KR101908019B1 - Noise reducing type vacuum blender - Google Patents

Abstract

The present invention relates to a vacuum blender with reduced noise and, more specifically, to a vacuum blender with reduced noise which can reduce noise produced when operating a blender while grinding food in a vacuum state. According to the present invention, the vacuum blender with reduced noise comprises: an accommodation member in which food is accommodated; a first check valve mounted on the accommodation member; a chamber member to cover the accommodation member; and a second check valve mounted on the chamber member. A vacuum unit is formed between the accommodation member and the chamber member. When a vacuum pump arranged on the outside operates while a suction hose of the vacuum pump is coupled to the second check valve, air in the vacuum unit is discharged to the outside by the second check valve and the vacuum pump, and the first check valve is opened by a vacuum pressure to discharge air in the accommodation member to the outside through the first check valve, the vacuum unit, and the second check valve by the vacuum pump.

Description

TECHNICAL FIELD [0001] The present invention relates to a noise reduction type vacuum blender,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a noise reduction type vacuum blender, and more particularly, to a noise reduction type vacuum blender capable of reducing noises generated during operation of a blender while pulverizing food in a vacuum state.

The blender (blender) is one of the most used electric appliances in the home today, and it can grind fruits such as fruits, vegetables and grains finely by using the mixer blade rotatably installed in the bottom of the storage container.

In general, the blender is rotated in a high speed rotating motor by closing the lid after inserting the food to be crushed into the storage container. In this process, the air in the storage container and the crushed food granules are mixed at a high speed and many bubbles are generated .

For example, when a fruit such as a banana or a tomato is put in a blender and crushed, a large amount of air bubbles are generated in the upper part of the fruit juice.

This not only lowers the taste and texture of fruit juices, but also means that the fruit fibers have already been oxidized during the grinding process and the nutrients have been largely destroyed.

In addition, when foods are stored without being consumed immediately after they are crushed, if they are stored in an air-exposed state, the oxidation process progresses more rapidly, the destruction of fibers and nutrients accelerates, the color is discolored, And layer separation occurs between food and food.

The foodstuffs crushed by the blender were difficult to store for a long period of time unless they were eaten immediately.

To solve these problems, a vacuum mixer designed to grind foods in a vacuum state has been developed.

On the other hand, since the blender grinds the food while rotating the blade by the motor, noise and crushing noise of the motor are generated.

And since the vacuum mixer requires a vacuum pump for the vacuum, it generates more noise than a conventional mixer.

Published Japanese Patent Application No. 10-2016-0137451

SUMMARY OF THE INVENTION It is an object of the present invention to provide a noise reduction type vacuum blender capable of minimizing noise transmitted to the outside by blocking noise generated during operation of a blender.

According to an aspect of the present invention, there is provided a noise reduction type vacuum blender including: a driving body having a motor mounted therein; A receiving member detachably coupled to an upper portion of the driving body and having a receiving portion for receiving food therein; A blade disposed in the receiving portion and connected to the motor to break the food contained in the receiving portion; A chamber member detachably coupled to the driving body while covering the outside of the housing member; A first check valve mounted to the housing member and selectively opened only when the air is discharged from the housing portion to the outside through the housing portion and the chamber member; A vacuum chamber formed along the periphery of the housing member between the outside of the housing member and the interior of the chamber member; And a second check valve mounted on the chamber member and opened only when air is externally discharged from the vacuum chamber by selectively communicating the vacuum chamber with the outside of the vacuum chamber, When the hose is coupled to the second check valve, the air inside the vacuum chamber is discharged to the outside through the second check valve and the vacuum pump when the vacuum pump is operated, And the air in the accommodating portion is discharged to the outside through the first check valve, the vacuum chamber and the second check valve through the vacuum pump.

The second check valve is forcibly opened to release the vacuum of the vacuum chamber existing in the chamber member.

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And a cushioning member having one end abutting the outer circumferential surface of the housing member and the other end abutting the inner circumferential surface of the chamber member to reduce vibration of the housing member.

