KR20120033428A - Cooking appliance - Google Patents

Abstract

PURPOSE: A cooking device is provided to enable precise cooking because a thermister sensing the temperature for controlling a heating source is installed inside a convection chamber. CONSTITUTION: A cooking device comprises a cooking chamber, a chamber, an intake port, an exhaust port, a cross-flow fan, a heating source, and a temperature sensing part. The cross-flow fan generates a flow of air between the cooking chamber and the chamber through the intake port and the exhaust port. The heating source is installed inside the chamber and heats the air discharged to the inside of the cooking chamber from the inside of the chamber by the rotation of the cross-flow fan through the intake port. The temperature sensing part is placed inside the chamber between the intake port and the cross-flow fan. The temperature sensing part senses the air drawn into the chamber from the cooking chamber.

Description

Cooking appliance

The present invention relates to a cooking appliance, and more particularly to a cooking appliance.

A cooking appliance is a home appliance that heats and cooks food inside a cooking chamber using microwaves or heater heat. On the other hand, the cooking apparatus is provided with a convection device for providing a high temperature hot air into the cooking chamber. Such a convection device generally includes a convection fan in communication with the cooking compartment, a convection heater installed inside the convection chamber, and a convection fan for allowing air heated by the convection heater to circulate inside the cooking compartment and the convection chamber. And a convection motor for driving the convection fan.

It is an object of the present invention to provide a cooking apparatus configured to enable more efficient cooking.

One aspect of an embodiment of a cooking appliance according to the present invention for achieving the above object is a cooking chamber in which food is cooked; A chamber in communication with the cooking chamber; An intake port through which air is sucked into the chamber from the inside of the cooking chamber; An exhaust port through which air is discharged from the inside of the chamber to the inside of the cooking chamber; A cross flow fan installed inside the chamber and configured to generate a flow of air between the cooking chamber and the chamber through the intake port and the exhaust port; A heating source installed inside the chamber and heating air discharged from the inside of the chamber to the inside of the cooking chamber through the exhaust port by rotation of the cross flow fan; And a temperature sensing unit located inside the chamber corresponding to the intake port and the cross flow fan to sense a temperature of air sucked into the chamber from the inside of the cooking chamber; It includes.

According to another aspect of the present invention, there is provided a cooking chamber in which food is cooked, and a cavity in which an inlet and an exhaust port are formed to be spaced apart from each other on a back plate forming a rear surface of the cooking chamber; A heating source for providing energy for cooking food in the cooking chamber; A convection cover fixed to a rear surface of the back plate and forming a convection chamber between an inner surface of the back plate and a rear surface of the back plate; Installed in the convection chamber, and is sucked into the convection chamber from the inside of the cooking chamber through the inlet port and discharged from the interior of the convection chamber to the interior of the cooking chamber through the exhaust port in a direction orthogonal to the rotation axis thereof; A convection fan for flowing air; A convection heater installed in the convection chamber and heating the air flowing by the convection fan; And a thermistor configured to sense a temperature of air sucked into the convection chamber from the inside of the cooking chamber through the inlet. Includes, the heating source, the convection fan and the convection heater is controlled according to the temperature sensed by the thermistor.

According to the embodiment of the cooking appliance according to the present invention as described above, the following effects can be expected.

First, in the present invention, by using a cross-flow pan as the convection pan, the flow rate circulating between the cooking chamber and the convection chamber is increased. Therefore, it is possible to cook the food more efficiently.

In the present invention, the thermistor for sensing the temperature for the control of the heating source including the convection device is installed in the convection chamber. Therefore, the thermistor senses the temperature for the control of the heating source more accurately, it is possible to more precise cooking by the cooking appliance.

1 is a perspective view showing a first embodiment of a cooking appliance according to the present invention.
Figure 2 is a perspective view showing the main part of the first embodiment of the present invention.
3 is a perspective view showing a convection device constituting the first embodiment of the present invention.
Figure 4 is an exploded perspective view showing a convection device constituting the first embodiment of the present invention.
FIG. 5 is a longitudinal sectional view showing a convection device of the first embodiment of the present invention; FIG.
6 is an exploded perspective view showing a convection fan constituting the first embodiment of the present invention.
Figure 7 is a side view showing the flow of air between the cooking chamber and the convection chamber in the first embodiment of the cooking appliance according to the present invention.
8 is a rear view showing the flow of air for cooling the convection motor in the first embodiment of the cooking appliance according to the present invention.
Figure 9 is a graph showing the temperature difference of the convection motor according to the presence or absence of the second air guide in the first embodiment of the cooking appliance according to the present invention.
10 is a graph showing the difference in temperature detected by the thermistor according to the position of the thermistor in the first embodiment of the cooking appliance according to the present invention.

Hereinafter, a configuration of a first embodiment of a cooking appliance according to the present invention will be described in more detail with reference to the accompanying drawings. Hereinafter, an example of a cooking apparatus, in particular, a microwave oven for cooking food using microwaves will be described.

