KR102276970B1 - Driving apparatus for mixer - Google Patents

Abstract

A driving device for a mixer according to the present invention comprises: a mixer main body which comprises a blade driving motor for rotating a grinding blade; and a cover unit which is installed at the mixer main body and covers the blade driving motor in a multiple manner to prevent operating noise of the blade driving motor from being transferred to the outside. According to the present invention, a level of the operating noise of the mixer can be highly reduced.

Description

The drive device of the mixer {DRIVING APPARATUS FOR MIXER}

The present invention relates to a driving device for a mixer, and to a driving device for a mixer for driving the mixer.

In general, a mixer is an electric device consisting of a container (cup) for putting a mixing object 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 stainless steel grinding blade is mounted in the lower part of the container while being engaged with the driving part.

As such a grinding blade rotates at high speed, it has been widely used at home for the purpose of cutting and pulverizing the mixing object including fruits and vegetables, and for extracting the juice of the mixing object.

However, as the blender generates a large noise when operating in the blade driving motor that rotates the grinding blade at high speed, the user has great inconvenience due to the loud operating noise when operating the blender, and furthermore, damage to the surroundings due to such noise pollution There is a problem with giving

Republic of Korea Patent Publication No. 10-1772862

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a driving device for a mixer capable of reducing the operation noise of the mixer.

In order to achieve the above object, a driving device of a mixer according to the present invention includes: a mixer body including a blade driving motor for rotating a grinding blade; and a cover unit that is installed in the mixer body and covers the blade drive motor multiple times so as to block external transmission of the operation noise of the blade drive motor, wherein the cover unit is located inside the main body case of the mixer body. an inner cover which is disposed and covers the blade driving motor; and at least one outer cover that covers the inner cover from the outside of the inner cover.
In the cover unit, the cooling fan provided on the upper part of the blade drive motor blows air toward the blade drive motor when it is operated, and an air discharge path is a path through which air is discharged from the inside of the inner cover to the outside of the mixer. It is formed in a straight line without bending,
The blade driving motor, the inner cover, and the outer cover are installed on the upper portion of the base plate inside the main body case of the mixer body, and a base discharge hole is formed in a portion of the base plate below the blade driving motor, and the base is discharged. A case discharge hole is formed in a part of the body case under the hole, and the air discharge passage is a path through which air sequentially passes through the base discharge hole and the case discharge hole from the cooling fan inside the inner cover. formed on the lower side.

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And, a case supply hole is formed at the lower end of the side of the main body case, a base supply hole is formed in a portion of the base plate on the lower side between the outer cover and the inner cover, and a cover supply hole is formed in the upper part of the inner cover, , an air supply passage that sequentially passes through the base supply hole and the cover supply hole from the case supply hole may be formed.

On the other hand, located in the rotation direction of the cooling fan at the edge of the cover supply hole so that the air supplied to the inside of the inner cover through the cover supply hole flows into the inner cover along the rotation direction of the cooling fan. The portion of the cooling fan may be extended in a direction opposite to the rotation of the cooling fan while protruding upward to form an air guide portion.

In the drive device of the mixer according to the present invention, a cover unit for multiple covers of the blade drive motor is configured to block external transmission of the operation noise of the blade drive motor, so that the noise of the motor generated from the blade drive motor is transmitted to the outside of the mixer. By blocking the exit, it is possible to significantly reduce the size of the operating noise of the mixer.

In addition, in the present invention, the air discharge flow path is configured in a straight line so that it is not bent, and specifically, by taking a structure formed in the longitudinal direction downward, the air discharged from the inside of the inner cover is discharged from the inner cover to the outside at a high speed without changing the direction. Accordingly, it is possible to increase the cooling efficiency of the blade drive motor by smoothly discharging air.

In addition, the present invention, when air is blown from the cooling fan to the lower blade drive motor, by the inner side of the inner cover that covers the blade drive motor around the blade drive motor, the air is not diffused and concentrated to control the blade drive motor By cooling, it is possible to further increase the cooling efficiency of the blade drive motor.

Furthermore, according to the present invention, the air guide part is configured on the upper part of the inner cover, so that air supplied to the inside of the inner cover through the cover supply hole flows into the inside of the inner cover along the rotational direction of the cooling fan, so that the air is supplied to the cover It is more smoothly supplied to the inside of the inner cover through the hole, and the cooling efficiency for the blade driving motor can be further increased.

