KR101581937B1 - a freezer using a mixing cooling air - Google Patents

Abstract

The present invention relates to a supercooling freezer capable of maintaining a supercooling state of a cooled object. The supercooling freezer using mixed air according to an embodiment of the present invention may include: a freezing main body including an accommodation space to accommodate a cooled object and a door opening or closing the accommodation space to put the cooled object in the accommodation space or to take out the cooled object from the accommodation space; a mixed chilly air generation part including a cooling passage where an evaporator cooling air in the accommodation space through heat exchange is installed, a direct passage to which the air of the accommodation space is supplied without passing through the evaporator, and a mixing circulation fan which mixes chilly air generated via the evaporator in the cooling passage with the air supplied through the direct passage and at the same time supplies the mixed chilly air to the accommodation space; a supply duct which guides the mixed chilly air generated in the mixed chilly air generation part to a lower part and an upper part of the accommodation space; and a plurality of cooling plates which is arranged in the accommodation space at intervals in a vertical direction, and cools the cooled object by heat exchange with the air of the accommodation space without spraying the chilly air to the cooled object directly by being cooled by the chilly air supplied by the supply duct. Therefore, the supercooling freezer according to the present invention can decrease power consumption, and can maintain the accommodation space in a uniformly supercooled state overall.

Description

A supercooling freezer using mixed cooling air.

The present invention relates to a supercooled freezer capable of maintaining the object to be cooled in a supercooled state.

The supercooling phenomenon is a phenomenon in which the molten matter or solid does not change even when cooled to the phase transition temperature or lower in the equilibrium state.

In the supercooled state, since the member is in an unstable state, if it is shocked, it freezes in the form of a slush. By using such a supercooled state, a slush drink can be provided to the consumer.

On the other hand, in order to provide a supercooled beverage, a "cooling tower" of Korean Registered Patent No. 10-1205822 (registered on November 22, 2012) has been disclosed.

As shown in Fig. 1, a conventional cooling compartment comprises a cooling chamber 2 for accommodating a liquid beverage container P, a heat exchanger 9 for cooling the air in the cooling chamber 2, A cooling duct 5 installed inside the cooling duct 5 and a suction port 10 provided in a part of the cooling duct 5 and a cool air discharge port 12 provided at a position different from the suction port 10 of the cooling duct 5. [ A cooling air supply duct 6 for circulating the air in the cooling chamber 2, an inlet 15 provided at one end of the cooling air supply duct 6, A ventilation hole 20 for blowing air into the chamber 2 and a fan 16 mounted so as to face the introduction port 15 of the cooling air supply duct 6. The cooling duct 5, The air in the cooling chamber 2 is sucked from the suction port 10 and cooled by the heat exchanger 9 and then blown into the cool air discharge port 12. The cool air supply duct 6 is connected to the cooling chamber 2 ) The inlet port 15 faces the cooling air discharge port 12 of the cooling duct 5 and faces the cooling chamber 2. The fan 15 faces the cooling air discharge port 12 of the cooling duct 5, (15) to suck air into the cold air supply duct (6) by the blower (16).

The conventional coolant of such a configuration can provide a supercooled beverage in such a manner as to delay the time for cooling the beverage by mixing the air and the cool air in the cooling chamber 2 and supplying the cooled mixture to the cooling chamber 2. [

However, in the conventional cooling hood, when the mixed air is generated, the fan 10 for introducing the air into the cooling duct 5 and the fan 16 for mixing the air are installed, which causes a problem of high power consumption. There is a problem that the effect of mixing the air mixed with the cooling air passing through the cooling duct 5 rather than the air inside the cooling chamber 2 by the fan 10 installed in the duct 5 is insufficient.

In addition, since the fan 16 is fixed to the introduction port 15, the mixing ratio can not be controlled and it is difficult to control the temperature of the mixed air.

Further, since the beverage is blown into the cooling chamber 2 containing the beverage through the cold air supply duct 6, the beverage located close to the cool air supply duct 6 from which the cool air is blown, that is, inside the cooling chamber 2, And the beverage located outside the cool air supply duct 6, that is, outside the coolant chamber 2, is insufficiently supercooled due to the transmitted cool air and is located in the middle of the coolant chamber 2 There is a problem that only the beverage is overcooled and uncooled unevenly according to the position in the cooling chamber 2.

Further, since the beverage is cooled by spraying cool air directly to the beverage, when the beverage is filled in the cooling chamber, there is a problem that resistance to circulation of cool air is generated and cooling efficiency is lowered.

In addition, when the door is opened, the outside air is introduced into the cooling chamber 2 to lower the efficiency of cooling the beverage, and it takes a long time to cool the beverage.

Since the cool air supplied to the cooling chamber 2 through the heat exchanger 9 has a lower temperature than the air of the existing cooling chamber 2, There is a problem that a cooling imbalance occurs in which the lower part is cooled more than the upper part of the upper part.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide an air- The present invention provides a supercooling freezer using mixed air capable of controlling the temperature of the mixed cool air by controlling the temperature of the mixed cool air.

Further, not only a direct cooling method by cold air but also an indirect cooling method can cool the entire accommodating space uniformly, and a supercooling freezer that can prevent the cooling efficiency from being lowered due to the resistance of cool air circulation .

It is another object of the present invention to provide a supercooling freezer which can prevent the cooling efficiency from being lowered by keeping the object to be cooled when the door is opened.

