and supported on the first rib jaw (110).

The height at which the first rib jaw (110) protrudes from the inner surface of the juice drum (100) may be constant along the entire length, but may gradually decrease from the upper part to the lower part, or at least one protruding step (not shown) may be formed in the middle of the length direction of the first rib jaw (110). Based on the step, the protruding height of the lower part of the first rib jaw (110) may be lower than the protruding height of the upper part of the first rib jaw (110). The position, number, and protruding height of the step may be variously modified depending on the formation of the screw (300) and the design conditions of the screw thread (330).

Additionally, a plurality of second ribs (120) may be formed on the inner surface of the juice drum (100).

The second rib jaw (120), like the first rib jaw (110), is spaced apart from each other along the inner circumference of the juicing drum (100), and may be formed to extend along the longitudinal direction of the juicing drum (100) or may be formed to extend at a slight angle with respect to the longitudinal direction of the juicing drum (100).

The second rib jaw (120) may be formed with a shorter length than the first rib jaw (110) in a portion of the length of the juicing drum (100), for example, at the lower end of the juicing drum (100).

The second rib jaw (120) enables the compression force and crushing force to be generated together with the first rib jaw (110) for the target for juicing to be large, and the target for juicing, which has been primarily crushed by the first rib jaw (110) at the upper part of the juicing drum (100), is further crushed together with the second rib jaw (120) at the lower part of the space of the juicing drum (100) to crush the target for juicing more finely and evenly.

If the second rib jaw (120) is formed in the middle part of the juicing drum (100) rather than the lower part, the juicing target is finely pulverized in the middle part of the juicing drum (100), and the particle size of the juicing target is rapidly reduced, so that the juicing target does not get caught on the inner surface of the juicing drum (100) at the lower part of the juicing drum (100) and rotates together with the screw (300). In this case, the juicing target is not smoothly transferred to the lower part of the juicing drum (100) and stagnates, so that when additional juicing target is to be added, the juicing target must be forcibly pressed, which is inconvenient. However, if the second rib jaw (120) is formed in the lower part of the juicing drum (100), the particle size of the juicing target is gradually changed, so that the juicing target is smoothly transferred to the lower part of the space of the juicing drum (100), and the juicing target transferred to the lower part of the juicing drum (100) can be further finely pulverized.

In addition, when the second rib jaw (120) is formed at the lower end of the juicing drum (100), the juice target is smoothly transferred from the upper end to the lower end of the juicing drum (100), and the pressure of the juice target residue against the juicing drum (100) and the screw (300) gradually increases, and by this pressure, the juice of the juice target can smoothly flow into the screw (300) through the gap (G) formed between the stopper (313) and the rib (322) of the screw (300) and be discharged to the outside of the juicing drum (100).

The first rib jaw (110) and the second rib jaw (120) do not necessarily have to be formed along the longitudinal direction of the juicing drum (100), and if efficient transport and compression of the juicing target can be achieved, they may be formed in a form that intersects the spiral screw thread (330) formed on the outer surface of the screw (300) with a constant incline in the longitudinal direction of the juicing drum (100).

A number of third rib jaws (130) may be formed on the inner surface of the juice drum (100). The third rib jaws (130) may be formed between the first rib jaws (110) or between the second rib jaws (120).

The third rib jaw (130) can be formed to extend along the length of the juice drum (100) like the first rib jaw (110) or the second rib jaw (120), and is formed to be shorter than the first rib jaw (110) and longer than the second rib jaw (120).

When the third rib jaw (130) is further formed, the number of rib jaws for crushing the juice target increases sequentially from the upper part to the lower part in the length direction of the juicing drum (100). In other words, at the top of the juicing drum (100), the first rib jaw (110) crushes the juice target, at the next height, the first rib jaw (110) and the third rib jaw (130) crush the juice target, and at the next height, the first rib jaw (110), the second rib jaw (120), and the third rib jaw (130) crush the juice target, so that as the juice target is gradually crushed, it can move more smoothly to the lower part of the juicing drum (100).

The length, shape, and inclination angle of the first, second, and third ribs (110, 120, 130) can take appropriately designed values as needed.

