KR200490466Y1 - Juicer - Google Patents

Abstract

The present invention relates to a juicer.
The juicer according to the embodiment of the present invention is a first module in which a plurality of first slits are formed by a plurality of rods on an outer circumferential surface, and a second module in which a plurality of first ribs are inserted into the first slits of the first module And a plurality of second slits formed of a through-hole having two side surfaces, an upper surface and a lower surface formed along the inner circumferential surface, and having a separating screw comprising a hollow cylinder having an upper portion open to receive the separating screw. An inner module having an inner rib rib protruding at regular intervals, and a second rib including an upper surface and a lower surface protruding from an inner circumferential surface thereof with an upper portion opened to be detachable from the inner module, Juice drum including a drum housing is formed spaced apart from the juice discharge port is discharged from the discharge discharge the residue The first module and the second module is detachably coupled, and when the second module is inserted into and coupled to the first module, the first rib of the second module is connected to the first module. A gap is formed between the rib of the second module and the first slit of the first module by being inserted into the first slit, and when the drum housing surrounds and couples the inner module, the second rib of the drum housing is A gap may be formed between the second slit side of the inner module and the second rib side of the drum housing by being inserted into the second slit of the inner module.

Description

Juicer {JUICER}

The present invention relates to a vertical slow juicer, and more particularly, to a juicer to which a two-module juice drum is applied.

In recent years, as the interest in health increases, the frequency of use of a juicer having a function of directly extracting juice from a juice target such as vegetables, grains, and fruits, and ingesting the same is increasing.

The general operation of such a juicer is, as disclosed in the Republic of Korea Patent No. 793852, for example, by pressing the juice object on the grater using the principle of grinding the mill to squeeze the juice.

To this end, the juicer comprises a drive unit that provides rotational force, a drum housing having a drive shaft that receives the rotational force from the drive unit, a screw that is connected to the drive shaft and screwed and pulverized the juice object by a screw spiral formed on a portion thereof, and a screw. A juice drum is provided for separating the juice made by. The drive unit for providing rotational force to the juicer includes a motor and a reducer. The motor is connected to the drive shaft to transmit rotational force to the screw. For this purpose, the drive shaft is connected to the screw through the lower part of the drum housing.

In general, the juice drum has a mesh structure consisting of a net. In the case of a juice drum having a mesh structure, there is a problem that the juice efficiency is low because it is easily blocked by the residue of the juice object in the juice process. In addition, since the mesh is densely formed, there is a problem that it is difficult to clean the residue of the juice object stuck on the mesh. In addition, various filter structures can be assumed, but it is difficult to apply to a juicer of the compression method using a screw, such as performing a simple filtration function.

In addition, in relation to the waste discharge control device, in the conventional juicer structure, a bottom ring is formed to ensure sufficient juice time of the juice material so that the ground dust is not moved directly to the discharge groove, and the waste material is discharged according to the juice material. There was a lot of demand for waste emission control from consumers.

In addition, the side of the conventional drum drum was formed to form a fine circular net hole to discharge the juice generated inside the drum drum to the outside. However, if the debris stuck in the mangong is not cleanly cleaned, the debris may decay and bacteria may propagate. In the conventional mandrel structure, it is difficult to clean the debris stuck in the manhole.

The juice drum according to an embodiment of the present invention is to solve the problems as described above, but the washing drum is composed of two modules but can be applied to the juicer of the crimping method, but can be easily washed and improve the juice efficiency. It is an object to provide a juice drum.

In addition, the juice drum assembly according to an embodiment of the present invention was devised to solve the problems as described above, by configuring the screw into two modules, the screw performs the function of the conventional mandrel and easy to clean the separation screw Its purpose is to provide.

In addition, the juice drum according to an embodiment of the present invention is devised to solve the problems as described above and maximize the juice efficiency, to provide a juice drum consisting of two modules of juice drum and applying a screw as a separate screw For that purpose.

The juicer according to the embodiment of the present invention is a first module in which a plurality of first slits are formed by a plurality of rods on the outer circumferential surface, and a second module in which a plurality of first ribs are inserted into the first slits of the first module. And a plurality of second slits formed of a through-hole having two side surfaces, an upper surface and a lower surface formed along the inner circumferential surface, and having a separating screw comprising a hollow cylinder having an upper portion open to receive the separating screw. An inner module having an inner rib rib protruding at regular intervals, and a second rib including an upper surface and a lower surface protruding from an inner circumferential surface thereof with an upper portion opened to be detachable from the inner module, Juice drum including a drum housing is formed spaced apart from the juice discharge port is discharged from the discharge discharge the residue The first module and the second module is detachably coupled, and when the second module is inserted into and coupled to the first module, the first rib of the second module is connected to the first module. A gap is formed between the rib of the second module and the first slit of the first module by being inserted into the first slit, and when the drum housing surrounds and couples the inner module, the second rib of the drum housing is A gap may be formed between the second slit side of the inner module and the second rib side of the drum housing by being inserted into the second slit of the inner module.

At least one first spiral protrusion is formed on an outer circumferential surface of the rod of the first module, at least one or more second spiral protrusions are formed on at least one of the plurality of ribs of the second module, and the second module When inserted into and coupled to the first module, the first spiral protrusion and the second spiral protrusion may form a continuous screw spiral.

The lower portion of the second module may be open and the upper portion may be blocked.

A screw shaft may be formed at an inner center of the first module, and a shaft through hole having a shape corresponding to the screw shaft may be formed at an upper surface of the second module to fit the screw shaft.

A key protrusion may be formed on an inner upper surface of the first module, and a key groove into which the key protrusion is inserted may be formed on an outer upper surface of the second module.

A magnet accommodating part in which a magnet is disposed may be formed on an upper surface of the second module, and a magnet or magnetic material having a polarity opposite to that of the magnet disposed in the magnet accommodating part may be disposed inside the first module.

The width of the rod of the first module may be narrower toward the radially inner side of the first module.

A juice discharge hole is formed at a lower side of the plurality of screw grooves formed between the plurality of ribs of the second module, and the bottom surface of the drum housing communicates with the juice discharge hole at a radially outer side around the shaft hole. Juice discharge groove is formed, the juice discharge groove may be in communication with the juice outlet.

Some juice juiced by the interaction of the separation screw and the inner module is moved into the separation screw through a gap between the rod and the first slit and discharged to the juice outlet through the juice discharge groove. The remaining juice may be moved to the lower portion of the inner module and the drum housing through a gap between the second rib and the second slit and discharged to the juice outlet through the juice discharge groove.

