KR20120011451A - A refrigerator comprising thawing chamber - Google Patents

Abstract

PURPOSE: A refrigerator having a defrosting room is provided to rapidly defrost a defrosting object by a molecular vibration heating using a infrared defrost heater and a rapid air flow using an air suction of an air suction motor. CONSTITUTION: A refrigerator comprises a main body, a defrosting room(100), a defrost heater(300), and an airflow induction device. The main body comprises a storage room. The defrosting room is installed in the main body. The defrosting heater installed inside of the defrosting room heats a defrosting object. The airflow induction device installed inside of the defrosting room induces airflow inside the defrosting room so that the airflow is passed through the defrosting object.

Description

Refrigerator with thawing chamber {A refrigerator comprising thawing chamber}

The present invention relates to a refrigerator having a thawing room, and more particularly, to a refrigerator capable of quickly defrosting and preventing deterioration of a quality of a thawing object.

Refrigerators are home appliances that can be stored in the refrigerator or frozen storage using the refrigerant cycle.

The configuration of the refrigerator includes a main body having a storage compartment and a door mounted to the main body to open and close the storage compartment.

In the conventional refrigerator, since there is no place for thawing the meat or other products stored in the freezer outside the storage room or the storage room, the refrigerator is usually thawed by storing the frozen product in the refrigerating chamber or by leaving the refrigerator outside at room temperature. .

The present invention is to solve such a problem, in detail, the thawing can be made quickly, and an object thereof is to provide a refrigerator capable of preventing the deterioration of the quality of the thawing object.

The present invention for achieving the above object, and a main body having the storage chamber; Thawing chamber provided in the main body; A thawing heater provided inside the thawing chamber and applying heat to the thawing object; It is provided in the thawing chamber, characterized in that it comprises an air flow inducing device for causing the air flow in the thawing chamber to pass the air flow to the thawing object.

A thawing shelf provided inside the thawing chamber, on which the thawing object is placed, wherein the thawing shelf includes a support for supporting the thawing object; It is formed in the support characterized in that it comprises a communication hole through which the flow of air passes.

The air flow inducing device is composed of an air intake motor, characterized in that the air intake motor is disposed under the support.

The thawing shelf further includes a front portion disposed in front of the support portion and formed with a pull-out handle portion, wherein the support portion is topped with a thawing object and the communication hole is formed; And a side wall portion provided at both sides of the upper surface portion, and the air suction motor is disposed to be surrounded by the upper surface portion, the side wall portion, and the front portion.

A first sealing portion disposed between the front portion and an upper surface portion of the support portion to block air flow between the portion; And a second sealing part disposed between the front part and the side wall part to block air flow therebetween.

The communication hole is disposed above the air suction motor, and after the air flow driven by the air suction motor passes through the thawing object, it passes through the communication hole to the air suction motor.

It is characterized in that it further comprises an insertion hole provided in the rear of the thawing shelf, the air suction motor is inserted and mounted.

The thawing chamber is provided inside the storage chamber, and further includes a partition wall for partitioning the thawing chamber and other storage spaces in the storage chamber, wherein a portion adjacent to an end of the partition wall is formed to communicate with another storage space. It is characterized by.

The thawing shelf is characterized in that it is arranged to be pulled out in the thawing chamber in a sliding manner.

The thawing heater is disposed on the upper surface of the storage compartment, characterized in that configured as an infrared heater.

And a control unit for controlling the operation of the air flow inducing device and the thawing heater, wherein the control unit controls the air flow inducing device to a stop state when the thawing heater is operated, and the air flow inducing device when the thawing heater is stopped. It characterized in that the control to operate.

The present invention has the advantage that the thawing of the thaw object is quickly performed by heating by molecular vibration using the infrared thawing heater and rapid air flow using the air suction action of the air suction motor.

In particular, it is possible to maximize the thawing ability by performing the operation of the heater and the induction of air flow alternately.

In addition, since the heating method using the vibration of molecules using an infrared heater instead of the direct heating heater does not cause a problem that the thawing object ripens.

In addition, the thawing object can be thawed uniformly rather than locally thawed.

