KR20150115129A - vacuum type mixing container of mixer - Google Patents

Abstract

The present invention relates to a new type of a vacuum type mixing container for a mixer which minimizes the bubble production amount by making a space where a corresponding mixing operation occurs while mixing various objects having moisture in a vacuum state, and enables the objects to be stored for a long period without putting the same in an additional place in a mixed state. To this end, the mixing container of the present invention comprises: a container main body having a container body of which an upper side is open; a floor portion for forming the floor of the container main body, having grinding blades installed to be rotated, and receiving a driving force for rotating the grinding blades by being installed in a mixer main body; an air tight cover formed to seal the open upper side of the container main body, having a communicating groove which connects the inside and the outside of the container main body in one part, and having a cylindrical protruding rib which protrudes from the circumference of the air tight groove; and a check valve assembly combined with the protruding rib of the air tight cover, making the communicating groove open when providing a vacuum suction force, and maintaining the communicating groove in a closed state when releasing the vacuum suction force.

Description

[0001] The present invention relates to a vacuum type mixing container for a mixer,

The present invention relates to a mixer container, and more particularly, to a mixer container that minimizes the amount of foam generated by allowing a space in which a corresponding mixing operation is performed to be in a vacuum state during mixing of various mixed objects having moisture, The present invention relates to a new type of vacuum type mixing container for a blender, which can be stored for a long time even if it is not moved to a separate place in a state where the container is not moved.

Generally, a blender is a device that grinds or buys vegetables or fruits to make breads or juices.

The mixer is roughly divided into a mixer body having a built-in driving motor and a mixing container mounted on the mixer body while the crushing blade is built in. The mixing container is mounted on the mixer body in a state of being mounted on the mixer body, Is provided as the crushing blade so that various mixing objects can be mixed by the rotation of the crushing blade. This is disclosed in various publications such as those disclosed in Japanese Utility Model Laid-Open Nos. 20-2011-009558, 10-1336733, and 10-2008-090220.

However, since the conventional mixing container of the conventional mixer is formed only of a cylinder in which the mixing object is received, it is difficult to mix a large amount of water with the air in the mixing container while the mixing object is mixed with various mixing objects having moisture The bubbles are generated and the disadvantage that the bubbles do not uniformly grind the mixing object causes a complaint of the consumer that the mixing of the mixed material is not good.

In addition, the mixing vessel of the conventional general mixer has a disadvantage that it must be stored in a separate storage container after storing the mixed mixture for a long period of time.

SUMMARY OF THE INVENTION The present invention has been made in order to solve various problems of the conventional art described above, and it is an object of the present invention to provide a method and apparatus for mixing and mixing various kinds of objects, The present invention provides a new type of vacuum type mixing container for a mixer, which minimizes the amount of bubbles generated and can be stored for a long time without being moved to a separate place in a mixed state.

According to an aspect of the present invention, there is provided a vacuum type mixing container for a mixer, comprising: A bottom which is rotatably provided with a crushing blade while forming the bottom of the container body and is mounted on the mixer main body and is provided with a driving force for rotating the crushing blade; An airtight cover formed to seal the opened upper surface of the container body and having a communicating hole communicating with the interior and the exterior of the container body at one portion thereof and a cylindrical protruding rib protruding from the periphery of the communicating hole; And a check valve assembly coupled to the protruding rib of the airtight cover to maintain the communicating hole in a state where the communicating hole is opened when the vacuum suction force is provided and to keep the communicating hole in a closed state when the vacuum suction force is released .

The check valve assembly includes a cylindrical guide packing having a lower end connected to the protruding rib of the airtight cover and made of a flexible rubber material capable of bending deformation, A valve cap formed in a cylindrical shape and having a bottom formed with a through hole communicating with the communication hole of the airtight cover; and a valve cap provided in the through hole of the valve cap, And a check valve that closes the through hole by a vacuum pressure and opens the through hole while being moved up while providing a vacuum suction force.

In addition, the guide packing may include a rib-engaging end coupled with the protruding rib of the air-tight cover and a receiving engagement end extending upward from the outer circumferential surface of the rib-engaging end, And an extended end that extends from the upper end of the body end and the upper end surface of the body end while covering the upper surface of the receiving end of the guide packing. And the check valve is provided at the upper end of the hook type coupling end, which is provided through the through hole formed in the valve cap, and the hook type coupling end, and is positioned so as to intercept the through hole at the time of non-provision of the vacuum suction force, So that the through hole is opened while being spaced apart from the through hole And a closed end to be positioned.