The buffer member is coupled to the inner circumferential surface of the chamber member and the buffer member is brought into close contact with the outer circumferential surface of the receiving member while the chamber member is bent toward the receiving member by the vacuum pressure in vacuum of the vacuum.

A vacuum channel is formed in a side wall of the driving body to communicate with the vacuum, and the vacuum channel is evacuated during operation of the vacuum pump.

The vacuum channel is formed along the periphery of the motor, and the lower end of the vacuum channel is formed to be longer than the lower portion of the motor.

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The chamber member is tightly coupled to the driving body by a vacuum pressure during vacuuming of the vacuum chamber.

The noise reduction type vacuum blender of the present invention as described above has the following effects.

Since the food is crushed in a vacuum state, it is possible to prevent a phenomenon such that the crushed food comes into contact with the air and the food is discolored or the nutrient is destroyed.

Particularly, the present invention can reduce the noise transmitted to the outside by blocking the noise generated during the operation of the blender through the vacuum, the vacuum channel, and the like.

1 is a side view of a noise reducing vacuum blender according to a first embodiment of the present invention;
FIG. 2 is a process diagram illustrating the operation of the noise reduction type vacuum blender according to the first embodiment of the present invention. FIG.
3 is a side view of a noise-reducing type vacuum blender according to a second embodiment of the present invention.
FIG. 4 is a view illustrating an operation process of a noise reduction type vacuum blender according to a second embodiment of the present invention. FIG.

First Embodiment

FIG. 1 is a side view of a noise reduction type vacuum blender according to a first embodiment of the present invention, and FIG. 2 is an operation and a degree of a noise reduction type vacuum blender according to the first embodiment of the present invention.

The noise reduction type vacuum blender of the present invention comprises a driving body 10, a housing member 20, a blade 25, a chamber member 30, a first check valve 41, a vacuum pump 50 ) And the like.

The driving body 10 has a motor 11 mounted therein.

The receiving member 20 is formed with a receiving portion 21 for receiving food or the like therein and is detachably coupled to the upper portion of the driving body 10.

The blade 25 is disposed in the receiving portion 21 and is connected to the motor 11 and rotates to grind food and beverage stored in the receiving portion 21. [

The chamber member 30 has a cup shape and is detachably coupled to the driving body 10 while covering the outside of the housing member 20. [

The first check valve 41 is mounted on the receiving member 20 and is opened only when air is discharged from the receiving portion 21 to the outside and is kept closed normally.

The first check valve 41 communicates the inside of the chamber member 30 with the accommodating portion 21 when the chamber member 30 covers the accommodating member 20.

The first check valve 41 may be mounted at various positions of the receiving member 20, but is preferably mounted on the upper portion of the receiving member 20.

Since the structure of the first check valve 41 is sufficient using a conventional known structure, a detailed description thereof will be omitted.

And a pivot 35 is formed between the outside of the housing member 20 and the inside of the chamber member 30.

The vacuum chamber 35 is formed entirely along the periphery of the housing member 20.

The vacuum pump (50) is mounted on the driving body (10).

The vacuum pump (50) communicates with the vacuum chamber (35).

A suction hole 18 connecting the vacuum chamber 35 and the vacuum pump 50 is formed in the driving body 10 and the suction hole 18 is formed in the housing 20, Is formed on the upper portion of the driving body (10) between the chamber members (30).

The suction hole 18 is communicated with the vacuum chamber 35 so that the air inside the vacuum chamber 35 and the accommodating portion 21 is supplied to the suction hole 18 To be evacuated to a vacuum.

More specifically, during operation of the vacuum pump 50, the air inside the vacuum chamber 35 passes through the suction hole 18 and is discharged to the outside through the vacuum pump 50.

In this case, since the suction hole 18 is formed between the vacuum chamber 35 and the receiving portion 21, the chamber member 30 is mounted on the driving body 10 in a specific direction The vacuum chamber 35 and the suction hole 18 are communicated with each other while being coupled to the upper portion of the driving body 10 without any need.