According to an aspect of the present invention, there is provided a supercooling freezer using mixed air according to an embodiment of the present invention includes a housing space for accommodating an object to be cooled and a door for opening and closing the accommodation space to carry the object to be cooled into or out of the accommodation space A direct flow path in which the air in the accommodation space is directly supplied without passing through the evaporator, and a cool air flow generated in the cooling flow path through the evaporator, And a mixed circulating fan for mixing the air supplied through the direct flow path and the mixed circulating fan to supply the mixed cool air to the receiving space, and a circulating fan for circulating the mixed cool air generated in the mixed cool air generating unit up and down And a plurality of supply ducts spaced apart from each other above and below the accommodation space, Is cooled by the cooling air without directly injecting the cooling air to the blood receiving water received in the receiving space is in the form of air and the heat of the receiving space may include a cooling plate cooling the blood receiving water.

The supply duct can supply only the cooling plate without directly discharging the mixed cold air toward the water receiving object.

The mixed cool air generating unit may be located at an upper portion or a lower portion of the accommodation space.

The mixing circulation fan is installed so as to be movable up and down between the cooling channel and the direct channel so as to control the mixing ratio of the mixed cool air according to the size of the cooling channel and the direct channel.

The cooling plate includes a cool air passage passing through the mixed cool air supplied from the supply duct, a cool air discharge hole for discharging the mixed cool air supplied to the cool air passage in a direction in which the door is positioned, And a radiating heat transfer hole for cooling the object to be cooled, which is located at a lower portion of the plate, by radiating heat of the mixed cool air, wherein the cool air discharging hole is formed to be larger than the size of the radiating heat transfer hole, The mixed cold air passing through the passage may be equal to or lower than the lower pressure of the radiating heat transfer hole, so that the mixed cold air may be discharged only to the cold air discharge hole and not to the radiating heat transfer hole.

When the mixed circulation fan stops, the pressure of the mixed cooling air supplied to the cooling plate is released, so that the mixed cooling air remaining in the cooling air passage is discharged to the radiating heat transfer hole to heat the object to be cooled.

The amount of the mixed cool air supplied to the supply duct is adjusted in such a manner that a part of the mixed cool air supplied to the supply duct is discharged and then supplied to the mixed cool air generating unit located between the cold air generating unit and the cooling plate immediately adjacent thereto And the amount of cold air discharged into the cold air amount adjusting space is automatically adjusted by changing the pressure of the cold air amount adjusting room according to the temperature of the object to be cooled housed in the accommodation space, The amount of cool air to be supplied can be adjusted.

And a shelf for supporting the object to be cooled so as to be separated from the cooling plate so that the object to be cooled does not contact the cooling plate.

And a cool air control plate for controlling the amount of cool air supplied to each of the cooling plates in the supply duct.

At least one of the plurality of cooling plates may have different lengths protruding in a direction in which the door is located.

According to the present invention, it is possible not only to mix air and cold air in the receiving space with the mixed circulating fan, but also to reduce the power consumption by circulating the mixed cool air in the receiving space, The temperature of the mixed cold air can be controlled by controlling the mixing ratio of the air and the cold air.

The cooling plate indirectly cools the object to be cooled in the form of cooling the air in the accommodation space and heat-exchanging the object with the air in the cooled accommodation space, It is possible not only to uniformly cool the accommodating space as a whole but also to prevent uneven cooling according to the position of the object to be held due to the resistance of the cold air.

In addition, the amount of cool air can be automatically adjusted according to the object to be accommodated in the accommodating space by the cold air amount adjusting space, thereby uniformly cooling the object to be supplied as a whole.

Further, by providing a mixed cold air in which air and cold air in the accommodation space are mixed and indirectly cooling the object, the object can be stably brought into the supercooled state and the supercooled state can be maintained.

1 is a side cross-sectional view showing a conventional coolant.
2 is a side cross-sectional view illustrating a supercooling freezer using mixed air according to a first embodiment of the present invention.
FIG. 3 is a front view showing a supercooling freezer using mixed air according to a first embodiment of the present invention, excluding a door. FIG.
4 is an exploded perspective view of a cooling plate of a supercooling freezer using mixed air according to a first embodiment of the present invention.
FIG. 5 is a side cross-sectional view illustrating a supercooling freezer using mixed air according to a first embodiment of the present invention, and shows a flow of a mixed cool air.
6 is an enlarged cross-sectional side view of a mixed cool air generating unit and a cool air amount adjusting space of a supercooling freezer using mixed air according to a first embodiment of the present invention.
7 is a schematic front view showing that a mixed circulation fan of a supercooling freezer using mixed air according to the first embodiment of the present invention is movably installed.
FIG. 8 is an enlarged cross-sectional side view of a mixed cool air generating unit and a cool air amount adjusting room of a supercooled freezer using mixed air according to a first embodiment of the present invention, and shows a flow of a mixed cool air when a door is opened.
9 is a side cross-sectional view of a supercooling freezer using mixed air according to a second embodiment of the present invention.
10 is an enlarged cross-sectional side view of a mixed cool air generating unit and a cool air amount adjusting space of a supercooling freezer using mixed air according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

First, a supercooling freezer 100 using mixed air according to an embodiment of the present invention forms a supercooling condition so that the object 200 to be cooled is supercooled to maintain the object 200 in an uncooled state and a supercooled state (100). ≪ / RTI >

Here, the supercooling phenomenon is a phenomenon in which the phase does not change even when the liquid is cooled to the phase change temperature or lower in the equilibrium state. Since the constituent is unstable in the supercooled state, when the supercooled liquid is impacted, 200) can be produced.