The check valve is formed on both sides of the upper end of the closed end so as to intersect in the radial direction of the closed end and to be rounded so as to be adjacent to each other in the direction toward the center side, And a bottom surface of the closed end of the check valve is in close contact with a bottom surface of the bottom surface of the valve cap.

In addition, the bottom of the bottom portion may further include an auxiliary cover for sealing the bottom of the container body when it is desired to store the mixture in the container body.

As described above, since the vacuum type mixing container for a mixer according to the present invention can be vacuumed to the inner space, it is possible to minimize the generation of foam at the time of crushing a mixed object having moisture, This has the effect of allowing the mixer to be able to perform the thickening even when the mixed material is fed.

In addition, the vacuum type mixing container for a mixer of the present invention further improves the structure of the check valve assembly, so that even if the airtight cover is flexibly deformed by the vacuum pressure in the container body, the check valve and the valve Since the through hole of the cap is not deformed, the sealing of the through hole by the check valve can always be stably maintained, thereby preventing unwanted vacuum release inside the mixing container.

In particular, since the inside of the container body can be kept airtight by the airtight cover at the upper part and the auxiliary cover at the bottom in addition to the above-described check valve assembly, the vacuum type mixing container for a mixer of the present invention can also be used for long- It has the added effect of being able to

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view for explaining an external structure of a vacuum type mixing container for a mixer according to an embodiment of the present invention;
2 is a cross-sectional view illustrating an internal structure of a vacuum type mixing container for a mixer according to an embodiment of the present invention.
3 is a cross-sectional view of a check valve assembly constituting a vacuum type mixing container for a mixer according to an embodiment of the present invention,
FIG. 4 is a perspective view of a check valve assembly constituting a vacuum type mixing container for a mixer according to an embodiment of the present invention,
FIGS. 5 to 8 are enlarged views for explaining the operation of a check valve assembly constituting a vacuum type mixing container for a mixer according to an embodiment of the present invention.
9 is a perspective view illustrating another embodiment of a vacuum type mixing container for a mixer according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a vacuum type mixing container for a blender according to the present invention will be described with reference to FIGS. 1 to 9.

FIG. 1 is a perspective view for explaining an external structure of a vacuum type mixing container for a mixer according to an embodiment of the present invention, FIG. 2 is a perspective view illustrating an internal structure of a vacuum type mixing container for a mixer according to an embodiment of the present invention Fig.

(Hereinafter referred to as " mixing container ") 10 according to an embodiment of the present invention includes a container body 100, a hermetic cover 200, and a check valve assembly 300, The check valve assembly 300 is mounted on a portion where the communication hole of the airtight cover 200 is formed so that the communication hole can be opened only when a vacuum suction force is provided, So that it is possible to prevent the generation of a large amount of bubbles due to the mixing of air during the process, and to uniformly pulverize the object to be mixed.

The construction of the mixing vessel 10 according to the embodiment of the present invention will now be described.

First, the container body 100 is formed as a cylinder that opens up and down as a site for providing a space to be crushed while receiving a mixing object (or a mixing material).

A handle 110 is provided on the circumferential surface of the container body 100 to provide a user's grip area.

Next, the bottom part 500 forms a bottom while closing the open lower part of the container body 100.

The bottom part 500 includes a cylindrical housing 510 having an upper end coupled to the lower end of the container body 100 and a lower end configured to selectively receive the lower end of the blender body 20, And a crushing blade 530 rotatably installed on the partition plate. The crushing blade 530 may be formed of a metal plate.

In this case, the mixer main body 20 is provided with a driving motor 21 for generating a driving force, and the driving shaft 21 of the driving motor 21 and the shaft 531 forming the crushing blade 530 correspond to each other And the power transmission members 540 and 23 are configured to be able to transmit power by engaging each other.

That is, when the bottom part 500 is mounted on the mixer body 20, the driving shaft 22, which receives the driving force from the driving motor 21 installed in the mixer body 20, is coupled with the power transmitting member 540 So that the power can be transmitted.

In this case, the bottom part 500 may be integrally formed at the bottom of the container body 100, but in this case, it is difficult to clean or maintain the crushing blade 530 provided in the bottom part 500 It is most preferable that the bottom portion 500 is detachably coupled to the bottom portion of the container body 100 as shown in the respective drawings shown in the embodiment of the present invention. Of course, this is not a limitation.

