KR100672476B1 - Vacuum storage device and refrigerator using the same - Google Patents

Abstract

The present invention relates to a vacuum storage device capable of storing food in a vacuum state and a refrigerator using the same. The present invention is a storage container for storing food; A suction pump provided at one side of the storage container to suck air in the container; An oxygen separator extracting oxygen from the air sucked by the suction pump; In addition, provided on the other side of the container, after passing through the oxygen separation unit and provides a vacuum storage device comprising a nitrogen inlet pump for re-introducing the remaining air after the oxygen is extracted into the container and a refrigerator using the same.

Therefore, according to the present invention, the food can be kept in a vacuum state and the food can be kept fresh for a long time.

Vacuum storage device, refrigerator, oxygen separator, suction pump, nitrogen inflow pump

Description

Vacuum storage device and refrigerator using the same}

1 is a three-dimensional view showing a conventional refrigerator equipped with a vegetable compartment;

2 is a three-dimensional view showing a refrigerator equipped with a vacuum storage device according to the present invention;

3 is a block diagram showing an embodiment of a vacuum storage device according to the present invention;

Figure 4 is a block diagram showing a refrigerator using a vacuum storage device according to the present invention.

<Explanation of Signs of Major Parts of Drawings>

100: refrigerator 110: cold storage room

120: freezer 200: vacuum storage device

210: storage container 221: first check valve

222: second check valve 230: suction pump

241: first valve 242: second valve

250: oxygen separation unit 260: oxygen discharge unit

270: nitrogen storage tank 280: nitrogen inlet pump

300: water supply 400: filter

500: oxygen dissolution unit 610: ice-making valve

620: ice maker 630: ice extraction unit

710: cold water storage unit 720: cold water extraction unit

The present invention relates to a vacuum storage device and a refrigerator using the same, and more particularly, by sucking the air in the storage container, separating nitrogen from the sucked air, and introducing the same into the storage container, thereby maintaining the freshness of the food in the container for a long time. It relates to a vacuum storage device and a refrigerator using the same.

Referring to Figure 1, the refrigerator according to the prior art will be described.

In general, the refrigerator 10 is divided into a refrigerating chamber 11 and a freezing chamber 12 and configured to perform heat exchange through refrigerant circulation. The refrigerating chamber 11 keeps food and vegetables fresh and long at a temperature of approximately 3 ° C. to 4 ° C., and the freezing chamber 12 keeps food such as meat and fish frozen in subzero temperatures.

The refrigerator 10 generally includes a vegetable compartment 15 for storing vegetables or fruits under the refrigerator compartment. While the temperature of the refrigerating chamber 11 is usually about 3 ℃, the storage temperature of the vegetable chamber 15 is about 2 ℃ to 8 ℃ to be stored at a temperature suitable for vegetables or fruits. However, the shelf life of fruits and vegetables is short, such as 5 to 10 days, and the freshness did not last long.

In order to keep food fresh for a long time and to store food for a long time, a vacuum storage device for extracting air in a storage container by using a vacuum pump or the like and storing the food by keeping the storage container in a vacuum state is proposed.

However, the above-described vacuum storage device has the following problems.

First, the vacuum storage method of simply extracting the air in the storage container for long-term storage of food is to obtain the vacuum storage effect above a certain level. There was a problem in maintaining the strength enough to withstand the car.

Second, the decay rate of food is increased due to oxygen in the refrigerating or freezing chambers for storing food, and oxygen is disadvantageous in relation to food freshness.

The present invention is to solve the above problems, an object of the present invention is to provide a vacuum storage device and a refrigerator using the same, which does not require high robustness to withstand a vacuum state while maintaining a long storage period and freshness of food. It is.

Another object of the present invention is to reduce the decay of oxygen associated with maintaining the freshness of the food to improve the freshness of the food, and to effectively utilize the beneficial function of the oxygen separated from the air in the refrigerator to the human body.

In order to achieve the above object, a storage container for storing food; A suction pump provided at one side of the storage container to suck air in the container; An oxygen separator extracting oxygen from the air sucked by the suction pump; And, provided on the other side of the vessel, and provides a vacuum storage device comprising a nitrogen inlet pump for allowing oxygen to be extracted after passing through the oxygen separation unit and re-introduced into the vessel.

The vacuum storage device may further include an oxygen discharge unit for discharging oxygen extracted through the oxygen separation unit. The vacuum storage device may further include a nitrogen storage tank connected between the outlet side of the oxygen separation unit and the container, and storing the remaining air after oxygen is extracted after passing through the oxygen separation unit.