A first step may be formed at a lower end of the bar of the first module, and a second step corresponding to the first step may be formed at a bottom of the rib of the second module.

The rib jaw may be formed adjacent to an upstream side edge of the second slit formed in the inner module based on the rotation direction of the separation screw.

The juicer according to an embodiment of the present invention further includes a first stepped portion formed below the outer circumferential surface of the inner module, and a second stepped portion formed below the rib of the drum housing, wherein the first stepped portion is the second stepped portion. It can be seated and supported on the step.

The inner module is formed with a waste discharge hole, the waste discharge hole may be combined with a waste discharge regulator.

The residue discharge hole may be formed in the fitting portion formed on the outer circumferential surface of the inner module.

An insertion groove may be formed on the inner circumferential surface of the drum housing to fit the fitting portion.

The waste discharge regulator may be hinged to the fitting portion to selectively open and close the waste discharge hole.

The waste discharge regulator can be opened and closed selectively by rotating the residue discharge hole in the vertical direction on the outer peripheral surface of the inner module.

The residue discharge hole may be formed in a flange formed on the lower end of the inner module.

The waste discharge regulator may be hinged to the flange of the inner module to selectively open and close the waste discharge hole.

The residue discharge controller may be selectively opened and closed by rotating the residue discharge hole to the bottom of the inner module.

The residue discharge regulator may be composed of an elastic member.

The lower ring formed at the lower end of the screw may be supported by a guide groove formed on the upper surface of the flange formed at the lower end of the inner module.

Juicer according to an embodiment of the present invention may further include a main body portion including a drive shaft which is inserted into the shaft hole formed on the bottom surface of the drum housing to transfer power to the separation screw.

In addition, at least one or more of the respective solutions devised in the above can be applied to devise a juicer.

According to the embodiments of the present invention as described above and the juice drum to which the common technical concept is applied, the juice drum is configured to combine the two modules, so that the two modules can be easily assembled and disassembled. The drum is easy to manufacture and easy to clean.

In addition, according to embodiments of the present invention to facilitate the transfer of the material by the screw in the pressing process, to increase the juice rate through the fine grinding and pressing of the material, it is possible to facilitate the input of the material.

In addition, according to the embodiments of the present invention by preventing the problem of the residue is caught in the juice drum through the first rib tuck and the inclined portion formed in the first slit during the juice process to prevent the problem of the juice to prevent the juice flow This may improve the juice efficiency.

In addition, according to embodiments of the present invention, by forming the juice drum with a hard material it can prevent the deformation of the juice drum in the juice process. Accordingly, the slit can be prevented from opening and the interval between the slits from which the juice is discharged can be kept constant.

In addition, according to the embodiments of the present invention, by combining the two modules through the coupling of the coupling protrusion and the coupling groove, and the combination of the key protrusion and the key groove, it is possible to accurately fix the combined position of the two modules, in the juice process Relative rotation and tilting between the two modules can be prevented from occurring.

In addition, instead of the crushing method by the blade rotating at a high speed, the screw rotates at a low speed and forms a juice by squeezing and crushing the material, there is also an advantage that can utilize the inherent taste and nutrition of the material.

In addition, since the housing and the screw of the juice juicer are vertically assembled to the upper side of the driving part, the material naturally descends by gravity and the rotation of the screw, so that the juice speed is high and there is no juice pooling phenomenon, so any kind of vegetable or fruit It can also be juiced.

In addition, according to the juice dreg automatic discharge controller according to an embodiment of the present invention, the juice dregs can be automatically discharged naturally according to the juice pressure can improve the juice efficiency, it can be made smoothly discharge of the dregs.

In addition, the effects that can be obtained or predicted by the embodiments of the present invention will be disclosed directly or implicitly in the detailed description of the embodiments of the present invention. That is, various effects predicted according to embodiments of the present invention will be disclosed in the following detailed description.

Since these drawings are for reference in describing exemplary embodiments of the present invention, the technical spirit of the present invention should not be construed as being limited to the accompanying drawings.
1A and 1B are perspective views of a juicer according to an embodiment of the present invention.
2a and 2b is an exploded perspective view of a juicer according to an embodiment of the present invention.
Figure 3 is a perspective view showing a cross-section partially cut in the drum housing, the juice drum and the separating screw according to an embodiment of the juice drum of the present invention.
4A and 4B are exploded perspective views of a juice drum according to an embodiment of the present invention.
5a and 5b is an exploded perspective view of the separation screw according to an embodiment of the juice drum of the present invention.
6 is a partial cross-sectional view of a drum housing assembly according to one embodiment of the juice drum of the present invention.
7 is an exploded perspective view of a juicer according to various embodiments to which an automatic waste discharger of the present invention is applied.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. The disclosure of the present specification is intended to describe in detail enough that a person skilled in the art to which the present invention pertains can easily carry out the present invention, and thus the technical spirit and scope of the present invention are defined herein. It is not meant to be limited to the disclosed embodiments or the description thereof.

In addition, since each configuration shown in the drawings are arbitrarily shown for convenience of description, the present invention is not necessarily limited to those shown in the drawings, the size or shape of the components shown in the drawings are exaggerated for clarity and convenience of description. Can be shown. Therefore, terms that are specially defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator, and the definition of these terms should be made based on the contents throughout the present specification.

In this specification, unless specifically stated otherwise, the term 'top', 'top', 'top' or similar term refers to the side or stage close to or to which the material is injected, 'bottom', 'bottom', 'Bottom' or similar term is used to refer to the part or stage opposite or near the side to which the material is introduced.

Hereinafter, a juice drum according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1a is an embodiment of the side-driven juicer to which the juice drum according to the present invention can be applied, the juicer may include a body portion 1, the hopper 100, the drum housing 200.

The main body part 1 may include an upper support part 2, a lower support part 3, and a speed reducer accommodation part 4. A drive motor for generating a driving force and a speed reducer (not shown) for transmitting the driving force to the drive shaft 6 may be disposed in the main body 1.

The upper support part 2 may be formed in a shape corresponding to a portion of the outer circumferential surface of the drum housing 200 to support the side of the drum housing 200.

The lower support part 3 extends in the downward direction of the drum housing 200 from the lower part of the main body part 1 and may be formed in a plate shape. On the lower support 3, a residue cup (not shown) may be disposed to contain the residue.

The reducer accommodating part 4 extends laterally toward the drum housing 200 from the center of the main body part 1, and the reducer may be disposed therein. The reducer accommodating portion 4 may be formed in a shape corresponding to the lower surface of the drum housing 200 so as to seat the drum housing 200 thereon.