In the meantime, in the embodiment of the present invention, it is further provided that an auxiliary cover 400 for sealing the bottom of the bottom part 500 is further provided at the lower end of the bottom part 500. At this time, the auxiliary cover 400 is formed in a cover-like structure for covering the lower end of the bottom part 500, and is formed of a flexible material for airtight maintenance or a seal member (not shown) So that the airtightness can be maintained at the time of coupling with the bottom part 500.

That is, in order to keep the mixed material in the container body 100 through the provision of the auxiliary cover 400, the auxiliary cover 400 and the airtight cover 200, which will be described later, So that the inside of the container body 100 can be maintained in a vacuum state.

Next, the airtight cover 200 is a portion that hermetically seals the open upper surface of the container body 100.

The airtight cover 200 is formed to have a circumferential wall 210 surrounding a part of an upper inner circumferential surface of the container body 100 and a communication hole 220 communicating with the interior and the exterior of the container body 100 is formed on the upper surface thereof. .

The peripheral portion of the upper surface of the airtight cover 200 where the communication hole 220 is formed is provided with a recess 230 that is concave compared to other portions of the airtight cover 200, (30) of various structures can be applied at the same time.

In addition, a cylindrical protruding rib 240 protrudes from the recess 230 of the airtight cover 200 around the communication hole 220. The protrusion rib 240 is a structure in which a check valve assembly 300 to be described later is installed. As shown in the figure, the protrusion rib 240 is spaced apart from the communication hole 220 by a predetermined distance. Of course, the protruding rib 240 may be formed to protrude upward in contact with the communication hole 220 though not shown.

The check valve assembly 300 is coupled to the protrusion rib 240 of the hermetic cover 200 so that the communication hole 220 formed in the hermetic cover 200 is opened when a vacuum suction force is applied thereto And the communicating hole 220 is closed when the vacuum suction force is released.

3 and 4, the check valve assembly 300 according to the embodiment of the present invention includes a guide packing 310, The cap 320 and the check valve 330 so that the bending deformation of the airtight cover 200 due to the vacuumization in the container body 100 prevents the check valve 330 from being So that it is possible to prevent the case from departing from the correct position. This will be described in more detail below for each configuration.

The guide packing 310 is a cylindrical structure that is coupled to the protruding rib 240 of the airtight cover 200. The guide packing 310 includes a rib coupling end which surrounds the protruding rib 240 of the airtight cover 200 311 and a receiving coupling end 312 extending upward from the outer peripheral surface of the rib coupling end 311.

Here, the rib coupling end 311 is formed by recessing a press-in groove 313 so as to press-fit the protruding rib 240 along the circumference of the bottom, and the receiving coupling end 312 is connected to the rib coupling end 311 And protruding upward from the outer periphery of the housing (not shown).

Particularly, in the embodiment of the present invention, the guide packing 310 is formed of a flexible rubber material having a ring shape. This is so that the guide packing 310 can be deformed together with the deformation of the airtight cover 200.

That is, the guide packing 310 is formed to have a structure that encloses the inner and outer wall surfaces and the upper surface of the protruding rib 240 formed in the airtight cover 200, so that the fluid such as water and air inside the container body 100 is guided to the guide packing It is possible to prevent the guide packing 310 from being detached or separated from the protruding rib 240 even if the airtight cover 200 is deformed while the airtight cover 200 is prevented from leaking, .

Also, the valve cap 320 is provided at a position where a check valve 330 to be described later is installed. Even if the guide packing 310 is warped, sealing by the check valve 330 can be stably performed So that it can be maintained.

The valve cap 320 includes a body 322 formed in a cylindrical shape having a bottom 321 and press-fitted into the inner circumferential surface of the upper end of the guide packing 310 and a body 322 extending from the peripheral surface of the body 322 And an expansion stage 323.

A through hole 324 communicating with the communication hole 220 of the airtight cover 200 is formed at an inner central portion of the bottom 321 forming the body end 322. At this time, along the perimeter of the through hole 324, an upper surface of the bottom 321 is formed with a protruding rib 325 to which a bottom surface of a closed end 332 of the check valve 330, which will be described later, is closely contacted.