1 is a view showing a mixer equipped with a driving device according to the present invention.
2 and 3 are views showing the configuration of the mixer of FIG. 1 excluding the cover unit.
Figure 4 is a view showing the covering of the blade drive motor of Figure 2 with the cover unit of the drive device according to the present invention.
5 is an exploded perspective view illustrating the cover unit of FIG. 4 being disassembled from the base plate.
6 is a longitudinal cross-sectional perspective view showing the inside of the main body case of FIG.

Hereinafter, preferred embodiments will be described in detail so that those of ordinary skill in the art can easily practice the present invention with reference to the accompanying drawings. However, in describing a preferred embodiment of the present invention in detail, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the same reference numerals are used throughout the drawings for parts having similar functions and functions. In addition, in this specification, terms such as 'top', 'top', 'top', 'bottom', 'bottom', 'bottom', 'side', etc. are based on the drawings, and in fact, elements or components may vary depending on the direction in which the is placed.

In addition, throughout the specification, when a part is 'connected' with another part, it is not only 'directly connected' but also 'indirectly connected' with another element interposed therebetween. include In addition, 'including' a certain component means that other components may be further included, rather than excluding other components, unless otherwise stated.

FIG. 1 is a view showing a mixer equipped with a driving device according to the present invention, and FIGS. 2 and 3 are views showing the configuration of the mixer of FIG. 1 excluding the cover unit.

Referring to the drawings, the mixer includes a mixer body 100 and a cover unit 200 .

Here, the mixer body 100 includes a grinding blade 110 and a blade driving unit 120 for rotating the grinding blade 110 .

Specifically, the grinding blade 110 is disposed in the rotary tube 130 of the barrel unit 200, and serves to pulverize the mixing object in the rotary tube 130 during rotation. In this case, the mixing object refers to food that is pulverized by the operation of the mixer.

In addition, the blade driving unit 120 is configured to provide a driving force for rotating the grinding blade 110 , and may include a blade rotating shaft 122 and a blade driving motor 121 .

Here, the blade rotation shaft 122 takes a structure linked to the lower portion of the crushing blade 110 .

This blade rotation shaft 122 connects the grinding blade 110 and the blade driving motor 121 to transmit the rotational driving force of the blade driving motor 121 to the grinding blade 110 to grind when the blade driving motor 121 is operated. The blade 110 is rotationally driven.

At this time, the blade rotation shaft 122 and the blade drive motor 121 may be connected to a blade drive connection line 123 such as a timing belt.

In addition, the mixer body 100 may include a rotary tube 130 and a tube driving unit 140 .

The rotary cylinder 130 has a structure with a crushing blade 110 disposed therein and an open upper portion thereof, and is configured to be opened and closed by the cylinder cover 150 .

In addition, the rotary tube 130 may have a protrusion 131 formed on the inner side so that the mixing object that rotates and flows while being pulverized by the crushing blade 110 is caught.

In addition, the barrel driving unit 140 is a configuration that provides a driving force for rotating the rotary tube 130 , and may include a barrel drive motor 141 and a barrel rotation shaft 142 .

Here, the tube rotation shaft 142 takes a structure linked to the lower portion of the rotation tube 130 .

This tubular rotation shaft 142 connects the rotator 130 and the tubular driving motor 141 to transmit the rotational driving force of the tubular driving motor 141 to the rotator 130 to rotate when the tubular driving motor 141 is operated. Tradition 130 is rotationally driven.

At this time, the through-drive motor 141 may be connected to the through-rotation shaft 142 and the through-drive connection line 143 such as a timing belt.

On the other hand, the aforementioned blade driving unit 120 and the barrel driving unit 140 can be controlled by a controller (not shown), specifically, the blade driving motor 121 and the barrel driving unit 140 of the blade driving unit 120 . The drive motor 141 is electrically connected to the controller, and the blade drive motor 121 and the barrel drive motor 141 are controlled by the controller.

In the conventional mixer, as the grinding blade 110 rotates in only one direction, the mixing object continues to rotate in only one direction in the mixer barrel, and the mixing object is maintained like a wall in a state in which it is pushed out toward the inner side of the mixer barrel, As it does not return to the grinding blade 110 again, the grinding performance is remarkably deteriorated.

Of course, even in the conventional mixer, a protrusion is formed on the inner wall of the mixer barrel to create a certain amount of vortex in the mixing object, but this is also implemented as a flow with a regular pattern, so there is a limit in that the mixing object is not well pulverized.

