KR20210029390A - Mixer with dewatering - Google Patents

Abstract

A dewatering mixer according to the present invention comprises: a mixer body having an outer container opened or closed by a mixer cover, a grinding blade, and a blade driving unit for rotating the grinding blade; and an inner container unit including an inner container which is disposed in the outer container, has the grinding blade located therein, has one or more protrusions formed on the inner side surface thereof, and has a dehydration hole, and an inner container driving unit which rotates the inner container. A blade rotation shaft of the blade driving unit is installed to axially rotate in a hollow portion formed in an inner container rotation shaft of the inner container driving unit, and the blade rotation shaft and the inner container rotation shaft axially rotate independently with respect to each other. The inner container driving unit comprises: an inner container driving connection unit which is for connection between the inner container rotation shaft and an inner container driving motor and between the inner container rotation shaft and the inner container driving motor; and a compressing member which changes a gear fastening structure of the inner container driving connection unit by pressing an inner container driving shaft connected to the inner container driving motor in the axial direction to allow the inner container driving shaft to reciprocate, so that the inner container has different rotational speeds during grinding and dewatering of a material to be mixed.

Description

Mixer with dewatering {MIXER WITH DEWATERING}

The present invention relates to a blender capable of dehydrating, and to a blender for pulverizing an object to be mixed.

In general, a blender is a transmission device consisting of a container (cup) into which an object to be mixed is placed and a body in which an electric motor is accommodated.

Here, the container is made of hard heat-resistant glass, synthetic resin or stainless steel, and a crushing blade of stainless steel is mounted on the driving part in the lower part of the container while being engaged with the driving part.

In addition, as the motor accommodated in the body rotates at high speed, it has been widely used at home for purposes of cutting and pulverizing mixing objects including fruits and vegetables, as well as for making juice of a mixing object.

By the way, the blender has a protrusion formed in the inner cylinder of the blender, as disclosed in Korean Patent Publication No. 10-1772862. As the mixing object accommodated in the inner cylinder rotates by the rotation of the grinding blade and is caught on the protrusion, the grinding blade The reverse rotation of the inner cylinder is not smoothly performed in the opposite direction of rotation. In particular, when the output of the inner cylinder driving motor is low, there is a limit that the reverse rotation of the inner cylinder is not made at all.

Furthermore, even if the object to be mixed is pulverized, in order to extract juice and eat it, there is an inconvenience of having to juice using a separate juicer.

The present invention has been invented to solve the above problems, and an object of the present invention is to provide a dehydration blender capable of pulverizing and dehydrating (juicing) an object to be mixed.

In order to achieve the above object, the blender capable of dehydrating according to an embodiment of the present invention includes: a mixer body having an outer cylinder opened and closed by a mixer cover, a grinding blade, and a blade driving part for rotating the grinding blade; And an inner cylinder unit disposed in the outer cylinder, wherein the grinding blade is positioned therein, at least one protruding portion formed on an inner side thereof, an inner cylinder having a dehydration hole, and an inner cylinder driving portion for rotating the inner cylinder; The blade rotation shaft of the drive unit is installed to be axially rotated in a hollow formed in the inner cylinder rotation shaft of the inner cylinder drive unit, and the blade rotation shaft and the inner cylinder rotation shaft rotate independently of each other, and the inner cylinder drive unit includes the inner cylinder rotation shaft, the inner cylinder drive motor, and the It has an inner cylinder drive connecting part connecting the inner cylinder rotation shaft and the inner cylinder drive motor, and reciprocates by pressing the inner cylinder drive shaft connected to the inner cylinder drive motor in the axial direction so that the inner cylinder has different rotational speeds during crushing and dehydration of the mixing object. It may be provided with a pressing member that is moved to change the gear fastening structure of the inner cylinder drive connection.

As an example, the pressing member may include an air cylinder for pressing the inner cylinder drive shaft in the axial direction.

As another example, the pressing member may include an air cylinder that presses the inner cylinder drive shaft in one of the axial directions, and a spring that presses the inner cylinder drive shaft in the other direction of the axial direction.

Specifically, the air cylinder includes: a cylinder body having an air extraction hole in communication with an external air pump formed on one side thereof; And a head part built into the cylinder body and moved along the longitudinal direction of the cylinder body by air extraction through the air extraction hole, and extending from the head part to the outside of the cylinder body, the inner cylinder drive shaft and the connecting moving bar. And a plunger having a rod portion connected thereto, and the inner cylinder drive shaft may be axially fastened to the connection moving bar.

And, the spring, one end is supported on a fixed plate fastened so that the inner cylinder drive shaft is axially moved and axially rotated, and the other end is supported by the connection movable bar, and when the air extraction of the air cylinder is stopped, the connection movable bar is elastically compressed. Thus, the connection moving bar moved by the air cylinder can be reversely moved.

