KR20220144751A - vacuum storage container - Google Patents

Abstract

A vacuum storage container according to an aspect of the invention comprises: a container having a storage space inside and an open upper side; and a vacuum cover coupled to an upper part portion the container. The vacuum cover includes: a connection part coupled to the upper portion of the container and sealing the storage space; a mechanism part coupled to an upper portion of the connection part and including a vacuum forming assembly which discharges air inside the storage space to the outside to form a vacuum state, a switch which is for controlling the operation of the vacuum forming assembly, a pressure sensor which detects pressure inside the storage space and generates a signal to control the operation of the vacuum forming assembly, an oxygen sensor which measures oxygen concentration inside the storage space, a control unit which collects and processes operation information of the vacuum forming assembly and oxygen concentration data, and a communication unit which receives a signal from the control unit and transmits the signal to the outside or delivers the received signal to the control unit; and a cover part coupled to an upper portion of the mechanism part and having a display displaying the oxygen concentration or the operation information of the vacuum forming assembly to the outside. Therefore, the present invention allows a user to easily visually confirm the condition inside the container.

Description

vacuum storage container

One aspect of the present invention relates to a vacuum storage container, and more particularly, to a vacuum storage container capable of storing pet food or food therein.

Currently, the number of households raising companion animals in Korea and around the world is increasing, and according to the '2021 Korea Pet Report' published by KB Financial Group in 2021, there are about 6.04 million companion households in Korea, accounting for about 29.7% of the total number of households. The companion animal products market is growing, with the number of companion households expected to increase in the future. In addition, as of April 2021, the number of single-person households was 9,139,287 households, accounting for 29.5% of the total households, and the proportion of single-person households is also increasing significantly.

As the proportion of companion households and single-person households increases in the total households, a method for keeping food or ingredients fresh, which is difficult to process alone, and a storage container for keeping pet food or snacks fresh for a long time The related market is also expected to grow significantly.

In general, storage containers used to store food, feed, vegetables, etc. in a fresh state for a long time have a structure that can be sealed to prevent oxidation or deterioration of food and maintain freshness for a long time. In order to keep feed safer, recently, research and development of containers that can be stored in a vacuum state have been developed.

For example, Republic of Korea Patent Publication No. 10-1670218 (registered on October 24, 2016) discloses an air pumping device for a food container, and a vacuum is created by manually moving the piston to the pump and discharging the air inside the container to the outside. It provides a container that can be formed.

As such, the conventional storage container often uses a manual decompression device to discharge the internal air to form a vacuum, and it is difficult to control the degree of vacuum even when operated electronically, or when the degree of vacuum is weakened after the vacuum is formed. There was a problem in that it was difficult for a user to notice, and a phenomenon such as food or feed left unattended in a state in which a vacuum was not formed occurred, and the utilization thereof was decreased.

Republic of Korea Patent Publication No. 10-1670218

It is an object of the present invention to include a cover capable of forming a vacuum inside the container, including a vacuum pump, and to notify the user when the concentration of oxygen that causes oxidation of food or feed increases by releasing the vacuum inside. An object of the present invention is to provide a vacuum storage container in which a user can easily understand and manage the vacuum state inside the container.

In addition, an object of the present invention is to provide a vacuum storage container that uses a rechargeable power source and enables wireless communication with a user's smartphone terminal to provide the operating state and vacuum state of the container in real time.

A preferred embodiment of the present invention is a vacuum storage container comprising a container having a storage space therein and a vacuum cover coupled to the upper portion of the container,

The vacuum cover,

a connection part coupled to the upper part of the container and sealing the storage space;

A vacuum forming assembly coupled to the upper part of the connection part to form a vacuum by discharging air inside the storage space to the outside, a pressure generating a signal for controlling the operation of the vacuum forming assembly by sensing the pressure inside the storage space A sensor, an oxygen sensor for measuring the oxygen concentration in the storage space, a control unit for collecting and processing operation information of the vacuum forming assembly and the oxygen concentration data, and a signal transmitted or received to the outside by receiving a signal from the control unit a communication unit for transmitting to the control unit, a mechanism unit including; and

a cover part coupled to the upper part of the mechanism part and having a display for displaying the oxygen concentration or operation information of the vacuum forming assembly to the outside;

It is a vacuum storage container comprising a.

