KR200229276Y1 - A upper heater cooling apparatus for micro wave oven - Google Patents

Abstract

The present invention relates to an upper heater cooling structure of a microwave oven. The present invention provides the influence of the airflow formed by the exhaust fan assembly 70 on the insulation 60 shielding the portion exiting the downstream portion of the air tunnel 50 for guiding the airflow for cooling the upper heater 40. A plurality of communication holes 62 were drilled. In addition, a plurality of communication louvers 43 for communicating the inside of the air tunnel 50 and the inside of the heater cover 42 to the heater cover 42 shielding the upper heater 40 in the air tunnel 50. Dogs formed. Therefore, the air flow formed in the air tunnel 40 is more activated, and the upper heater 40 and the heater cover 42 are efficiently cooled.

Description

A upper heater cooling apparatus for micro wave oven

The present invention relates to a microwave oven, and more particularly, to an upper heater cooling structure of a microwave oven for more efficiently cooling the upper heater installed on the cavity top of the microwave oven.

A microwave oven mainly uses microwaves to heat food and sometimes uses a heater as an auxiliary heat source. There are various types of such microwaves, one of which is a built-in type. The built-in microwave oven is configured to install the microwave inside the furniture of the kitchen, and the air flows in and out of the microwave oven on the front of the microwave oven.

FIG. 1 shows a main configuration of a built-in microwave oven according to the prior art, and FIG. 2 shows a flow of air for cooling the heater in the configuration of the built-in microwave oven according to the prior art.

As shown in these figures, the cooking chamber 2 is formed inside the cavity 1 constituting the frame of the microwave oven, and the cooking chamber 2 is a portion where cooking of the food is made. One side of the cavity 1 corresponding to the cooking chamber 2 is provided with an electrical equipment chamber 2 ′ in which electrical equipment constituting a microwave oven is installed.

The front surface of the cooking chamber 2 is selectively opened and closed by the door 3 and selectively communicates with the outside. The door 3 selectively opens and closes the inside of the cooking chamber 2 to partition the inside of the cooking chamber 2 from the outside during cooking.

A suction grill 5 is installed at the front of the microwave oven corresponding to the upper part of the door 3 to suck outside air into the microwave oven, and the air flowing inside the microwave oven is located at the lower part of the door 3. Exhaust grill 7 discharged to the outside is installed.

In addition, the front of the microwave oven corresponding to the upper end of the suction grill (5) is provided with a control panel unit 8 for the operation for driving the microwave oven. On the other hand, the exhaust motor assembly 10 for air flow in the inside of the microwave oven is installed on the left side of the upper surface of the cavity 1 to provide a driving force for air suction through the suction grill 5 and the upper portion of the microwave oven. The flowed air is delivered to the lower part through one side of the cavity 1 to be discharged to the exhaust grill 7.

The lower heater 12 is provided on the lower surface of the cavity 1 to provide heat to the food inside the cooking chamber 2. The lower heater 12 is shielded by the heater cover 14. The heater cover 14 is shielded by the air tunnel 16. The air tunnel 16 is a passage through which cooling air flows to manage the temperature at both ends of the lower heater 12 and the temperature of the heater cover 14, and a lower cooling fan 18 is installed at an upstream portion thereof. It is.

Next, the upper heater 20 is installed on the upper surface of the cavity 1. The upper heater 20 is covered by the heater cover 22 to provide heat to the cooking chamber 2 from the upper surface of the cavity 1. An air tunnel 24 is installed on the upper surface of the cavity 1 to shield the heater cover 22. The air tunnel 24 guides the airflow for cooling the upper heater 20 and the heater cover 22, and an upper fan assembly 25 is installed upstream of the air tunnel 24. The upper fan assembly 25 provides air for cooling the upper heater 20 into the air tunnel 24.

An insulator 26 is installed on the air tunnel 24. The insulator 26 is to insulate between the top and the bottom so that the heat of the upper heater 20 side is not transferred between the insulator 26 and the outer case 28.

On the other hand, a partition wall 26 is provided between one side of the cavity 1 and the outer case 28, the passage for passing the air passing through the air tunnel 24 to the lower portion of the cavity 1 To form.

In the conventional microwave oven having the above configuration, the air flowing in the upper portion of the microwave oven is formed by driving the exhaust motor assembly 10. That is, the outside air is sucked into the inner upper portion of the microwave oven through the suction grill 5, and the air flowing in the inner upper portion is transferred to the exhaust motor assembly 10, as shown by an arrow in FIG. 1. It is transmitted downward through one side of the cavity (1). The air delivered to the lower part is discharged to the exhaust grill 7 through a lower part of the air tunnel 16 and a base plate (not shown) which is a bottom surface of the microwave oven.