Accordingly, in the mixer according to the present invention, in order to realize the irregular flow of the mixing object, that is, in order for the controller to break the balanced state of the mixing object in the rotary tube 130, the rotation direction of the grinding blade 110 and the opposite direction As a result, the cylinder 130 can control the barrel driving unit 140 to mix the mixing object while repeating a pattern that stops after reverse rotation, or a pattern that changes speed after reverse rotation.

As described above, the mixer according to the present invention controls the barrel 140 so that the controller breaks the balanced state of the mixing object, so that the mixing object is not stacked up like a wall on the inner side of the rotary tub 130, As it returns back to the grinding blade 110 rotating in the central part of the rotary tube 130, the grinding performance can be significantly increased.

That is, the mixer according to the present invention is configured to break the balanced state of the mixing object, thereby breaking down the mixing object maintained like a wall on the inner side of the rotary tube 130, ultimately increasing the grinding performance of the mixing object can do it

Specifically, the mixing object is moved to the inner side of the rotary tube 130 by the centrifugal force caused by the rotation of the grinding blade 110 in the process of mixing, at this time, the balance (balance) of the force between the particles of the mixing object is achieved. In this case, as it is stopped without moving any more, it does not move toward the grinding blade 110, so that the grinding is no longer possible.

However, the balance of the forces between the particles of the mixing object is unbalanced by repeating a pattern in which the rotary tube 130 stops after reverse rotation in the mixer according to the present invention, or a pattern in which the speed changes after reverse rotation. Accordingly, the particles flow again and as they move toward the grinding blade 110 in this flow process, the grinding is continuously performed.

Figure 4 is a view showing the cover unit of the drive device according to the present invention covering the blade driving motor of Figure 2, Figure 5 is an exploded perspective view showing that the cover unit of Figure 4 is disassembled from the base plate, Figure 6 is It is a longitudinal cross-sectional perspective view showing the inside of the main body case of FIG.

Referring to the drawings, the cover unit 200 of the present invention is installed in the mixer main body 100 so as to cover the blade driving motor 121 multiple times.

This cover unit 200 has a role to block the external transmission of the operation noise of the blade drive motor (121).

Specifically, the cover unit 200 includes an inner cover 210 and an outer cover 220 .

The inner cover 210 covers the blade driving motor 121 .

Also, the outer cover 220 covers the inner cover 210 from the outside of the inner cover 210, and one such outer cover 220 is provided in the drawing to cover the inner cover 210, but is not limited thereto. One or more may be provided to cover the inner cover 210 in multiple numbers.

As such, the present invention includes an inner cover 210 and one or more outer covers 220, thereby covering the blade drive motor 121 with a cover configuration formed in at least two layers, resulting in the blade drive motor 121 By blocking the noise of the motor from going to the outside of the mixer, it is possible to significantly reduce the size of the operating noise of the mixer.

Furthermore, the present invention is configured to lower the heat of the motor generated during operation of the blade drive motor 121 as much as possible despite the blade drive motor 121 being covered due to the cover unit 200 .

That is, in the present invention, a cooling fan 121a is provided on the upper portion of the blade driving motor 121 so that the blade driving motor 121 is cooled by the operation of the cooling fan 121a, and the cooling efficiency by the cooling fan 121a An air discharge flow path may be formed so that the air exiting from the inner cover 210 can be smoothly discharged to increase the temperature.

Specifically, in the present invention, the cooling fan 121a provided on the upper part of the blade driving motor 121 is configured to blow air toward the blade driving motor 121, and also from the inside of the inner cover 210 to the outside of the mixer. An air discharge path, which is a path through which air is discharged, may be formed in a straight line without being bent.

As such, the air discharge flow path is formed in a straight-line structure, not in a bent or bent shape, so that the air escaping from the inside of the inner cover 210 is prevented from being discharged smoothly due to a change of direction in the discharging process. can

In other words, in the present invention, since the air discharge flow path is non-bent and linear, the air exiting from the inside of the inner cover 210 can be discharged from the inner cover 210 to the outside at a high speed without changing the direction.

More specifically, the present invention may take the following structure so that the air discharge passage takes a non-curved straight structure.

The blade driving motor 121 , the inner cover 210 , and the outer cover 220 are installed on the base plate 190 inside the main body case 180 of the mixer main body 100 .

Here, the inner cover 210 and the outer cover 220 take a lower open structure to cover the blade drive motor 121 while descending from the upper side of the blade drive motor 121 to the blade drive motor 121 side.

At this time, the base discharge hole 190b is formed in the portion of the base plate 190 under the blade driving motor 121, and the case discharge hole 180b is formed in the portion of the body case 180 under the base discharge hole 190b. can be formed.