Here, the oxygen sensor,

It is preferable to include an oxygen sensing unit including a housing, a semi-permeable separator provided inside the housing, an electrolyte provided in a region separated by the separator, and an electrode in contact with the electrolyte.

In addition, the oxygen sensor preferably has a long axis or a long axis of 30 mm or less and a weight of 6 g or less.

In addition, the control unit may include a vacuum forming assembly and a circuit board electrically connected to the oxygen sensor.

In this case, the circuit board is preferably connected to a cable connection terminal provided outside the cover part.

In addition, the vacuum forming assembly may include a motor and a diaphragm piston coupled to the motor.

In addition, the inside of the pressure sensor communicates with the storage space and is made of a flexible material, and when the pressure in the storage space is lowered to a predetermined value or less, it is preferable to be depressed by a pressure difference with the outside.

In addition, the communication unit,

When the oxygen concentration measured by the oxygen sensor is greater than or equal to a predetermined value in a state in which the vacuum forming assembly is not operated, it is preferable to transmit a signal to an interlocked user's terminal.

In addition, the control unit,

When the vacuum forming assembly operates for more than a predetermined time and the oxygen concentration measured by the oxygen sensor is greater than or equal to a predetermined value, it is preferable to stop the operation of the vacuum forming assembly and transmit a signal to an interlocked user's terminal .

On the other hand, it is preferable to include a vacuum holding cover coupled to the upper side of the container part and maintaining the vacuum of the storage space even after the vacuum cover is separated from the container part,

At this time, the vacuum holding cover,

an upper holding cover coupled to the connection part; and

It is preferable to include; a lower holding cover rotatably coupled to the lower portion of the upper holding cover and coupled to the container.

In addition, it is preferable that the upper holding cover is rotated with respect to the lower holding cover to convert the depression provided in the lower part of the vacuum holding cover into an open state in which air can communicate and a closed state in which air flow is blocked.

Here, it is preferable that the upper holding cover and the lower holding cover are provided on the outer circumferential surface of the mark indicating the open state and the closed state.

The vacuum storage container according to an aspect of the present invention is provided with a pressure sensor on the cover so that when the degree of vacuum inside the container becomes higher than a predetermined value, the power of the vacuum motor is automatically cut off to maintain an appropriate degree of vacuum.

In addition, in the vacuum storage container according to an aspect of the present invention, an oxygen sensor is provided on the cover to sense the oxygen concentration inside the container so that the concentration of elements causing oxidation of food or feed can be sensed in real time, so the pressure sensor Even when the vacuum is not working or the vacuum level is low, it is possible to detect a change in the degree of vacuum through the oxygen concentration, and by displaying this on the display provided on the upper part, the user can easily check the condition of the inside of the container with the naked eye.

In addition, the vacuum storage container according to an aspect of the present invention is provided with a communication unit capable of communicating with an external smart phone terminal so that it is possible to transmit the operating state of the pump and the oxygen concentration data sensed by the oxygen sensor to the external terminal, so that the user can By using a smartphone terminal linked with the communication unit, it is possible to easily manage the storage state of the container even from a distance.

1 is a perspective view schematically showing a vacuum storage container according to an embodiment of the present invention.
2 is an exploded view schematically showing a vacuum storage container according to an embodiment of the present invention.
3 is a view showing the structure of the vacuum forming assembly and the air circulation module of the vacuum storage container according to an embodiment of the present invention.
4 is a view showing a vacuum maintenance cover according to another embodiment of the present invention.
5 is a view showing the step of forming a vacuum of the container using a vacuum storage container according to another embodiment of the present invention.

