KR20230003956A - Sealing Device for Forming Vacuum of Container - Google Patents

Abstract

The present invention relates to a sealing device for a container, which seals an inlet, through which food ingredients are inputted, and discharges air from a container in the container including the inlet for inputting food ingredients and storing the input food ingredients, thereby leaving the container in an air-thin state during grinding or mixing of the food ingredients. According to the present invention, the sealing device comprises: a sealing material coming into close contact with an inlet due to a negative pressure formed within a container, thereby sealing the inlet; a main body receiving the sealing material, having rigidity not deformed due to a negative pressure formed within the container, and having a distribution port through which air in the container is discharged to the outside and outside air is introduced into the container; and a valve provided in the main body and having a sealing surface disposed on the outside of the container to come in contact with the circumference of the distribution port and thus, close the distribution port, thereby allowing the negative pressure within the container to act through the distribution port.

Description

Sealing device for forming vacuum of container {Sealing Device for Forming Vacuum of Container}

The present invention relates to a container sealing device, and more specifically, to a sealing device that seals an inlet of a container containing food or food, sucks air from the container and discharges it, and maintains the container in a vacuum state.

A blender, also called a blender, is used to grind or mix ingredients such as fruits, vegetables, and grains. A blender puts ingredients to be crushed or mixed into a container and grinds or mixes the ingredients with blades disposed at the bottom of the container and rotated by an electric motor.

Such a blender covers the container with a cover to pulverize or mix, but the air present in the container is mixed with the food to be pulverized, resulting in significant oxidation of the food, change in color, and generation of bubbles.

Therefore, recently, in order to solve this problem, a vacuum blender for pulverizing or mixing ingredients while maintaining a container in a vacuum state has been developed and used.

As an example of such a vacuum blender, there is an invention related to a vacuum blender disclosed in Korean Patent Publication No. 10-2165314 (Document 1) and an invention related to a vacuum blender disclosed in Korean Patent Publication No. 10-1943098 (Document 2).

The vacuum blender currently under development or marketed and used, including the inventions disclosed in these documents, includes a vacuum suction mechanism including a motor and a vacuum pump and a dedicated cover for sealing the inlet of the container so that air does not flow, and the cover or An air distribution path is provided between a vacuum suction port formed in a part of the container and a vacuum suction mechanism.

Therefore, these vacuum blenders have a complicated structure and high manufacturing cost compared to blenders without a vacuum function, since they include a mechanism for vacuum suction and must have a container or cover having a structure suitable for vacuum suction.

On the other hand, in order to prevent food ingredients or food from being oxidized in contact with air, a mechanism is used to seal the entrance of the pouch after accommodating food ingredients or food in a pouch made of a synthetic resin film, sucking air from the pouch, and vacuuming it. .

In order to use such a vacuum pouch, there is an inconvenience in that food or food must be transferred to a separate pouch.

Document 1: Korean Patent Publication No. 10-2165314 Document 2: Korean Patent Publication No. 10-1943098

The present invention is to provide a device capable of mixing or pulverizing food ingredients in a thin air condition such as a vacuum state using a conventional blender without using a vacuum blender having a complicated structure and high manufacturing cost.

Specifically, the present invention uses a vacuum aspirator capable of vacuum suction of a conventional blender equipped with a blade for mixing or crushing ingredients by rotating and equipped with an inlet for food ingredients, sucking air in the container and maintaining the inside of the container in a vacuum state. It is intended to provide a device that enables mixing or grinding of ingredients.

In particular, the present invention is to provide a device that can be used in a blender having a general shape and structure without being restricted by the shape of a container for ingredients.

In addition, the present invention is to provide a sealing device that seals a container containing food or food and sucks air from the inside of the container to keep the food or food in a vacuum state.

In particular, it is intended to provide a sealing device that allows a general container to be vacuum-sealed without using a dedicated container suitable for the sealing device and without being restricted by the shape or size of the container.