The juicer of the present embodiment may further include an inner drum (140) that is detachably assembled inside the juice drum (100), and the first rib jaw (110), the second rib jaw (120), and the third rib jaw (130) may be formed on the inner surface of the inner drum (140).

In this way, when the inner drum (140) is detachably assembled to the juicing drum (100), not only is it easy to clean, but the durability of the product can be further improved by composing the inner drum (140) with a material having excellent wear resistance.

Meanwhile, in this embodiment, the juicing drum (100) is described as additionally equipped with an inner drum (140), but it is also possible to integrally form the first, second, and third rib jaws (110, 120, 130) on the inner surface of the juicing drum (100).

Among the attached drawings, FIGS. 8 and 9 are perspective views of the screw illustrated in FIG. 2, FIGS. 10 and 11 are exploded perspective views of the screw illustrated in FIG. 2, and FIG. 12 is an explanatory drawing regarding a gap formed in the screw of the juicer of the present invention.

The screw (300) may be composed of a first module (310) and a second module (320) having a roughly cylindrical shape.

The first module (310) may be configured to include a first main body (311) formed in a cylindrical shape with a hollow space formed inside. The shape of the first main body (311) will be described in more detail. As illustrated, it is formed in a generally cylindrical shape. The upper part of the first module (310) may be formed in a shape in which the radius gradually decreases as it goes upward.

The lower surface of the first main body (311) is open and the upper surface is closed, and a screw thread (330) may be formed on the outer surface. In addition, a screw wing (330a) may be formed on the outer surface of the upper portion. The screw thread (330) may be formed to protrude in a spiral shape on the outer surface of the first main body (311), and the screw wing (330a) refers to a part of the upper portion of the screw thread (330), and the protrusion height from the upper portion of the screw (300) is large to form a spiral wing. The screw wing (330a) mainly performs the function of cutting the juice material and conveying the juice material downward along the wing surface, and the screw thread (330) with a relatively small protrusion height below the screw wing (330a) mainly performs the function of crushing and compressing the crushed juice material into an even smaller size to extract juice.

The above screw threads (330) can be formed in multiple numbers on the outer surface of the screw (300).

A plurality of slits (312) may be formed in the circumferential direction in the first main body (311). The slits (312) may be formed axially and long in a form extending to the bottom of the first main body (311). A blocking plate (313) is formed between two adjacent slits (312). Accordingly, since a plurality of slits (312) are formed along the circumferential direction, a plurality of blocking plates (313) may also be formed along the circumferential direction. It is preferable that the spacing between the slits (312) is formed at a constant interval, but it is not necessarily limited thereto.

A lower rotation shaft (316) protruding downwards may be formed in the hollow center of the first module (310). The lower rotation shaft (316) may be coupled with a driving shaft (not shown) to transmit power.

In addition, an upper rotation shaft (317) protruding upward may be formed at the top of the first module (310), which may be inserted into an axial hole formed at the bottom surface of the supply unit (400) and rotatably supported, and may be connected to a cutting blade (404) of the supply unit (400).

The second module (320) may be configured to include a second main body (321) and a waste discharge induction unit (326).

The second main body part (321) is cylindrical and inserted into the hollow of the first module (310). Therefore, the second main body part (321) of the second module (320) has a diameter slightly smaller than that of the first main body part (311) of the first module (310).

In the second main body (321), a plurality of ribs (322) may be formed in a long rod shape in the axial direction along the circumferential direction. In addition, in the present embodiment, the ribs (322) may be formed in a shape that protrudes radially outward from the outer surface of the second main body (321), but are not necessarily limited thereto. For example, the ribs (322) may be formed in a shape that is formed between slits (312), such as the blocking plate (313) of the first module (310).

Since the above rib (322) is inserted into the slit (312) of the first module (310), it can be formed to have the same spacing as the slit (312). At this time, the width of the rib (322) can be formed to be slightly smaller than the width of the slit (312).