Here, the inner cylinder drive connection part, a driving small gear and a driving standby gear are installed on an inner cylinder drive shaft connected to the inner cylinder driving motor, and a driven standby gear and a driven small gear on the inner cylinder rotation shaft or an intermediate rotation shaft interlocked with the inner cylinder rotation shaft. Is installed, and the inner cylinder drive shaft reciprocates in the axial direction, or the inner cylinder rotation shaft or the intermediate rotation shaft reciprocates in the axial direction, and the driving small gear and the driven standby gear are connected to the driving standby gear when the gear is fastened. When the all-in-one gear is non-geared, and the driving standby gear and the driven small gear are engaged with each other, the driving small gear and the driven small gear may be non-gear-fastened.

In this case, the inner cylinder drive shaft may be slide-fastened so as to be axially movable while one end of the inner cylinder drive shaft is keyed so as to be interlocked with the motor shaft of the inner cylinder drive motor.

Specifically, the motor shaft has a hollow cross section, the inner cylinder drive shaft has a cross section of one end matched with the hollow end face of the motor shaft, and the other end of the inner cylinder drive shaft may be connected to the shaft moving member by a shaft rotation bearing.

Further, the inner cylinder drive connection unit may be configured with a gear structure such that the rotational speed of the inner cylinder when the mixing object is dehydrated is 5 times or more faster than the rotational speed of the inner cylinder when the mixing object is pulverized.

More specifically, the inner cylinder drive connection may be configured such that the inner cylinder is 50rpm to 350rpm when the mixing object is crushed, and the inner cylinder becomes 1500rpm to 3500rpm when the mixing object is dehydrated.

The dehydration mixer according to the present invention takes a structure in which the gear fastening structure of the inner cylinder drive connection is variable so that the inner cylinder has different rotational speeds during pulverization and dehydration of the mixing object. By raising the torque while lowering the reverse rotation speed of the inner cylinder, the mixing object close to the inner side of the inner cylinder can be smoothly reversely rotated among the mixing objects that rotate forward by the forward rotation of the grinding blade, and when the pulverized mixing object is dehydrated, mixing The dehydration effect can be maximized by increasing the rotational speed of the inner cylinder as much as possible than when the object is crushed.

In addition, the dehydration mixer according to the present invention comprises a pressing member that presses the inner cylinder drive shaft until the gear fastening structure of the inner cylinder drive connecting portion is variablely completed, so that even if the inner cylinder drive shaft moves, the gear teeth of the gears do not mesh with each other. By continuously pressing the inner cylinder drive shaft in the axial direction until the gear coupling structure is completely variable, the gear coupling structure of the inner cylinder drive connecting portion can be completely changed as the gears are eventually meshed with each other while the gear rotates.

1 is a view showing a blender capable of dehydration according to the present invention.
2 is a view showing the interior of the blender capable of dehydration according to an embodiment of the present invention.
3 and 4 are views showing the operating state of the inner cylinder drive in the blender capable of dehydration of FIG. 2.

Hereinafter, it will be described in detail through exemplary drawings of the present invention. In adding reference numerals to elements of each drawing, it should be noted that the same elements are assigned the same reference numerals as much as possible, even if they are indicated on different drawings. In addition, in describing the present invention, when it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

1 is a view showing a dehydration blender according to the present invention, Figure 2 is a view showing the interior of a dewaterable blender according to an embodiment of the present invention, Figures 3 and 4 are inner cylinders in the dewaterable blender of Figure 2 It is a view showing the operating state of the driving unit.

Referring to the drawings, the blender capable of dehydration according to an embodiment of the present invention includes a mixer body and an inner cylinder unit.

Here, the mixer body 100 includes an outer cylinder 110, a grinding blade 120, and a blade driving unit 130.

Specifically, the outer cylinder 110 has a structure in which the lower surface is closed and the upper part is opened upward so that the mixing object can be accommodated therein, and is configured to be opened and closed by the mixer cover 140.

In addition, the outer cylinder 110 may be closed by covering the outer cylinder cover 110a on the upper portion before being seated in the barrel support case 300 to be described later, and this outer cylinder cover 110a includes a vacuum unit 400 to be described later. A suction hole may be formed to form a vacuum of the outer cylinder 110 by this.

In addition, when the juice of the mixing object comes out through the dehydration hole 210b of the inner cylinder 210 by the dehydration process of the mixing object to be described later, the juice can be extracted without separating the outer cylinder 110 from the barrel support case 300. To be able to do so, a downwardly inclined discharge part (not shown) may be formed at the lower end of the side of the outer cylinder 100.