And, the object 200 to be cooled may be a beverage containing carbonic acid or a beverage containing alcohol or a general beverage.

On the other hand, the method of satisfying the supercooling condition is a method of rapidly cooling the temperature of the object 200 to be cooled to a temperature not higher than the phase change temperature or a method of slowly cooling the object 200 to be cooled to a phase change temperature Lt; 0 > C.

The freezer for maintaining the supercooled state according to the embodiment is configured to satisfy the supercooling condition by slowly cooling the cooled object 200 to the phase change temperature or lower.

2 and 3, the supercooling freezer 100 using the mixed cold air according to the first embodiment of the present invention may include a freezing body 110.

The freezing body 110 is formed in a box shape and includes a receiving space 111 for receiving the object 200 to be cooled and a door 113 for opening and closing the receiving space 111.

A heat insulating material (not shown) for inserting the receiving space 111 may be provided on a wall surface of the freezing body 110.

In addition, the door 113 may be formed of glass so that the object to be cooled 200 contained in the accommodation space 111 can be seen, and the glass can be realized by a vacuum glass having high heat insulation property.

5 and 6, the supercooling freezer 100 using the mixed cold air according to the first embodiment of the present invention may include a mixed cool air generating unit 120. [

The mixed cold air generating unit 120 may generate cold air by partially cooling the air in the receiving space 111 and supplying cold air to the remaining part of the air in the receiving space 111 without cooling the mixed air cooler.

The mixed cold air generating unit 120 may be positioned above the receiving space 111. The mixed cold air generated by the mixed air generating unit 120 may be supplied to the accommodating space 111 through the supply duct 130, ). ≪ / RTI >

The mixed cold air generating unit 120 may include an air inlet 127 through which the air in the receiving space 111 is sucked in front of the door 113 in the direction in which the door 113 is positioned, And includes a cooling channel 121 and a direct channel 123 that are partitioned by the partition walls in the upper and lower portions.

The cooling channel 121 can generate cool air through heat exchange through a part of the air in the accommodation space 111 sucked into the air intake hole 127. The cooling channel 121 can generate cool air, And an evaporator 122 for exchanging heat with the sucked air so as to cool the air.

Here, the evaporator 122 can be cooled by the refrigerant while passing through the refrigerant, and the evaporator 122 is cooled by the compression and expansion of the refrigerant together with the known cooling means, the compressor 180, the expansion valve, and the condenser Can be cooled by a cooling cycle.

Since the cooling means constituting the cooling cycle are well known in the art, a detailed description thereof will be omitted, and the mixed cool air generating portion 120 may further include a device for performing the defrosting of the evaporator 122, The detailed description is omitted.

The direct flow path 123 can be partitioned from the direct flow path 123 in the mixed cool air generating portion 120 so that the air in the accommodation space 111 can be supplied directly without passing through the evaporator 122, May be positioned below the cooling channel 121. [

In addition, the mixed cool air generating portion 120 may include a mixing space 125.

The mixing space 125 is located at the end of the direct flow path 123 and the cooling flow path 121 in the mixed cool air generating section 120 to cool the air in the uncooled receiving space 111 passing through the direct flow path 123, The cool air cooled by the evaporator 122 through the flow path 121 can be mixed.

The mixed cool air generating unit 120 may include a mixed circulating fan 126.

The mixed circulating fan 126 is installed in the mixing space 125 to mix air discharged from the direct flow path 123 and cool air discharged from the cooling flow path 121 and to circulate air in the accommodation space 111 as a whole .

On the other hand, the mixed circulation fan 126 is disposed in the partition plate 124 partitioning the direct flow passage 123 and the cooling flow passage 121 so as to extend between the direct flow passage 123 and the cooling flow passage 121, And exposed to the direct flow path 123, and a part thereof may be installed to be exposed to the cooling flow path 121.

7, the mixed circulation fan 126 is installed so as to be slidable up and down so as to mix the air discharged through the direct flow path 123 and the cool air discharged through the cooling flow path 121 The ratio can be adjusted to control the temperature of the mixed cold air.

For example, when the mixed circulation fan 126 is moved upward from the mixing space 125, the area of the mixed circulation fan 126 exposed from the cooling flow path 121 is larger than the direct flow path 123, The temperature of the mixed cool air can be lowered by sucking the cool air discharged from the cooling channel 121 more.

On the contrary, when the mixed circulation fan 126 is moved downward from the mixing space 125, since the area exposed by the direct flow path 123 is larger than the cooling flow path 121, The temperature of the mixed cool air can be increased by sucking the air discharged from the flow path 123 more.

That is, the mixing circulation fan 126 is configured such that the suction amount of the air or the cool air differs according to the area facing the cooling passage 121 or the direct passage 123, and the mixing ratio of the cool air and the air is changed according to the position of the mixing circulation fan 126 The temperature of the mixed cool air can be adjusted in a controlled manner.

The mixed cold air generating unit 120 having such a structure mixes the cold air generated by heat exchange in the evaporator 122 and the air that has not been cooled in the accommodation space 111 to generate mixed cooling air, It is possible to make the object to be supercooled by delaying and at the same time to keep the object to be supercooled.