The upper fan assembly 25 is driven to cool the upper heater 20. The air flow formed by the upper fan assembly 25 is guided into the air tunnel 24 to manage temperature while passing through the upper heater 20 which is shielded by the heater cover 22. Air passing through the air tunnel 24 as described above is moved to the lower portion of the cavity 1 through the flow path between the partition wall 26 and the side wall of the cavity 1 through the exhaust grill (7) It is discharged to the outside.

However, the microwave oven according to the prior art as described above has the following problems.

The air flow for cooling the upper heater 20 is formed by the upper fan assembly 25 and is discharged through the exhaust grill 7 through the lower portion of the cavity 1. As such, the passage through which the air flow formed by the upper fan assembly 25 passes is quite long and is bent several times starting from the top of the cavity 1 and passing through the side surface to the bottom.

Therefore, the air flow for cooling the upper heater 20 is not formed smoothly, when the upper heater 20 is used in harsh conditions, there is a problem that the temperature management is not properly.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, and to activate the air flow for cooling the upper heater.

Another object of the present invention is to more efficiently control the temperature of the upper heater.

1 is a bottom perspective view showing the main structure of a built-in type microwave oven according to the prior art;

Figure 2 is a cross-sectional view showing the flow of air for cooling the heater in the configuration of the built-in type microwave oven according to the prior art.

Figure 3 is an exploded perspective view showing the configuration of a preferred embodiment of the upper heater cooling structure of the microwave oven according to the present invention.

Figure 4 is a view showing the configuration of the embodiment of the present invention from the front of the microwave oven.

Explanation of symbols on the main parts of the drawings

30: cavity 32: cooking chamber

34: battlefield 35: front plate

36: intake port 37: exhaust port

40: upper heater 42: heater cover

43: communication louver 50: air tunnel

52: upper fan assembly 60: insulation

62: communication hole 70: exhaust fan assembly

According to a feature of the present invention for achieving the object as described above, the present invention is installed on the upper surface of the cavity to provide heat to the interior of the cooking chamber, and guides the air flow for cooling the upper heater assembly An air tunnel, an upper fan assembly for providing airflow for cooling the upper heater assembly into the air tunnel, and a flow from one side of the cavity to the bottom of the cavity separately from the airflow for cooling the upper heater assembly; The exhaust fan assembly for forming the air flow is formed, and is installed on the upper portion of the air tunnel to block the heat transfer between the upper and lower portions, the communication with the air flow formed by the exhaust fan assembly at a position past the end of the air tunnel It is configured to include an insulator having a plurality of communication holes for.

The upper heater assembly includes an upper heater positioned at a porous portion formed on an upper surface of the cavity to transfer heat to the inside of the cooking chamber, and a heater cover that reflects radiant heat provided from the upper heater. The heater cover further includes a communication louver for communicating the inside of the heater cover with the inside of the air tunnel.

According to the upper heater cooling structure of the microwave oven according to the present invention having such a configuration, while the air flow for cooling the upper heater and the air flow for exhaust inside the microwave communicate with each other more smoothly the air flow for cooling the upper heater. There is an advantage that is formed.

Hereinafter, a preferred embodiment of the upper heater cooling structure of the microwave oven according to the present invention as described above will be described in detail with reference to the accompanying drawings.

3 and 4, the cooking chamber 32 is formed inside the cavity 30 serving as a frame of the microwave oven. In the cooking chamber 32, the cooking is performed while the food is heated by the microwave and the heater heat. One side of the cavity 30 corresponding to the cooking chamber 32 is provided with an electrical equipment chamber 34 in which various electronic components are installed.

And the front surface of the cavity 30 is formed by the front plate 35, the upper end of the front plate 35 is formed with an inlet port 36 for sucking outside air into the inside of the microwave oven, the front plate An exhaust port 37 for discharging air circulated inside the microwave oven to the outside is formed at the lower end of the 35.

On the other hand, the upper surface of the cavity 30 is formed by the upper plate 38, the upper plate 38, while sending the heat of the upper heater 40 to be described below to the inside of the cooking chamber 32 of the microwave Pores 39 are formed to minimize leakage.

The upper heater 40 is installed on the porous portion 39 on the upper surface of the cavity 30. The upper heater 40 supplies heat to the inside of the cooking chamber 32 to heat the food, and is shielded by the heater cover 42. The heater cover 42 also serves to reflect the radiant heat of the upper heater 40 into the interior of the cooking chamber 32. The heater cover 42 is provided with a plurality of communication louvers 43 for communicating the inside and the outside of the heater cover 42.

Next, an air tunnel 50 for guiding airflow for cooling the upper heater 40 and the heater cover 42 is installed on the upper surface of the cavity 30. As shown in FIG. 4, the air tunnel 50 covers one end of the upper heater 40, also known as an encapsulation part. And both ends of the air tunnel 50 is open. On the other hand, the upper fan assembly 52 is installed upstream of the air tunnel 50 to provide airflow for cooling the upper heater 40 into the interior of the air tunnel 50.