Between the neighboring ribs (322), a juice passage hole (324) for moving the juice into the screw (300) can be formed. When the juice passage hole (324) is formed large in the space between the neighboring ribs (322), or when the juice passage hole (324) is formed in the entire space between the neighboring ribs (322), the second module (320) can be formed in a shape in which the rib (322) is extended downwardly in a second main body part (321) having a ring shape or a disk shape at the upper end. That is, depending on the shape of the juice passage hole (324), the second main body part (321) can be formed in a cylindrical shape (ring shape) with a short vertical length only at the upper end of the rib (322), or can be formed in a long cylindrical shape including the entire vertical length of the rib (322).

In addition, the lower ends of the plurality of ribs (322) may be formed to be separately supported in a ring shape, but in this embodiment, the lower ends of the ribs (322) are formed in a form that is supported on the upper surface of the waste discharge induction part (326).

The residue discharge guide part (326) is formed in a ring shape under the second main body part (321). The diameter of the residue discharge guide part (326) may be formed slightly larger than the diameter of the second main body part (321), and the inner surface of the lower part may be rotatably supported on the outer surface of the guide protrusion (104) formed on the upper surface of the lower plate part (102) of the juicing drum (100).

An outer surface having a predetermined vertical length is formed on the outer surface of the residue discharge induction unit (326), and a protrusion (327) protruding in the radial direction can be formed on the outer surface. As described below, when the first module (310) and the second module (320) are combined, the residue discharge induction unit (326) forms the lower part of the screw (300), and the residue moved to the lower side of the screw (300) during the juicing process is pushed or stirred by the protrusion (327), so that the residue discharge can proceed smoothly together with the protrusion (328) described below.

If the residue stagnates at the bottom of the screw (300), a large load is applied to the screw (300), which may reduce the extraction efficiency and generate noise and vibration. However, in the present invention, the residue can be discharged more effectively by the protrusion (327).

A plurality of protrusions (327) may be formed along the outer circumferential direction of the waste discharge induction part (326), and may be formed to be inclined up and down in the rotational direction of the screw (300). In addition, they may be formed in a form that extends from the screw thread (330) of the first module (310).

At the lower end of the protrusion (327) extending in a spiral shape, a plurality of protrusions (328) may be formed along the circumferential direction. The protrusions (328) may not be formed by extending from the protrusion (327) but may be formed separately. The protrusions (328) generally have an inverted triangle shape as illustrated, and one side toward the outer circumference of the screw (300) may be formed as an inclined surface. Since the lower end of the residue discharge guide portion (326) is formed to have a smaller radius toward the lower end and to be inclined inward, the protrusion height of the protrusions (328) may be formed to be relatively larger toward the lower end. Since the lower end of the residue discharge guide portion (326) is formed to have an inwardly inclined radius, a space where residue accumulates can be secured relatively larger than the upper end. At this time, the protrusion (328) performs the function of sweeping down the debris accumulated in the space.

On the inner surface of the second module (320), a sweep rib (325) is formed that protrudes radially inwardly and longitudinally to perform the function of stirring the juice inside the screw (300). At this time, as illustrated, the lower end of the sweep rib (325) protrudes toward the bottom surface of the juice drum (100) to prevent the juice from settling, thereby maintaining a fresh taste. The radially outer end of the lower end of the sweep rib (325) can be spaced apart from the inner surface of the second module (320). At this time, by allowing the juice to flow through the spaced space, the juice can be stirred through the sweep rib (325), while minimizing the juice from acting as resistance when the screw (300) rotates.

The first module (310) and the second module (320) can be detachably coupled, and when coupled, as shown in FIG. 8, the rib (322) of the second module (320) is inserted into the slit (312) of the first module (310).

As shown in FIG. 12, the screw (300) of the present invention has a width of the rib (322) that is slightly smaller than the width of the slit (312), so that when the first module (310) and the second module (320) are combined, a gap (G) is formed between the rib (322) and the slit (312). In the present invention, a dregs discharge guide portion (326) having a predetermined upper and lower thickness is formed at the lower portion of the second module (320), so the gap (G) formed by the combination between the slit (312) and the rib (322) may not have a shape that extends to the lower portion of the screw (300), but only to the upper portion of the dregs discharge guide portion (326).

