KR20010055388A - A multifunctional microwave oven with quartz tube heaters - Google Patents

Abstract

PURPOSE: A multi-functional microwave oven adopting a quartz tube heater is provided to shorten the cooking time of food and to simplify the structure of radiation by using a quartz tube heater having a short preheat time instead of a sheath heater having a long preheat time. CONSTITUTION: A convection fan(122) is mounted on the rear of a cavity(110) and rotated by a motor(120). A couple of quartz tube heaters(130) are installed at the exhaust area of the convection heater. A suction hole(112) is formed outside the cavity at the center of the convection fan, and an exhaust hole(114) is formed outside near the quartz tube heaters. A reflector(140) reflects the radiant heat from the quartz tube heaters and prevents heated air from being discharged. The reflector has both connecting holes accepting the ends of the quartz tube heaters to supply power to the heaters easily. When the quartz tube heaters are started, radiant heat is generated to heat air. The convection heater is rotated by the motor, and the air in the cavity is ventilated into the quartz tube heaters from the center of the convection fan through the suction hole. The ventilated air is heated by the heaters and then ventilated to food from the rear in the cavity through the exhaust hole. The quartz tube heaters are preheated within 20-30sec. Therefore, hot air is supplied into the cavity within a short time and the cooling time of food is shortened.

Description

Multifunctional microwave oven which adopted quartz tube heater {A MULTIFUNCTIONAL MICROWAVE OVEN WITH QUARTZ TUBE HEATERS}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multifunctional microwave oven employing a quartz tube heater. In particular, a quartz tube heater having a short preheating time and easy heat dissipation is used instead of a sheath heater having a long preheating time as a heat source for convection. This is to shorten the cooking time of food and to simplify the heat dissipation structure.

In general, a microwave oven is a device for cooking food by a high frequency, and is divided into a cooking chamber and an electrical equipment room. In the electrical equipment room, a magnetron, a high pressure transformer, a cooling fan, etc. are installed, and the cooking chamber is provided with a tray on a bottom plate. The high frequency emitted by the magnetron is irradiated on the food.

In addition, in the microwave, since the high frequency oscillated from the magnetron is reflected and irradiated only in a certain direction, the high frequency is not uniformly irradiated on the food in the cooking chamber, so that a part of the food is overcooked and a part is not cooked. The tray rotation method to rotate the food placed on the tray as the tray is rotated by installing the tray motor so that high frequency is irradiated to the food evenly. It adopts the stirrer pan rotation method to be investigated.

In addition, the microwave oven has a single function microwave for cooking food using only high frequency and a grill cooking function for heating food by radiant heat of a heater installed at the upper or lower portion of the cooking chamber in addition to the high frequency or the convection pan installed at one side of the cooking chamber. It is divided into multi-functional microwave oven with oven cooking function that convections hot air by rotation.

An example of a conventional microwave oven having such an oven cooking function is shown in FIG. 1.

As shown in this figure, the convection fan 22 is provided in the rear outer wall of the cooking chamber 10, and the sheath heater 30 is provided in the circumference | surroundings of this convection pan 22 in a circular shape. The sheath heater 30 coats a metal around the hot wire coil, fills therein with magnesium oxide, and generates heat by supplying power to heat the surrounding air.

In addition, an intake hole 12 is formed in the outer wall of the cooking chamber 10 so that air is sucked into the center of the convection fan 22, and the heated air passing the sheath heater 30 by the convection fan 22 is cooked in the cooking chamber ( 10) the exhaust hole 14 is formed on the outer wall of the cooking chamber 10 to be introduced into the.

In addition, a cover 32 is installed at the rear of the convection fan 22 to prevent the blowing air from being discharged to the rear, and a heat insulating material 40 for heat dissipation is provided outside the cover 32. The heat insulation cover 42 is provided at the rear of the 40.

In addition, a guide 34 is installed between the heat insulating material 40 and the outer wall of the cooking chamber 10 to guide the blowing air to the exhaust hole 14.