Prior to describing the present invention in detail below, it is to be understood that the terminology used herein is for the purpose of describing specific embodiments and is not intended to limit the scope of the present invention, which is limited only by the appended claims. shall. All technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art, unless otherwise stated.

Throughout this specification and claims, unless stated otherwise, the term comprise, comprises, comprising is meant to include the stated object, step or group of objects, and steps, and any other object. It is not used in the sense of excluding a step or a group of objects or groups of steps.

On the other hand, various embodiments of the present invention may be combined with any other embodiments unless clearly indicated to the contrary. Any feature indicated as particularly preferred or advantageous may be combined with any other feature and features indicated as preferred or advantageous.

In the drawings, the width, length, thickness, etc. of the components may be exaggerated for convenience. In the description of the drawings as a whole, it has been described from an observer's point of view, and when it is said that one component is "above/below" or "above/below" another component, it is not only the case where another component is "directly above/under" , including the case where there is another component in the middle.

One aspect of the present invention discloses a vacuum storage container having a storage space therein, and including a container having an upper side and a vacuum cover coupled to the upper portion of the container.

Hereinafter, a vacuum storage container will be described in detail with reference to the drawings.

1 is a perspective view showing the exterior of a vacuum storage container according to a preferred aspect, and FIG. 2 is an exploded view showing the coupling structure of the vacuum storage container and the vacuum cover.

The container is a component provided with a storage space therein, such as food or feed to be stored, and the shape or size is not limited, but is preferably a cylindrical shape with an open top or a truncated cone with an open top. It is preferable that it is made of a transparent or translucent material that can visually confirm the inside.

The vacuum cover is coupled to the open upper part of the container and seals the storage space inside the container, thereby separating and blocking food or feed placed in the storage space from the outside.

The vacuum cover is characterized in that it includes a connection part, a mechanism part, and a cover part, and the connection part, the mechanism part, and the cover part are sequentially stacked and combined to form a vacuum cover.

The connection part serves to separate the internal storage space from the outside by being coupled to the upper part of the container and sealing the vacuum cover and the upper part of the container, and includes a hole provided in the center so that the space between the mechanism part and the internal space to be described later can communicate. . The vacuum cover includes a sealing member in the form of an O-ring surrounding the outer circumferential surface of the lower part, thereby blocking the air flow between the container and the connection part and preventing the vacuum of the storage space from being broken.

The mechanism unit is screwed with the connection unit at an upper portion of the connection unit and includes a vacuum forming assembly, a switch, a pressure sensor, an oxygen sensor, a control unit, and a communication unit. The mechanical part is a part where the main operating functions of the vacuum cover and the vacuum storage container are made, and all of the vacuum formation, vacuum control, communication with the outside, and control can be made.

The mechanism part is detachably screwed to the connection part, and a protrusion in which an internal air discharge hole communicating with the container is formed is extended on the bottom surface. The protrusion is inserted into the hole of the connection part and protrudes downward, and a coupling screw screwed to the protrusion from the lower part of the connection part may fix the protrusion and the connection part.

The vacuum forming assembly functions to form a vacuum by discharging air inside the storage space to the outside, and includes a motor and a pump, wherein the pump is preferably a pump including a diaphragm-type piston.

According to a preferred embodiment, the vacuum forming assembly includes a motor, a cam connected to the motor shaft, and a diaphragm-type piston fixed to the shaft eccentrically connected to the cam and displaced up and down by driving the motor to generate a suction force. .

It is preferable that the air in the storage space is discharged to the outside by the operation of the vacuum forming assembly, and an air circulation module is provided to sense the pressure and oxygen concentration of the air inside. The air circulation module of a preferred embodiment of the present invention is fixed to the bottom of the mechanism to support the pump, and the first boss 23 and the second boss 24 in the form of a tube communicating with the internal air outlet hole of the protrusion extend on the bottom surface formed, and an outlet passage 25 and an inlet passage 26 communicating with the first boss 23 and the second boss 24 are formed therein, and communicating with the discharge passage 25 and the inlet passage 26 A first air pipe (27) and a second air pipe (28) in the form of a daerong are included.