Next, as shown in Figure 1b, the downward driven juicer according to another embodiment of the present invention is generally the same as the embodiment of the juicer shown in Figure 1a described above, but the juice drum 400 is the main body ( There is a difference in that the drive shaft 6 of the drive motor 5 seated on the top of 1) can transmit power to the screw 300 on the same axis.

The main body part 1 may include an upper support part 2 and a lower support part 3. A drive motor for generating a driving force and a speed reducer (not shown) for transmitting the driving force to the drive shaft 6 may be disposed in the main body 1.

The upper support part 2 may be formed in a shape corresponding to a portion of the lower surface of the drum housing 200 in order to connect the drive shaft 6 to the screw 300 while receiving the drum housing 200 thereon. Furthermore, the drive shaft 6 is configured to be connected to the shaft of the screw 300 through a hole penetrated in the center of the drum housing 200.

The lower support part 3 extends in the juice outlet direction from the lower part of the main body part 1 and may be formed in a plate shape (in FIG. 1C, the direction of the lower support part 3 is not represented to extend in the juice outlet direction correctly. Did). A juice cup (not shown) may be disposed on the lower support part 3 to contain juice.

As will be described later, the driving motor (not shown) of the main body part 1 of the present invention shown in FIGS. 1A and 1B transmits power to the screw 300 through a driving shaft (not shown). The drive motor includes a reducer (not shown), and the reducer decelerates the rotational speed (about 1800 rpm) of the drive motor so that the screw 300 rotates at a low speed (about 80 rpm or less). This makes it possible to juice without destroying nutrients. Usually, a juicer having such a batch structure is called a vertical slow juicer.

2a and 2b is an exploded perspective view of a configuration in which the main body portion is excluded from the juicer according to the embodiment shown in Figures 1a and 1b of the present invention to be described later. As shown in Figures 2a and 2b, the hopper 100 is capable of injecting the juice object (for example, vegetables, grains, fruits, etc.) into the inside, the juice object is added to the juice drum 400 To guide.

As shown in Figure 2a and 2b, juicer according to an embodiment of the present invention includes a hopper 100, a drum housing 200, a separation screw 300, and a juice drum 400.

The hopper 100 is a cover for closing the upper side of the juice space where the juice proceeds in the juicer. In addition, the hopper 100 is formed with an injection hole 102 perforated in the vertical direction from the upper end to the lower end so that the juice object can be injected into the juice space.

The drum housing 200 may be formed in a hollow cylindrical shape closed downward to surround the juice space. That is, the hollow of the drum housing 200 becomes the juice space. In addition, the upper side of the drum housing 200 is opened to receive the juice object injected into the injection hole 102 of the hopper 100. Furthermore, the upper circumferential portion of the drum housing 200 and the lower circumferential portion of the hopper 100 are formed in a corresponding shape such that the upper end of the drum housing 200 and the lower end of the hopper 100 are detachably coupled to each other. do.

The juice drum 400 includes a drum housing 200, an outer module 401 and an inner module 402. The drum housing 200 replaces the outer module 401 of the juice drum 400. That is, the outer module 401 is integrally formed on the inner surface surrounding the hollow of the drum housing 200, so that the drum housing 200 functions as the outer module 401 of the juice drum 400. On the other hand, the lower end of the center of the drum housing 200 is closed is formed a shaft hole 260 perforated from the bottom surface of the drum housing 200 to the bottom surface of the drum housing 200.

The inner module 402 is formed in a hollow cylindrical shape to be inserted into the drum housing 200. That is, the drum housing 200 is configured to surround the inner module 402. Here, the upper surface of the inner module 402 is opened to receive the juice object injected into the input hole 102 of the hopper 100, the lower surface is opened to secure a space for the separation screw 300 and the drive shaft connected do.

The separating screw 300 is formed in a cylindrical shape including a rotating blade 305 of the screw shape on the top, it is disposed in the hollow of the inner module 402. Here, the inner module 402 and the separation screw 300 may be designed in the shape of a truncated cone narrowing downwards in consideration of the efficiency of pressing or crushing the juice object by the interaction. On the other hand, the shaft hole 260 accommodates a drive shaft 6 connected to a motor (not shown) that is a power source. Accordingly, the drive shaft and the separation screw 300 is connected, the separation screw 300 may receive a rotational force from the drive shaft. In other words, the separation screw 300 is configured to be rotatable by receiving rotational force from the drive shaft, and compress or crush the juice object between the inner module 402. To this end, a screw shaft 312 is formed in the separating screw 300, the upper portion of the drive shaft is coupled to transmit power to the screw shaft 312. In addition, the inner circumferential surface of the shaft hole 260 may have a shape corresponding to engage with the non-rotating support portion of the drive shaft.

At least one first spiral protrusion 310 is formed on an outer circumferential surface of the separation screw 300 to spirally extend along the outer circumference to contact the inner circumferential surface of the inner module 402. The juice object is transferred to the lower side by the first spiral protrusion 310, and the separation screw 300 and the inner module 402 are disposed in a narrow gap between the separating screw 300 and the inner module 402. By this, the juice object is compressed to perform the juice. For this compression and juice efficiency, the vertical gap of the first spiral protrusion 310 extending in a spiral along the outer circumference of the separation screw 300 may be narrower than the upper portion from the lower portion.

On the other hand, the juice outlet 220 and the residue outlet 230 is formed on the lower outer peripheral surface of the drum housing 200.

The juice outlet 220 is in communication with the hollow of the drum housing 200 so that the juice extracted by the juice drum 400 and the separating screw 300 can be discharged to the outside of the drum housing 200. It is formed to protrude from the outer peripheral surface of the drum housing 200.

The dregs outlet 230 is in communication with the hollow of the drum housing 200 so that the dregs filtered by the juice drum 400 and the separating screw 300 can be discharged to the outside of the drum housing 200, In communication with the hollow of the inner module 402, it is formed to protrude from the outer peripheral surface of the drum housing 200.

Here, the waste outlet 230 is drilled to communicate with the hollow of the drum housing 200, while ensuring the communication between the waste outlet 230 and the inner module 402 hollow, the drum housing 200 and the A drum protrusion 420 is formed on the outer circumferential surface of the inner module 402 in the vertical direction so as to block the juice flowing down between the inner module 402 and the outlet of the waste outlet 230, and the drum housing ( A drum groove 410 (see FIG. 5) in which the drum protrusion 420 is seated is formed at an inner circumferential surface of the 200 to overlap with the dregs outlet 230, and the dregs outlet 230 and the inner module ( A communication hole 425 (see FIG. 2A) communicating the hollow of 402 may be drilled in the drum protrusion 420.