In this case, the mixing object refers to food for producing juice by being pulverized by the operation of a blender.

In addition, the crushing blade 120 is disposed in the inner cylinder 210 and serves to pulverize and liquefy the mixing object in the inner cylinder 210 when rotating.

In addition, the blade driving unit 130 is configured to rotate the grinding blade 120.

In addition, the outer cylinder 110 is supported by the barrel supporting case 300, and the barrel supporting case 300 as a whole takes a b-shape as shown in the drawings.

The tube support case 300 includes a lower casing part 310 positioned under the outer cylinder 110 and a side casing part 320 extending upward from the lower casing part 310 and connected to the mixer cover 140. ).

Specifically, the tube support case 300 has an outer cylinder 110 seated on the upper surface of the lower casing 310 disposed in the transverse direction, and the side portion extending upward from the lower casing 310 and disposed in the longitudinal direction The mixer cover 140 is hinged to the upper end of the casing part 320 so as to rotate up and down.

In this barrel support case 300, a blade driving unit 130 and an inner cylinder driving unit 220 to be described later are installed therein, and when the outer cylinder 110 in which the inner cylinder 210 is embedded is seated, crushing located in the inner cylinder 210 The blade 120 and the blade driving unit 130 installed in the barrel support case 300 are connected to each other so that the driving force is transmitted, and the inner cylinder 210 installed in the outer barrel 110 and the inner cylinder driving unit 220 installed in the barrel support case 300 ) Are connected to each other so that the driving force is transmitted.

More specifically, the outer tube 110 is detachably connected to the tube support case 300. For example, on the outer circumferential surface of the lower protrusion 110b of the outer cylinder 110, a spiral protrusion fitted to the tubular support case 300 is formed, and the seating groove of the tubular support case 300 in which the lower protrusion 110b is seated ( 300a) A spiral groove is formed on the inner circumferential surface, so that the protrusion is fitted into the groove, so that the outer cylinder is mounted on the tube support case 300, and can be removed by releasing it oppositely.

In addition, the outer cylinder 110 includes a crushing blade 130 disposed therein and a plurality of intermediate rotation shafts for transmitting the driving force transmitted from the outside to each of the inner cylinder 120. Specifically, the outer cylinder 110 includes a first intermediate rotation shaft 121 and a second intermediate rotation shaft 211 surrounding the first intermediate rotation shaft 121.

Here, the first intermediate rotation shaft 121 has a structure capable of transmitting power to the grinding blade 130 by receiving power from the blade driving motor 132 disposed in the barrel support case 300, For example, the lower part may be key fastened to the blade rotation shaft 131 of the blade driving unit 130, and the upper part may be key fastened to the crushing blade 130.

And the second intermediate rotation shaft 211 receives power from the inner cylinder drive motor 222 disposed in the barrel support case 300, and has a structure capable of transmitting the power to the inner cylinder 120, as an example, the lower portion The inner cylinder rotation shaft 221 of the inner cylinder driving unit 220 and the key fastening, the upper portion of the inner cylinder 120 and the key can be fastened.

In this case, a bearing may be disposed between the first intermediate rotation shaft 121 and the second intermediate rotation shaft 211 so that they can rotate independently of each other.

Meanwhile, the inner cylinder unit 200 includes an inner cylinder 210 and an inner cylinder driving part 220.

Here, the inner cylinder 210 is installed in the outer cylinder 110, the inner cylinder cover 210a may be covered on the top and closed before being seated on the cylinder support case 300, and the inner cylinder cover 210a will be described later. A suction hole may be formed to form a vacuum of the inner cylinder 210 by the vacuum unit 400.

In addition, at least one protrusion 213 may be formed on the inner side of the inner cylinder 210 so that the mixing object that rotates while being crushed by the grinding blade 120 is caught.

When the grinding blade 120 rotates while the mixing object is accommodated in the inner cylinder 210, when the mixing object hits the protrusion 213 formed on the inner side of the inner cylinder 210 rotating in the opposite direction, it occurs accordingly. By increasing the turbulence of the mixing object to be mixed, the crushing effect of the mixing object is increased.

In addition, the mixing object is radially pushed by centrifugal force by the rotation of the grinding blade 120 and flows upward, and the screw protrusion-shaped protrusion 213 for inducing the downward spiral flow of the mixing object is inside the inner cylinder 210 By being configured on the side, as the object to be mixed flows toward the grinding blade 120 disposed below the inner cylinder 210, the grinding effect of the blender can be further increased.