A ring-shaped receiving rib 326 is formed on the bottom surface of the extended end 323 so as to surround the outer peripheral surface of the receiving end 312 of the guide packing 310. The upper end of the receiving coupling end 312 constituting the guide packing 310 can be maintained in a press-fit state between the inner peripheral surface of the receiving rib 326 and the bottom surface of the extended end 323 and the peripheral surface of the body end 322 .

Particularly, the valve cap 320 according to the above-described embodiment of the present invention is formed to have a rigidity not to be flexibly deformed by the vacuum force, so that even when the airtight cover 200 is bent, only the guide packing 310 is deformed And that the valve cap 320 is not deformed.

The check valve 330 selectively opens and closes the through hole 324 formed in the body end 322 of the valve cap 320. The check valve 330 is installed in the through hole 324 of the valve cap 320, When the vacuum suction force is not supplied, the through hole 324 is closed by the vacuum pressure provided from the inside of the container body 10, and when the vacuum suction force is provided, the through hole 324 is separated from the through hole 324 324 are opened.

The check valve 330 may include a hook type coupling end 331 formed through the through hole 324 formed in the valve cap 320 and a hook type coupling end 331 extending through the hook type coupling end 331, And a closed end 332 formed in a plate shape so as to be in close contact with the upper surface of the contact rib 325 formed around the through hole 324 and to block the through hole 324.

That is, when the vacuum suction force is not supplied to the check valve 330, the closed end 332 closes the through hole 324 by the vacuum pressure provided from the inside of the container main body 100, The closing end 332 is moved upward by the vacuum suction force so that the through hole 324 is opened.

At this time, since the outer peripheral surface of the hook type coupling end 331 is formed so as to gradually decrease its diameter toward the bottom, it is possible to smoothly install the through hole into the through hole 324, So that the check valve 330 is prevented from being excessively moved upward by hanging on the floor bottom of the body end 322 constituting the cap 320.

Also, in the embodiment of the present invention, a strength reinforcing portion 333 is further formed on the upper surface of the closed end 332 constituting the check valve 330. The strength reinforcing portion 333 reinforces the strength of the closed end 332 in order to prevent a bending deformation of the closed end 332. When the check valve 330 is inserted into the through hole 332 of the valve cap 320, (332) is prevented by the strength reinforcing portion (333) even if vacuum pressure in the container body (100) is provided in a state where the closed end (332) It is possible to prevent the occurrence of a gap with the contact rib 325 caused by the bending deformation.

The strength reinforcement portions 333 are formed on both sides of the upper surface of the closed end 332 in such a manner as to protrude from the closed end 332 in the radial direction of the closed end 332 and to be adjacent to each other in the opposite direction And the bending deformation of the closed end 332 with respect to the peripheral portion can be prevented by the feature of the strength reinforcing portion 333.

Hereinafter, the use process of the mixing vessel 10 according to the embodiment of the present invention and the operation performed by the check valve assembly 330 at this time will be described in more detail.

First, the airtight cover 200 coupled to the upper surface of the container body 100 is separated, and the mixing object is inserted through the upper surface of the opened container body 100. At this time, the bottom of the container body 100 maintains the closed bottom of the container body 100 in a state where the bottom portion 500 is engaged.

Thereafter, when the mixing object is completely filled, the open upper surface of the container body 100 is closed again by the airtight cover 200.

5, the check valve 330 is maintained in a state of closing the through-hole 324 of the valve cap 320, and the guide packing 310 is inserted into the through- And the lower end portion of the body end 322 constituting the valve cap 320 is press-fitted into the inner peripheral surface of the valve cap 320 to block the communication hole 322 from communicating with the external environment Lt; / RTI >

Particularly, since the inside of the container body 100 is maintained at the same atmospheric pressure state as the outside of the container body 100, the check valve 330 is maintained only in a state where the through hole 324 of the valve cap 320 is blocked by its own weight do.

When the air existing in the container main body 100 is forcibly discharged using the purge air 30 in the above-described state, the inside of the valve cap 320 is checked by the vacuum suction force provided from the purge air 30 The valve 330 is moved upward. This is shown in Fig. 6 attached hereto.