As the screw (300) rotates, the juice of the juice target generated between the outer surface of the screw (300) and the juice drum (100) can move into the screw (300) through the gap (G) and be spatially separated from the residue. That is, the screw (300) can play a role in compressing and crushing the juice target by interaction with the juice drum (100) and at the same time, in separating the juice and the residue, and accordingly, the mesh drum used in the past to separate the juice and the residue can be omitted.

And when the first module (310) and the second module (320) of the screw (300) are combined, the gap (G) formed between the blocking plate (313) and the rib (322) is narrow, but when the first module (310) and the second module (320) are separated, the gap between the blocking plate (313) of the first module (310) and the gap between the rib (322) of the second module (320) is relatively wide enough, so that the screw (300) can be easily cleaned.

When the first module (310) and the second module (320) are combined, the diameter of the residue discharge induction part (326) may be almost the same as the diameter of the first main body part (311) of the first module (310), so that the outer surface may be formed integrally. However, the diameter of the residue discharge induction part (326) may be formed slightly larger than the diameter of the first main body part (311) of the first module (310), so that a small step may be formed on the upper surface of the residue discharge induction part (326).

As illustrated in the enlarged view of Fig. 10, the inner surface of the lower portion of the blocking plate (313) formed between the slits (312) of the first module (310) may be formed in a shape that is slightly bent radially inward. In addition, a catch (329) may be protrudingly formed on the upper surface of the residue discharge induction unit (326) so that the lower portion of the blocking plate (313) is fastened to the outer surface and supported. Therefore, when the lower portion of the blocking plate (313) is fastened to the outer surface of the catch (329), a radial elastic force is applied due to the slightly bent shape of the lower portion of the blocking plate (313), which increases the frictional force between the lower portion of the blocking plate (313) and the catch (329). Therefore, it is possible to prevent the second module (320) from being easily disengaged by falling off from the first module (310) due to its own weight.

Although not shown, a magnet (not shown) may be placed inside the upper surface of the second main body (321) of the second module (320), and a magnet or magnetic body having a polarity opposite to that of the magnet placed in the second module (320) may be placed inside the upper surface of the first main body (311) of the first module (310). In this case, when the first module (310) and the second module (320) are combined, they are not easily separated due to magnetic force, so that the first module (310) and the second module (320) can be stably combined and maintained.

At least one spiral screw thread (330) may be formed on the outer surface of at least one of the first module (310) and the second module (320).

The screw thread (330) forms a kind of roughness on the outer surface of the screw (300) so that when the screw (300) rotates, the crushing, pressing, and filtering processes for the juice target can occur more effectively between the screw (300) and the juice drum (100), and the juice target can move smoothly to the lower part of the juice drum (100).

As described above, the screw thread (330) may be formed in a continuous spiral shape from the screw wing portion (330a). Alternatively, it may be formed in a straight line shape intersecting the axial direction of the screw (300).

The screw threads (330) are preferably formed on both the outer surfaces of the first module (310) and the second module (320) (more specifically, the outer surfaces of the ribs (322)), and when the first module (310) and the second module (320) are coupled, the screw threads (330) can be formed in a continuous shape on the outer surfaces of the first module (310) and the second module (320).

The fact that the screw threads (330) are formed continuously on the outer surfaces of the first module (310) and the second module (320) does not mean that the screw threads (330) are physically connected on the outer surfaces of the first module (310) and the second module (320), but rather that they have a generally continuous shape. Accordingly, the screw threads (330) may be partially disconnected at the adjacent portion of the blocking plate (313) and the rib (322).

The screw thread (330) can be formed so that the height at which the screw thread (330) protrudes from the blocking plate (313) and the rib (322) is almost the same so that the screw thread (330) can have a shape that is as continuous as possible on the outer surfaces of the first module (310) and the second module (320).

At this time, it is preferable that the protrusion (327) of the residue discharge induction part (326) be formed to protrude more in the radial direction than the screw thread (330) formed at the lower end of the screw (300).