On the other hand, the first check valve that can control the flow rate of air introduced into the suction pump; And, it is preferable to include a second check valve for controlling the flow rate of air flowing into the storage container. The vacuum storage device may include a first valve connected to an inlet side of the oxygen separator to control a flow rate of air introduced into the oxygen separator; Further, it is more preferable to include a second valve connected to the outlet side of the oxygen separator to control the flow rate of air discharged from the oxygen separator. In addition, the suction pump and the nitrogen inlet pump is more preferably a vacuum pump.

The refrigerator using the vacuum storage device includes the vacuum storage device; A water supply unit for supplying water into the refrigerator; And an oxygen dissolving unit for dissolving oxygen discharged from the oxygen discharge unit of the vacuum storage device in the water flowing through the water supply unit to make oxygen water. The refrigerator may further include an ice extracting unit configured to extract ice iced through the ice making device; And it is preferable to include the cold water extraction part which takes out the said oxygen water. In addition, the refrigerator preferably includes a filter for filtering impurities from the water supplied through the water supply unit.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described.

2 and 3, an embodiment of a vacuum storage device according to the present invention will be described.

In general, oxygen has an adverse function with respect to maintaining food freshness. Specifically, when the refrigerator has a large amount of oxygen in the refrigerating compartment or the freezing compartment for storing food, the decay rate of the food is increased, and there are many limitations in maintaining the freshness of the food. Therefore, the refrigerator is provided with a separate vegetable room to maintain the freshness of fruits, vegetables and other foods, but the freshness does not last long.

In order to eliminate the adverse effects of oxygen associated with maintaining freshness, the vacuum storage device 200 according to the present invention is a suction pump 230, oxygen separation unit 250, oxygen discharge unit 260, nitrogen storage tank 270 , Nitrogen inlet pump 280.

The suction pump 230 is provided on one side of the storage container 210 for storing food, and serves to suck the air in the storage container 210. The suction pump 230 may be any structure as long as it is configured to suck air in the storage container 210. More specifically, the suction pump 230 is preferably a vacuum pump to suck air efficiently with relatively low noise.

The oxygen separator 250 performs a function of separating oxygen from sucked air, and there is no particular way. In general, air is composed of nitrogen and other components, including pure oxygen, and contains 20.9% oxygen in the atmosphere. An oxygen separator separates pure oxygen by taking in air from the atmosphere. In the conventional oxygen separator, oxygen is separated from the atmosphere by using an electrolysis method for electrolyzing water, a chemical reaction method by chemical reaction, PSA method, VGA method, UFL method, and the like.

In the present specification, an oxygen separator in a VGA method using an adsorption tower and a vacuum pump will be described as an example. Here, the basic principle of the VGA method is that the material gas passes through the adsorption tower filled with the adsorbent under high pressure to adsorb the high selectivity components first, and the low selectivity components are discharged out of the adsorption tower. In order to remove the adsorbed components, the pressure in the adsorption column is lowered to rejuvenate and the tower is washed with a portion of the high pressure product. By repeating this series of steps, the product can be obtained continuously. Synthetic zeolites are used as such adsorbents, and these synthetic zeolites are used as ion exchangers, catalysts, adsorption and dehydrating agents, and are widely used in separation processes due to their excellent adsorption and separation properties.

The air passing through the oxygen separation unit 250 is separated into oxygen and oxygen extracted air, respectively, the separated oxygen is the oxygen discharge unit 260, the air is oxygen is extracted air, most of which is made of nitrogen (hereinafter " Is abbreviated as " nitrogen &quot;.

The oxygen discharge unit 260 serves to discharge the oxygen separated through the oxygen separator 250 to the outside. By discharging oxygen to the outside, the vacuum storage device 200 also serves as the generation of oxygen, so that the user can be a comfortable indoor space. In addition, it can be used to make oxygen water by dissolving in water through the oxygen dissolving unit, which will be described in detail later.

The nitrogen storage tank 270 serves to store nitrogen separated by the oxygen separator 250. Although nitrogen may be configured to flow directly into the nitrogen inflow pump 280, in order to supply nitrogen more stably, the nitrogen is stored in the nitrogen storage tank 270, and nitrogen is introduced into the nitrogen storage tank 270. Preferably, the vacuum storage device 200 is configured to be supplied into the storage container 210 by the pump 280.