As shown in FIGS. 5 and 6, the supercooling freezer 100 using the mixed cold air according to the first embodiment of the present invention may include a supply duct 130.

The supply duct 130 communicates with the mixed cool air generating unit 120 to guide the mixed cool air generated in the mixed cool air generating unit 120 to a lower portion of the receiving space 111.

Meanwhile, the supply duct 130 may be installed on the wall surface of the freezing body 110 facing the door 113 in the accommodation space 111.

Here, the supply duct 130 does not form a hole for ejecting the mixed cool air into the receiving space 111 where the object to be received is located such that the mixed air does not directly contact the object to be received.

That is, when the mixed cool air directly comes into contact with the water-receiving material, the water-receiving material does not reach the supercooling state because it is cooled immediately without delay cooling the water-receiving material.

And, the supply duct 130 may include a cool air guide member 135.

The cool air guide member 135 is rotated by the mixing circulation fan 126 so that the mixed cool air that is rotated in one direction by the mixed circulation fan 126 and discharged to the supply duct 130 is uniformly dispersed and supplied The cool air can be guided to be dispersed in a direction opposite to the direction in which the mixed cool air discharged is discharged.

The cool air guide member 135 may be installed on the inner wall surface of the supply duct 130. The cool air guide member 135 may be formed long in the vertical direction of the supply duct 130, The guide member 135 is bent in the direction opposite to the direction in which the cool air is rotated so that the mixed cool air is uniformly dispersed throughout the supply duct 130 in the direction opposite to the rotating direction of the mixed cool air discharged from the mixed circulating fan 126 Or in the form of a curve.

At this time, the cool air guide member 135 may be installed to adjust the angle of the cool air guide member 135 according to the intensity of the mixed cool air.

4 to 6, the supercooling freezer 100 using the mixed cooling air according to the first embodiment of the present invention may include a cooling plate 150.

The cooling plate 150 is cooled by the mixed cool air supplied from the supply duct 130 and can cool the air in the accommodation space 111 in the form of heat exchange with the air in the accommodation space 111.

The cooling plate 150 may protrude toward the front where the door 113 is located in the supply duct 130 and a plurality of the cooling plates 150 may be disposed above and below the accommodation space 111 .

The cooling plate 150 may be configured such that a cool air passage is formed so that mixed air can pass therethrough and is cooled by the mixed air passing through the cool air passage.

On the other hand, a cool air discharge hole 151 may be formed at an end of the cooling plate 150 in the direction in which the door 113 is positioned, through which the mixed air passing through the coolant passage is discharged to the front where the door 113 is positioned.

The mixed cold air introduced into the cooling plate 150 is discharged through the cold air discharge hole 151 of the cooling plate 150 and is discharged into the door 113 by the mixed circulation fan 126, So that it can be sucked into the mixed cool air generating unit 120. [0053]

A radiating heat transfer hole 153 formed through the cooling plate 150 to cool the object 200 to be cooled, which is located below the cooling plate 150, may be formed on the bottom surface of the cooling plate 150 have.

A plurality of radiating heat transfer holes 153 may be formed and the radiating heat transfer holes 153 may have a size smaller than that of the cool air discharging holes 151. Conversely, So that the mixed cool air passing through the cool air passage can be discharged only to the cool air discharge hole 151 without being discharged to the radiating heat transfer hole 153.

When the radiating heat transfer hole 153 is formed to be larger than the size of the cool air discharging hole 151, the mixed cool air passing through the cooling plate 150 is discharged to the radiating heat transfer hole 153, The supercooled state can not be directly brought into contact with the mixed cool air, and the supercooled state may immediately change to freeze.

The cooling heat transfer holes 153 are formed in the cooling plate 150, which will be described later, because the mixed cooling air is not discharged unless the pressure according to the flow rate of the cooling air passing through the cooling air passage is lower than the pressure directly below the radiating heat transfer hole 153. [ So that the mixed cool air is not discharged to the radiating heat transfer hole 153 in a form of adjusting the amount of the mixed cool air supplied to the cooling plate 150 by the radiating heat transfer hole 153. [

On the other hand, the mixed cold air passing through the cooling plate 150 is blown by the forced pressure of the mixed circulation fan 126. When the door 113 is opened, the mixed circulation fan 126 is stopped and the cooling plate 150 The pressure of the mixed cold air passing through the mixing circulation fan 126 is stopped, and the flow rate of the mixed cool air passing through the cooling passage is not generated.

8, when the mixed circulation fan 126 is stopped, the mixed cool air remaining in the cooling plate 150 can not be discharged to the cool air discharge hole 151 and cooled through the radiating heat transfer hole 153 The object to be cooled 200 can be kept warm by blocking the contact of the outside air in the form of covering the object 200 to be cooled by discharging it to the object 200 to be cooled,

The cooling plate 150 located at the uppermost portion of the accommodation space 111 among the plurality of cooling plates 150 may be excessively cooled due to the cold air amount adjusting space 140 through which the mixed cold air to be described later is discharged Therefore, the radiating heat transfer hole 153 for transmitting radiant heat to the object 200 to be cooled may not be formed in the lower portion.

The plurality of cooling plates 150 may be formed such that the length of the plurality of cooling plates 150 protruding in the direction in which the door 113 is positioned is shortened from the upper portion to the lower portion or the length is decreased from the lower portion to the upper portion, 150 may be formed to be long or short.