The gap (G) between the slit (312) and the rib (322) can be formed to become wider as it goes radially inward of the screw (300), as shown in FIG. 12.

When the gap (G) is formed to become wider as it goes radially inward of the screw (300), the problem of the gap (G) being blocked by residue or the flow of juice being obstructed during the juicing process can be prevented.

For example, as in Fig. 12, if the width of the blocking plate (313) is formed to become narrower as it goes radially inward of the screw (300), when the rib (322) is inserted into the slit (312), the gap (G) formed between the slit (312) and the rib (322) becomes larger as it goes radially inward of the screw (300).

Unlike the above example of adjusting the width of the blocking plate (313), it is also possible to form the gap (G) to become wider toward the radial inward direction of the screw (300) by adjusting the shape of the rib (322) or adjusting the shapes of the rib (322) and the blocking plate (313) together.

Additionally, the gap (G) can be formed to become narrower as it goes toward the longitudinal lower portion of the screw (300).

Since the crushed residue is driven to the lower part of the juicing drum (100), a relatively greater pressure is applied to the lower part of the screw (300), and the juice target is crushed more as it goes to the lower part of the juicing drum (100), so the size of the crushed particles becomes smaller, and thus the possibility of the residue flowing into the screw (300) through the gap (G) at the lower part of the screw (300) increases.

Accordingly, by forming the gap (G) narrower toward the lower end of the length of the screw (300), the juice extraction efficiency can be improved by preventing the residue of the juice extraction target from flowing into the screw (300).

When a gap (G) that becomes narrower toward the bottom longitudinal portion of the screw (300) is applied, for example, in the case of a hard juice target such as a carrot, most of the juice flows into the screw (300) through the gap (G) at the bottom portion of the screw (300) during the squeezing process. In addition, in the case of a soft juice target such as a tomato, the juice target collected in the gap (G) at the bottom portion of the screw (300) rises to the gap (G) at the top portion during the squeezing process, causing the juice to flow into the screw (300).

The gap (G) may be formed to gradually narrow from the upper part to the lower part of the screw (300), or may be formed to gradually change by making the gap (G) above a certain point wider and the gap (G) below it narrower based on a certain point.

The shape of the gap (G) in the longitudinal direction of the screw (300) can be changed by adjusting the shape of at least one of the blocking plate (313) and the rib (322).

As illustrated in FIG. 11, a first gap (G)-maintaining step (313b) may be formed protruding on the upper side of the blocking plate (313), and as illustrated in FIG. 10, a second gap (G)-maintaining step (322b) may be formed protruding on the lower side of the rib (322).

The size of the gap (G) between the blocking plate (313) and the rib (322) can change depending on the rotational force generated when the screw (300) rotates at high speed during juicing or the pressure applied to the outer surface of the screw (300) by the juice target. The first gap (G)-maintaining step (313b) and the second gap (G)-maintaining step (322b) serve to maintain the size of the gap (G) formed between the blocking plate (313) and the rib (322) constant during the juicing process.

Below, the operation of the water level display unit (200) of the present invention is described.

Among the attached drawings, FIG. 13 is a cross-sectional view showing the function of a thorn chamber according to the juicer of the present invention, FIGS. 14 and 15 are drawings showing the function of a juice stopper according to the juicer of the present invention, and FIG. 16 is a drawing showing the function of a chamber cover according to the juicer of the present invention.

First, as illustrated in FIG. 13, juice separated from the residue located between the juicing drum (100) and the screw (300) flows into the receiving space (301) inside the screw (300) through the gap (G, see FIG. 12) of the screw (300). Since the juice discharge port (105) is closed by the juice stopper (230), the juice is not discharged outside the juicing drum (100), and as the juicing progresses, the water level of the juice extracted and stored in the receiving space (301) rises.

At this time, the juice stored in the receiving space (301) of the screw (300) cannot escape to the external space of the screw (300) through the gap (G) of the screw (300) because the residue located between the inner surface of the juicing drum (100) and the outer surface of the screw (300) is compressed under a large pressure within the narrow space.