When the vacuum forming process according to the operation of the motor is described in detail, the cam installed on the shaft of the motor rotates as the motor is driven, and the diaphragm-type piston connected to the shaft fixed to be eccentric to the cam is repeatedly displaced up and down, and the suction force causes Here, the description of the principle in which the piston connected to the shaft is repeatedly displaced up and down and the principle in which the suction force is generated by the diaphragm-type piston is used in the technical field to which the present specification belongs, and thus a detailed description thereof is omitted.

The generated suction force forms an air flow in one direction along two holes formed on the edge of the port 29a under the piston, and an air passage formed in the second plate 50 coupled to the bottom of the first plate 40 of the air circulation module ( 50a) is moved.

That is, as the suction force moved to the air passage 50a moves to the air passage 60a formed on the upper surface of the third plate 60 that is in close contact with the bottom of the second plate 50, it is first made to communicate with the air passage 60a. 3 is moved to the second air pipe (28) protruding from the bottom surface of the plate (60).

The suction force moved to the second air pipe 28 is transmitted to the inside of the container through the internal air discharge hole formed inside the protrusion of the mechanism.

On the other hand, the air inside the container is moved to the discharge passage 25 through the first air pipe 27 protruding from the bottom surface of the third plate 60 of the air circulation module past the internal air discharge hole of the protrusion.

The air moved to the discharge passage 25 passes through the first boss 23 protruding on the upper surface of the first plate 40 of the air circulation module 29 and can escape to the outside through the air outlet of the cover. One end of the boss 23 can block the inflow of air from the outside to the inside by a packing made of silicon or a flexible material.

The switch is a component for controlling the operation of the vacuum forming assembly, and it is preferably a toggle switch for controlling the power applied to the motor and protruding from the upper part of the mechanism.

The pressure sensor senses the pressure inside the storage space to generate a signal for controlling the operation of the vacuum forming assembly. The inner space of the pressure sensor is in communication with the discharge passage 35 of the second plate 50 of the air circulation module 29, so that the pressure inside the container and the pressure in the inner space of the pressure sensor are equal, and the internal pressure of the container can detect

At this time, the pressure sensor can be used both mechanically and electronically.

A preferred embodiment discloses a mechanical pressure sensor. The pressure sensor has a structure in which the inside communicates with the storage space and has the same pressure as the pressure of the storage space, and the outside has the same pressure as the external atmospheric pressure separated from the storage space. And, when the pressure in the storage space is lowered to a certain value or less because it is made of a flexible material, it may be depressed into the inside by the pressure difference between the outside and the inside.

The pressure sensor can control the power of the motor by applying a force to the elastic piece provided on the upper part according to the state of being depressed or protruding. The power of the motor can be applied by raising and operating the switch connected to the elastic piece, but if a vacuum is formed and collapsed, the elastic piece does not come into contact with the elastic piece and cannot be pushed up. can be controlled to

The oxygen sensor is a sensor that measures the oxygen concentration inside the storage space, and can directly measure the oxygen concentration that causes oxidation of stored food or feed, and has the advantage of checking the vacuum state.

The oxygen sensor can receive air inside the storage space flowing through the internal air outlet hole of the mechanism and measure the oxygen concentration inside the storage space, and according to a preferred embodiment, such that the oxygen sensor communicates with the air circulation module 29 . Combined, it is possible to sense the concentration of oxygen by receiving air from the air circulation module 29 .

More specifically, the discharge passage 35 provided in the second plate 50 may include a hole communicating with the outside of the air circulation module 29, and the air in the discharge passage 35 through this hole The oxygen concentration of the air inside the container may be measured by being supplied to the oxygen sensor 35 .