The temperature of the accommodation space 111 may vary depending on the degree of filling and temperature of the object 200 to be cooled or the temperature of the mixed cold air. By varying the length, the temperature of the accommodation space 111 can be adjusted uniformly.

Since the mixed cool air generating portion 120 for generating mixed cool air is positioned above the accommodation space 111 and the lower portion of the accommodation space 111 has a lower temperature than the lower portion of the accommodation space 111, The length of the cooling plate 150 located at the lower portion of the accommodation space 111 is longer than the length of the cooling plate 150 located at the upper portion of the space 111. [

The cooling plate 150 configured as described above is cooled by the mixed cooling air supplied from the supply duct 130 and a plurality of the cooling plates 150 are arranged above and below the accommodation space 111 to entirely cool the air in the accommodation space 111, The air in the accommodated space 111 is configured to cool the object 200 to be cooled so that the cooled air does not directly cool the object 200 to be cooled but indirectly cools the object 200 to be cooled The object to be cooled 200 can be maintained in a supercooled state.

By indirectly cooling the cooled object 200 by directly spraying the mixed cold air, the front of the housing space 111 where the door 113 is positioned and the rear side where the supply duct 130 is positioned are uniformly arranged And also prevents the mixed cool air from being struck against the object 200 to be cooled to prevent the air from moving, so that it is possible to circulate the cool air quickly and improve the cooling efficiency.

As shown in FIGS. 5 and 6, the freezer for maintaining the supercooled state according to the first embodiment of the present invention may include a cold air amount adjusting space 140.

The cooling air amount adjusting space 140 delays the cooling speed of the object 200 to be cooled in such a manner that the amount of mixed cooling air supplied to the receiving space 111 is totally controlled through the supply duct 130, 200 can be made into a supercooled state that is not frozen.

In order to overcool the object 200 to be cooled, it is necessary to cool the cooling object 200 more slowly than the normal cooling rate. To increase the cooling rate, if it is assumed that the required amount of supercooled cooling heat is constant throughout the accommodation space 111, It is necessary to reduce the temperature difference between the inlet and outlet of the supply cold air (supercooling supply amount of heat of cooling, amount of heat of cold air, difference of inlet / outlet temperature, and supply time).

The cold air amount adjusting space 140 may be positioned between the cooling plate 150 and the mixed cool air generating unit 120 located at the uppermost portion of the accommodation space 111 and may penetrate a part of the supply duct 130 The amount of the mixed cool air supplied to the supply duct 130 can be adjusted in such a manner that a part of the mixed cool air supplied from the mixed cool air generating unit 120 to the supply duct 130 is discharged into the accommodation space 111.

Here, the cold air amount adjustment space 140 is formed in such a manner that the pressure for supplying the mixed cool air to the supply duct 130 by the mixed circulation fan 126 is higher than the pressure generated by the flow rate of the mixed cool air passing through the supply duct 130 The mixed cold air can be discharged from the supply duct 130 to the cold air amount adjustment space 140. [

At this time, depending on the load condition of the object to be cooled (200), the cold air amount adjusting space (140) may be in a neutral state in which there is substantially no flow of mixed cold air.

The mixed cold air discharged into the cold air amount regulating space 140 does not cool the receiving space 111, that is, does not perform the heat exchange, and is immediately returned to the mixed cold air generating unit 120 So that the cooling efficiency can be improved.

When the load of the accommodation space 111 is increased, for example, when the object to be cooled 200 is further stored in the accommodation space 111 or the door 113 of the accommodation space 111 The temperature difference between the accommodating space 111 and the supply duct 130 is largely changed. As a result, the natural convection increases the internal flow rate of the mixed cool air generating portion 120 and the pressure is reduced (Bernoulli The amount of mixed cool air discharged through the cold air amount adjusting space 140 may be reduced.

Accordingly, the amount of the mixed cool air discharged into the receiving space 111 through the cooling plate 150 becomes relatively large, so that the supply amount of the mixed cool air can be automatically adjusted in proportion to the size of the load.

On the other hand, when the load of the accommodation space 111 is reduced, the temperature difference between the inlet and outlet of the mixed cool air generating unit 120 is reduced, the flow rate in the supply duct 130 is slowed and the pressure is increased, The amount of mixed cooling air discharged to the cooling plate 150 is relatively increased and the amount of mixed cooling air supplied to the cooling plate 150 is reduced, so that the object 200 to be cooled can be gradually supercooled.

That is, the cold air amount adjusting space 140 automatically adjusts the discharge amount of the mixed cool air according to the load, thereby uniformly controlling the time for cooling the object 200 to be cooled, regardless of the load, ) Can be subcooled.

As described above, the mixed cold air discharged from the cold air amount adjusting space 140 is discharged directly below the mixed cold air generating unit 120, and therefore, before the object 200 to be cooled in the accommodation space 111 is cooled The mixed circulating fan 126 is again sucked into the mixed cool air generating unit 120 so that the heat exchange temperature of the evaporator 122 is minimized and the cooling efficiency of the evaporator 122 can be improved.

Since the cooling air amount adjusting space 140 is formed to open a part of the supply duct 130, the pressure of the mixed cool air leaks into the cool air amount adjusting space 140 and is supplied to the supply duct 130 It is possible to prevent the occurrence of noise due to the supplied pressure of cold air.

As shown in FIGS. 5 and 6, the supercooling freezer 100 using mixed air according to the first embodiment of the present invention may include a cool air control plate 160.