As the air inside the vacuum chamber 35 is discharged to the outside, the first check valve 41 is opened by the vacuum pressure of the vacuum chamber 35.

When the first check valve 41 is opened, air in the accommodating portion 21 is discharged to the vacuum chamber 35 through the first check valve 41, 18 and the vacuum pump 50, as shown in Fig.

Accordingly, as the vacuum pump 50 is operated, the vacuum chamber 35 and the receiving chamber 21 are in a vacuum state, and the chamber member 30 is vacuum- And is tightly coupled to the driving body 10.

By vacuuming the accommodating portion 21 as described above, the food can be crushed in a vacuum state at the time of crushing the foodstuff contained in the accommodating portion 21, thereby preventing the browning phenomenon and the destruction of nutrients caused by the food being connected with the air can do.

In addition, by vacuuming the vacuum chamber 35 formed on the outside of the accommodating portion 21, the noise generated during the grinding of the foodstuff contained in the accommodating portion 21, the noise of the blade 25, It is possible to more effectively reduce the amount of excitation to the outside as well as the excitation 30 due to the excitation by the vacuum excitation 35.

A pressure sensor 16 and a communication valve 17 are mounted on the driving body 10.

The pressure sensor 16 is attached to the driving body 10 and measures a pressure of air moving through the suction hole 18 to the vacuum pump 50.

The communication valve 17 opens and closes a path between the vacuum pump 50 and the vacuum chamber 35.

The communication valve 17 is a solenoid valve or the like and determines that the vacuum is established when the measured pressure value of the pressure sensor 16 is equal to or greater than a predetermined value, ), And may be opened as needed.

On the other hand, a vacuum channel 15 communicating with the vacuum chamber 35 is formed on the side wall of the driving body 10.

The entire upper surface of the vacuum channel 15 may be communicated with the vacuum chamber 35 or a part thereof may be communicated.

A side wall of the driving body 10 is formed in the vacuum channel 15 so as to surround the periphery of the motor 11.

Accordingly, when the vacuum pump 50 is operated, the air in the vacuum channel 15 is discharged to the outside, and the vacuum chamber 15 is evacuated together with the vacuum chamber 35.

As described above, since the vacuum channel 15 surrounding the periphery of the motor 11 is evacuated, noise generated during operation of the motor 11 can be prevented from being transmitted to the outside.

The lower end of the vacuum channel 15 is formed to be longer than the lower portion of the motor 11 so that the noise generated by the motor 11 is more effectively blocked by the vacuum channel 15 .

The present invention may further comprise a cushioning member (37) which has one end abutting the outer circumferential surface of the housing member (20) and the other end abutting the inner circumferential surface of the chamber member (30) have.

The buffer member 37 is made of rubber, cylinder, sponge, spring or the like having elasticity.

It is possible to minimize the generation of noise by suppressing the vibration of the receiving member 20 during pulverization by the buffer member 37 as described above.

In the drawings of the present embodiment, the buffer member 37 is brought into close contact with the upper surface of the housing member 20 and the upper inner circumferential surface of the chamber member 30 so that a plurality of the buffer members 37 are spaced apart from each other, .

The buffer member 37 is coupled to the inner circumferential surface of the chamber member 30 and is slightly spaced from the receiving member 20 so that the chamber member 30 can be vacuum- The cushioning member 37 may be brought into close contact with the outer circumferential surface of the housing member 20 while the buffer member 37 is bent toward the housing member 20 so that the housing member 20 and the chamber member 30 may be shaken have.

Hereinafter, an operation process of the present invention having the above-described configuration will be described.

The food is put into the accommodating portion 21 formed inside the accommodating member 20 and the accommodating member 20 is engaged with the drive main body 10.

At this time, the lower part of the blade 25 and the motor 11 are coupled and coupled to each other.

Then, the chamber member 30 is covered with the chamber member 30 so as to cover the outside of the housing member 20 and is coupled to the driving body 10.