Considering that the space inside the valve cap 320 is closed from the external environment by the tip of the purge air 30, the check valve 330 is opened by the vacuum suction force provided from the purge air 30 And the through hole 324 of the valve cap 320 is opened while moving upward toward the purge air 30 provided with the vacuum suction force. Of course, there is a fear that the check valve 330 is not moved upward by the vacuum suction force but only the peripheral portion of the closed end 332 is bent upward to open the through hole 324. However, the closed end 332 The upper end of the closed end 332 is prevented from being bent upwardly, considering that the upper end of the closed end 332 is further provided with the strength reinforcing portion 333.

When the hook type coupling end 331 constituting the check valve 330 is caught on the bottom surface of the bottom 321 constituting the valve cap 320 during the ascending movement of the check valve 330, As the check valve 330 is not moved upward, the check valve 330 is prevented from being removed from the valve cap 320 due to the excessive upward movement of the check valve 330.

When the opening of the through hole 324 is made as described above, air existing in the container body 100 passes through the communication hole 220 of the airtight cover 200 and flows through the through hole 324, Flows into the space inside the cap 320 and then flows into the purge air 30, whereby the inside of the container body 100 is gradually evacuated.

Particularly, while the inside of the container body 100 is evacuated, the airtightness of the airtight cover 200 is deformed by the vacuum pressure inside the container body 100, As shown in FIG.

However, even if the airtight cover 200 described above is deflected, the valve cap 320 is not deformed at the portion where the check valve 330 is installed. When the bending deformation of the airtight cover 200 occurs, only the guide packing 310, which is fixedly coupled to the airtight cover 200, is flexibly deformed and the deformation of the valve cap 320 installed on the guide packing 310 Is not generated.

When the operation of the vacuum cleaned air 30 is stopped by the above process, the closed end 332 of the check valve 330 is closed by the vacuum pressure in the container body 100 The external air is prevented from flowing into the container body 100 through the through hole 324 by blocking the through hole 324 of the body end 322 forming the valve cap 320 . This is shown in FIG. 8 attached hereto.

Particularly, considering that the strength reinforcing portion 333 is additionally formed on the upper surface of the closed end 332 of the check valve 330, the problem that the peripheral portion of the closed end 332 is bent or deformed, So that the inside of the container body 100 can be maintained in a vacuum state as the through hole 324 is closed while the closed end 332 is kept horizontal at all times.

Next, the mixing vessel 10 is placed in the mixer main body 20 in such a manner that the object to be crushed is stored in a vacuum state through the above-described process.

In this case, the power transmitting member 540 constituting the bottom portion 500 of the mixing container 10 is engaged with the power transmitting member 23 coupled to the driving shaft 22 of the mixer main body 20, Thereby achieving a deliverable state.

When power is supplied to the driving motor 21 of the blender main body 20 by the user's operation in the above-described state, the driving motor 21 is driven to rotate the driving shaft 22, The power transmitting member 23 coupled to the power transmitting member 23 rotates to rotate the power transmitting member 540 coupled to the shaft 531 of the crushing blade 530 so that the crushing blade 530 is also rotated.

Therefore, the mixing object existing in the container body 100 is crushed by the rotation of the crushing blade 530.

Particularly, in the course of crushing the mixing object, the generation of foam can be minimized in consideration of the absence of air in the container body 100, and the degree of crushing of the object to be mixed can be made uniform .

When the grinding of the object to be mixed is completed through the above process, the user removes the mixing vessel 10 from the mixer body 20, opens the air-tight cover 200, And then transferred into a separate container (for example, a cup or the like).

If the user wishes to store the mixed material in a separate container, the mixing container 10 is separated from the mixer main body 20, and the auxiliary container 400 is connected to the mixing container 10 The bottom surface of the bottom part 500 may be sealed and stored.

That is, considering that the interior of the container body 100 constituting the mixing vessel 10 is in a state of being evacuated before grinding the mixing object, if the bottom face of the container body 100 is further hermetically sealed, So that the mixing vessel 10 can be used as a vacuum storage vessel.

Of course, in this state, even though no additional evacuation is made to the inside of the container body 010, the airtight cover 200 and the guide packing 310 directly coupled to the airtight cover 200 are still deflected And the check valve 330 of the check valve assembly 300 is maintained in a state where the through hole 324 of the valve cap 320 is blocked.

As a result, since the mixing vessel 10 according to the present invention is capable of vacuuming the internal space, it is possible to minimize the generation of foam at the time of crushing the object to be mixed with moisture and to achieve an even crushing degree, When you eat water, you will be able to make a lot of headwinds.