In addition, for irregular flow of the inner cylinder 210 to the object to be mixed, the controller (not shown) performs a repetitive operation in which the inner cylinder 210 is rotated in the opposite direction to the grinding blade 120, or reversely rotated and stopped. It is possible to control the inner cylinder drive motor 222 of the inner cylinder drive unit 220 to be described later.

Further, the inner cylinder 210 is formed with a plurality of dehydration holes 210b for performing a dehydration process on the side so that only juice can be extracted from the mixing object crushed by the grinding blade 120.

At this time, the dehydration hole 210b is largely illustrated in the drawing, but is actually a very small hole through which only the juice of the mixing object can escape, and a plurality of mesh structures may be formed on the side of the inner cylinder 210. Furthermore, the dehydration hole 210b may be formed directly on the side of the inner cylinder 210 as shown in the drawing, and although not shown in the drawing, a separate member, for example, a mesh member is used on the side of the inner cylinder 210 It can take a structure mounted to be a part of.

In addition, the dehydration hole 210b may be formed in the lower part or the side of the inner cylinder 210, and at this time, it is preferable that it is not formed in the lower part but formed in the side part, and further preferably formed in the side part from a certain height or higher. However, this is because when there is a certain amount of liquid (for example, separate water or juice generated during mixing) when mixing the object to be mixed, the mixing effect is enhanced.

Of course, even if the dehydration hole 210b is formed from a certain height or higher from the side of the inner cylinder 210, when the mixing object is dehydrated, the inner cylinder 210 rotates at a much higher speed than when pulverized, so that the juice is in the inner cylinder. As the inner side of the 210 moves more easily upward, the juice may sufficiently escape to the outside of the inner barrel 210 through the dehydration hole 210b.

In addition, the inner cylinder driving unit 220 is configured to rotate the inner cylinder 210.

Specifically, the inner cylinder drive unit 220 includes an inner cylinder rotation shaft 221, an inner cylinder drive motor 222, and an inner cylinder drive connection unit 223.

In addition, the above-described blade driving unit 130 includes a blade rotation shaft 131, a blade driving motor 132, and a blade driving connection part 133.

Here, the inner cylinder rotation shaft 221 is connected so that rotational driving force is transmitted to the lower portion of the inner cylinder 210 built in the outer cylinder 110 when the outer cylinder 110 is seated in the tube support case 300, and the blade rotation shaft ( 131 is connected so that rotational driving force is transmitted to the lower portion of the grinding blade 120 built in the inner cylinder 210 when the outer cylinder 110 is seated in the barrel support case 300.

At this time, the blade rotation shaft 131 is installed to be axially rotated in a hollow formed in the inner cylinder rotation shaft 221, so that the blade rotation shaft 131 and the inner cylinder rotation shaft 221 axially rotate independently of each other.

That is, a bearing is provided in the hollow of the inner cylinder rotation shaft 221 so as to be installed while the blade rotation shaft 131 penetrates, so that the blade rotation shaft 131 can rotate independently inside the inner cylinder rotation shaft 221.

On the other hand, the inner cylinder drive unit 220 takes a structure in which the gear fastening structure of the inner cylinder drive connection part 223 is variable so that the inner cylinder 210 has different rotational speeds during pulverization and dehydration of the mixing object.

That is, in the case of dehydration after pulverizing the object to be mixed with a blender, the inner cylinder 210 is rotated faster than when the object is pulverized (dehydration) according to the need to extract juice from the object to be pulverized (dehydration). ) Is a gear fastening structure in which the inner cylinder 210 has a slower rotational speed than during dehydration when the mixing object is crushed, and when the mixing object is dehydrated, the inner cylinder 210 has a faster rotational speed than when pulverized. To form a structure.

Accordingly, the present invention increases the torque while lowering the reverse rotation speed of the inner cylinder 210 when pulverizing the mixing object, and the mixing object close to the inner side of the inner cylinder 210 among the mixing objects rotated forward by the forward rotation of the grinding blade. It is possible to smoothly reverse rotation, and when the pulverized mixing object is dehydrated, the rotational speed of the inner cylinder 210 can be increased as much as possible than when the mixing object is pulverized to maximize the dehydration effect.

Specifically, the inner cylinder drive connection part 223 is provided with a small drive gear 223b and a drive standby gear 223c on the inner cylinder drive shaft 223a connected to the inner cylinder drive motor 222, and the inner cylinder rotation shaft 221 or A driven standby gear 223e and a driven small gear 223f are installed on an intermediate rotation shaft 223d that rotates interlocking with the inner cylinder rotation shaft 221.

Here, the inner cylinder drive shaft 223a and the inner cylinder rotation shaft 221 are arranged parallel to each other, and as an example, as an additional driving force transmission medium in the middle when transmitting the driving force from the inner cylinder drive shaft 223a to the inner cylinder rotation shaft 221, the intermediate The rotation shaft 223d may be disposed in parallel with the inner cylinder drive shaft 223a and the inner cylinder rotation shaft 221.