At this time, the oxygen sensor preferably includes a sensor cover in which a space separated from the outside is formed so as to separate and measure the outside air and the inside air of the container, and as shown by way of example in FIG. 3 , the oxygen sensing unit (35-1) is provided in the sensor cover, it is preferable to receive the air supplied from the inside of the container to sense the oxygen concentration.

The oxygen sensor 35 is preferably small enough to be disposed in the mechanical unit, and is preferably electrically connected to a battery and a printed circuit board (PCB) for power supply and signal processing.

According to a preferred embodiment of the present invention, the oxygen sensor is preferably a sensor having a small size so that it can be provided inside the mechanism part, for example, the length of the long axis or the length of the long axis is 30 mm or less, and the weight is 6 g or less. It is recommended that a sensor be used. If the sensor is too large or heavy, it becomes difficult to mount the sensor on the mechanical unit, and there is a problem in that it is difficult to control the portability or capacity of the entire container.

More specifically, the oxygen sensing unit 35-1 of the oxygen sensor according to an embodiment of the present invention preferably includes a housing, a dust filter, a separator, and an electrode.

The electrode is made of high-purity metal and includes an anode and a cathode, an electrolyte is provided to surround the electrode, and a semi-permeable, waterproof separator that surrounds the electrolyte so as not to leak. The separator and the electrode are fixed inside the housing of the oxygen sensing unit, and a dust filter is provided in the opening through which external air can be introduced from the housing to receive external air and contact the separator.

After the foreign substances are filtered through the dust filter, the incoming air can be dissolved by penetrating into the electrolyte chamber through the separator, and it reacts with the dissolved oxygen at the anode to generate a current proportional to the concentration of oxygen penetrating into the electrolyte. This allows the concentration of oxygen to be measured.

Here, the electrode used is preferably a lead-free metal that does not contain lead, and preferably any one or more materials selected from the group consisting of pure gold with a purity of 99.99% or more and a porous carbon electrode. can be used

The oxygen sensor is preferably a sensor capable of measuring the concentration of oxygen in a pressure range of 600 mbar to 1200 mbar, and a sensor capable of measuring oxygen of 0 to 25 vol% is preferably used.

The control unit receives, collects, controls, and processes information on the operating state of the vacuum forming assembly and data sensed by the oxygen sensor or pressure sensor. The control unit may receive and process the connection state of the circuit that controls the operation of the motor or the state of the switch connected to the elastic piece to know the operation state of the vacuum forming assembly, and collect data generated from the pressure sensor or oxygen sensor .

The control unit includes a circuit board, and the circuit board is preferably a printed circuit board (PCB), and is electrically connected to the vacuum forming assembly and the oxygen sensor to control their operating state or to receive and process a sensed signal, If the pressure sensor is an electronic sensor, it is preferable to be electrically connected to the pressure sensor as well.

In addition, the control unit may perform a function of displaying the oxygen concentration sensed by the oxygen sensor and the operating state of the vacuum forming assembly on the display.

The communication unit is responsible for receiving a signal from the control unit and transmitting it to the outside, or transmitting a signal received from the outside to the control unit. The communication unit may perform Bluetooth or wireless communication with the outside, and may transmit/receive data by interworking with a terminal such as a user's smartphone.

On the other hand, the control unit of the vacuum storage container according to an embodiment of the present invention is a signal to the user's terminal interlocked through the communication unit when the oxygen concentration measured by the oxygen sensor in a state in which the vacuum forming assembly does not operate is equal to or greater than a predetermined value It is possible to send

In addition, the control unit may stop the operation of the vacuum forming assembly when the operation of the vacuum forming assembly exceeds a predetermined time, and the oxygen concentration measured by the oxygen sensor is equal to or greater than a predetermined value, and transmit a signal to the communication unit.

It is preferable that a battery for supplying power to the vacuum pump and the oxygen sensor is provided in the mechanism unit, but it is also possible that the battery is not included therein. When the battery is provided in the mechanism part, the battery is mounted in the battery coupling compartment, so that power can be stably supplied.