Accordingly, the air discharge path may be formed as a path through which air sequentially passes through the base discharge hole 190b and the case discharge hole 180b from the inside of the inner cover 210 .

That is, the air blown from the cooling fan 121a cools the blade driving motor 121 downward, and then passes through the base discharge hole 190b and the case discharge hole 180b sequentially to be discharged to the outside of the mixer. .

In this way, the cooling fan 121a, the blade driving motor 121, the base discharge hole 190b, and the case discharge hole 180b are sequentially arranged downward, so that the air discharge flow path can form a structure formed in the longitudinal direction downward. .

In this way, the present invention is configured in a straight line so that the air discharge flow path is non-bent, and specifically, by taking a structure formed downward in the longitudinal direction, the air discharged from the inside of the inner cover 210 is rapidly discharged without changing the direction of the inner cover ( As it is discharged from the 210) to the outside, the air discharge is made smoothly, so that it is possible to increase the cooling efficiency for the blade driving motor 121.

Further, when air is blown from the cooling fan 121a to the blade drive motor 121 on the lower side, the inner side of the inner cover 210 that covers the blade drive motor 121 around the blade drive motor 121 by the inner side , as the air is concentrated and not diffused to cool the blade drive motor 121, the cooling efficiency for the blade drive motor 121 can be further increased.

On the other hand, in the present invention, the air supply passage, which is a path through which air is supplied from the outside of the mixer to the inside of the inner cover 210 , passes between the outer cover 220 and the inner cover 210 and through the upper portion of the inner cover 210 . It can take a structure leading to the inside of the inner cover (210).

Specifically, according to the present invention, the case supply hole 180a is formed at the lower end of the side of the main body case 180 , and the base supply hole is formed in a portion of the base plate 190 on the lower side between the outer cover 220 and the inner cover 210 . A 190a is formed, and a cover supply hole 210a may be formed in the upper portion of the inner cover 210 .

Accordingly, the air supply passage may be formed by sequentially passing through the base supply hole 190a and the cover supply hole 210a from the case supply hole 180a.

That is, the air introduced through the case supply hole 180a from the outside of the mixer is introduced between the outer cover 220 and the inner cover 210 through the base supply hole 190a and moves to the upper side of the inner cover 210. Then, it may be supplied to the inner cover 210 through the cover supply hole (210a).

As such, by taking a structure in which the air supply flow path rises along between the outer cover 220 and the inner cover 210 and then descends through the cover supply hole 210a formed on the upper portion of the inner cover 210, it becomes curved. It may be formed in a straight line, and accordingly, although the air is supplied to the inner cover 210 while changing the direction, air may be supplied to the inside of the inner cover 210 at a high speed.

When comparing the air supply flow path and the air discharge flow path in the flow of air, the structure of the air discharge flow path has a relatively greater influence on the flow of air.

Specifically, when the air discharge is smoothly performed first, the air supply is performed smoothly as a large negative pressure is formed in the inner space of the inner cover 210. On the contrary, if the air discharge is not performed smoothly first, the inner cover 210 ), as the negative pressure is not sufficiently large in the internal space, the air supply is not performed smoothly.

For example, in the present invention, if the air supply passage and the air discharge passage are configured to be opposite, that is, if the flow arrow direction of the air shown in the drawing is formed in the opposite direction, the supply of air is not substantially made smoothly.

Specifically, even if the air supply passage is formed in a non-curved straight shape, when the air discharge passage is curved and non-linear, air is not smoothly supplied through the air supply passage.

That is, when air is discharged through the curved non-linear air discharge passage, the air collides with the inner wall of the portion where the direction of the air discharge passage changes, so that the discharge speed is significantly reduced and vortex is also generated in the portion where the direction is changed, so that the discharge is smooth will not be done.

Meanwhile, in the present invention, the air guide part 211 may be formed on the inner cover 210 .

The air guide part 211 allows the air supplied to the inside of the inner cover 210 through the cover supply hole 210a to flow into the inner cover 210 along the rotational direction of the cooling fan 121a. play a role

Specifically, the air guide part 211 is formed by extending in the direction opposite to the rotation of the cooling fan 121a while protruding upward from the edge of the cover supply hole 210a in the rotational direction of the cooling fan 121a. do.

Accordingly, the cover supply hole 210a is changed from a structure in which the inlet through which air is introduced is disposed in the transverse direction on the upper surface of the inner cover 210 to a vertically erected structure due to the air guide part 211 , as well as a cooling fan. By having a structure facing in the direction opposite to the rotation of the 121a, the air supplied to the inside of the inner cover 210 through the cover supply hole 210a moves along the rotational direction of the cooling fan 121a of the inner cover 210. Let it flow inward.