The nitrogen inflow pump 280 allows the nitrogen separated through the oxygen separation unit 250 to be reintroduced into the storage container 210. By simply extracting the air in the storage container 210 to create a vacuum state to maintain the freshness of food for a long time, in order to achieve a certain level of vacuum storage effect, the components constituting the storage container 210 or other vacuum storage devices are Maintain a certain level of robustness.

To solve this problem, by introducing nitrogen back into the storage container, the degree of vacuum in the storage container 210 is low, but the ratio of oxygen can be lowered, so that the strength of the storage container or other components can be adjusted to the degree of weak vacuum. On the other hand, the freshness of the food is advantageous because it can have the same effect as in a vacuum.

The nitrogen inflow pump 280 may be any structure so as to introduce nitrogen back into the storage container. In more detail, the nitrogen inflow pump 280 is preferably a vacuum pump to suck air efficiently with relatively low noise like the suction pump 230.

The vacuum storage device 200 preferably includes a first check valve 221 between the container and the suction pump, and a second check valve 222 between the container and the nitrogen inflow pump. The first and second check valves 221 and 222 serve to control the flow rate of air and nitrogen in a predetermined direction. That is, the first and second check valves 221 and 222 open when the air is sucked and the nitrogen is re-introduced into the storage container 210. However, the first and second check valves 221 and 222 are opened. The first and second check valves 221 and 222 are closed to keep the storage container closed.

In addition, the vacuum storage device 200 is connected between the suction pump 230 and the inlet side of the oxygen separator 250 to control the flow rate of air flowing into the oxygen separator 250. 241 and a second valve 242 connected between the outlet side of the oxygen separator 250 and the oxygen outlet 260 to control the flow rate of oxygen discharged. The second valve 242 is composed of a three-way valve to allow gas to flow to the oxygen discharge unit 260 and the nitrogen storage tank 270 according to the operating state. Of course, it is also possible to perform this role through two anisotropic valves.

The process of removing oxygen from the air inside the storage container 210 and filling nitrogen is as follows.

First, the first check valve 241 is opened, and the air inside the storage container 210 is supplied to the oxygen separator 250 by the suction pump 230. The supplied air is separated into oxygen and nitrogen through the oxygen separator 250, and the nitrogen separated through the oxygen separator 250 is introduced into and stored in the nitrogen storage tank 270. The separated oxygen is discharged to the outside of the vacuum storage device 200 through the oxygen discharge unit 260. On the other hand, the nitrogen stored in the nitrogen storage tank 270 is subjected to the process of being re-introduced into the storage container 210 by the nitrogen inflow pump 280 is opened by the second check valve 242.

While the oxygen is generated, the first valve 241 is opened to allow the air in the storage container 210 to flow into the oxygen separator 250, and the pressure in the oxygen separator 250 increases due to the operation of the suction pump 230. As a result, nitrogen is adsorbed and oxygen is concentrated. The concentrated oxygen is discharged to the oxygen discharge part 260 through the second valve 242.

When nitrogen is generated, the first valve 241 is closed, and the second valve 242 allows gas to flow in the direction of the nitrogen storage tank 270, so that the nitrogen inflow pump 280 operates to separate the oxygen separation unit 250. In this case, the pressure in the N) decreases, so that nitrogen adsorbed in the oxygen separation unit 250 is desorbed. The desorbed nitrogen is introduced into and stored in the nitrogen storage tank 270.

Referring to Figure 4, when describing the refrigerator using a vacuum storage device according to the present invention.

The basic configuration of the refrigerator according to the present invention is the same as that of a conventional refrigerator. That is, the main body is divided into the refrigerating chamber 110 and the freezing chamber 120, and configured to perform heat exchange through refrigerant circulation.

However, the refrigerator further includes a configuration for making oxygen water through oxygen generated in the vacuum storage device 200 and the vacuum storage device. Specifically, the refrigerator is provided with a water supply unit 300, a filter 400, the oxygen dissolving unit 500 in the vacuum storage device 200 to make acid acid.

The water supply unit 300 is a component for supplying water to the refrigerator through a water supply pipe to supply cold water and ice, and is connected to a water supply source to supply water to the filter 400.

The filter 400 filters the water supplied from the water supply unit 300 so that the user can drink the water.

The oxygen dissolving unit 500 is the oxygen separated through the oxygen separation unit 250 provided in the vacuum storage device 200 as shown in Figure 3, the water supply pipe from the water supply unit 300 By contacting with water passed through and passing through the filter 400, oxygen is dissolved in water and serves to make oxygen water having a high oxygen concentration. This dissolution process may be achieved by mixing concentrated oxygen air and water at normal pressure, and may increase the amount of dissolved oxygen of water by mixing under pressure higher than normal pressure by pressurization.