The battery coupling compartment is provided with a metal piece in contact with the positive electrode and the negative electrode of the battery to be electrically connected to the battery, and the pair of metal pieces may be electrically connected to the circuit board by a conductive wire.

In addition, the circuit board may be provided on the lower side of the cover portion, and is connected to a cable connection terminal provided on the outside of the cover portion to receive power or data through an external cable or to charge the battery.

The cover part is coupled to the upper part of the mechanism part and constitutes the exterior of the vacuum storage container, and covers the mechanism part to prevent foreign substances from entering the mechanism part or damage to the mechanism part. The cover part also includes a display that displays information on the oxygen concentration or the operating state of the vacuum forming assembly to the outside so that the user can visually check it, and it is also possible that an inlet for introducing external air into the storage space is formed.

It is also preferable that a handle is provided on the cover part of an embodiment of the present invention, and it is easy for the user to carry the vacuum cover by using the handle.

Another embodiment of the present invention discloses a vacuum storage container including a vacuum holding cover that can be coupled to the container portion.

4 and 5 are diagrams schematically showing the configuration of the vacuum holding cover and the operation state diagram of the vacuum storage container using the vacuum holding cover.

The vacuum holding cover includes an upper holding cover coupled to a lower portion of the connection part, and a lower holding cover coupled to a lower portion of the upper holding cover and coupled to the container on an outer circumferential surface.

At this time, the lower holding cover can seal the storage space by including a sealing silicone ring made of flexible silicone material that is in close contact with the container on the outer circumferential surface, and it is preferable that the upper holding cover has a structure that can be rotated with respect to the lower holding cover.

It is preferable that the upper holding cover and the lower holding cover include a depression recessed to the bottom, and the recessed part has a shape in which the protrusion of the connection part can be included therein.

The upper holding cover includes a communication hole in the lower portion of the recessed portion, and the lower holding cover includes an open hole having a larger size than the communication hole in the lower portion of the recessed portion.

Arrows indicating the rotation and relative positional relationship with the lower holding cover may be displayed on the outer circumferential surface of the upper holding cover, and characters indicating the state of the communication hole and the open hole of the recessed portion may be displayed on the lower holding cover on the outer circumferential surface.

For example, when the communication hole and the open hole coincide with each other, the arrow points to the 'open' or 'open' position, and when the upper holding cover is rotated 180 degrees, the communication hole and the open hole move to opposite positions. The air flow is blocked, and the arrow points to the 'close' or 'close' position, so that the user can know the relative positional relationship between the communication hole and the open hole.

Referring to FIG. 5 , it is possible to understand step-by-step how to maintain the container in a vacuum state after using the vacuum cover using the vacuum cover.

After coupling the vacuum cover in the 'open' state to the upper part of the container, when the vacuum cover is coupled to the upper part of the upper holding cover, the vacuum cover and the vacuum cover are coupled.

After that, when the vacuum cover is operated by pressing the switch of the vacuum cover, the air inside the storage space is released and a vacuum is formed.

Afterwards, the user rotates the upper holding cover of the vacuum holding cover from the 'open' state to the opposite side to make the 'close' state to block the air flow in the depression and seal the storage space. At this time, the vacuum of the storage space is maintained.

Remove the vacuum cover from the vacuum cover while the vacuum of the storage space is maintained. The container can be sealed by the upper holding cover and the lower holding cover to maintain an internal vacuum, and the separated vacuum cover can be combined with another container or used continuously.

The vacuum maintenance cover according to this embodiment can solve the limitation in which one vacuum cover is used to maintain the vacuum of one container. That is, even if only one vacuum cover is prepared, if there are a plurality of containers and a plurality of vacuum holding covers, there is an advantageous effect in that all of the plurality of containers can be made in a vacuum state by continuously using the vacuum cover.

Features, structures, effects, etc. exemplified in each of the above-described embodiments may be combined or modified with respect to other embodiments by those of ordinary skill in the art to which the embodiments belong. Accordingly, the contents related to such combinations and modifications should be interpreted as being included in the scope of the present invention.