In addition, the residue discharge guide part (326) located at the lower end of the screw (300) is supported on the outer surface of the guide protrusion (104) formed on the lower plate (102) of the juicing drum (100) with the inner surface thereof. As the residue is compressed between the outer surface of the residue discharge guide part (326) and the juicing drum (100), the inner surface of the residue discharge guide part (326) and the outer surface of the guide protrusion (104) are strongly pressed against each other, so that the juice stored in the receiving space (301) may not escape out of the screw (300) through the joint surface between the screw (300) and the guide protrusion (104).

As described above, the juice stored in the receiving space (301) inside the screw (300) cannot be directly checked during the juicing process because residue is located between the juicing drum (100) and the screw (300) even if the juicing drum (100) and the screw (300) are made of a transparent material. Accordingly, in the present embodiment, a visible chamber (210) communicating with the receiving space (301) inside the screw (300) is formed on the outer surface of the juicing drum (100), and at least a portion of the visible chamber (210) is made of a transparent material, so that even in a situation where the juicing drum (100) and the screw (300) are made of an opaque material or residue is located between the juicing drum (100) and the screw (300), making it impossible to secure a view, the water level of the extracted juice can be easily checked from the outside of the juicing drum (100).

Since the lower part of this thorn chamber (210) is connected to the receiving space (301) through the juice discharge hole (105a), the juice stored in the receiving space (301) inside the screw (300) can move to the thorn chamber (210) through the juice discharge hole (105a).

In addition, since the thorn chamber (210) is connected to the internal space of the juicing drum (100) through the ventilation hole (211), even when the internal pressure increases or decreases while the internal space of the juicing drum (100) is sealed, the water level corresponding to the water level of the juice stored in the receiving space (301) can be maintained.

The lower opening of the above-mentioned thorn chamber (210) is closed by a chamber cover (220), and a juice discharge port (105) capable of discharging juice is formed in the chamber cover (220), and the juice discharge port (105) can be opened and closed by a juice stopper (230) that is rotatably supported on the chamber cover (220).

When the above juice stopper (230) is rotated toward the closed side around the hinge (223), the sealing valve (232) provided in the juice stopper (230) seals the juice discharge port (105), thereby preventing the juice stored in the storage space (301) inside the screw (300) from leaking out to the outside through the juice discharge port (105).

In this state, when the lever (231) of the juice stopper (230) is pulled downward as shown in FIG. 14, the juice stopper (230) rotates toward the open side centered on the hinge (223), and accordingly, the discharge cover (233) rotates together with the lever (231) and is separated from the lower side of the juice discharge port (105), thereby opening the juice discharge port (105) as the sealing valve (232) supported on the discharge cover (233) is separated from the juice discharge port (105).

That is, the user can store a desired amount of juice in the juice drum (100) by closing the juice outlet (105) through the juice stopper (230), and, if necessary, open the juice outlet (105) to extract the juice stored in the receiving space (301) of the screw (300) to the outside for drinking.

Here, when the juice stopper (230) that rotates around the hinge (223) is in a state where the juice discharge port (105) is closed as shown in (a) of FIG. 15, i.e., rotated toward the closed side, the discharge cover (233) is in close contact with the lower surface of the chamber cover (220) and thus further rotation is restricted, so that the closed-side rotation position of the juice stopper (230) can be guided. In addition, when the juice stopper (230) is in a state where the juice discharge port (105) is opened as shown in (b) of FIG. 15, the open-side rotation position of the juice stopper (230) can be guided as one end of the discharge cover (233) is in close contact with the stopper (224) provided on the chamber cover (220) and further rotation is restricted.

The chamber cover (220) that closes the lower opening of the thorn chamber (210) is configured to be able to open and close the thorn chamber (210) for ease of cleaning. Accordingly, as shown in FIG. 16, the thorn chamber (210) can be rotated around the rotation support shaft (221) to be separated from the lower opening of the thorn chamber (210), thereby opening the lower opening of the thorn chamber (210), and accordingly, the inside of the thorn chamber (210) and the inner surface of the chamber cover (220) can be easily cleaned.

