KR20020041252A - A heater cooling structure for ventilation hooded microwave oven - Google Patents

Abstract

PURPOSE: Cooling structure of a radiation heater for a microwave oven used as a hood is provided to adjust temperature of the radiation heater efficiently without interference with function of the hood by using an additional cooling fan assembly, and to cook food promptly by forming air flow from the radiation heater to a cooking chamber. CONSTITUTION: A cooling system of a radiation heater(30) for a microwave oven is composed of the radiation heater supplying radiant heat to a cooking chamber(22) formed in a cavity(20); a heater chamber(35) installed at the side of the cavity to place the radiation heater; and a cooling fan assembly(37) forming air flow from the heater chamber through the radiation heater to the cooking chamber. A heater cover(32) and the radiation heater are cooled with forming air flow by the cooling fan assembly. Cooling efficiency is improved with blowing directly for the heater cover by the cooling fan assembly. Food is cooked promptly with increasing the temperature of the cooking chamber by air flow from the heater. Temperature of the radiation heater is adjusted efficiently with forming cooling flow and exhaust flow individually.

Description

A heater cooling structure for ventilation hooded microwave oven

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microwave oven for hood, and more particularly, to a radiation heater cooling structure of a microwave oven for hood, which enables cooling of a radiation heater more efficiently in a hood microwave oven.

1 is a schematic configuration diagram showing a radiant heater cooling structure of a microwave oven according to the prior art. As shown in the drawing, the cooking chamber 3 is formed inside the cavity 1 constituting the frame 1 of the microwave oven. The cooking chamber 3 is a place where cooking is performed while the food is heated by microwave or heater heat therein. The upper plate 4 constitutes an upper surface of the cavity 1 forming the ceiling of the cooking chamber 3.

In addition, an electric field chamber 5 is formed at one side of the cavity 1 corresponding to the cooking chamber 3. The electric component chamber 5 is provided with various electric components for oscillating microwaves. Reference numeral 6 is a cooling fan for cooling the various electrical components inside the electrical equipment room.

On the upper surface of the upper plate 4, which is the upper surface of the cavity 1, a radiation heater 7 for heating the food inside the cooking chamber 3 with radiant heat is installed. The upper plate 4 on which the radiant heater 7 is installed is formed with a porous part (not shown) composed of a plurality of openings. The porous portion prevents the microwaves from leaking out of the cavity 1 through the radiant heat of the radiant heater 7 more smoothly through the cooking chamber 3.

The radiation heater 7 is covered by a heater cover 8. The heater cover 8 shields the radiant heater 7 from the outside, and its inner surface serves to reflect radiant heat emitted from the radiant heater 7 into the interior of the cooking chamber 3. The radiant heater 7 is provided with a plurality of through holes (not shown) for communicating the inside of the cooking chamber 3 through the outside of the heater cover 8 and the porous portion. In addition, an air tunnel 9 for guiding the airflow for cooling the heater cover 8 while passing through the outside of the heater cover 8 is installed on the upper plate 4.

On the other hand, at the position corresponding to the upper rear end of the cavity 1, the exhaust fan assembly 10 for the hood function is installed. The exhaust fan assembly 10 serves to discharge the heat generated in the gas range and the like installed below the microwave oven under the hood through the configuration to be described below.

And the outer case 12 forms the upper surface and both side surfaces of the microwave oven. The outer case 12 may form a flow path for exhausting the inside of the microwave oven while shielding the cavity 1 and various components installed around the cavity 1. In particular, the portion of the outer case forming the side of the microwave oven facing the left side of the cavity 1 serves as a flow path for guiding the heat sucked from the gas range to the exhaust fan assembly 10.

Finally, the base plate 14 is formed at the bottom of the microwave oven, and the base plate 14 is formed with a suction part 16 that sucks heat generated from a gas lane or the like below to function as a hood.

In the radiant heater cooling structure of the microwave oven according to the prior art having such a configuration, when the radiant heater 7 is operated, the exhaust fan assembly 10 performing the hood function is operated so that the heat dissipation is achieved. do.

That is, when the grill cooking is performed, the radiant heater 7 generates radiant heat. At this time, the exhaust fan assembly 10 is operated for temperature management of the encapsulation part of the radiant heater 7 and the heater cover 8. .