At this time, the driven standby gear 223e and the driven small gear 223f may be installed directly on the inner cylinder rotation shaft 221, and may be installed on the intermediate rotation shaft 223d as shown in the drawing. It will be described as an example that is installed on the intermediate rotation shaft (223d).

Accordingly, the arrangement of the driven standby gear 223e and the driven small gear 223f to be described later is, when the driven standby gear 223e and the driven small gear 223f are directly installed on the inner cylinder rotation shaft 221, the inner cylinder rotation shaft 221 Of course)

The driving small gear 223b and the driving standby gear 223c are arranged to be spaced apart from each other along the axial direction on the inner cylinder driving shaft 223a, and the driven standby gear 223e and the driven small gear 223f are intermediate rotation shafts 223d. ) Are spaced apart from each other along the axial direction.

At this time, the driving small gear 223b of the inner cylinder drive shaft 223a corresponds to the driven standby gear 223e of the intermediate rotation shaft 223d, and the driving standby gear 223c of the inner cylinder drive shaft 223a is of the intermediate rotation shaft 223d. In order to correspond to the driven small gear 223f, the driving small gear 223b and the driving standby gear 223c are arranged in order on the inner cylinder driving shaft 223a, and the driven standby gear 223e and the driven small gear 223f are intermediate rotation shafts. It is placed in order at (223d).

As an example, as shown in the drawing, the small driving gear 223b and the small driving gear 223c are arranged in an upward direction from the inner cylinder driving shaft 223a, and the driven standby gear 223e and the driven small gear 223f Are arranged in order from the intermediate rotation shaft 223d in the upward direction.

For reference, as the name of each component is also implied, the driving small gear 223b has a relatively smaller diameter than the driving standby gear 223c, and the driven standby gear 223e is a driven small gear 223f. It has a relatively large diameter.

In the inner cylinder drive connection part 223 configured as described above, while the inner cylinder drive shaft 223a reciprocates in the axial direction, the driving small gear 223b and the driven standby gear 223e are coupled to the driving standby gear 223c when the gear is fastened. When the all-in-one gear (223f) is non-geared, and the driving standby gear (223c) and the driven small gear (223f) are geared together, the small driving gear (223b) and the driven standby gear (223e) are non-geared. have.

That is, when the mixing object is pulverized, the inner cylinder drive shaft 223a moves downward in the axial direction as shown in FIG. 3, and the driving standby gear 223c and the driven small gear 223f are geared together, so that the inner cylinder 210 Although this is decelerated, as it rotates with a large torque, it can smoothly rotate in the opposite direction to the grinding blade.

In addition, when the mixing object is dehydrated, as shown in FIG. 4, the inner cylinder drive shaft 223a moves downward in the axial direction, and the driving standby gear 223c and the driven small gear 223f are geared together, thereby crushing the mixing object. As the inner cylinder 210 rotates at a relatively higher speed than when the process is performed, a dehydration action of extracting juice from the pulverized mixing object can be effectively performed.

Further, the inner cylinder drive connection part 223, although not shown in the drawing, the inner cylinder drive shaft 223a does not reciprocate in the axial direction, and the intermediate rotation shaft 223d reciprocates in the axial direction, while the driving small gear 223b When the and driven standby gear (223e) is engaged with a gear, the driving standby gear (223c) and the driven small gear (223f) are non-geared, and the driving standby gear (223c) and driven small gear (223f) are the driving small gear when the gear is fastened. (223b) and the driven standby gear (223e) may take a non-geared structure.

And, although not shown in the drawings, in the case where the driven standby gear 223e and the driven small gear 223f are directly installed on the inner cylinder rotation shaft 221, the inner cylinder rotation shaft 221 is of course moved.

Meanwhile, the inner cylinder drive shaft 223a may be slide-fastened so as to be axially movable while one end of the inner cylinder drive shaft 223a is keyed so as to be axially rotated interlocked with the motor shaft 222a of the inner cylinder drive motor 222.

That is, the inner cylinder drive shaft 223a is keyed so that one end is interlocked with the motor shaft 222a of the inner cylinder drive motor 222, so that the inner cylinder drive motor 222 is operated and the motor shaft 222a rotates. , As the shaft rotates in conjunction with each other, the rotational driving force is transmitted from the inner cylinder driving motor 222.

In addition, the inner cylinder drive shaft 223a is slide-fastened so that one end of the inner cylinder drive motor 222 is axially movable, even when moving in the axial direction by the shaft moving member 223g, the motor shaft ( 222a) can maintain the key fastening state.