The cool air control plate 160 controls the amount of mixed cool air supplied to the cooling plates 150 from the supply duct 130 and the amount of the mixed cool air discharged from the supply duct 130 to the cool air amount control space 140 .

The cool air control plate 160 may be installed at a portion where the supply duct 130 and each cooling plate 150 communicate with each other and at a portion where the cool air amount control space 140 and the supply duct 130 communicate with each other, The cooling duct 150 and the cold air amount adjusting space 140 may be formed such that the mixed cold air moves downward from the upper portion of the supply duct 130 and flows upward.

The cooling control plate 160 may be configured to be rotatable up and down so as to adjust the amount of cooling air flowing into the cooling plate 150 and the cooling air amount control space 140 have.

As shown in FIGS. 5 and 6, the freezer for maintaining the supercooled state according to the first embodiment of the present invention may include a shelf 170.

The shelf 170 can support the object 200 to be cooled in the receiving space 111 so as to place the object 200 to be cooled in the receiving space 111.

The shelf 170 can support the object 200 to be cooled in the cooling plate 150 so that the object 200 to be cooled is not in direct contact with the cooling plate 150, May be disposed between a plurality of cooling plates 150 so that the object 200 to be cooled may be positioned between a plurality of cooling plates 150 arranged up and down in the accommodation space 111. [

At this time, the shelf 170 is positioned at a close position of the cooling plate 150 positioned below so that the object 200 to be cooled can be cooled by the radiant heat from the lower part of each cooling plate 150 Can be installed.

The shelf 170 may be formed in a grid shape so that the air in the accommodation space 111 can freely flow into the object 200 to be cooled and exchange heat with the object 200 to be cooled.

The freezer for maintaining the supercooled state according to the first embodiment of the present invention may include an illumination (not shown).

This illumination can illuminate the accommodation space 111 to illuminate the dark accommodation space 111.

On the other hand, the illumination may be realized by an LED module having a plurality of LEDs, and may be installed on the periphery of the accommodation space 111 or on the door 113.

Then, the illumination can be operated to be turned on or off according to the opening and closing of the door 113.

The operation and effect between the above-described respective constitutions will be described.

The supercooling freezer 100 using the mixed air according to the first embodiment of the present invention includes a door 113 that opens the door 113 and accommodates the object 200 to be cooled in the shelf 170 installed in the accommodation space 111 ) Is closed.

When the door 113 is closed, as shown in FIG. 5, the mixed circulation fan 126 operates to circulate air in the accommodation space 111 to start cooling.

When the mixed circulation fan 126 operates, the air in the accommodation space 111 is sucked into the air intake port 127 of the mixed cool air generating unit 120, and a part of the sucked air passes through the cooling channel 121, And the remaining part of the air is also directly introduced into the mixing space 125 without being cooled by the evaporator 122 through the direct flow path 123.

The cool air generated through the cooling channel 121 discharged to the mixing space 125 and the air passing through the direct channel 123 are mixed by the mixed circulation fan 126 to generate a mixed cool air whose temperature is controlled And is discharged to the supply duct 130 by the mixed circulating fan 126.

At this time. The mixed circulating fan 126 extends between the cooling channel 121 and the direct channel 123 and is installed so as to be slidable up and down so as to be discharged from the cooling channel 121 according to the position of the mixed circulation fan 126 The temperature of the mixed cool air can be adjusted in such a manner that the mixing ratio of the air discharged from the cold air and the direct flow path 123 is controlled.

The mixed cold air discharged to the supply duct 130 passes through the cooling plate 150 to cool the cooling plate 150 to perform heat exchange with the accommodation space 111 in which the cooling plate 150 is installed, The cool air is discharged into the cool air discharge hole 151 positioned in front of the accommodation space 111 where the door 113 is located and then introduced into the mixed cool air generating unit 120 again by the mixed circulating fan 126, .

Here, the mixed cool air in the cool air circulation path is not supplied to be directly in contact with the object 200 to be cooled. Instead, the cooled object 200 is cooled indirectly by the cooling plate 150, So that the object to be cooled 200 can be maintained in a supercooled state.

The mixed cold air discharged to the supply duct 130 is discharged to a part of the cold air amount adjusting space 140 according to the load of the accommodation space 111 and is discharged to the mixed cold air generator 120 again by the mixed circulation fan 126 The cool air is automatically supplied to the supply duct 130 in accordance with the change in the pressure of the cooling object 200 in the accommodation space 111. [ To adjust the temperature of the accommodation space (111).

For example, when the amount of the object 200 to be filled in the accommodation space 111 is large and the temperature is high and the load is increased, the pressure of the accommodation space 111 is increased and the cool air amount adjustment space 140 is relatively small The amount of the mixed cool air can be automatically adjusted in such a manner that the mixed cool air, that is, the mixed cool air for cooling the accommodation space 111 is supplied to the supply duct 130 more.

Since the amount of the cold air to be cooled is controlled according to the load accommodated in the accommodation space 111, the cold air amount adjustment space 140 can be gradually and stably By cooling, it is possible to uniformly make all the water-receiving materials into a supercooled state and simultaneously keep them in a supercooled state.

The cooling plate 150 is cooled by the mixed cooling air, and the cooled cooling plate 150 is cooled by not directly spraying mixed cooling air to the object 200 to be cooled on the cooling circulation path, The object to be cooled 200 can be indirectly cooled in the form of heat exchange with the air in the accommodation space 111 so that the air in the accommodation space 111 cools the object 200 to be cooled.