When the exhaust fan assembly 10 is operated, external air is sucked in through the suction part 16 of the base plate 14, and inside the microwave oven through the lower space of the base plate 14 and the cavity 1. It is moved to the left space. The outside air flows through the space between the left side of the cavity 1 and the outer case 12 to enter a portion of the air tunnel 9. Air entering the inside of the air tunnel 9 passes through the outside of the heater cover 8 to cool the heater cover 8 and passes through the air tunnel 9 by the exhaust fan assembly 10 by the microwave oven. Is exhausted to the outside.

In addition, when the exhaust fan assembly 10 is operated to form an air flow into the air tunnel 9, the heater cover 8 may be formed in the cooking chamber 3 through the porous part due to the influence. Air flows inside and is delivered to the inside of the air tunnel 9 through a through hole formed in the heater cover 8 and is also exhausted to the outside by the exhaust fan assembly 10. Such air performs cooling of the radiant heater 7.

However, the prior art as described above has the following problems.

When grill cooking is performed, since the air inside the cooking chamber 3 is also discharged through the heater cover 8 by the suction force of the exhaust fan assembly 10, there is a problem that the hood function is relatively decreased.

In addition, when the hood function is not used, that is, when only grill cooking is performed, if the exhaust fan assembly 10 is operated at the rated value, there is a serious problem of operating noise. Therefore, when the grill is cooked, there is a problem that the exhaust fan assembly 10 is not operated as rated.

Accordingly, an object of the present invention is to solve the conventional problems as described above, and to efficiently perform the temperature management of the radiant heater while maintaining the hood function of the combined microwave oven.

Another object of the present invention is to maximize the use efficiency of the copy heater.

1 is a schematic configuration diagram showing a radiant heater cooling structure of a microwave oven according to the prior art.

Figure 2 is a schematic configuration diagram showing a configuration of a preferred embodiment of the radiant heater cooling structure of the microwave oven with hood according to the present invention.

Explanation of symbols on the main parts of the drawings

20: cavity 22: cooking chamber

24: battle room 25: cooling fan

27: upper plate 28: porous part

30: radiant heater 32: heater cover

34: through hole 35: heater chamber

37: cooling fan assembly 40: exhaust fan assembly

50: outer case 60: base plate

62: suction part

According to a feature of the present invention for achieving the above object, the present invention is a radiant heater for providing radiant heat to the cooking chamber formed in the cavity, and the heater is installed on one side of the cavity so that the radiant heater is located therein And a cooling fan assembly configured to form an airflow through the radiation heater in the heater chamber and into the cooking chamber.

The heater chamber is disposed on an exhaust air stream formed by an exhaust fan assembly installed on an upper side of the cavity and functioning as a hood.

Hereinafter, according to the radiation heater cooling structure of the microwave oven according to the present invention as described above, there is an advantage that the cooling of the radiation heater is more efficiently performed without affecting the hood function at all, when performing the grill function There is an additional advantage that the convective heat of the radiant heater is also available.

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

As illustrated in FIG. 2, a cooking chamber 22 in which food is cooked is formed in the cavity 20 serving as a frame of the microwave oven. The inside of the cooking chamber 22 is heated by the microwave and heater heat.

An electrical equipment room 24 is provided at one side of the cavity 20 corresponding to the cooking chamber 22. The electrical equipment room 24 is equipped with various electrical components for oscillation of the microwave. Reference numeral 25 is a cooling fan for heat dissipation of the electrical component.

The ceiling of the cooking chamber 22, which is the upper surface of the cavity 20, is formed by the upper plate 27. A porous portion 28 is formed at one side of the upper plate 27, and the porous portion 28 transfers radiant heat of the radiant heater 30 to the inside of the cooking chamber 22, which will be described below. It is formed to minimize the microwave leakage inside.

The radiation heater 30 is installed on the porous portion 28. The radiant heater 30 transmits radiant heat to the inside of the cooking chamber 22 through the porous portion 28 to heat the food. As the radiant heater 30, a halogen lamp is preferably used.

The radiant heater 30 is shielded by the heater cover 32. The heater cover 32 serves to shield the radiant heater 30 while the inner surface of the heater cover 32 reflects the radiant heat of the radiant heater 30 into the cooking chamber 22. The heater cover 32 is formed with a plurality of through holes 34.