1 is a front view of a refrigerator according to the present invention.
2 is an exploded perspective view of a thawing chamber and a thawing shelf according to the present invention.
Figure 3 is an exploded perspective view of the thawing shelf and the air suction motor according to the present invention.
4 is a perspective view showing a thawed state in a thawing chamber according to the present invention.
Fig. 5 is a side sectional view showing a thawing state in a thawing chamber according to the present invention.
Figure 6 is a graph showing the operating state of the thawing heater and the air suction motor according to the present invention.
7 is a comparison graph and table of a thawing method according to the present invention and another thawing method.

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

As shown in FIG. 1, the refrigerator according to the present invention includes a main body 10, a storage compartment 20 provided in the main body, and a door 30 provided in the main body 10 to open and close the storage compartment 20. Equipped with.

The storage chamber 20 includes a storage shelf 21 on which a storage object can be placed, and a storage drawer 22 that accommodates the storage and is retractable from the storage chamber.

The storage chamber 20 is provided with a thawing chamber 100 separately from the storage shelf 21 and the storage drawer 22, wherein the thawing chamber 100 is a part capable of thawing the storage object stored frozen.

The storage compartment 20 is typically divided into a refrigerating compartment and a freezing compartment, wherein the thawing chamber 100 is preferably provided in the refrigerating compartment.

This is because, in the thawing action in the thawing chamber 100 of the present invention, thawing is performed by using a flow of air having a temperature condition of an image.

The thawing chamber 100 is equipped with a thawing shelf 200 on which a thawing object can be placed, and the thawing shelf 200 is drawn out in a slide manner with respect to the thawing chamber 100.

As shown in FIG. 2, the thawing chamber 100 is mutually partitioned from other storage spaces in the storage chamber 20, and a thawing heater 300 is provided on an inner ceiling of the thawing chamber 100.

The thawing heater 300 is preferably composed of an infrared heater, not a convection heater causing convection or conduction of heat, and preferably, a plurality of thawing heaters are configured to adjust the degree of heating.

The thawing chamber 200 is mounted to the thawing chamber 100. Looking at the configuration of the thawing shelf 200, the support part 210 on which the storage object is placed and the front part coupled to the front part of the support part ( 220).

The front portion 220 is formed with a groove-shaped handle portion 221 that can be pulled out by the user walking the finger, the handle portion 221 may be protruded in addition to the groove shape.

Therefore, when the user pulls out the thawing shelf 200, the user may pull the hand by the hand to the handle part 221, and when the thawing shelf 200 is inserted into the thawing chamber, the support part of the thawing shelf 200 is provided. Align the 210 with the thawing chamber 100 and push the front part 220.

In order to smoothly move the thawing shelf 200, a rail part 230 is provided on a side surface of the support part 210, and the rail part 230 is formed in a partition wall 110 constituting an inner wall of the thawing chamber 100. It is preferable that the guide member 120 for guiding the movement of the) is provided.

Here, the guide member 120 is preferably composed of a rail or a roller.

The support portion 210 includes an upper surface portion 211 on which the thawing object is placed, and sidewall portions 212 provided on both lower sides of the upper surface portion 211.

A space surrounded by the upper surface portion 211, the side wall portion 212, and the front portion 220 is formed in the support portion 210, and the air causing the air flow for thawing is formed in the space. Flow generating device is installed.

The air flow inducing device is preferably composed of an air intake motor 400, so that the speed of the air sucked by the air intake motor 400 can be increased in the portion where the thawing object is located, the upper surface portion ( 211 is provided with a communication hole 213 for communicating between the upper surface portion 211 and the space in which the air suction motor 400 is installed.

Therefore, when the air intake motor 400 operates, the air inside the thawing chamber 100 may move to the air intake motor 400 through the communication hole 213.

It is preferable that a plurality of positions of the communication hole 213 are mutually spaced apart from each other at a position where the thawing object is normally expected to be placed.