That is, the juice flowing down between the drum housing 200 and the inner module 402 by the stepped end of the drum protrusion 420 and the outer circumferential surface of the inner module 402 is blocked from flowing out to the waste outlet 230. do. In addition, the drum protrusion 420 and the drum groove 410 guide the inner module 402 when the inner module 402 is inserted into the drum housing 200. While the separation screw 300 rotates therein, the inner module 402 is prevented from being rotated in the drum housing 200 by the rotational force transmitted indirectly. In other words, the drum protrusion 420 and the drum groove 410 may limit the coupling position, relative rotation, and tilting of the inner module 402 and the drum housing 200.

On the other hand, the residue outlet 230 may be opened or closed by the opening and closing mechanism 240 provided in the drum housing 200. The debris collected on the inner lower side of the inner module 402 moves to the drum housing 200 through the communication hole 425, and finally discharged through the debris outlet 230 formed in the drum housing 200. Can be.

The juice outlet 220 and the residue outlet 230 may be formed to protrude in a pipe shape or similar shape so that juice and residue can be easily discharged, respectively.

3 is a perspective view showing a cross-sectional view of a portion of the drum housing, the juice drum and the separating screw in accordance with an embodiment of the present invention, Figures 4a and 4b is a juice drum according to an embodiment of the present invention Is an exploded perspective view of the.

As shown in Figure 4a, 4b, and 3, the juice drum 400 according to an embodiment of the present invention is configured by the combination of the drum housing 200 and the inner module 402, the inner The module 402 is detachable from the drum housing 200.

The inner module 402 is formed with a slit 421, a rod 422, a drum inclined surface 424, a first rib jaw 426, a second rib jaw 428, and a flange 429.

The slits 421 are formed in plural to be perforated radially from the inner circumferential surface to the outer circumferential surface of the inner module 402. In addition, the slit 421 is formed narrow in the circumferential direction and long in the vertical direction, and has a constant length upward from the lower end of the inner module 402. That is, the slit 421 may not extend to the upper end of the inner module 402. In addition, the plurality of slits 421 are arranged in a plurality of equal intervals, one bundle and another bundle along the circumference are spaced apart at an interval larger than the equal interval of the slits 421 belonging to the one bundle. Can be.

The rod 422 is a portion between one slit 421 formed by drilling the slit 421 and another slit 421 neighboring. That is, the rod 422 is a plate portion in which the slit 421 is not formed, and the rod 422 and the slit 421 are alternately formed in a bundle of the slit 421. On the other hand, the slit 421 is formed long in the vertical direction to be disposed so as to intersect the skeletal position (skew position) with the first spiral protrusion 310, the shape is not limited to a square or oval. In addition, the width of the upper portion of the slit 421 may be smaller than the width of the lower portion, the width of the upper portion of the rod 422 may be larger than the width of the lower portion. Here, the slit 421 may be gradually narrowed toward the upper portion, and the rod 422 may gradually become thinner toward the lower portion. In addition, the slit 421 may be narrower than the upper portion based on the step, and the rod 422 may be thinner than the upper portion based on the step.

The drum inclined surface 424 is the circumferential surface of the inner module 402 in the rod 422. In addition, the drum inclined surface 424 is formed in such a shape that the rod 422 is gradually narrowed toward the radially outer side of the inner module 402, thereby being inclined with respect to the radial direction of the inner module 402. It is a part. For convenience of the description that follows, the circumferential surface of the inner module 402 of this rod 422 will be referred to as drum inclined surface 424.

The first rib jaw 426 is formed on the rod 422 on the inner circumferential surface of the inner module 402. That is, the first rib jaw 426 is formed on the radially inner surface of the inner module 402 of the rod 422. The first rib jaw 426 is a protrusion formed vertically long, and the material is formed by the interaction of the first spiral protrusion 310 and the first rib jaw 426 according to the rotation of the separation screw 300. It can be compressed or crushed. Without the first rib jaw 426, the juice object may be stagnant without falling down, and the compressive force or the grinding force may be low or may not occur.

The second rib jaw 428 is formed on a plate portion in which a bundle of a plurality of slits 421 and another bundle are spaced apart from each other on an inner circumferential surface of the inner module 402. On the other hand, the drum protrusion 420 is formed on the radially outer surface of the inner module 402 in one of the plate portion spaced apart from one bundle of the plurality of slits 421 and the other bundle. The second rib jaw 428 may perform a function of reinforcing the inner module 402, and may perform a function of sending a juice object to a lower portion of the inner module 402. Furthermore, the second rib jaw 428 may perform a function of adjusting an accommodation position for receiving the separation screw 300 in the inner module 402 and adjusting a juice space.

The first rib jaw 426 and the second rib jaw 428 may perform a function of crushing the material well together with the separating screw 300 while lowering the juice object. Therefore, the first rib jaw 426 and the second rib jaw 428 are not necessarily formed in the vertical direction of the juice drum 400, but in a twisted position with the spiral 310 of the screw 300. It may also be formed in an inclined form having a constant inclination with respect to the vertical direction for efficient transport and compression of the material in the cross form.

The flange 429 is formed below the rod 422. The flange 429 supports the width of the slit 421 between the plurality of rods 422 to be fixed. Since the lower side of the inner module 402 is supported by the flange 429, the width of the slit 421 is prevented from being changed by a load such as a pressing force in the juice process.

Ribs 412 are formed on the inner circumferential surface of the drum housing 200 at positions corresponding to the slits 421 to be inserted into the slits 421 between the rods 422. That is, in order to fix the coupling position of the inner module 402 and the drum housing 200, a space between the plurality of ribs 412 is relatively narrow and a relatively wide space may be formed. In addition, a plate portion in which a bundle of a plurality of slits 421 is spaced apart from a bundle of the plurality of slits 421 may be positioned in a space where a plurality of ribs 412 are relatively wide. In the state where the rib 412 is inserted into the slit 421, a predetermined gap is formed between the rod 422 and the rib 412, and juice is extracted through the gap. That is, the rod 422 filters the residue, and the slit 421 functions to extract the juice. In addition, the drum juice passage 414 having a cross section similar to a triangle surrounded by the drum inclined surface 424, the rib 412, and the inner circumferential surface of the drum housing 200 by the shape of the drum inclined surface 424 of the rod 422. Is formed (see FIG. 3). Meanwhile, the drum housing 200 and the inner module 402 are inserted such that the rib 412 is inserted into the slit 421 as the slit 421 does not extend to the upper end of the inner module 402. In a coupled state, the bottom surface of the inner module 402 may be spaced apart from the bottom surface of the drum housing 200 by a predetermined distance.