As an example, the motor shaft 222a has a rectangular cross section of the hollow 222b, and the inner cylinder drive shaft 223a has a cross section at one end of the motor shaft 222a that is matched with the cross section of the hollow 222b of the motor shaft 222a. The one end may be slide-fastened to be axially movable while the key is fastened so as to be axially rotated to the motor shaft 222a.

In addition, the inner cylinder driving shaft 223a is connected to the shaft moving member 223g even when the other end is axially rotatably connected to the shaft moving member 223g, even when moving in the axial direction by the shaft moving member 223g. It can be rotated by axis.

On the other hand, the inner cylinder drive unit 220 has a gear fastening structure of the inner cylinder drive connecting portion 223 is variable so that the inner cylinder 210 has different rotational speeds during crushing and dehydration of the mixing object, specifically, the inner cylinder drive shaft 223a ) May be provided with a pressing member 230 that reciprocates by pressing in the axial direction to change the gear fastening structure of the inner cylinder drive connection part 223.

That is, the pressing member 230 is configured to move the inner cylinder drive shaft 223a in the axial direction, but simply moves the inner cylinder drive shaft 223a at a time and the driving force does not disappear regardless of the variable completion of the gear fastening structure. , It is configured to press the inner cylinder drive shaft (223a) in the axial direction until the gear fastening structure of the inner cylinder drive connecting portion 223 is variable completed.

As an example, the drive small gear 223b of the inner cylinder drive shaft 223a and the driven standby gear 223e of the inner cylinder rotation shaft 221 or the intermediate rotation shaft 223d are in a non-geared state, thereby being a gear fastening structure. Is variable, but when the small driving gear 223b moves toward the driven standby gear 223e, the gear teeth of the small driving gear 223b and the gear teeth of the driven standby gear 223e are in contact with each other, but the gear teeth do not mesh with each other. If so, there is a problem that the gear fastening structure does not change.

As an example, when the small driving gear 223b moves toward the driven standby gear 223e, when the gear teeth of the small driving gear 223b and the gear teeth of the driven standby gear 223e do not mesh with each other, the gear fastening structure is not changed. In order to prevent this, the pressing member 230 of the present invention continuously presses the inner cylinder drive shaft 223a in the axial direction, so that when the driving small gear 223b rotates, the gear teeth of the driving small gear 223b are driven by a driven standby gear ( As the gear teeth of 223e) are inserted, the gear teeth of the small driving gear 223b and the gear teeth of the driven standby gear 223e may eventually mesh with each other.

Specifically, the pressing member 230 may include an air cylinder 231 and a spring 232.

Here, the air cylinder 231 may press the inner cylinder drive shaft 223a in one of the axial directions (lower side in the drawing).

As shown in the drawing, the air cylinder 231 may include a cylinder body (231a) and a plunger (231b).

At this time, the cylinder body 231a may have an air extraction hole in communication with an external air pump formed on one side thereof, and this air extraction hole is connected to the vacuum unit 400 by the operation of the vacuum unit 400. Air may flow out from the inside of the cylinder body 231a.

In addition, the plunger 231b may have a head portion H and a rod portion R.

Here, the head portion (H) is built in the cylinder body (231a) is moved along the longitudinal direction of the cylinder body (231a) by air extraction through the air extraction hole.

In addition, the rod portion (R) extends from the head portion (H) to the outside of the cylinder body (231a) and is connected by the inner cylinder drive shaft (223a) and the connection moving bar (240). In this case, the inner cylinder drive shaft 223a is axially rotatably fastened to the connection moving bar 240, and as an example, it may be fastened through a bearing member.

In addition, the spring 232 may press the inner cylinder drive shaft 223a in the other direction (upper side in the drawing) of the axial direction.

Specifically, the spring 232 is supported by one end of the fixed plate 250 is fastened so that the inner cylinder drive shaft 223a is axially moved and rotated, and the other end is supported by the connection moving bar 240, and the air cylinder 231 When the air extraction of) is stopped, the connection moving bar 240 is elastically compressed to reversely move the fixed plate 250 moved by the air cylinder 231. For reference, the inner cylinder drive shaft 223a is fastened to be axially rotated to the fixed plate 250, and as an example, it may be fastened through a bearing member.

A process in which the inner cylinder drive shaft 223a is reciprocated by the air cylinder 231 and the spring 232 configured as described above will be described as follows.

First, as shown in FIG. 3, when air is extracted through the air extraction hole of the air cylinder 231, the internal space on the side of the air extraction hole in the cylinder body 231a becomes negative pressure, so that the plunger 231b descends. And, as the connection moving bar 240 descends in connection with this, the inner cylinder drive shaft 223a descends.