At this time, the chamber member 30 may be coupled to the upper surface of the driving body 10 without specific mounting directionality.

When the power is applied in this state, the blade 25 rotates by the motor 11 to crush the foodstuffs present in the accommodating portion 21. [

The vacuum pump 50 operates to discharge the air existing in the vacuum chamber 35 and the accommodating portion 21 to the outside.

More specifically, air existing in the accommodating portion 21 moves to the vacuum chamber 35 as the first check valve 41 is opened, and then flows into the suction hole 18 and the vacuum pump 50, As shown in FIG.

The vacuum channel 15 formed on the side wall of the driving body 10 along the periphery of the motor 11 is also vacuumed as the vacuum chamber 35 is vacuumed.

As described above, when the accommodating portion 21 is vacuumed, it is possible to prevent the food from being discolored, the nutrients being destroyed or contaminated, and the like.

In addition, since the vacuum chamber 35 formed around the housing member 20 is vacuumed, noise generated during rotation of the blade 25 can be blocked.

In addition, as the vacuum channel 15 formed along the periphery of the motor 11 is vacuumed, noise generated during operation of the motor 11 and the vacuum pump 50 can be prevented from being diverted to the outside .

As the vacuum chamber 35 is evacuated, the chamber member 30 is further tightly coupled to the driving body 10, and the buffer member 37 is in close contact with the outer peripheral surface of the receiving member 20 It is possible to further prevent the receiving member 20 and the chamber member 30 from shaking.

The pressure sensor 16 measures the pressure of the air moving to the vacuum pump 50 through the suction hole 18 while the accommodating portion 21 and the vacuum chamber 35 are evacuated. The communication valve 17 closes the passage between the vacuum pump 50 and the vacuum chamber 35 when the pressure value measured by the pressure sensor 16 exceeds a predetermined value .

Therefore, the accommodating portion 21, the vacuum chamber 35 and the vacuum channel 15 can be maintained in a vacuum state.

After the grinding is completed, the communication valve 17 is opened to allow external air to move into the vacuum chamber 35 and the vacuum chamber 15, so that the vacuum of the vacuum chamber 15 and the vacuum chamber 15 Is released.

At this time, as the external air flows into the vacuum chamber 35, the first check valve 41 is closed and the vacuum chamber 21 is kept in a vacuum state without releasing the vacuum.

The chamber member 30 is separated and the vacuum in the accommodating portion 21 is released through the first check valve 41 and fresh food present in the accommodating portion 21 can be consumed .

As described above, according to the present invention, the food can be pulverized by vacuum, and noise generated during the operation of the blender, that is, the blender, can be reduced, and the product can be applied as a superior performance and product.

Second Embodiment

FIG. 3 is a side view of a noise reduction type vacuum blender according to a second embodiment of the present invention, and FIG. 4 is an operation and a degree of a noise reduction type vacuum blender according to a second embodiment of the present invention.

The second embodiment differs from the first embodiment in the second check valve 42, the vacuum pump, and the like, and will be mainly described.

In the first embodiment, the vacuum pump 50 is mounted on the driving body 10, but in the second embodiment, the vacuum pump exists outside the driving body 10.

The vacuum pump may be a separate device, or a conventional vacuum pump may use a vacuum packing machine or the like.

That is, in the second embodiment, the vacuum blender differs from the first embodiment in that the vacuum pump is not equipped with a vacuum pump but uses an external vacuum pump.

The second check valve 42 is mounted to the chamber member 30 and is opened only when air is discharged from the vacuum chamber 35 by selectively communicating the vacuum chamber 35 with the outside.

Since the specific structure of the second check valve 42 is sufficient by using a conventional known check valve structure, a detailed description thereof will be omitted.

The second check valve 42 may be installed at any position of the chamber member 30, but it is preferably mounted at the upper end of the chamber member 30 as in the present embodiment.

The second embodiment vacuum blender constructed as above operates as shown in Fig.