Juice spilled radially outwardly of the inner module 402 through the gap between the rod 422 and the rib 412 of the slit 421 flows downward through the drum juice passage 414. Accordingly, residues remain in the inner module 402 of the juice drum 400 and the juice may be separated and discharged toward the drum housing 200. In other words, the gap formed between the slit 421 of the inner module 402 and the rib 412 of the drum housing 200 is configured to be wider toward the radially outer side of the juice drum 400 to process the juice process. In order to prevent the problem of clogging or disrupting the flow of juice by the debris. To this end, the cross section in which the rod 422 is horizontally cut may be a semi-circle, ellipse, or trapezoidal shape.

Meanwhile, the material is transferred downward by the rotation of the separation screw 300 inside the inner module 402 of the juice drum 400, and between the separation screw 300 and the inner circumferential surface of the inner module 402. As the gap becomes narrower toward the lower side, the material is gradually compressed so that the grains become smaller, and the compressive force due to the compression of the material becomes larger and larger toward the lower side. Therefore, the lower gap of the juice drum 400 through which the juice is filtered may be formed narrower than the upper gap. In addition, depending on the material, the discharge of juice through the lower side gap may be hindered by debris generated during the juice process. Therefore, the upper gap of the juice drum 400 may be formed relatively wider than the lower gap so that the juice overflows through the upper gap. For example, when the width of the slit 421 between the rod 422 on the upper side is constant, and the width of the rib 412 becomes narrower toward the upper side, between the rod 422 and the rib 412 The gap and the size of the drum juice passage 414 is wider toward the upper side. In addition, the gap between the rod 422 and the rib 412 and the size of the drum juice passage 414 may be kept constant without changing during the juice process.

In the case of a hard juice object such as carrots, juice can be discharged through a narrow gap formed in the lower part in the pressing process. However, in the case of a soft juice object such as a tomato, in the pressing process, the juice can be discharged through the wide gap in the upper side as the juice target which is stuck in the gap formed in the lower side as well as the gap formed in the lower side rises to the wide gap in the upper side. have. As such, when the size of the gap is not constant along the length direction, the juice efficiency can be improved for both the hard juice object such as carrot and the soft juice object such as tomato.

On the other hand, the first rib jaw 426 formed on the inner circumferential surface of the rod 422 may be formed adjacent to the slit 421 disposed in the rotational direction of the separation screw 300. When the first rib jaw 426 is formed adjacent to the slit 421 disposed in the rotational direction of the separation screw 300 based on the first rib jaw 426 itself, the first rib jaw 426. ) Is less likely to be trapped in the slit 421 than when formed in the central portion of the rod 422. That is, when the first rib jaw 426 is formed adjacent to the slit 421, the juice object is rotated by the separation screw 300 as compared with the case where the first rib jaw 426 is formed near the slit 421. In the process of crossing the first rib chin 426, the compressive force applied toward the slit 421 is lowered, thereby alleviating debris from being caught in the slit 421.

5A and 5B are exploded perspective views of a separating screw according to an embodiment of the present invention.

As shown in Figure 5a, 5b, and 3, the separation screw 300 according to an embodiment of the present invention is configured by the combination of the first module 301 and the second module 302, The first module 301 is detachable from the second module 302.

The rotary blade 305, the first spiral protrusion 310, and the screw shaft 312 are formed in the first module 301.

The first module 301 is formed in a hollow cylindrical shape, the upper part of which is closed to a portion where the rotary blade 305 is formed and the lower part of which is opened. In addition, most of the screw shaft 312 is disposed in the hollow central portion of the first module 301, the upper end of the screw shaft 312 protrudes upward from the upper end of the first module 301 to the hopper It may be inserted into the receiving hole formed in the lower surface of the (100). Thus, the phase of the screw shaft 312 is fixed so that the separation screw 300 rotates stably. Further, the first module 301 is further formed with a slit 315, a rod 314, and a screw inclined surface 317.

The slits 315 are formed in plural so as to pierce radially from the inner circumferential surface to the outer circumferential surface on the circumference of the first module 301. In addition, the slit 315 is formed narrow in the circumferential direction and long in the vertical direction, and has a constant length upward from the lower end of the first module 301. That is, the slit 315 does not extend to the upper end of the first module 301, and the lower side is opened. Furthermore, the plurality of slits 315 may be arranged at equal intervals along the circumference.

The rod 314 is a portion between one slit 315 formed by the slit 315 being drilled and another adjacent slit 315. That is, the rod 314 is a plate portion in which the slit 315 is not formed, and the rod 314 and the slit 315 are alternately formed along the circumference. On the other hand, the slit 315 is formed long in the vertical direction to intersect the first spiral protrusion 310, the shape is not limited to a square or elliptical. In addition, the slit 315 may have an upper width smaller than a lower width, and the rod 314 may naturally have an upper width larger than a lower width. Here, the slit 315 may be gradually narrowed toward the upper portion, and the rod 314 may be gradually thinned toward the lower portion. In addition, the slit 315 may be narrower than an upper portion based on a step, and the rod 314 may be thinner than an upper portion based on a step.

The screw inclined surface 317 is the circumferential surface of the first module 301 in the rod 314. In addition, the screw inclined surface 317 is formed in a shape that the rod 314 is gradually narrowed toward the radially inner side of the first module 301, based on the radial direction of the first module 301 It is formed to be inclined. For convenience of the following description, the circumferential surface of the first module 301 of the rod 314 will be referred to as screw inclined surface 317.

The second module 302 is formed in a hollow cylindrical shape with the top closed and the bottom open. In addition, the second module 302 is formed with a rib 321, juice discharge hole 328, and the shaft through-hole 324.