That is, when the air intake motor 400 positioned below the upper surface portion 211 is operated, the upper portion of the defrosting object placed on the upper surface portion 211 and air in and around the thaw flow, while the thawing After exchanging heat with the object, it passes through the communication hole 213 and enters the air suction motor 400,

As shown in FIG. 3, an insertion hole 214 through which the air suction motor 400 is inserted is formed at the rear of the support part 210, and the air suction motor 400 is inserted into the insertion hole. When combined into the (214), the air suction motor 400 is fixed to the support (210).

When the air suction motor 400 is a suction action, the suction of air should be made only through the communication hole (213).

This is because active heat exchange between the thawing object and the air flow placed around the communication hole 213 only when the air flow intensively passes through the communication hole 213 is performed to defrost the thawing object intensively.

Therefore, the sealing of the rear of the front portion 220 and the front of the support portion 210 should be made sure.

Accordingly, a first sealing part 251 is disposed at the front of the upper surface part 211 and the rear of the front part 220, and at the front of the side wall part 212 and the rear of the front part 220. The two sealing part 252 is arrange | positioned.

In addition, coupling portions 211a and 220a that are coupled to each other are provided at the front center portion of the upper surface portion 211 and the rear portion of the front portion 220. It is preferable that the part 251 is arrange | positioned.

Due to the arrangement of the first and second sealing parts 251 and 252, when the air suction motor 400 operates, air may flow into a gap between the front part 220 and the front of the support part 210. The possibility disappears.

On the other hand, since the upper surface portion 211 and the side wall portion 212 is originally composed of one injection molding, there is no fear of air passing through the seam.

Therefore, when the air suction motor 400 operates under such a configuration, a flow path of air is formed along the upper surface portion 211, the communication hole 213, and the air suction motor 400. .

In particular, active heat exchange may occur between the air moving at a high speed immediately before passing through the communication hole 213 and a thawing object placed near the communication hole.

The operation of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 4, the thawing chamber 100 is partitioned by a neighboring storage space and the partition wall 110.

The partition wall 110 divides the thawing chamber 100 with most of the adjacent storage spaces, but a small gap is formed at the upper end and the front end thereof.

That is, the upper end of the partition wall 110 is spaced apart from the storage shelf (see Fig. 1, 21) provided above the thawing chamber 100 to form a gap. In addition, the front end of the partition wall 110 is slightly spaced apart from the end of the front portion 220 of the thawing shelf 200 to form a gap.

Therefore, when the user places a thawing object on the upper surface of the support portion 210 of the thawing shelf 200 and starts the thawing operation, the air suction motor 400 starts the air suction action.

When the air suction is started, the air in the thawing chamber 100 and the air introduced into the gap formed between the partition wall 110 and the adjacent structure move in the direction of the communication hole.

Here, the flow of air introduced into the gap is represented by A.

Since the communication hole 213 is disposed only on the upper surface of the support part 210, after the air flows around the thawing object M before passing through the communication hole 213, the communication hole 213. Flows into.

On the other hand, during thawing, the thawing heater 300 provided above the thawing chamber 100 selectively operates. The thawing heater 300 acts when the air suction motor 400 is stopped. desirable.

Because, in the case where the thawing action occurs because the heat is released from the thawing object (M) due to the operation of the thawing heater 300, when the air intake motor 400 is operated, the heat is not used to thaw and most of the communication This is because the air flows to the ball 213 is lost.

Here, the flow of infrared rays emitted from the thawing heater 300 made of an infrared heater is indicated by B.

Fig. 5 is a side sectional view showing the operation of the present invention.

Since the temperature of the thawing object M is below zero and the temperature of the air passing through the thawing object M is the temperature of the image, when heat exchange occurs between them, the temperature of the thawing object M rises to thaw. It begins to be.

As the air suction motor 400 operates, the speed of the air passing through the thawing object M is increased, and a rapid flow of air causes friction with the thawing object M to generate such frictional heat.

Thus, the thawing operation on the thawing object M can be made faster.

On the other hand, the air passing through the thawing object (M) passes through the communication hole 213, the air flow (C) passing through the communication hole 213 is moved to the air suction motor 400.

When the operation of the air suction motor 400 is completed and stopped, a rapid flow state of air is released, and then thawing is started by infrared radiation of the thawing heater 300.