On the other hand, a bracket 52 is installed outside the heat insulation cover 42, and a motor 20 for rotating the convection fan 22 is installed in the bracket 52. In order to prevent overheating of the motor 20, an intake fan 50 that is rotated by the motor 20 is installed between the motor 20 and the bracket 52. Since the intake fan 50 is blocked by the bracket 52 at the rear, a product that sucks air on the motor 20 side in front and disperses it to the outside is used.

The operation of the conventional microwave oven having such a configuration will be described.

When the motor 20 is driven to rotate the convection fan 22 and power is supplied to the sheath heater 30 to heat the surrounding heat, the air in the cooking chamber 10 passes through the intake hole 12 to the convection fan ( After being sucked to the center of 22, it moves up and down with reference to FIG. 1 and is heated through the sheath heater 30, and is discharged to the exhaust hole 14 by the guide 34. The heated air circulates in the cooking chamber 10 to heat and cook food, and then enters the intake hole 12.

In this case, the cover 32 prevents the external separation of the heating air, and the heat insulating material 40 and the heat insulating cover 42 prevent heat from flowing around the sheath heater 30 to the outside or being transferred to the motor 20 side.

In addition, the intake fan 50 is rotated by the rotation of the motor 20 to suck air around the motor 20 and disperse it up and down based on FIG. 1 to prevent the motor 20 from being cooled and overheated.

However, the sheath heater 30 takes about 2 to 3 minutes to preheat time until the heating coil is heated to heat the metal coating. Therefore, the conventional microwave oven has a problem in that cooking is delayed due to a slow preheating time of the sheath heater 30.

In the conventional microwave oven, the heat insulating material 40 and the heat insulating cover 42 are used to prevent the heat of the sheath heater 30 from being discharged, and the bracket 52 is used to install the motor 20. There was a problem of low productivity due to this excess.

In addition, since the intake fan 50 is installed in the bracket 52 whose rear part is blocked due to excessive parts for thermal insulation, the motor 20 is cooled by intake air.

The present invention has been made to solve the above-mentioned conventional problems, by using a quartz tube heater having a short preheating time and easy heat dissipation as a heat source for convection of a multi-functional microwave oven, cooking food, To shorten the time and simplify the heat dissipation structure.

Figure 1 is a side cross-sectional view showing a typical multifunctional microwave.

Figure 2 is a side cross-sectional view showing a portion of a microwave oven according to an embodiment of the present invention.

3 is a plan sectional view of the microwave oven illustrated in FIG. 2.

<Explanation of symbols for main parts of drawing>

110: cooking chamber 112: intake air

114: exhaust hole 116: opening hole

120: motor 122: convection fan

130: quartz tube heater 132: terminal portion

140: reflector 142: coupling hole

150: blower fan

The present invention for achieving the above object is a quartz tube heater installed in the exhaust region of the convection fan; And a reflector installed at an outer wall of the cooking chamber in a rear region of the quartz tube heater.

Since the preheating time of the quartz tube heater is short, hot air is rapidly supplied into the cooking chamber from the convection pan, and radiant heat generated from the quartz tube heater is directly irradiated onto the food, thereby quickly cooking the food in the cooking chamber. In addition, since the radiant heat generated from the quartz tube heater can be radiated with a simple reflector, it is possible to save parts and improve productivity.

Hereinafter, preferred embodiments of the present invention as described above will be described to facilitate implementation of the present invention. FIG. 2 shows a side cross-sectional view of the microwave oven according to the present embodiment, and FIG. 3 shows a flat cross-sectional view.

As shown in FIGS. 2 and 3, a convection fan 122 that is rotated by the motor 120 is installed in the rear region of the cooking chamber 110, and a pair of quartz tube heaters are provided in the exhaust region of the convection fan 122. 130 is installed. Intake holes 112 are formed in the outer wall of the cooking chamber 110 in the central region of the convection fan 122, and exhaust holes 114 are formed in the outer wall near the quartz tube heater 130.