As a result, the driving small gear 223b is gear-engaged with the driven standby gear 223e, so that the inner cylinder 210 rotates at low speed and high torque, thereby effectively crushing the mixing object in the inner cylinder 210.

Of course, at this time, the spring 232 is compressed between the fixed plate 250 and the connection moving bar 240 as the connection moving bar 240 descends.

And on the contrary, when the air extraction through the air extraction hole of the air cylinder 231 is stopped, as shown in FIG. 4, the internal space on the side of the air extraction hole in the cylinder body 231a changes from negative pressure to atmospheric pressure. As the spring 232 is stretched upward with the lower end supported by the fixed plate 250 and elastically compresses the connection moving bar 240, the connection moving bar 240 rises and interlocks with the inner cylinder drive shaft 223a. ) Rises.

Accordingly, the driving standby gear 223c is gear-engaged with the driven small gear 223f, so that the inner cylinder 210 rotates at high speed and low torque, thereby effectively dewatering the mixing object in the inner cylinder 210.

Furthermore, although not shown in the drawings, an additional air cylinder may be used instead of the spring 232. That is, the lifting of the inner cylinder drive shaft 223a can be implemented with two air cylinders arranged in opposite directions to each other.

Meanwhile, the inner cylinder drive connector 223 may have a gear structure such that the rotational speed of the inner cylinder 210 when the mixing object is dehydrated is 5 times or more faster than the rotational speed of the inner cylinder 210 when the mixing object is crushed.

As a specific example, the inner cylinder drive connection 223 is configured such that the inner cylinder 210 is 50rpm to 350rpm when the mixing object is crushed, and the inner cylinder 210 is 1500rpm to 3500rpm when the mixing object is dehydrated.

By the configuration of the inner cylinder drive connection 223, the present invention can increase the torque by lowering the rotation speed of the inner cylinder 210 when the mixing object is pulverized, and the rotation speed of the inner cylinder 210 when the mixing object is dehydrated. You can maximize the dehydration effect by raising it to the maximum.

Meanwhile, the mixer according to the present invention may further include a vacuum unit 400 configured to form a vacuum in the inner cylinder 210 as shown in FIG. 2.

The vacuum unit 400 may include a suction pipe and a vacuum driving unit 410.

Here, the suction pipe is formed inside the outer cover, the outer cover covers the outer cylinder 110 and communicates with the outer cylinder 110 when closed, and at the same time communicates with the inner cylinder 210 disposed in the outer cylinder 110. I can have it.

In addition, the vacuum driving unit 410 is connected to a suction pipe, and may be formed of a vacuum motor and a vacuum pump.

The blender of the present invention allows the mixing operation including the grinding operation and the dehydration operation to be performed under vacuum by the vacuum unit 400 configured as described above, so that the mixing object including fruits and vegetables is not oxidized. As a result, fresh, nutrient-indestructible juices can be obtained.

As a result, the dehydration mixer according to the present invention takes a structure in which the gear fastening structure of the inner cylinder drive connection part 229 is variable so that the inner cylinder 210 has different rotational speeds during pulverization and dehydration of the mixing object. Accordingly, when the mixing object is pulverized, the torque is raised while lowering the reverse rotation speed of the inner cylinder 210, and the mixing object close to the inner side of the inner cylinder 210 among the mixing objects rotated forward by the forward rotation of the grinding blade 120 When the pulverized mixing object is dehydrated, the rotational speed of the inner cylinder 210 can be increased as much as possible when the pulverized mixing object is pulverized to maximize the dehydration effect.

In addition, the dehydration mixer according to the present invention comprises a pressing member 230 that presses the inner cylinder drive shaft 223a until the gear fastening structure of the inner cylinder drive connection part 223 is variablely completed, so that the inner cylinder drive shaft 223a is If the gear teeth of the gears do not mesh with each other even when the shaft moves, the internal cylinder drive shaft 223a is continuously pressed in the axial direction until the gear fastening structure is variable, so that the gear teeth eventually mesh with each other while the gear rotates, thereby driving the internal cylinder. The gear fastening structure of the connection part 223 may be completely variable.

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those of ordinary skill in the art to which the present invention pertains. It goes without saying that various modifications and variations are possible within the equivalent range of the claims to be described.