That is, the cooling plate 150 can delay the cooling by indirect cooling of the object 200 to be cooled, thereby bringing the object 200 to be cooled into a supercooled state.

The shelf 170 is installed between the plurality of cooling plates 150 to seat the object to be cooled 200 and to separate the object 200 to be cooled 200 from the cooling plate 150, Can be prevented from being supercooled by direct contact with the cooling plate (150).

A radiating heat transfer hole 153 is formed in the lower part of the cooling plate 150. The radiating heat transfer hole 153 does not discharge mixed cooling air, 200 to cool the object 200 to be cooled by radiant heat.

At this time, the mixed cool air passing through the cooling plate 150 is guided to the radiating heat transfer hole 153 by the mixed air circulation fan 126 and the cooling air discharge hole 151 formed in the cooling plate 150, The cool air is not discharged to the radiating heat transfer hole 153. [

On the other hand, when the door 113 is opened, the operation of the mixed circulation fan 126 is stopped and the operation of the mixed circulation fan 126 is stopped to minimize the loss of the mixed cool air as shown in FIG. 8, The flow rate of the cooling air passing through the cooling plate 150 is lost and the mixed cooling air remaining in the cooling plate 150 is discharged to the lower portion through the radiating heat transfer hole 153, The object to be cooled 200 can be kept warm by blocking the water 200 from the outside.

Hereinafter, a supercooling freezer 100 using mixed air according to a second embodiment of the present invention will be described.

In the supercooling freezer 100 using the mixed air according to the second embodiment of the present invention, the same components as those of the first embodiment are denoted by the same reference numerals, and the same components have the same functions and effects, do.

9 and 10, the supercooling freezer 100 using the mixed air according to the second embodiment of the present invention is the same as that of the first embodiment, and in the first embodiment, 120 and the cold air amount adjusting space 140 are located at the upper portion of the accommodation space 111. In the second embodiment, however, only the difference is that the mixed cold air generating portion 120 and the cold air amount adjusting space 140 are located at the lower portion have.

The mixed cool air generating portion 120 according to the second embodiment may be positioned below the receiving space 111 of the freezing body 110. [

In the mixed cold air generating unit 120, the cooling channel 121 provided with the evaporator 122 may be located at the lowest position, and a direct flow channel 123 partitioned by the diaphragm 124 may be disposed on the cooling channel 121 .

At the end of the coolant passage 121 and the direct passage 123 where the cool air cooled by the evaporator 122 and the air in the storage space 111 flowing directly without passing through the evaporator 122 are exhausted And a mixed circulation fan 126 may be disposed in the mixing space 125. The mixing circulation fan 126 may be disposed in the mixing space 125. [

The cooling air amount adjustment space 140 is located between the cooling plate 150 and the mixed air generation portion 120 located at the lowermost end of the accommodation space 111 among the plurality of cooling plates 150.

The cool air control plate 160 for controlling the amount of mixed cool air flowing into the cooling plate 150 or the cold air amount adjusting space 140 can be controlled by controlling the amount of cool air supplied from the lower portion to the upper portion through the supply duct 130, 130 so that they can be introduced when they are downwardly turned.

The radiating heat transfer hole 153 of the cooling plate 150 located at the lowermost end of the receiving space 111 is formed on the upper surface of the cooling plate 150 to transmit radiant heat to the object 200 to be cooled, Or may not be formed to prevent excessive cooling.

The supercooling freezer 100 using the mixed air according to the second embodiment opens the door 113 to house the object 200 in the accommodation space 111 and then closes the door 113, The air in the accommodation space 111 flows into the cooling flow path 121 and the direct flow path 123 through the air intake port 127 of the mixed cool air generating portion 120.

The air in the accommodation space 111 flowing into the cooling flow path 121 is cooled through the evaporator 122 and discharged to the mixing space 125. The air in the accommodation space 111 into which the direct flow path 123 flows, And is discharged into the mixing space 125 without being cooled by the evaporator 122.

Meanwhile, the cool air and air discharged to the mixing space 125 are mixed by the mixed circulation fan 126 to generate mixed cool air, and the mixed cool air passes through the cooling duct 150 through the supply duct 130, 150 to the front where the door 113 is located.

The mixed cool air discharged through the cool air discharge hole 151 is circulated through the cool air circulation path in such a manner that the mixed cool air flows downward by the mixed circulation fan 126 and then flows into the mixed cool air generating unit 120 again.

The mixed cool air supplied from the mixed cool air generating unit 120 to the supply duct 130 is discharged to the accommodating space 111 in a form of partially discharging the mixed cool air through the cool air amount adjusting space 140 according to the load of the accommodating space 111 111 can be controlled.

The mixed cold air discharged through the cold air amount adjusting space 140 may be introduced into the mixed cold air generating unit 120 by the mixed circulating fan 126 without being discharged to the receiving space 111.

As described above, the supercooling freezer 100 using the mixed air according to the second embodiment directly sucks and circulates mixed cold air that sinks to the lower portion of the accommodation space 111 due to its low temperature, It is possible to eliminate the uneven cooling of the object to be accommodated depending on the position of the accommodation space 111.

Further, the cooling efficiency can be improved by sucking and circulating cool air moving to the bottom of the accommodation space 111 according to the temperature difference.