The receiving portion 21 and the chamber member 30 are engaged after putting food into the receiving portion 21 in the same manner as in the first embodiment.

The suction hose 55 of the vacuum pump disposed outside is brought into close contact with the upper portion of the second check valve 42.

In this state, when the motor 11 and the vacuum pump are operated, the air inside the vacuum chamber 35 passes through the second check valve 42 and the suction hose 55 and is discharged to the outside through the vacuum pump .

The first check valve 41 is opened by the vacuum pressure of the vacuum chamber 35 so that the air inside the accommodation chamber 21 flows through the first check valve 41, 2 check valve 42 and the suction hose 55 to the outside through the vacuum pump.

The air in the vacuum channel 15 formed on the side wall of the main body passes through the vacuum chuck 35, the second check valve 42 and the suction hose 55, .

Therefore, as in the first embodiment, the outer periphery of the accommodating portion 21 and the outer periphery of the motor 11 are evacuated, so that noise during operation can be reduced more effectively.

In the second embodiment, by forcibly opening the second check valve 42 by the user, the vacuum of the vacuum chamber 35 existing in the chamber member 30 can be released.

Other details are the same as in the first embodiment, and therefore, a detailed description thereof will be omitted.

The noise reduction type vacuum blender of the present invention is not limited to the above-described embodiments, but can be variously modified and embodied within the scope of the technical idea of the present invention.

10: driving body, 11: motor, 15: vacuum channel, 16: pressure sensor, 17: communicating valve, 18:
20: housing member, 21: receiving portion, 25: blade,
30: chamber member, 35: vacuum chamber, 37: buffer member,
41: first check valve, 42: second check valve,
50: vacuum pump, 55: suction hose.

Claims (7)

A drive main body having a motor mounted therein;
A receiving member detachably coupled to an upper portion of the driving body and having a receiving portion for receiving food therein;
A blade disposed in the receiving portion and connected to the motor to break the food contained in the receiving portion;
A chamber member detachably coupled to the driving body while covering the outside of the housing member;
A first check valve mounted to the housing member and selectively opened only when the air is discharged from the housing portion to the outside through the housing portion and the chamber member;
A vacuum chamber formed along the periphery of the housing member between the outside of the housing member and the interior of the chamber member;
And a second check valve mounted on the chamber member and opened only when air is discharged from the vacuum chamber to the outside by selectively communicating the vacuum chamber with the outside,
The air in the vacuum chamber is discharged to the outside through the second check valve and the vacuum pump when the vacuum pump is operated in a state where the suction hose of the vacuum pump disposed outside is coupled to the second check valve, The first check valve is opened by the pneumatic pressure so that the air in the accommodating portion is discharged to the outside through the first check valve, the vacuum check and the second check valve through the vacuum pump,
As the external air is introduced into the vacuum chamber, the first check valve is closed so that the receiving portion is kept in a vacuum state without releasing the vacuum,
And the vacuum in the receiving portion is released through the first check valve. The method according to claim 1,
And the second check valve is forcibly opened to release the vacuum of the vacuum chamber existing in the chamber member. The method according to claim 1,
Further comprising: a cushioning member having one end abutting the outer circumferential surface of the receiving member and the other end abutting the inner circumferential surface of the chamber member to reduce vibration of the receiving member. The method of claim 3,
Wherein the buffer member is coupled to the inner circumferential surface of the chamber member,
Wherein the chamber member is bent in the direction of the receiving member by the vacuum pneumatic pressure during vacuuming so that the buffer member is brought into close contact with the outer peripheral surface of the receiving member. The method according to claim 1,
A vacuum channel is formed on a side wall of the driving body to communicate with the vacuum,
Wherein the vacuum channel is evacuated during operation of the vacuum pump. The method of claim 5,
The vacuum channel is formed along the periphery of the motor,
And the lower end of the vacuum channel is formed to be longer than the lower portion of the motor or downward. The method according to claim 1,
Wherein the chamber member is tightly coupled to the driving body by a vacuum pressure when vacuum is applied to the vacuum chamber.

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