In addition, since the screw (300) is detachable from the juicing drum (100), and the first module (310) and the second module (320) constituting the screw (300) are also detachable, the residue caught in the gap (G) between the screw (300) and the juicing drum (100) and between the first module (310) and the second module (320) can be easily washed.

Among the attached drawings, FIGS. 17 and 18 are exploded perspective views of a juicer according to a second embodiment of the present invention, FIGS. 19 and 20 are cross-sectional views showing the opening and closing state of a juicer cap according to a second embodiment of the present invention, and FIG. 21 is a diagram showing the opening and closing operation of a juicer cap according to a second embodiment of the present invention.

The juicer according to the second embodiment of the present invention, as shown in the drawing above, differs from the first embodiment in that the juice stopper (230') for opening and closing the juice discharge port (105) is configured in a sliding manner, unlike the rotating manner of the first embodiment.

Specifically, the juice plug part (230') includes a discharge cover (233') that is movably supported with respect to the chamber cover (220') so that the discharge port (236) formed on the plate surface selectively communicates with the juice discharge port (105).

That is, when the discharge port (236) formed on the surface of the discharge cover (233') is located below the juice discharge port (105) and communicates with the juice discharge port (105), juice can be discharged through the juice discharge port (105) and the discharge port (236).

In addition, when the plate surface of the discharge cover (233') closes the lower part of the juice discharge port (105), the discharge of juice through the juice discharge port (105) can be restricted.

To this end, it is preferable that the upper surface of the discharge cover (233') facing the chamber cover (220') and the lower surface of the chamber cover (220') where the juice discharge port (105) is formed are kept in close contact with each other while the discharge cover (233') is assembled to the chamber cover (220'). In addition, when the discharge cover (233') is moved to a position where the juice discharge port (105) is closed, it may be possible to place a sealing valve capable of sealing the juice discharge port (105) at a position corresponding to the juice discharge port (105) of the discharge cover (233').

On both sides of the chamber cover (220'), a pair of rail grooves (225) are formed in a direction parallel to the direction of movement of the discharge cover (233'), and on both sides of the discharge cover (233'), a slide projection (235) that can slide within the rail grooves (225) is formed.

That is, as shown in FIG. 19, when a user pushes in the discharge cover (233'), the discharge port (236) formed on the surface of the discharge cover (220') is misaligned with the juice discharge port (105), and the surface of the discharge cover (233') can close the juice discharge port (105), and as shown in FIG. 20, when the discharge cover (233') is pulled, the discharge port (236) formed on the surface of the discharge cover (233') is communicated with the juice discharge port (105), and the juice discharge port (105) can be opened.

Here, as in (a) of FIG. 19 and FIG. 21, when the user pushes the discharge cover (233') so that the discharge port (236) is completely removed from the juice discharge port (105), the slide projection (235) of the discharge cover (233') is supported by one end of the rail groove (225) to limit further movement, and as in (b) of FIG. 20 and FIG. 21, when the user pulls the discharge cover (233') so that the discharge port (236) is in communication with the juice discharge port (105), the slide projection (235) of the discharge cover (233') is supported by the other end of the rail groove (225) to limit further movement.

When the discharge cover (233') is slid as described above to open the juice discharge port (105), the area of communication between the discharge port (236) and the juice discharge port (105) gradually increases as the discharge cover (233') moves toward the open side, thereby preventing the juice stored in the juicer from being suddenly discharged.

The scope of the present invention is not limited to the above-described embodiments, but can be implemented in various forms of embodiments within the scope of the attached utility model registration claims. It is deemed that the scope of the claims of the present invention is within the scope of the description of the claims of the present invention to the extent that anyone with ordinary knowledge in the technical field to which the present invention belongs can make modifications without departing from the gist of the present invention claimed in the utility model registration claims.