The rib 321 is formed in plural radially of the second module 302. In addition, the rib 321 is formed narrow in the circumferential direction and long in the vertical direction. Further, the rib 321 is formed at a position corresponding to the slit 315 to be inserted into the slit 315, it may be arranged at equal intervals along the circumference. Meanwhile, in order to fix the coupling position of the first module 301 and the second module 302, there may be a gap between the plurality of ribs 321 and a narrow array, and the slit 315 ) May also be formed in a shape corresponding thereto. When the rib 321 is inserted into the slit 315 and the first module 301 and the second module 302 are coupled, a predetermined gap is formed between the rib 321 and the rod 314. The juice is introduced into the radially inward direction of the separating screw 300 through this gap. That is, the rod 314 filters the debris and the slit 315 functions to extract the juice. In addition, a screw juice passage having a cross section similar to a triangle surrounded by the screw inclined surface 317, the rib 321, and the outer circumferential surface of the second module 302 by the shape of the screw inclined surface 317 of the rod 314 ( 319 is formed (see FIG. 3). The juice spilled radially inwardly of the first module 301 through the gap between the rod 314 and the rib 321 of the slit 315 flows downwardly through the screw juice passage 319. Accordingly, residue remains between the inner module 402 of the juice drum 400 and the separation screw 300, and juice may be separated and discharged toward the second module 302. In other words, the gap formed between the slit 315 of the first module 301 and the rib 321 of the second module 302 is configured to be wider toward the radially inner side of the separation screw 300. It is possible to prevent the problem of clogging the gap or disturbing the flow of juice by debris during the juice process. To this end, the cross section in which the rod 314 is horizontally cut may be a semi-circle, ellipse, or trapezoidal shape.

The juice discharge hole 328 is perforated from the outer circumferential surface of the second module 302 to the inner circumferential surface near the lower side of the screw juice passage 319 so as to communicate with the screw juice passage 319.

A second spiral protrusion 329 may be formed on a radially outer surface of the second module 302 of the rib 321. According to the shape of the first spiral protrusion 310 and the position of the rib 321, the second spiral protrusion 329 may not include the second spiral protrusion 329 on the outer circumferential surface of the rib 321. .

When the first module 301 and the second module 302 are combined, the inner diameter of the first module 301 is larger than the outer diameter of the second module 302 so that the first module 301 may It is coupled to surround the second module 302, and the rib 321 of the second module 302 is inserted into the slit 315 of the first module 301. In addition, since the second spiral protrusion 329 is formed, a portion of the first spiral protrusion 310 broken by the slit 315 continues continuously. To this end, the radius of the second module 302 of the portion where the rib 321 is formed is the same as the radius of the first module 301 of the portion where the rod 314 is formed, and the first spiral protrusion 310 The height and shape of the protrusion of the second spiral protrusion 329 may also be the same.

Alternatively, the second spiral protrusion 329 may not be formed on the rib 321. In this case, by narrowing the width of the rib 321, the same or similar juice efficiency can be achieved as compared with the case where the second spiral protrusion 329 is formed on the rib 321. Furthermore, the performance of cutting the juice object when the first spiral protrusion 310 is not continuous may be further improved.

The outer circumferential surface portion of the second module 302 disposed between one rib 321 and the neighboring rib 321 to surround the screw juice passage 319 will be referred to as screw groove 322.

The juice discharge hole 328 is drilled in the lower portion of the screw groove 322. In addition, a gap may be formed between the screw groove 322 and the rod 314. Furthermore, the play may be wider toward the lower side of the separation screw 300. Through the play, juice flows down between the first module 301 and the second module 302 and through the juice discharge hole 328, the first module 301 and the second module ( Juice collected in the lower portion between the 302 may be introduced into the radially inward of the second module 302. On the other hand, the lower portion of the screw groove 322 may take an open form to serve as the juice discharge hole 328.

The shaft through hole 324 is formed such that the screw shaft 312 penetrates the closed upper surface 327 of the second module 302. The shaft through hole 324 is fixed to fix a coupling position of the first module 301 and the second module 302 and to prevent relative rotation of the first module 301 and the second module 302. ) May be a polygon. On the other hand, the shape of the shaft through-hole 324 is not limited.

In the embodiment of the present invention, the screw shaft 312 is formed in a generally rectangular shape, the shaft through-hole 324 is also formed in a square shape to correspond to the shape of the screw shaft 312. In this case, when the first module 301 and the second module 302 are coupled, when the second module 302 is rotated within a 90 degree angle while fixing the position of the first module 301, the screw shaft ( The coupling position of the 312 and the shaft through hole 324 may be naturally aligned to facilitate coupling of the first module 301 and the second module 302.

A mounting recess 320 recessed upward may be formed below the second module 302 so that the separation screw 300 may be seated on the juice drum 400. In addition, as shown in FIGS. 4A and 4B, a mounting protrusion 427 corresponding to the mounting groove 320 may protrude upward from an upper surface of the flange 429 of the inner module 402. Since the seating groove 320 is coupled to surround the seating protrusion 427, the residues separated in the juice process may be prevented from flowing into the screw 300. A packing (not shown) for sealing may be interposed between the seating recess 320 and the seating protrusion 427.

Meanwhile, referring back to FIGS. 5A and 5B, a magnet accommodating part 326 may be formed on the upper surface 327 of the second module 302. When the second module 302 is coupled to the first module 301, a magnet is attached to the magnet receiving part 326 so that the second module 302 and the first module 301 are not easily separated. By arranging and arranging magnets or magnetic bodies having opposite polarities inside the first module 301, the coupling force between the second module 302 and the first module 301 may be increased. That is, by combining the magnet and the magnetic material, the first module 301 and the second module 302 are coupled to the inside of the drum housing 200 or easily separated from the drum housing 200, and the separation screw ( When washing the 300, the user may easily separate the first module 301 and the second module 302 by applying a predetermined force to the second module 302 while holding the first module 301. .

In addition, a key groove 325 may be further formed on the top surface 327 of the second module 302. The key groove 325 is a key protrusion (not shown) formed on the lower surface of the rotary blade 305 of the first module 301 to fix the coupling position of the first module 301 and the second module 302. Is inserted). In addition, the key protrusion is inserted into the key groove 325 to limit the coupling position, relative rotation, and tilting of the first module 301 and the second module 302.

A first step 316 is formed at a lower end of the rod 314 of the first module 301, and correspondingly, a second step is located below the juice discharge hole 328 in the screw groove 322. 323 may be formed. By combining the second step 323 of the second module 302 and the first step 316 of the first module 301 to withstand the load transmitted to the separation screw 300 and the residue is the separation screw ( Do not flow into the inside of 300).

6a to 6c is a partial cross-sectional view of the juice drum of the embodiment of the present invention coupled to the drum housing. Figure 6a is a top view of the juicer is applied juice juicer of an embodiment of the present invention, Figure 6b shows a path through which juice is discharged in the "AA" direction of Figure 6a, Figure 6c is a "BB of Figure 6a The cross-section in the "direction shows the path from which the waste is discharged. 6B and 6C, the juice discharge passage and the residue discharge passage are shown to be well visible.