1: container 2: vacuum cover
3: connection part 4: mechanical part
5: cover part 6: coupling screw
7: vacuum maintenance cover 10: switch
30: vacuum forming assembly 18: motor
19: cam 20: axis
21: piston 23: first boss
24: second boss 25: exhaust passage
26: inlet passage 27: first air pipe
28: second air pipe 29: air circulation module
34: pressure sensor 35: oxygen sensor
35-1: oxygen sensing unit 36: control unit
37: communication unit 38: battery compartment
40: first plate 41: air outlet
42: display 50: second plate
51: circuit board 52: cable connection terminal
60: third plate 101: depression
102: communication hole 103: open hole
110: silicone ring 120: protrusion

Claims (13)

A vacuum storage container comprising a container having a storage space therein and a vacuum cover coupled to an upper portion of the container,
The vacuum cover,
a connection part coupled to the upper part of the container and sealing the storage space;
A vacuum forming assembly coupled to the upper part of the connection part to form a vacuum by discharging air inside the storage space to the outside, a pressure generating a signal for controlling the operation of the vacuum forming assembly by sensing the pressure inside the storage space A sensor, an oxygen sensor for measuring the oxygen concentration in the storage space, a control unit for collecting and processing operation information of the vacuum forming assembly and the oxygen concentration data, and a signal transmitted or received to the outside by receiving a signal from the control unit a communication unit for transmitting to the control unit, a mechanism unit including; and
a cover part coupled to the upper part of the mechanism part and having a display for displaying the oxygen concentration or operation information of the vacuum forming assembly to the outside;
A vacuum storage container comprising a.
According to claim 1,
The oxygen sensor is
A vacuum storage container comprising a housing, a semi-permeable separator provided inside the housing, an electrolyte provided in a region separated by the separator, and an electrode in contact with the electrolyte, and an oxygen sensing unit.
3. The method of claim 2,
The oxygen sensor is a vacuum storage container having a long axis or a long axis of 30 mm or less and a weight of 6 g or less.
According to claim 1,
The control unit is a vacuum storage container including a vacuum forming assembly and a circuit board electrically connected to the oxygen sensor.
5. The method of claim 4,
The circuit board is a vacuum storage container connected to a cable connection terminal provided on the outside of the cover.
6. The method of claim 5,
The vacuum forming assembly includes a motor and a diaphragm piston coupled to the motor.
7. The method of claim 6,
The pressure sensor has an interior in communication with the storage space and is made of a flexible material, and when the pressure in the storage space is lowered to a predetermined value or less, the vacuum storage container is depressed by a pressure difference with the outside.
8. The method of claim 7,
The communication unit,
A vacuum storage container for transmitting a signal to the user's terminal interlocked when the oxygen concentration measured by the oxygen sensor exceeds a predetermined value in a state in which the vacuum forming assembly does not operate.
9. The method of claim 8,
The control unit is
When the vacuum forming assembly operates for more than a predetermined time and the oxygen concentration measured by the oxygen sensor is greater than a predetermined value, the vacuum storage for stopping the operation of the vacuum forming assembly and transmitting a signal to an interlocked user's terminal Vessel.
According to claim 1,
A vacuum storage container comprising a vacuum holding cover coupled to the upper side of the container part and maintaining the vacuum of the storage space even after the vacuum cover is separated from the container part.
11. The method of claim 10,
The vacuum maintenance cover,
an upper holding cover coupled to the connection part; and
A vacuum storage container comprising a; rotatably coupled to a lower portion of the upper holding cover and a lower holding cover coupled to the container.
12. The method of claim 11,
The upper holding cover is rotated with respect to the lower holding cover to convert the depression provided at the lower part of the vacuum holding cover into an open state through which air can communicate and a closed state in which air flow is blocked.
13. The method of claim 12,
A vacuum storage container in which the upper holding cover and the lower holding cover are provided on an outer circumferential surface with a mark indicating the open state and the closed state.

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