The problem to be solved by the above-described invention is, in a container having an inlet into which food or food is introduced and accommodating the food or food, the inlet into which the food is introduced is sealed in the container and air is discharged from the container by a vacuum aspirator. This is achieved by the container closure device according to the present invention, which makes the container air-lean by making it

The sealing device of this invention,

a sealing material that is in close contact with the inlet by the negative pressure formed in the container and seals the inlet; a main body having a sealing material disposed thereon, having rigidity that does not deform due to negative pressure formed in the container, and having a distribution port through which air in the container is discharged to the outside and outside air is introduced into the container; and a valve provided on the main body and having a sealing surface disposed outside the container to close the flow port by contacting the circumference of the flow port and closing the flow port when negative pressure in the container acts through the flow port;

An element for sucking air in the vacuum extractor is arranged to surround the sealing surface of the valve and draws air from the container through the flow hole, so that the air inside the container is discharged and the inside of the container is vacuumed, and when the vacuum suction is finished, the inside of the container The negative pressure formed in the valve acts on the sealing surface of the valve through the flow hole, and the sealing surface of the valve adheres to the circumference of the flow hole, so that the inside of the container is maintained in a vacuum state.

The sealing device having such a structure is disposed in the inlet of the food material of the container having a normal structure.

Put ingredients into the container, place the sealing device over the inlet of the container so that the circumference of the inlet is in contact with the sealing material of the sealing device, and so that the tip of the hose for sucking air from the vacuum suction device or the tip of the suction port surrounds the sealing surface of the valve. place

In this state, when the vacuum sucker is operated, the sealing surface of the valve is spaced from the circumference of the flow hole so as not to close the flow hole due to the negative pressure caused by the suction, and the air in the container is sucked and discharged through the flow hole.

When the container is in a vacuum state and the operation of the vacuum suction machine is finished, the inside of the container is vacuumed, and the negative pressure according to the vacuum state acts on the sealing surface of the valve through the flow port to pull the valve inside the container so that the sealing surface of the valve is close to the main body flow port. It adheres to the circumference, and the negative pressure in the container acts as a tensile force that adheres the sealing material to the inside of the container, so that the sealing material adheres to the inlet.

Accordingly, the container is sealed from the outside in a vacuum state and the vacuum is maintained.

Here, the vacuum state does not have an absolute pressure value standard, and means a low pressure set suitable for mixing or grinding of ingredients or a low pressure that can be provided by a vacuum aspirator.

On the other hand, the container in which the sealing device according to the present invention is used does not mean a container for storing only food materials, and a container for accommodating food materials or food in a blender that accommodates food ingredients or food and crushes or mixes food materials with blades. Including, it is to include all types of containers for accommodating ingredients or food.

In addition, unless otherwise defined, the term food material in this specification does not mean only food ingredients before cooking, but is used to include cooked food.

The expression 'crushing or mixing' does not mean that the grinding and mixing operations of the ingredients are performed separately, and it does not exclude that the grinding and mixing operations are performed together.

In addition, the term 'crushing' does not mean only crushing of the food material by pressing force, but refers to all operations of reducing the size by applying force to the food material, including an operation of cutting and crushing the food material.

When the sealing device of the present invention is used in a blender, the container is placed in a vacuum state as described above, and the blender operates to rotate the blade, thereby mixing or pulverizing food ingredients in a vacuum state.

When the blender finishes pulverizing or mixing the ingredients, if the valve is pulled so that the sealing surface of the valve is separated from the circumference of the flow hole of the main body, outside air flows into the container through the flow hole, and the container becomes atmospheric pressure, and the sealing material and the container The close contact state between the slots is released, so that the sealing device of the present invention can be easily separated from the container.

The sealing device is separated from the container, and the crushed or mixed ingredients are taken out from the inlet of the container.

In this way, according to the sealing device of this invention, it is possible to pulverize or mix ingredients in a vacuum state by making a blender having a normal configuration and maintaining the vacuum, and in the case of a container for storing normal ingredients, etc. Ingredients can be stored in a condition where the air that causes food to go rancid is rare.

On the other hand, storage containers and blenders have different shapes of the inlet of the container depending on the manufacturer, but the sealing device of the present invention can form a wide sealing material to close the inlet, so the inlet can be closed without being restricted by the shape of the inlet. .

In addition, according to the present invention, the blender container may be vacuumed using an external vacuum source even if the blender or the sealing device does not have a vacuum suction device.