100: mixer body 110: external cylinder
110a: outer cylinder cover 120: grinding blade
130: blade drive unit 131: blade rotation shaft
132: blade driving motor 140: mixer cover
200: inner cylinder unit 210: inner cylinder
210a: inner cover 210b: spin-off hole
213: protrusion 220: inner cylinder driving part
221: inner cylinder rotation shaft 300: cylinder support case
400: vacuum unit 410: vacuum drive unit
222: inner cylinder drive motor 222a: motor shaft
222b: hollow (of the motor shaft) 223: inner cylinder drive connection
223a: inner cylinder drive shaft 223b: small drive gear
223c: drive gear 223d: intermediate rotation shaft
223e: driven standby gear 223f: driven small gear
223h: Shaft rotation bearing
230: pressing member 231: air cylinder
231a: cylinder body 231b: plunger
H: (of plunger) head R: (of plunger) rod
240: connection moving bar 250: fixed plate

Claims (10)

A mixer body having an outer cylinder opened and closed by a mixer cover, a grinding blade, and a blade driving part for rotating the grinding blade; And
And an inner cylinder unit disposed in the outer cylinder, the grinding blade disposed therein, at least one protrusion formed on an inner side surface, an inner cylinder having a drain hole, and an inner cylinder driving portion for rotating the inner cylinder, and
The blade rotation shaft of the blade drive unit is installed to be axially rotated in a hollow formed in the inner cylinder rotation shaft of the inner cylinder drive unit, and the blade rotation shaft and the inner cylinder rotation shaft rotate independently of each other,
The inner cylinder drive unit,
The inner cylinder rotation shaft, the inner cylinder drive motor, and an inner cylinder drive connection for connecting the inner cylinder rotation shaft and the inner cylinder drive motor,
A pressing member for reciprocating the inner cylinder drive shaft connected to the inner cylinder driving motor by pressing in the axial direction so that the inner cylinder has different rotational speeds during crushing and dehydration of the mixing object to change the gear fastening structure of the inner cylinder driving connector. Dehydration blender provided.
The method of claim 1,
The pressing member,
And an air cylinder for pressing the inner cylinder drive shaft in the axial direction.
The method of claim 1,
The pressing member,
And an air cylinder for pressing the inner cylinder drive shaft in one direction of the axial direction, and a spring for pressing the inner cylinder drive shaft in the other direction of the axial direction.
The method according to claim 2 or 3,
The air cylinder,
A cylinder body having an air extraction hole in communication with an external air pump formed on one side thereof; And
A head part built into the cylinder body and moved along the longitudinal direction of the cylinder body by air extraction through the air extraction hole, and extending from the head part to the outside of the cylinder body by the inner cylinder drive shaft and the connecting moving bar. And a plunger having a connected rod portion,
The inner cylinder drive shaft is dewaterable mixer, characterized in that the shaft rotationally fastened to the connection moving bar.
The method of claim 4,
The spring,
One end is supported on a fixed plate fastened so that the inner cylinder drive shaft is axially moved and rotated, and the other end is supported by the connection movable bar, and when the air extraction of the air cylinder is stopped, the connection movable bar is elastically compressed by the air cylinder. Dewaterable blender, characterized in that for reversely moving the moved connection moving bar.
The method of claim 1,
The inner cylinder drive connection part,
A driving small gear and a driving standby gear are installed on the inner cylinder drive shaft, and a driven standby gear and a driven small gear are installed on the inner cylinder rotation shaft or an intermediate rotation shaft interlocked with the inner cylinder rotation shaft,
When the inner cylinder drive shaft reciprocates in the axial direction, or the inner cylinder rotation shaft or the intermediate rotation shaft reciprocates in the axial direction, when the driving small gear and the driven standby gear are geared together, the driving standby gear and the driven small gear are non-gear-fastened, When the driving standby gear and the driven small gear are geared together, the driving small gear and the driven small gear are non-gear-fastened.
The method of claim 1,
The inner cylinder drive shaft,
A dewaterable mixer, characterized in that one end is slide-fastened so as to be axially movable while being key-fastened so as to be axially coupled to the motor shaft of the inner cylinder drive motor.
The method of claim 7,
The motor shaft has a hollow cross section, and the inner cylinder drive shaft has a cross section of one end matched with the hollow cross section of the motor shaft,
The inner cylinder drive shaft is dewaterable mixer, characterized in that the other end is connected to the shaft moving member by a shaft rotation bearing.
The method of claim 1,
The inner cylinder drive connection part,
A dewaterable mixer, characterized in that the gear structure is configured such that the rotational speed of the inner cylinder when the mixing object is dehydrated is 5 times or more faster than the rotational speed of the inner cylinder when the mixing object is pulverized.
The method of claim 9,
The inner cylinder drive connection part,
A dewatering mixer, characterized in that the gear structure is configured such that the inner cylinder is 50 rpm to 350 rpm when the mixing object is pulverized, and the inner cylinder is 1500 rpm to 3500 rpm when the mixing object is dehydrated.

Images