100: Juicing drum, 101: Side wall, 102: Bottom plate,
103: Waterproof cylinder, 103a: Drum hole, 104: Guide jaw,
105: juice discharge port, 105a: juice discharge hole, 106: residue discharge port,
106a: waste discharge hole, 110: first rib jaw, 120: second rib jaw,
130: 3rd rib jaw, 140: inner drum, 200: water level indicator,
210: thorn chamber, 211: ventilation hole, 212: rotary joint,
220,220':Chamber cover, 221:Rotating support shaft, 222:First packing,
223: Hinge, 224: Stopper, 225: Rail home,
230,230': juice stopper, 231: lever, 232: sealing valve,
233,233': exhaust cover, 234: guide rib, 235: slide projection,
236: outlet, 300: screw, 301: receiving space,
310: 1st module, 311: main body, 312: slit,
313:Shield plate, 316:Lower rotation axis, 317:Upper rotation axis,
320:2nd module, 321:main body, 322:rib,
324: Juice passage hole, 326: Dregs discharge induction part, 325: Sweep rib,
327:Protrusion, 328:Protrusion, 329:Hanging bracket,
330: Screw thread, 330a: Screw wing, G: Gap,
400: Supply section, 401: Drum cover, 402: Hopper housing,
403: Hopper cover, 404: Cutting blade, 405: Second packing

Claims (15)

A juice drum having a juice discharge port for discharging juice extracted from juice ingredients and a residue discharge port for discharging residue;
A screw which is arranged inside the juicing drum and rotates to crush and press the juice material fed into the juicing drum between itself and the juicing drum, has a receiving space provided inside that communicates with the juice discharge port, and has a gap formed on the outer surface that spatially separates the juice extracted from the juicing material from the residue and moves it to the receiving space; and
It includes a water level indicator that extends in the height direction from the outer surface of the juicing drum and communicates with the juice discharge port to visually provide a water level corresponding to the water level of the juice stored in the receiving space of the screw;
The above water level indicator is a juicer including a visible chamber having an opening formed at the bottom and a chamber cover that opens and closes the opening. In paragraph 1,
A juicer including a visible chamber at least partially made of a transparent material so that the water level indicator can visually check the water level of the juice stored inside. In paragraph 1,
A juicer in which one end of the chamber cover is rotatably hinged to the juicing drum. In the third paragraph,
A juicer in which a rotation support shaft is formed on one side of the chamber cover, and a rotation joint is formed on one side of the opening of the thorn chamber to which the rotation support shaft is rotatably coupled. In the third paragraph,
A juicer wherein the water level indicator further includes a first packing interposed between the inner edge of the chamber cover and the edge of the opening of the thorn chamber. In the second paragraph,
A juicer in which a ventilation hole is formed at the top of the thorn chamber to communicate with the outside of the thorn chamber. In paragraph 6,
A juicer in which the above ventilation holes are formed so that the thorn chamber communicates with the internal space of the juicing drum. In the third paragraph,
A juice extractor in which the juice outlet is formed in the chamber cover and the juice outlet is opened and closed by a juice stopper. In Article 8,
A juicer comprising an operating lever that is rotatably hinged to the chamber cover and a sealing valve that is connected to the operating lever and opens and closes the juice discharge port according to the rotational position of the operating lever. In Article 9,
A juicer including a discharge cover that supports the sealing valve and can be brought into close contact with the chamber cover while the operating lever is rotated toward the closing side. In Article 10,
A juicer including a stopper that restricts further rotation of the discharge cover by contacting the end of the discharge cover with the chamber cover while the operating lever is rotated toward the open side. In Article 10,
A juicer in which guide ribs for guiding the discharge of juice are formed protruding on both sides of the surface of the discharge cover facing the chamber cover. In Article 8,
A juice extractor comprising a discharge cover having a discharge port formed on a plate surface and movably supported with respect to the chamber cover so that the discharge port selectively communicates with a juice discharge port. In Article 13,
A juicer in which the chamber cover includes a rail groove formed along the direction of movement of the discharge cover, and the discharge cover includes a slide projection that engages with the rail groove so as to be able to slide within the rail groove. In Article 14,
A juicer in which the above rail home is set to limit further movement of the sliding projection when the discharge port of the chamber cover is in communication with the juice discharge port, and to limit further movement of the sliding projection when the discharge port is completely removed from the juice discharge port.

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