As a further feature of this invention, in the sealing device according to this invention,

The valve includes a sealing portion having the sealing surface and disposed outside the container, a separation preventing portion disposed inside the container and having a size and shape that cannot pass through the distribution port, and connecting the sealing portion and the separation prevention portion and passing through the distribution opening. It may be configured to include a connecting portion disposed in such a way.

According to this configuration, the valve remains coupled to the main body of the sealing device without using a complicated mechanism during vacuum formation of the container or storage of the sealing device.

Also, as a further feature to this additional feature, in the sealing device according to the present invention,

In the main body, a flat sealing surface wider than the sealing surface of the valve is formed around the outer end of the flow port, the sealing surface of the valve is formed as a circular flat surface in close contact with the sealing surface of the main body, and the connecting portion is formed in a cylindrical shape concentric with the sealing surface. It may be formed having a smaller diameter than the flow hole.

According to this configuration, the valve can be formed as an integrally formed element with a simple structure, the sealing portion with the sealing surface, the separation preventing portion and the connection portion, and the valve does not come off from the main body during vacuum formation.

As an embodiment of such a sealing device, in the sealing device according to the present invention,

The separation prevention unit is made in the form of a flat circular panel concentric with the connection unit,

In the main body, the circumference of the inner end of the flow port may be configured to be formed of a surface having concavo-convex surfaces that are not sealed by the separation prevention unit.

According to this embodiment, when air is sucked to make the inside of the container vacuum, occurrence of a state in which the separation prevention part is in close contact with the surface of the element constituting the main body and the vacuum suction is not performed is prevented.

As another additional feature of this invention, in the sealing device of this invention,

The main body is formed in the form of a circular panel in which the distribution port is formed in the center,

A side surface into which the sealing material is inserted is formed around the outer circumference and the circumference of the flow port,

The sealing material may be configured to be inserted between the side surfaces formed around the flow port on the outer circumference of the main body.

According to this configuration, since the sealing material sealing the inlet of the container can be formed to have a large area, the inlet can be sealed with a sealing material that does not conform to the shape of the inlet of the container.

As another additional feature of this invention, in the sealing device of this invention,

The main body may be made of a transparent synthetic resin having rigidity, and the sealing material and the main body may be made of a flexible silicone resin.

1 is a perspective view showing a state in which a sealing device according to an embodiment of the present invention is mounted on a blender.
2 is an exploded perspective view of a sealing device according to an embodiment of the present invention.
Figure 3 is a perspective view of the inlet of the main body viewed from the bottom in the sealing device according to an embodiment of the present invention.
4 to 7 are cross-sectional views showing operation of the sealing device according to an embodiment of the present invention while being mounted on a blender container.

Hereinafter, with reference to the drawings, the configuration and operation of an embodiment in which the sealing device according to the present invention is used in a blender for mixing or grinding ingredients will be described as specific details for carrying out the present invention.

1 shows a state in which a sealing device according to an embodiment of the present invention is mounted on a blender.

The blender has a conventional configuration and operation, and is composed of a container 2 and a main body 1 into which ingredients are put and pulverized or mixed. The container 1 is equipped with a blade 3 for crushing or mixing ingredients by rotation at the bottom, and the upper end is open to form an inlet 4 into which ingredients are introduced.

A drive mechanism including a motor for rotating the blade 3 is disposed on the main body 2, and a control module for supplying power to the drive mechanism and controlling rotation and a button operated by a user are provided.

Since the configuration of such a blender is widely known, a detailed description of the configuration and operation will be omitted.

However, in the blender in which the sealing device 100 of this embodiment is used, the shape of the inlet 4 at the top of the container 2 is not particularly limited, but the surface of the inlet is flat to form a sealing device. It can be sealed by a sealing material (30 in FIG. 2).

Ingredients are put into the container 2 of the blender, and in a state where the sealing device 100 of this embodiment seals the inlet 4 of the container 2, the container passes through the sealing device 100 by a separate vacuum suction device. (2) By sucking the air inside, the inside of the container becomes a vacuum state where air is rarefied or a low pressure state where air is less than atmospheric pressure.

The configuration of the sealing device 100 of this embodiment will be described with reference to the exploded perspective view of FIG. 2 and the assembled cross-sectional view of FIG. 4 .