An insulation 60 is installed on the upper surface of the cavity 30 to cover the air tunnel 50. The insulation 60 is intended to block heat transfer between the heater side and the upper portion of the insulation 60 around itself. As shown in FIG. 4, the insulation 60 is provided at a position corresponding to one end of the air tunnel 50 and the other end up to a position corresponding to one end of the cavity 30. It is extended. In addition, a plurality of communication holes 62 are drilled at one side of the insulation 60 and a portion past the downstream portion of the air tunnel 50.

Here, the portion shielded by the insulation 60 past the downstream portion of the air tunnel 50 may pass through the air stream passing through the air tunnel 50 to the side wall of the cavity 30 and the partition wall 64 (see FIG. 4). It serves as a guide to the flow path formed between.

In addition, an exhaust fan assembly 70 is installed at an upper end of the cavity 30 to transfer air circulated in the upper portion of the microwave oven to the lower portion of the microwave oven through the side surface of the cavity 30.

Hereinafter will be described the operation of the upper heater cooling structure of the microwave oven according to the present invention having the configuration as described above.

When cooking is performed using the upper heater 40, the encapsulation portion of the upper heater 40 is brought to a high temperature and must be cooled appropriately. And the heater cover 42 is also heated to a high temperature by the heat of the upper heater 40, it should be cooled appropriately.

To this end, the upper fan assembly 52 is operated to supply cooling airflow into the air tunnel 50. Therefore, the air flow formed by the upper fan assembly 52 is guided and flows along the air tunnel 50 to cool the upper heater 40 and the heater cover 42. At this time, since the inside of the heater cover 42 and the inside of the air tunnel 50 communicate with each other by the communication louver 43 formed in the heater cover 42, the air is smoothly transferred to the inside of the heater cover 42. , Temperature management of the upper heater 40 is made more efficient.

Next, the air passing through the air tunnel 50 flows into the lower portion of the cavity 30 through the interior of the insulation 60 and between the side wall of the cavity 30 and the partition wall 64, and the cavity 30. At the bottom of the exhaust through the exhaust port 37 and the exhaust grill (not shown).

On the other hand, the exhaust fan assembly 70 provides a motive force for sucking the air for cooling the electrical components through the inlet port 36 while flowing in the upper portion of the microwave oven. Air flowing in the upper portion of the microwave oven moves to the lower portion of the cavity 30 through the space between the partition wall 64 and the outer case by the operation of the exhaust fan assembly 70. And it is discharged to the outside through the exhaust port 37 and the exhaust grill under the cavity 30.

Here, the air flow formed by the exhaust fan assembly 70 and the air flow formed in the insulation 60 are partially communicated with each other by the communication hole 62. That is, when the air flow formed by the suction force of the exhaust fan assembly 70 flows through the outer surface of the insulation 60 at a high speed, the pressure from the inside of the insulation 60 to the outside through the communication hole 62. The air is forced out of the insulation 60 by the car.

Therefore, the air flow formed inside the insulation 60, that is, inside the air tunnel 50 is more activated. That is, the air flow inside the air tunnel 50 is more smoothly driven by driving the upper fan assembly 52 and discharging air through the communication hole 62.

As such, when the airflow passing through the inside of the air tunnel 50 is activated, the upper heater 40 and the heater cover 42 are more smoothly cooled.

In the upper heater cooling structure of the microwave oven according to the present invention as described in detail above, the airflow for cooling the upper heater is added to the airflow for cooling the upper heater so as to more smoothly form the airflow for cooling the upper heater. Accordingly, the upper heater and the heater cover can be cooled relatively smoothly, so that the operation reliability of the upper heater can be increased and its service life can be long.

Claims (2)

An upper heater assembly installed on the upper surface of the cavity to provide heat to the inside of the cooking chamber; An air tunnel for guiding airflow for cooling the upper heater assembly; An upper fan assembly for providing airflow for cooling the upper heater assembly into the air tunnel; An exhaust fan assembly for forming an airflow flowing downwardly through one side of the cavity from the upper portion of the cavity separately from the airflow for cooling the upper heater assembly; An insulator provided at an upper portion of the air tunnel to block heat transfer between upper and lower portions thereof, and having a plurality of communication holes for communicating with air flow formed by the exhaust fan assembly at a position past the end of the air tunnel; Upper heater cooling structure of a microwave oven, characterized in that configured to include. According to claim 1, wherein the upper heater assembly is located in the porous portion formed on the upper surface of the cavity and the upper heater for transferring heat to the interior of the cooking chamber, It is configured to include a heater cover that serves to reflect the radiant heat provided from the upper heater, The heater cover is the upper heater cooling structure of the microwave oven, characterized in that the communication louver for further communicating the inside of the heater cover and the inside of the air tunnel.