Meanwhile, a dike device 620 is provided to allow the user to receive ice through the ice extraction unit 630, and a cold water storage unit 710 to allow the user to receive cold water through the cold water extraction unit 720. ) Is provided.

The ice making device 620 serves to automatically provide the ice extracting unit 630 after ice making ice through oxygen water passed through the oxygen separating unit 250. This refrigerator ice maker is made of a flexible synthetic resin material according to the method of taking out the ice and twisted to separate the ice by twisting type, and made of a material such as aluminum having good thermal conductivity and using a heater separately installed. It is divided into heating type to separate ice. Here, the twisting type has a simple structure but low thermal conductivity, and the heating type has a complicated structure but good thermal conductivity. Therefore, in recent years, the heating type is mainly used for the embankment device. In addition, a control valve 610 is provided at the inlet side of the ice making machine to control the flow rate of water flowing into the ice making machine.

The cold water storage unit 710 stores a predetermined amount of cold water, so that the user can be stably supplied cold water through the cold water extraction unit 720. In addition, the cold water storage unit 720 is preferably located in the refrigerating chamber to maintain the proper temperature of the water.

The process of supplying oxygen water and ice containing oxygen to the user using oxygen generated in the vacuum storage device 200 will be described below.

First, after inhaling air in the storage container 200 to separate oxygen and nitrogen, oxygen generated in the process of re-introducing the separated nitrogen into the storage container 210 is supplied to the oxygen dissolving unit 500. On the other hand, the water supplied from the water supply unit 300 is available to drink through the filter is supplied to the oxygen dissolving unit 500, the oxygen generated in the vacuum storage device 200 is supplied to the oxygen dissolving unit 500 By dissolving water, oxygen water is produced. In addition, the oxygen water generated by the oxygen dissolving unit 500 is supplied to the ice maker 620 and the cold water storage unit 710, respectively, so that the user can drink the oxygen water and the ice containing oxygen.

The present invention is not limited to the above-described embodiment, and as can be seen in the appended claims, modifications can be made by those skilled in the art to which the present invention pertains, and such modifications are within the scope of the present invention.

The refrigerator according to the present invention described above has the following effects.

First, by maintaining the freshness of food by reducing the oxygen decay-related action associated with elongation maintenance, and by reintroducing nitrogen into the storage container can obtain a strong vacuum storage effect.

Second, by using the oxygen separated from the storage container can be obtained ice water containing oxygen water and oxygen favorable to the human body.

Claims (9)

A container for storing food; A suction pump provided at one side of the storage container to suck air in the container; An oxygen separator extracting oxygen from the air sucked by the suction pump; And, And a nitrogen inflow pump provided at the other side of the vessel and allowing oxygen to be extracted and re-introduced into the vessel after passing through the oxygen separation unit. The method of claim 1, The vacuum storage device, Vacuum storage device further comprises an oxygen discharge unit for discharging the oxygen extracted through the oxygen separation unit. The method of claim 2, The vacuum storage device, And a nitrogen storage tank connected between the outlet side of the oxygen separation unit and the container, and storing the remaining air after oxygen is extracted after passing through the oxygen separation unit. The method of claim 3, The vacuum storage device, A first check valve capable of controlling a flow rate of air introduced into the suction pump; And, And a second check valve for controlling a flow rate of air introduced into the storage container. The method of claim 3, The vacuum storage device, A first valve connected to an inlet side of the oxygen separator to control a flow rate of air introduced into the oxygen separator; And, And a second valve connected to the outlet side of the oxygen separator, the second valve controlling a flow rate of air discharged from the oxygen separator. The method according to any one of claims 1 to 5, The suction pump and the nitrogen inlet pump is a vacuum storage device, characterized in that the vacuum pump. The vacuum storage device of any one of claims 1 to 5; A water supply unit for supplying water into the refrigerator; And, And an oxygen dissolving unit communicating with the water supply unit through a water supply pipe and dissolving oxygen discharged from the oxygen discharge unit of the vacuum storage device in water introduced through the water supply unit to form oxygen water. The method of claim 7, wherein The refrigerator, An ice making apparatus for deicing the oxygen water, An ice extraction unit capable of taking out the ice iced through the ice making apparatus; And The refrigerator further comprises a cold water extraction unit for taking out the oxygen water. The method of claim 8, The refrigerator, The refrigerator further comprises a filter for filtering impurities from the water supplied through the water supply unit.

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