The sealing device has a sealing material 30 that is in close contact with the inlet 4 by the negative pressure formed in the container 2 of the blender and seals the inlet, and a rigidity that accommodates the sealing material and does not deform its shape by the negative pressure formed in the container. Equipped with a main body 10 having a flow port 16 through which air in the container is discharged to the outside and outside air is introduced into the container, and disposed in the main body and disposed outside the container 2 to contact the circumference of the flow port It consists of a valve (20) with a sealing surface (25) through which the negative pressure in the container acts through the flow port (4) while closing the flow port (4).

The main body 10 has a circular panel 11 formed flat to close the inlet 4 of the blender, and a first side surface 12 extending downward is provided around the outer circumference of the panel 11.

A cylindrical flow port wall 14 extending perpendicularly to the panel 11 is formed at the center of the radial direction of the panel 11, so that air flows in and out between the inside and outside of the container 2 on the inside of the wall of the flow port. It constitutes the distribution port 16 to do.

A sealing surface 15 formed of a flat surface to which the sealing surface 25 of the valve 20 is in close contact with the outside of the wall surface 14 of the outlet port in the radial direction and the tip of the vacuum hose (7 in FIG. 4) of the vacuum sucker is in close contact with ) protrudes from the panel 11 to the outside of the container 2 and is formed as a surface parallel to the panel 11 . A second side surface 13 is formed concentrically with the side surface 12 of the outer circumference to the outside of the outlet wall surface 14 in the radial direction.

Referring to FIG. 3 , four arc-shaped protrusions 17 are formed on the end face of the outlet wall 14 placed inside the container 2 and are spaced apart from each other in the circumferential direction.

As will be described later, when air is sucked in and discharged from the container 2, the suction pressure causes the release preventing portion 24 of the valve 20 to move from the wall surface 14 of the outlet toward the end surface placed inside the container 2. It sticks.

At this time, the separation preventing part 24 comes into contact with the protrusions 17, and a passage through which air can flow from the inside of the container 2 to the distribution port 16 is formed between the protrusions, leading to the separation preventing part 24. As a result, there is no obstruction of air intake.

The main body 10 is integrally formed by injection molding of a styrene-butadiene copolymer resin as a main raw material, but the material of the main body is not limited thereto and is hardly deformed in shape at low pressure or vacuum negative pressure in the container 2. It may be made of a material having rigidity.

A sealing material 30 is inserted and mounted on the panel 11 and the first and second side surfaces 12 and 13 of the main body. The sealing material 30 is made in the form of a flat circular panel, and is in the form of a donut with a hole 32 formed in the center in the radial direction, and is sandwiched between the panel 11 of the main body and the first and second side surfaces 12 and 13 It is fixed.

The sealing material 30 is made of silicone rubber having elasticity, and adheres to the surface of the inlet 4 of the container 2 to maintain an airtight closing device of the container.

In particular, since the surface of the sealant 30 extends from the outer circumference of the main body 10 to the circumference of the outlet 16 when viewed in plan, the inlet 4 of the container 2 is placed only on the same plane. If so, it is possible to close the inlet of various types regardless of the shape of the inlet 4.

As a whole, the valve 20 is integrally formed with four parts of elastic silicone rubber.

The valve 20 includes a cylindrical operation unit 22 that can be held by a person by hand to open the valve, a sealing unit 21 disposed on the lower side of the operation unit and formed in a hemispherical shape to form a circular sealing surface 25 with a flat lower side. ), a connecting portion 25 extending downward from the sealing portion and formed in a cylindrical shape concentric with the sealing portion, and a separation preventing portion 24 connected to the lower end of the connecting portion and formed in a circular panel shape.

In the valve 20, the control unit 22 and the sealing unit 21 are disposed outside the body 10, that is, outside the container 2, and the connection unit 21 penetrates the outlet 16 of the body and is disposed. And, the departure prevention unit 24 is disposed on the inside. The separation prevention unit 24 is formed in the form of a flat circular panel concentric with the connection unit 23 .