According to one embodiment of the present invention, two paths are formed in the path between the drum housing 200 and the inner module 402 and the separation screw of the separation screw, thereby greatly increasing the juice efficiency. Referring to FIG. 6C, a shaft hole 260 is formed at the center of the inner bottom surface of the drum housing 200. The inner circumferential surface 261 of the shaft hole 260 may include a waterproof seal (not shown), and may include a cylinder 280 protruding into the central space inside the screw 300 according to a design need. As described above, the flange 429 or the stepped portion formed at the bottom of the inner module 402 may be seated and supported by the stepped formed on the bottom inner circumferential surface of the drum housing 200.

In addition, the upper surface of the flange 429 formed on the lower end of the inner module 402 is formed with a guide jaw 282 is fixedly supported so that the screw is rotatably seated and supported on the upper surface of the guide jaw 282 A guide groove 291 may be formed by inserting the lower ring 390 of the screw into the guide groove. In addition, the guide groove 291, the packing 295 is assembled or the screw bottom is formed in a shape corresponding to the guide jaw 282, the packing may be assembled in its position. In this way, while the screw is rotatably fixed and supported, the pressure of the dregs or juice is dropped and the dregs or juice do not enter the drive shaft.

The juice is not only flows between the inner module 402 and the drum housing inner side and exits to the juice outlet, but also the juice passing through the separating screw 300 is extruded into the screw inner space and formed in the drum housing bottom center. It flows into the groove 281 and collects. The juice collected here can be discharged through the juice discharge furnace. Juice outlet groove 281 may be a storage space formed by the outer wall is an annular guide jaw 282, the inner wall is formed of a waterproof cylinder 280.

As described above, according to an embodiment of the present invention, the juice drum 400 and the separation screw 300 performs a double juice to maximize the juice efficiency, the juice drum 400 and the separation screw 300 are separated, respectively This can facilitate the cleaning.

In addition, according to the embodiment of the present invention, as described above, the separation screw and the two drums are combined to combine the juice drum consisting of the two filters to remove the juice by extracting the juice, respectively, Can be improved.

In addition, the separation screw and the juice drum can be separated into two, each can be easily washed, manufacturing and assembly can be facilitated.

On the other hand, according to an embodiment of the present invention, the material is smoothly transferred by the separation screw in the pressing process, the juice efficiency is improved through the fine grinding and compacting of the material, it is possible to facilitate the further input of the material.

In addition, it is possible to prevent the residue from being caught in the juice drum during the juice process may not interfere with the flow of juice from which the residue is extracted.

Furthermore, since the juice drum is formed of a hard material, deformation such as a slit of the juice drum spreads in the juice process can be prevented.

In addition, since the juice can be extracted from each of the separation screw and the drum, even if the juice is not made smoothly in any one of the separation screw, the drum has an effect that can maintain the juice operation steadily.

7 is a view of the automatic residue discharge device that can be applied to the inner module of the juice drum of the present invention. As can be seen in Figure 7a, the fitting portion (11a) is formed on one side of the lower outer peripheral surface of the inner module 10, the outer peripheral surface of the inner module 10 in the lower portion of the fitting portion (11a) of the inner module 10 The residue discharge hole 719 communicating with the inside may be formed.

Here, a fitting groove may be formed at one lower side of the inner circumferential surface of the drum housing 200 to correspond to the fitting portion 11a so that the fitting portion 11a is fitted when the inner module 10 and the drum housing 200 are coupled to each other. .

Accordingly, the fitting portion 11a is inserted into the fitting groove when the inner module 10 is inserted into the drum housing 200, thereby guiding the movement of the inner module 10 and at the same time the inside of the drum housing 200. In the inner module 10 can be performed with a function to position.

On the other hand, the residue discharge hole 719 may be further coupled to the residue discharge regulator (719a). The waste discharge controller 719a may be hinged to the fitting portion 11a so that the upper portion is rotated upward from the outer circumferential surface of the inner module 10 to selectively open and close the waste discharge hole 719. Here, the waste discharge controller 719a may be configured as a packing.

That is, the debris generated in the juice process is collected in the inner lower portion of the inner module 10, pushing the residue discharge controller 719a from the residue discharge hole 719 to the outside of the drum housing 200 through the residue discharge port 230. May be discharged. In this case, the waste discharge controller 719a may be formed of an elastic member, and one side thereof may be in contact with the protrusion of the drum housing, thereby allowing the waste to be automatically discharged only when the set pressure is exceeded.

In addition, when the user separates and washes the inner module 10 from the drum housing 200, the user rotates and lifts the residue discharge controller 719a hinged to the fitting portion 11a, thereby leaving the residue discharge hole ( 719) can easily be removed.

7b and 7c are perspective views of the inner module applied to the juice drum according to another embodiment of the present invention.

Referring to FIG. 7B, the inner module 40 according to another embodiment of the present invention may have a stepped portion 42a of the outer shape, the rod 41, the slit 42, and the slit 42, as in the above-described embodiment. Since the structure, shape, and features of the key groove 45 and the flange 46 are the same, detailed description thereof will be omitted below.

In another embodiment of the present invention, the fitting portion 48 is formed at one lower side of the outer circumferential surface of the inner module 40, and the waste discharge hole 49 communicating with the inside of the inner module 40 at the lower end of the fitting portion 48. This can be formed.

Here, an annular flange 46 connected to the fitting portion 48 is formed at the lower end of the inner module 40, and a residue discharge regulator 49a is disposed at the lower end of the fitting portion 48 corresponding to the residue discharge hole 49. Coupling groove 49b may be formed to be coupled.

Here, the coupling groove 49b may be formed to be concave upward from the bottom surface of the flange 46 so that the dreg discharge regulator 49a is coupled to smoothly close the dreg discharge hole 49.

Accordingly, the waste discharge regulator 49a may be hinged to one end that is radially inwardly coupled to the coupling groove 49b so as to be rotated to the lower portion of the inner module 40 to selectively open and close the waste discharge hole 49.

That is, when the debris generated in the juice process gathers a predetermined amount or more in the inner lower portion of the inner module 40, the debris pushes the debris discharge regulator 49a from the debris discharge hole 49. At this time, the waste discharge regulator 49a may be made of an elastic member, and one side thereof may be in contact with the protrusion of the drum housing, thereby allowing the waste to be automatically discharged only when the set pressure is exceeded.

Then, as can be seen in Figure 7a, the residue discharge regulator (49a) is rotated to the bottom by the residue discharged from the residue discharge hole 49 to open the residue discharge hole 49, thereby leaving the drum housing 200 It may be discharged to the outside of the drum housing 200 through the waste outlet 230 of the).