Accordingly, in the supercooling freezer 100 using the mixed air according to the embodiment of the present invention, the air in the accommodation space 111 is mixed with the cool air cooled through the evaporator 122, and the cooled object 200 is cooled By indirect cooling, the object 200 to be cooled can easily be brought into a supercooled state and can be maintained in a supercooled state.

In addition, since the mixed circulation fan 126 circulates the air in the accommodation space 111 at the same time as the mixed cool air is mixed, the consumed electric power can be minimized.

 In addition, the temperature of the mixed cool air can be controlled by controlling the mixing ratio of the cool air and the air in the form of adjusting the position of the mixed circulating fan 126 in the mixed cool air generating unit 120.

The amount of the cooling air supplied to the supply duct 130 in accordance with the load of the accommodation space 111 in the cold air amount adjustment space 140 is adjusted so that the object 200 to be cooled is uniform regardless of the amount and temperature The object to be cooled 200 can be stably brought to a supercooling degree.

It is also possible to prevent the cooling plate 150 from heat-exchanging with the air in the accommodation space 111, instead of directly blowing the mixed cold air from the cooling plate 150 toward the object 200 to be cooled, Indirectly cooling the cooled object 200 in the form of heat exchange with the water 200 not only makes it possible to easily maintain the object 200 to be cooled in a supercooled state but also allows the mixed cool air to be supplied unevenly according to the resistance of the object 200 to be cooled Cooling imbalance can be solved.

The mixed cooling air remaining in the cooling plate 150 when the door 113 is opened is discharged to the radiating heat transfer hole 153 of the cooling plate 150 to warm the object 200 to be cooled, .

Also, the accommodating space 111 can be uniformly cooled as a whole by adjusting the length of the cooling plate 150 or adjusting the supply of the amount of cooling air by the cooling plate 160.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes and modifications to the scope of the invention.

100: supercooling freezer 110: freezing body
111: accommodation space 113: door
120: Mixed cool air generating unit 121: Cooling channel
122: Evaporator 123: Direct flow
124: diaphragm 125: mixing space
126: Mixed circulation fan 127: Air inlet
130: supply duct 135: cool air guide member
140: Cooling amount control space 150: Cooling plate
151: Cool air discharge hole 153: Radiation heat transfer hole
160: Cooling control plate 170: Shelf
180: compressor 200:

Claims (10)

A freezing body including a housing space for housing the object to be cooled and a door for opening and closing the housing space to carry the object to be cooled into or out of the housing space,
A direct flow path in which the air in the accommodation space is directly supplied without passing through the evaporator, and a cool air generated through the evaporator and the direct flow path, And a mixed circulating fan for mixing the air supplied through the circulating fan and supplying the mixed air to the receiving space,
A supply duct for guiding the mixed cool air generated in the mixed cool air generating unit to a lower portion of the accommodation space,
Wherein a plurality of heat exchangers are arranged above and below the accommodating space and are cooled by cold air supplied to the supply duct to heat exchange with air in the accommodating space without directly injecting cool air into the water contained in the accommodating space, And a cooling plate for cooling the water content,
Wherein the mixing circulation fan is provided so as to be movable up and down between the cooling channel and the direct channel so as to control the mixing ratio of the mixed cool air according to a size of the cooling channel and the direct channel,
The cooling plate includes a cool air passage passing through the mixed cool air supplied from the supply duct, a cool air discharge hole for discharging the mixed cool air supplied to the cool air passage in a direction in which the door is positioned, And a radiating heat transfer hole for cooling the object to be cooled, which is located at a lower portion of the plate, by radiating heat of the mixed cool air, wherein the cool air discharging hole is formed to be larger than the size of the radiating heat transfer hole, Wherein the pressure of the mixed cool air passing through the passage is equal to or lower than the pressure of the lower portion of the radiating heat transfer hole so that the mixed cool air is discharged only to the cold air discharge hole and not discharged to the radiating heat transfer hole. The method according to claim 1,
The supply duct
Wherein the cooling air is supplied only to the cooling plate without directly discharging the mixed cooling air toward the water receiving object. The method according to claim 1,
The mixed cold air generating unit
Wherein the freezing chamber is located above or below the accommodation space. delete delete The method according to claim 1,
Wherein when the mixed circulating fan is stopped, the pressure of the mixed cool air supplied to the cooling plate is released, and the mixed cool air remaining in the cool air passage is discharged to the radiating heat transfer hole. Supercooling freezer using. The method according to claim 1,
The amount of the mixed cool air supplied to the supply duct is adjusted in such a manner that a part of the mixed cool air supplied to the supply duct is discharged and then supplied to the mixed cool air generating unit located between the cold air generating unit and the cooling plate immediately adjacent thereto And a cold air amount adjusting space,
The amount of cool air discharged into the cool air amount adjusting space is automatically controlled by adjusting the pressure of the cooled object accommodated in the accommodating space according to the temperature of the cool air amount adjusting room so that the amount of cold air supplied to the supply duct is controlled A supercooling freezer using mixed cold air. The method according to claim 1,
And a shelf for supporting the object to be cooled so as to be separated from the cooling plate so that the object to be cooled is not in contact with the cooling plate. The method according to claim 1,
And a cool air regulating plate for regulating an amount of cool air supplied to each of the cooling plates in the supply duct. The method according to claim 1,
The plurality of cooling plates
Wherein at least one of the lengths protruding in a direction in which the door is located is differently formed.

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