The diameter of the sealing surface 25 of the sealing part 21 and the diameter of the separation prevention part 24 are formed larger than the diameter of the flow hole 16 of the main body, and the connection part 23 is formed larger than the diameter of the flow hole 16. formed small.

With this configuration, the valve 20 is disposed in and out of the flow port 16 of the main body 10 and can move up and down around the flow port 16 without being separated from the main body 10 .

In addition, since the diameter of the connection portion 23 is formed smaller than the diameter of the flow hole 16, the connection portion 23 does not close the flow hole 16, so that air can flow through the flow hole 16, The negative pressure in the container 2 acts through the flow port 16 on the sealing surface 15 of the valve exposed to the flow port 16 .

Referring to FIGS. 4 to 4 , a process in which the sealing device configured as described above is applied to the blender and operates will be described.

In the state shown in FIG. 4, ingredients to be mixed or pulverized are put into the container 2 through the inlet 4 of the container 2 of the blender, and the sealing device 100 of this embodiment is applied to the sealing material 30. It is placed in the inlet 4 so that the sealing surface 31 comes into contact with the inlet 4 of the container.

Next, the sealing surface 15 of the main body 10 is disposed so that the front end 7 of the vacuum hose of the vacuum aspirator is in contact, but at this time, the sealing surface 25 of the valve is placed inside the front end 7 of the vacuum hose. let it lie

As a vacuum aspirator, a normal one equipped with a motor and a pump and a vacuum hose connected to the pump can be used, and in particular, a packaging machine of the type that sucks air from a container or packaging film for storing food or food and seals it can be used as a vacuum aspirator. there is.

As shown in FIG. 5, when the vacuum sucker is operated, negative pressure (S) that moves the valve 20 in the direction in which air is sucked is generated. The valve 20 is moved by the negative pressure S, so that the sealing surface 25 of the valve is separated from the sealing surface 15 of the main body, and the separation preventing part 24 is installed at the end of the wall surface 14 of the outlet of the main body. Although they are close to each other, passages through which air can flow are formed between the projections 17 without being in close contact with the front end of the wall surface 14 of the passage port.

Accordingly, an air flow passage leading from between the outlet port wall surface 14 and the separation preventing portion 24 to the space between the outlet port 16 and the sealing surfaces 15 and 25 is formed, and the suction of the vacuum aspirator is formed. By this, the air inside the container 2 is sucked out. Due to this air suction, the inside of the container becomes a low-pressure to vacuum state in which air is rarefied.

As shown in FIG. 6, when the suction by the vacuum suction source is finished and the tip 7 of the vacuum suction hose is separated from the sealing device, the valve 20 is opened by the negative pressure inside the container 2. will move toward the inner side of the

Negative pressure is applied to the sealing surface 25 of the valve facing the passageway 16, and the sealing surface 25 of the valve is pressed against the sealing surface 15 of the main body by this negative pressure, so that the passage port 16 is closed. do.

In addition, the negative pressure (N) in the container 2 also acts on the sealing material 30 that is in close contact with the inlet 4, and acts as a tensile force pulling the sealing material 30 toward the inside of the container 2. Due to the negative pressure (N), the surface 31 of the sealing material adheres to the inlet 4 of the container 2, and the inside of the container 2 is sealed and a vacuum or low pressure is maintained.

In this way, the inside of the container 2 maintains a low pressure even if the vacuum aspirator is no longer operating, and in this state, the blender is operated to rotate the blade 3 to mix the ingredients put into the container 2. or crush

Since the inside of the container 2 is in a rare state of air due to vacuum or low pressure, rapid oxidation of the food material or generation of bubbles while the air is mixed with the food material during grinding or mixing of the food material does not occur or very little occurs. .

When the mixing or pulverization of the ingredients is completed, the sealing device must be separated from the container and the pulverized or mixed ingredients must be taken out from the inlet 4.

Although the sealing device of this embodiment can be removed from the inlet 4 of the container 2 by pulling it, negative pressure acts on the sealing material 30 of the sealing device in close contact with the inlet 4, so unless the negative pressure is removed, The sealing device can be removed only with great force.

Before removing the sealing device, as shown in Fig. 7, the operating portion 22 of the valve is pulled up. Since negative pressure is applied only to the sealing surface 25 facing the flow port 16 in the valve 20, the control unit 22 can be pulled in the opposite direction to the negative pressure with a very small force.