The heater cover 32 is shielded by the heater chamber 35. The heater chamber 35 is installed on the upper surface of the cavity 20, and a cooling fan assembly 37 is installed therein. The cooling fan assembly 37 forms a cooling airflow for cooling the radiation heater 30. Meanwhile, the heater chamber 35 is not completely shielded from the inside thereof, and is configured to allow air to be sucked into the surroundings by the operation of the cooling fan assembly 37.

An exhaust fan assembly 40 is installed at the upper rear end of the cavity 20. The exhaust fan assembly 40 is to provide a suction force for the hood function. And the outer case 50 forms the upper surface and both sides of the microwave oven. The outer case 50 serves to shield various components therein and also to form a flow path therein.

On the other hand, the base plate 60 forms the bottom surface of the microwave oven. The base plate 60 is formed with a suction part 62 for a hood function.

The operation of the radiant heater cooling structure of the hood-use microwave oven according to the present invention having such a configuration will be described.

First, the hood function is achieved by driving the exhaust fan assembly 40. When the exhaust fan assembly 40 is driven to generate suction power, air including hot light generated in a gas range installed in the lower portion of the microwave oven is sucked through the suction part 62. The air flows between the base plate 60 and the lower surface of the cavity 20, and flows between the side wall of the cavity 20 and the outer case 50 to the inner portion of the microwave oven.

Air flowing into the upper portion of the microwave oven is sucked into the exhaust fan assembly 40 and discharged to the outside of the microwave oven.

On the other hand, when performing grill cooking using the radiant heater 30, the cooling fan assembly 37 is driven. The cooling fan assembly 37 sucks air around the heater chamber 35 and flows the inside of the heater cover 32. That is, the air sucked into the heater chamber 35 by the cooling fan assembly 37 flows into the heater cover 32 through the through hole 34 of the heater cover 32, and the heater cover Inside the 32, the radiant heater 30 is passed through the porous portion 28 to the inside of the cooking chamber 22. While passing through the radiant heater 30, the air receives heat from the radiant heater 30 and transfers convective heat into the cooking chamber 22.

Therefore, cooling of the heater cover 32 and the radiation heater 30 is made by the air flow formed by the cooling fan assembly 37. In particular, since the cooling fan assembly 37 directly blows air toward the heater cover 32, the cooling fan has a relatively good cooling efficiency. The cooling fan assembly 37 enters the heater cover 32 and is relatively heat exchanged with the radiant heater 30. The high temperature air makes the cooking within the cooking chamber 22 in which grill cooking is performed relatively high, so that quick cooking is performed.

The air sucked into the heater chamber 35 by the cooling fan assembly 37 may be a part of the exhaust air flow formed by the exhaust fan assembly 40 by being sucked from the periphery of the heater chamber 35. have. However, even when the cooling fan assembly 37 is driven while the hood function is driven by the exhaust fan assembly 40, the airflow by the cooling fan assembly 37 does not interfere with the exhaust airflow. Can be maintained. In fact, the air around the heater chamber 35 is sucked by the suction force by the cooling fan assembly 37, and may help to form the air flow by the exhaust fan assembly 40.

The radiant heater cooling structure of the microwave oven according to the present invention as described above in detail affects the function of the hood by using a cooling fan assembly separately from the exhaust fan assembly to form a separate air flow for cooling the radiant heater from the exhaust air stream. Without this, the temperature management of the radiant heater can be efficiently performed.

In addition, since the cooling fan assembly forms an airflow through the radiant heater to be delivered to the inside of the cooking chamber, the airflow receives the heat of the radiant heater to provide convective heat to the interior of the cooking chamber, thereby making the grill cooking more quickly. The effect can also be obtained.

Claims (2)

A radiant heater that provides radiant heat to a cooking chamber formed inside the cavity; A heater chamber installed at one side of the cavity such that the radiant heater is positioned inside the radiant heater; And a cooling fan assembly configured to form an airflow passing through the radiation heater in the heater chamber and toward the interior of the cooking chamber. 2. The radiant heater cooling structure according to claim 1, wherein the heater chamber is disposed on an exhaust air stream formed by an exhaust fan assembly installed on an upper side of the cavity to function as a hood.