The thawing through the infrared heating technique does not heat the thawing object by radiation or convection of heat, but causes thawing by causing molecules constituting the thawing object to vibrate to cause heat generation of the molecules.

Infrared is an electron pie, so the principle of heat transfer, absorption, and heating is different from that of conventional conduction, convection, or radiation.

When the thawing by the operation of the thawing heater 300 is performed to some extent, the thawing heater 300 is stopped and the air suction motor 400 is driven again to perform thawing by air flow.

That is, as shown in FIG. 6, when the thawing heater is turned on, the air suction motor is turned off, and when the thawing heater is turned off, the air suction motor is turned on to alternate with each other. To on state.

As described above, when heat is generated by the vibration of molecules in the thawing object due to infrared emission of the thawing heater, if a rapid flow of air occurs, the heat disappears through heat exchange with the air, so This is to prevent the flow from occurring so that the heat due to molecular vibration is used to heat the thawing object.

Figure 7 shows the effect of thawing according to the present invention in graphs and tables.

First, the temperature of the thawing object at the start of thawing was -18 ° C, and the temperature of the thawing object when thawing was completed was assumed to be -1.5 ° C.

If thawing is performed while the packaged thawing object is kept refrigerated, it takes 1120 minutes, that is, 18 hours and 40 minutes.

On the other hand, when thawing by jet thawing, that is, the air inhalation method and infrared heating method of the present invention, it takes 242.13 minutes (about 4 hours) for the packaged thawing object, and 131.53 minutes for the unpackaged thawing object ( About 2 hours and 12 minutes).

On the other hand, in the case of jet thawing, the thawing time is similar to the thawing time at room temperature if there is a package, but the thawing may be completed within a significantly faster time than the normal temperature state if there is no packing.

10: main body 20: storage compartment
100: thawing room 110: partition wall
200: thawing shelf 210: support
211: upper surface portion 212: side wall portion
213: communication hole 220: front part
221: handle portion 300: thawing heater
400: air suction motor

Claims (11)

A main body having a storage compartment;
A thawing chamber provided in the main body;
A thawing heater provided inside the thawing chamber and applying heat to the thawing object;
And an air flow inducing device provided in the thawing chamber and causing an air flow in the thawing chamber to allow the flow of air to pass through the thawing object. The method of claim 1,
It further includes a thawing shelf provided inside the thawing room, on which the thawing object is placed.
The thawing shelf includes a support for supporting the thawing object;
And a communication hole formed in the support part, through which air flows. The method of claim 2,
The air flow inducing device is composed of an air intake motor,
And the air intake motor is disposed under the support. The method of claim 3,
The thawing shelf further includes a front portion disposed in front of the support and formed with a handle for drawing,
The support portion is placed on the thawing object and the upper surface portion the communication hole is formed;
It includes side wall portions provided on both sides of the upper surface portion,
The air suction motor is arranged to be surrounded by the upper surface portion, the side wall portion and the front portion. The method of claim 4, wherein
A first sealing portion disposed between the front portion and an upper surface portion of the support portion to block air flow between the portion;
And a second sealing part disposed between the front part and the side wall part to block air flow therebetween. The method of claim 2,
The communication hole is disposed above the air intake motor,
And an air flow driven by the air suction motor drives the thaw object and passes through the communication hole to the air suction motor. The method of claim 3,
The refrigerator further comprises an insertion hole provided at the rear of the thawing shelf and into which the air suction motor is inserted. The method of claim 7, wherein
The thawing chamber is provided in the storage compartment,
And a partition wall for partitioning the thawing chamber and other storage spaces in the storage compartment, wherein a portion adjacent to an end portion of the partition wall is provided with a gap for communicating with another storage space. The method of claim 2,
And the thawing shelf is arranged to be drawn out in the thawing chamber in a slide manner. The method of claim 1,
The thawing heater is disposed on the upper surface of the storage compartment, characterized in that consisting of an infrared heater. The method of claim 1,
Further comprising a control unit for controlling the operation of the air flow inducing device and the thawing heater,
The control unit is characterized in that the refrigerator controls the air flow inducing device to a stop state when the thawing heater is operated, and controls the air flow inducing device to be operated when the thawing heater is stopped.

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