The mixing container 100 of the present invention further improves the structural integrity of the check valve assembly 300 so that even if the hermetic cover 200 is flexibly deformed by the vacuum pressure in the container body 100, And the through hole 324 of the valve cap 320 closed by the check valve 330 is not deformed so that the sealing of the through hole 324 by the check valve 330 is stably maintained, The vacuum storage of the vacuum chamber 10 can be performed stably for a long time.

Particularly, in the mixing container 10 of the present invention, since the inside of the container body 100 can be kept in a hermetic state by the airtight cover 200 at the upper part and the auxiliary cover 400 at the lower part, Can also be used.

Meanwhile, FIG. 9 attached herewith shows another embodiment of the mixing container 10 of the present invention.

That is, the mixing container 10 of the present invention can be deformed into various shapes, so that the structures of the container body 100 and the airtight cover 200 of the mixing container 10 are shown in FIGS. 1 and 2 But is not limited to.

10. Mixing vessel 20. Mixer body
21. Drive motor 22. Drive shaft
23. Power transmission member 30. Genuine air
100. Container body 110. Handle
200. Airtight cover 210. Perimeter wall
220. Communication hole 230. Concave portion
240. Projecting rib 300. Check valve assembly
310. Guide Packing 311. Rib Joining Step
312. Acceptable coupling end 313. Press-fit groove
320. Valve cap 321. bottom
322. Body section 323. Expansion stage
324. Through-hole 325. Contact rib
326. Receiving rib 330. Check valve
331. Hook-shaped coupling end 332. Closing end
333. Strength reinforcement part 400. Auxiliary cover
500. Bottom 510. Housing
520. Compartment plate 530. Crushing blade
531. Shaft 540. Power transmission member

Claims (5)

1. A container comprising: a container body formed with a tubular body having an opened upper surface;
A bottom which is rotatably provided with a crushing blade while forming the bottom of the container body and is mounted on the mixer main body and is provided with a driving force for rotating the crushing blade;
An airtight cover formed to seal the opened upper surface of the container body and having a communicating hole communicating with the interior and the exterior of the container body at one portion thereof and a cylindrical protruding rib protruding from the periphery of the communicating hole; And,
And a check valve assembly coupled to the protruding rib of the airtight cover to maintain the communicating hole in a state where the communicating hole is opened when the vacuum suction force is provided and to keep the communicating hole in a closed state when the vacuum suction force is released Wherein the mixing container is a vacuum type mixing container for a blender. The method according to claim 1,
The check valve assembly
A cylindrical guide packing made of a flexible rubber material capable of being deformed while being coupled to the protruding ribs of the airtight cover,
A valve cap having a cylindrical shape having a bottom formed with a through hole communicating with the communication hole of the airtight cover, the valve cap being formed to have a rigidity not to be deformed by the vacuum force,
The vacuum cap is installed in the through-hole of the valve cap. When the vacuum suction force is not supplied, the through-hole is closed by the vacuum pressure provided from the inside of the container body. In addition, when the vacuum suction force is provided, And a valve disposed in the mixing chamber. 3. The method of claim 2,
Wherein the guide packing comprises a rib engagement end which is engaged with a protruding rib of the airtight cover and a receiving engagement end which extends upward from an outer circumferential surface of the rib engagement end,
The valve cap is press-fitted into a receiving coupling end of the guide packing and is extended from an upper end surface of the body end and an upper end surface of the body end while being extended to an upper portion of the press-in end, And an extending end surrounding the upper surface of the receiving end of the packing,
Wherein the check valve is provided at the upper end of the hook type coupling end, which is provided through the through hole formed in the valve cap, and the hook type coupling end, and is positioned so as to intercept the through hole at the time of non-provision of the vacuum suction force, And a closed end which is positioned to open the through-hole while being spaced apart from the through-hole. The method of claim 3,
Wherein the check valve is formed on both sides of the upper surface of the closed end so as to intersect in the radial direction of the closed end and to be rounded so as to be closer to the opposite direction toward each other toward the center side portion, A reinforcing portion is further formed,
Wherein a contact rib is formed to protrude from the top surface of the bottom of the valve cap to closely contact the bottom surface of the closed end of the check valve along the perimeter of the through hole. The method according to claim 1,
Wherein the bottom of the bottom portion is further provided with an auxiliary cover for closing the bottom portion when it is desired to store the mixture in the container body.

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