As such, due to the air guide unit 211, the air supplied to the inside of the inner cover 210 through the cover supply hole 210a flows into the inner cover 210 along the rotational direction of the cooling fan 121a. Accordingly, as the air is more smoothly supplied to the inside of the inner cover 210 through the cover supply hole 210a, it is possible to further increase the cooling efficiency for the blade driving motor 121.

As a result, the drive device of the mixer according to the present invention is configured with a cover unit 200 that multi-covers the blade drive motor 121 to block the external transmission of the operation noise of the blade drive motor 121, so that the blade drive motor By blocking the noise of the motor generated in (121) from going to the outside of the mixer, it is possible to significantly reduce the size of the operating noise of the mixer.

In addition, the present invention is configured in a straight line so that the air discharge flow path is non-bent, and specifically, by taking a structure formed downward in the longitudinal direction, the air discharged from the inside of the inner cover 210 is rapidly discharged without changing the direction of the inner cover ( As it is discharged from the 210) to the outside, the air discharge is made smoothly, so that it is possible to increase the cooling efficiency for the blade driving motor 121.

In addition, in the present invention, when air is blown from the cooling fan 121a to the blade drive motor 121 on the lower side, the inner cover 210 that covers the blade drive motor 121 around the blade drive motor 121 By the side, as the air is concentrated and not diffused to cool the blade drive motor 121, it is possible to further increase the cooling efficiency for the blade drive motor 121.

Furthermore, according to the present invention, the air guide part 211 is configured on the upper part of the inner cover 210, so that the air supplied to the inside of the inner cover 210 through the cover supply hole 210a rotates the cooling fan 121a. As the air flows into the inner cover 210 along the direction, the air is more smoothly supplied to the inside of the inner cover 210 through the cover supply hole 210a, and the cooling efficiency for the blade driving motor 121 is increased. can be raised even higher.

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains will realize that the present invention may be embodied in other specific forms without changing the technical spirit or essential features thereof. You will understand. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

100: mixer body 110: grinding blade
120: blade driving unit 121: blade driving motor
121a: cooling fan 122: blade rotation shaft
123: blade drive line 130: rotary tube
131: protrusion 140: tonggudong
141: through-drive motor 142: through-rotation shaft
143: Tonggudong line 150: Tong cover
180: body case 180a: case supply hole
180b: case discharge hole 190: base plate
190a: base supply hole 190b: base discharge hole
200: cover unit 210: inner cover
210a: cover supply hole 211: air guide part
220: outer cover

Claims (5)

a mixer body including a blade driving motor for rotating the grinding blade; and
It is installed on the mixer body, so as to block external transmission of the operation noise of the blade drive motor, a cover unit for multiple covers of the blade drive motor; includes,
The cover unit is disposed inside the main body case of the mixer body,
an inner cover covering the blade drive motor; and
At least one outer cover that covers the inner cover from the outside of the inner cover; includes,
The cover unit is
The cooling fan provided on the upper part of the blade drive motor blows air toward the blade drive motor during operation,
An air discharge flow path, which is a path through which air is discharged from the inside of the inner cover to the outside of the mixer, is formed in a straight line without bending,
The blade driving motor, the inner cover, and the outer cover are installed on the upper portion of the base plate inside the main body case of the mixer body,
A base discharge hole is formed in a portion of the base plate under the blade drive motor, and a case discharge hole is formed in a portion of the main body case under the base discharge hole, and the air discharge flow path allows air to pass through the inner side of the inner cover. A drive device for a mixer, characterized in that it is formed in the longitudinal direction as a path sequentially passing through the base discharge hole and the case discharge hole from the cooling fan of the mixer.
delete delete According to claim 1,
A case supply hole is formed in the lower end of the side of the main body case, a base supply hole is formed in a portion of the base plate on the lower side between the outer cover and the inner cover, and a cover supply hole is formed in the upper part of the inner cover,
An air supply flow passage sequentially passing through the base supply hole and the cover supply hole from the case supply hole is formed.
5. The method of claim 4,
so that the air supplied to the inner side of the inner cover through the cover supply hole is introduced into the inner cover along the rotational direction of the cooling fan,
A driving device for a mixer, characterized in that a portion positioned in the rotational direction of the cooling fan from the edge of the cover supply hole extends in a direction opposite to the rotation of the cooling fan while protruding upward to form an air guide portion.

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