In addition, when the user separates and cleans the inner module 40 according to another embodiment of the present invention from the drum housing 200, the user hinges the residue discharge controller 49a hinged to the coupling groove 49b. By rotating it down, it is possible to easily remove the debris that may be caught in the debris discharge hole 49.

According to the embodiment of the present invention as described above, by configuring the juice drum 400 consisting of two modules can be easy to clean, improve the juice efficiency.

As described above, the juice drum according to the embodiment of the present invention is configured to combine the two modules in the vertical direction, the assembly and disassembly of the two modules is easy and easy to clean.

In addition, the first ribs formed in the first slit and the inclined portion formed between the two modules can be prevented from being caught in the gaps through which juice is discharged, it is possible to improve the juice efficiency.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and the present invention can be modified and practiced in various ways within the scope of the appended claims and the detailed description of the claims and the present invention. Naturally, it belongs to the scope of the invention.

1: main body
2: upper support
3: lower support
4: reducer housing
6: drive shaft
100: Hopper
200: drum housing
220: juice outlet
230: garbage outlet
260: shaft hole
300: separation screw
301: a first module
302: second module
305: rotary blade
310: first spiral projection
312: screw shaft
314: rod
315: slit
316: first step
320: seating groove
321: rib
322: screw groove
323: second step
328: juice outlet
324: shaft through hole
325: key groove
326: magnet receiver
329: 2nd spiral turning
400: juice drum
401: outer module
402: inner module
421: slit
422: rod
424: drum slope
426: first rib chin
428: second rib chin
429: flange
420: drum turning
410: drum groove
425: communication hole
429: flange
427: seating protrusion
719: garbage discharge hole
719a: exhaust regulator

Claims (23)

A separation screw including a first module having a plurality of first slits formed on the outer circumferential surface by a plurality of rods, and a second module having a plurality of first ribs inserted into the first slits of the first module; And
A plurality of second slits formed by a hollow cylinder having an upper portion open to accommodate the separation screw and formed through holes having both side surfaces, an upper surface and a lower surface along an inner circumferential surface thereof, and a rib jaw protruding radially inwardly on the inner circumferential surface thereof are formed. An inner module formed at regular intervals, and a second rib including a protruding surface, an upper surface, and a lower surface on an inner circumferential surface, the upper opening of which is detachable, and a protruding surface and an upper surface and a lower surface formed radially inwardly, and the juice discharge port and the dregs discharged from the juice Juice drum comprising a drum housing is spaced apart from the discharge outlet is formed;
Including,
The first module and the second module are detachably coupled, and when the second module is inserted into and coupled to the first module, the first rib of the second module is connected to the first slit of the first module. A gap is formed between the rib of the second module and the first slit of the first module,
When the drum housing surrounds and engages the inner module, the second rib of the drum housing is inserted into the second slit of the inner module such that the second slit side of the inner module and the second rib side of the drum housing Juicer, in which a gap is formed. The method of claim 1,
At least one first spiral protrusion is formed on an outer circumferential surface of the rod of the first module,
At least one or more second spiral protrusions are formed on at least one of the plurality of ribs of the second module,
And wherein when the second module is inserted into and coupled to the first module, the first spiral protrusion and the second spiral protrusion form a continuous screw spiral. The method of claim 1,
The juicer of the second module is open, the top is blocked. The method of claim 3,
A screw shaft is formed in the inner center of the first module,
Juicer is formed in the upper surface of the second module shaft through-hole of the shape corresponding to the screw shaft so that the screw shaft is fitted. The method of claim 3,
Key protrusions are formed on the inner upper surface of the first module,
Juicer is formed on the outer upper surface of the second module is a key groove into which the key projection is inserted. The method of claim 3,
The upper surface of the second module is formed with a magnet receiving portion is disposed,
Juicer having a magnet or magnetic body of the opposite polarity to the magnet disposed in the magnet receiving portion inside the first module. The method of claim 1,
The width of the rod of the first module is narrowed toward the radially inner side of the first module. The method of claim 1,
Juice discharge holes are formed in the lower side of the plurality of screw grooves formed between the plurality of ribs of the second module,
Juicer is formed on the bottom surface of the drum housing in the radially outward communication with the juice outlet hole in the radial direction, the juice outlet groove is in communication with the juice outlet. The method of claim 8,
Some juice juiced by the interaction of the separation screw and the inner module is moved into the separation screw through a gap between the rod and the first slit and discharged to the juice outlet through the juice discharge groove.
The remaining juice is moved to the lower portion of the inner module and the drum housing through the gap between the second rib and the second slit is discharged to the juice outlet through the juice discharge groove. The method of claim 1,
The juicer of claim 1, wherein a first step is formed at a lower end of the rod of the first module, and a second step is formed at a lower end of the rib of the second module, the second step corresponding to the first step. The method of claim 1,
The rib jaw is a juicer formed adjacent to the upstream edge of the second slit formed in the inner module based on the rotation direction of the separation screw. The method of claim 1,
A first stepped portion formed under the outer circumferential surface of the inner module; And
A second stepped portion formed below the rib of the drum housing;
More,
The first step is juicer that is seated and supported by the second step. The method of claim 1,
The inner module is formed with a waste discharge hole,
Juice extractor coupled to the waste discharge regulator in the waste discharge hole. The method of claim 13,
The dregs discharge hole is formed in the fitting portion formed on the outer peripheral surface of the inner module. The method of claim 14,
The drum housing is the inner circumferential surface of the juicer is formed with a fitting groove to be fitted. The method of claim 14,
The waste discharge regulator
Juicer is hinged to the fitting portion to selectively open and close the residue discharge hole. The method of claim 16,
The dregs discharge regulator is a juicer for selectively opening and closing the dregs discharge hole by rotating in the vertical direction from the outer peripheral surface of the inner module. The method of claim 13,
The dregs discharge hole is formed in the flange formed on the lower end of the inner module juicer. The method of claim 18,
The residue discharge regulator is a juicer coupled to the flange of the inner module to selectively open and close the residue discharge hole. The method of claim 19,
The dregs discharge controller is rotated to the lower portion of the inner module, the juicer to selectively open and close the dregs discharge hole. The method of claim 13,
The dreg discharge regulator is composed of an elastic member juicer. The method of claim 1,
The lower ring formed at the lower end of the screw is supported by a guide groove formed on the upper surface of the flange formed on the lower end of the inner module. The method of claim 1,
A main body part including a drive shaft inserted into a shaft hole formed in a bottom surface of the drum housing to transmit power to the separation screw;
Juicer comprising more.

Images