The reflector 140 is installed at the rear and side of the convection fan 122 and the quartz tube heater 130 to reflect the radiant heat generated from the quartz tube heater 130 and to prevent the release of heating air. The reflector 140 has a coupling hole 142 into which the terminal portions 132 of the pair of quartz tube heaters 130 are inserted at both sides thereof, so that the power source can be easily connected to the quartz tube heater 130.

Such a reflector 140 is preferably formed of a stainless material that reflects light.

As the heat dissipation structure is simplified in this manner, a free space is generated at the rear of the reflector 140, and thus, the motor 120 is installed when the convection fan 122 is rotated at the rear of the reflector 140. Blower fan 150 for cooling the motor 120 is installed on the rear shaft of the). The blower fan 150 uses a fan made of plastic that sucks air from the rear and blows the air to the front motor 120. The blowing fan 150 is a known fact that the cooling capacity is much superior to the conventional intake fan.

Hereinafter, the operation of the microwave oven having the above configuration will be described.

When the quartz tube heater 130 is activated, radiant heat is generated to heat air, and when the motor 120 is driven to rotate the convection fan 122, the air inside the cooking chamber 110 is convection through the intake hole 112. It blows into the quartz tube heater 130 from the center of the fan 122. The blown air is heated by the quartz tube heater 130 and then blown to the food from the rear in the cooking chamber 110 through the exhaust hole 114. Since the quartz tube heater 130 is sufficiently preheated in about 20 to 30 seconds, the speed at which hot air is supplied into the cooking chamber 110 is also increased, thereby shortening the cooking time of the food.

In addition, the radiant heat generated from the quartz tube heater 130 is directly transmitted to the food through the open hole 142 formed in the outer wall of the cooking chamber 110, so that browning effect due to the radiant heat also occurs, thereby making the cooking of the food faster. Further, since the quartz tube heater 130 emits red color when heated, the user knows the heating state of the quartz tube heater 130 through the opening 142 in the cooking chamber 110.

Meanwhile, the reflector 140 installed at the rear of the convection fan 122 and the quartz tube heater 130 reflects the radiant heat of the quartz tube heater 130 into the cooking chamber 110 to prevent heat loss.

In addition, the blowing fan 150 installed on the rear shaft of the motor 120 sucks air from the rear and blows the air to the motor 120, thereby rapidly cooling the motor 120 to prevent overheating.

As described above, the present invention includes a quartz tube heater 130 installed in the exhaust region of the convection fan 122 and a reflector 140 provided on the outer wall of the cooking chamber 110 in the rear region of the quartz tube heater 130. As the convection device, since the heating time of the quartz tube heater 130 is short, the convection fan 122 quickly supplies hot air into the cooking chamber 110, and radiant heat generated from the quartz tube heater 130 is directly irradiated to the food. Food in the cooking chamber 110 can be quickly cooked, and the radiant heat generated from the quartz tube heater 130 can be radiated as a simple reflector 140, thereby reducing parts and improving productivity.

While the invention has been shown and described with respect to certain preferred embodiments thereof, the invention is not limited to the embodiments described above, and is typically defined in the art to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Anyone with knowledge of the world can make many variations.

Claims (3)

A quartz tube heater 130 installed in the exhaust region of the convection fan 122; And Multifunctional microwave oven employing a quartz tube heater comprising a; reflector 140 installed on the outer wall of the cooking chamber 110 in the rear region of the quartz tube heater (130). According to claim 1, wherein the outer wall of the cooking chamber 110 is a multi-function microwave oven employing a quartz tube heater, characterized in that the opening 142, the quartz tube heater 130 is exposed to the cooking chamber 110 is formed. . According to claim 1, wherein the rear shaft of the motor 120 for rotating the convection fan 122, a blower fan 150 for cooling the motor 120 is further installed multifunction employing a quartz tube heater. microwave.