Accordingly, the sealing surface 15 of the body and the sealing surface 25 of the valve are spaced apart from each other, an air flow passage is formed from the outside to the inside of the container 2, and outside air flows into the container 2. As a result, the inside of the container 2 becomes atmospheric pressure, and the negative pressure is removed.

Accordingly, the sealing device can be easily separated from the inlet 4 of the container, and the crushed or mixed ingredients in the container are taken out through the inlet 4.

As described above, the container of the blender is sealed using the sealing device of this embodiment, and the inside of the container is vacuumed or low-pressured using a separate external vacuum suction device to mix or grind ingredients.

In addition, after mixing or grinding the ingredients, the sealing device can be easily removed by simply releasing the vacuum or low pressure state inside the container and returning the container to atmospheric pressure.

Meanwhile, in this embodiment, a vacuum aspirator equipped with a vacuum pump was used, but any means capable of sucking air while surrounding the circumference of the valve exposed to the outside of the main body may be used even if it is not a vacuum pump.

In addition, in this embodiment, the inlet of the container has been described by limiting the circumference to being placed on the same plane, but if the blender has a height difference in the shape of the circumference of the inlet, the sealing material is configured according to the shape, and the sealing material is replaced and inserted can also be used

As above, the embodiment in which the sealing device according to the present invention is used in a blender has been described, and the sealing device of the present invention is not limited to the blender and can be used in any container equipped with an inlet through which food or food is put. The invention is not limited to the configuration of the sealing device of the above-described embodiment, and various modifications and additions of elements are possible within the scope described in the claims.

100: sealing device 10: body
20: valve 30: sealing material

Claims (6)

A sealing device for a container that has an inlet into which the food material is put, seals the inlet into which the food material is put in a container accommodating the food material, and allows air to be discharged from the container so that the container is in an air-thin state,
a sealing material that is in close contact with the inlet by the negative pressure formed in the container and seals the inlet;
a body that accommodates a sealing material, has rigidity that does not deform due to negative pressure formed in the container, and has a flow port through which air in the container is discharged to the outside and outside air is introduced into the container; and
A valve having a sealing surface provided on the body and disposed outside the container to contact the circumference of the flow port to close the flow port while allowing the negative pressure in the container to act through the flow port.
including,
The front end of the external vacuum suction machine is arranged to surround the sealing part of the valve to vacuum, so that the air inside the container is discharged to the outside through the flow hole, and the inside of the container becomes vacuum or low pressure, and when the vacuum suction is finished, A device for sealing a container, wherein a negative pressure acts on a sealing surface of a valve through a flow hole so that the sealing surface adheres to the circumference of the flow hole so that the inside of the container is sealed in a vacuum or low pressure state. The method of claim 1,
the valve,
A seal having a sealing surface and disposed outside the container;
A departure prevention unit disposed inside the container and having a size and shape that cannot pass through the distribution port, and
A connecting part that connects the sealing part and the separation prevention part and passes through the distribution port
Which is configured to include, the closure device of the container. The method of claim 2,
A flat surface wider than the sealing surface of the valve is formed around the outer end of the flow port in the body,
A sealing device for a container, wherein the sealing surface of the valve is formed as a circular flat surface in close contact with the surface of the main body around the flow port, and the connection portion is formed in a cylindrical shape concentric with the sealing surface and has a diameter smaller than that of the flow port. The method of claim 3,
The separation prevention unit is made in the form of a flat circular panel concentric with the connection unit,
A closure device for a container, wherein the periphery of the inner end of the flow port in the main body is formed with a surface having irregularities that are not sealed by the separation preventing portion. The method of claim 1,
The main body is formed in the form of a circular panel in which the distribution port is formed in the center,
A side surface into which the sealing material is inserted is formed around the outer circumference and the circumference of the flow port,
A sealing device for a container, wherein the sealing material is inserted between the side surfaces formed around the flow port on the outer circumference of the main body. In the claim of any one of claims 1 to 5,
A sealing device for a container, wherein the main body is made of a transparent synthetic resin having rigidity, and the sealing material and the main body are made of a flexible silicone resin.

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