1 is a perspective view showing a first embodiment of a cooking appliance according to the present invention, Figure 2 is a perspective view showing the main portion of the first embodiment of the present invention, Figure 3 is a convection device constituting a first embodiment of the present invention 4 is an exploded perspective view showing a convection device constituting the first embodiment of the present invention, Figure 5 is a longitudinal sectional view showing a convection device constituting the first embodiment of the present invention, Figure 6 is a An exploded perspective view showing a convection fan constituting the first embodiment of the present invention.

First, referring to FIG. 1, the front plate 110 forms the front surface of the cavity 100 of the microwave oven, and the back plate 120 forms the rear surface of the cavity 100. In addition, an upper plate 130 and a bottom plate 140 respectively form upper and lower surfaces of the cavity 100. In addition, two side plates 150 are formed on both sides of the cavity 100. In this case, the upper plate 130, the bottom plate 140, and the side plate 150 may be formed by bending one member.

Meanwhile, the cooking chamber 160 is provided inside the cavity 100. Substantially, the cooking chamber 160 is formed in a hexahedral shape in which the front surface is opened, and the back plate, the upper and lower surfaces, and both sides of the cooking chamber 160 are the back plate 120, the upper plate 130, the bottom plate 140, And the side plate 150 is formed. The cooking chamber 160 is a place where food is cooked. The cooking chamber 160 is selectively opened and closed by a door (not shown).

And one side of the cavity 100 is provided with an electrical equipment room 170. Various electrical components are installed in the electrical equipment room 170. In FIG. 1, the electrical equipment room 170 is illustrated as being provided on the right side of the cooking chamber 160, but the position of the electrical equipment chamber 170 is not limited thereto.

Meanwhile, an inlet port 121 (see FIG. 2) and an exhaust port 123 (see FIG. 2) are formed on the rear surface of the cooking chamber 160, that is, the back plate 120. The intake port 121 serves as an inlet through which air in the cooking chamber 160 is sucked into the convection chamber 301 which will be described later. The exhaust port 123 serves as an outlet through which air in the convection chamber 301 is discharged into the cooking chamber 160. In the present embodiment, the exhaust port 123 is located below the inlet port 121. In addition, the inlet port 121 and the exhaust port 123 may be formed in the form of a porous portion, respectively. This is to prevent leakage of microwaves supplied into the cooking chamber 160 and to prevent foreign substances generated during cooking of the food inside the cooking chamber 160 to flow into the convection chamber. .

The back cover 180 is installed at the rear of the back plate 120. The back cover 180 shields the convection cover 300 to be described later. In the present embodiment, the back cover 180 is formed in a polyhedral shape with a substantially front surface opening. In addition, a cooling inlet 181 (see FIG. 8) is formed on the right side of the back cover 180. In addition, a cooling exhaust port 183 (see FIG. 8) is formed on the left side of the back cover 180. The cooling intake port 181 and the cooling exhaust port 183 are places where air for cooling the convection motor 500 to be described later is sucked and discharged. In the present embodiment, the cooling inlet 181 is located on the upper right side of the drawing of the back cover 180 adjacent to the convection motor 500, and the cooling exhaust port 183 is the convection motor 500. It is located at the bottom of the left side in the drawing of the back cover 180 is relatively spaced apart from).

The microwave oven is provided with a plurality of heating sources for cooking food in the cooking chamber 160. For example, a magnetron (not shown) for supplying microwaves into the cooking chamber 160 may be installed in the electric compartment 170. In addition, an upper heater 200 for supplying heater heat into the cooking chamber 160 may be installed in the upper plate 130.

In the present embodiment, a convection device is installed at the rear of the cooking chamber 160, that is, at the rear of the back plate 120. The convection device serves to supply high temperature air into the cooking chamber 160. 2 to 6, the convection device includes a convection cover 300, a convection fan 400, a convection motor 500, a cooling fan 600, a convection heater 710, 720, and first and Second air guides 810 and 820 are included.

In more detail, the convection cover 300 is fixed to the rear surface of the back plate 120 to form a convection chamber 301. In this case, the convection cover 300 may be substantially positioned between the back plate 120 and the back cover 180. The convection chamber 301 is a space in which the convection fan 400, the convection heater 710, 720, and the first air guide 810 are installed, and substantially the inlet 121 and the exhaust port 123. In communication with the cooking chamber 160 through. The convection cover 300 includes an inner cover 310, an outer cover 320, and two side covers 330 and 340.

The inner cover 310 and the outer cover 320 are each formed to have a substantially U-shaped longitudinal section. In addition, the inner cover 310 and the outer cover 320 are sequentially fixed to the rear surface of the back plate 120. Therefore, it can be said that the outer cover 320 substantially shields the inner cover 310 forward and backward. In addition, the inner cover 310 and the outer cover 320 are formed with thermistor mounting holes 311 and 321, respectively. The thermistor mounting holes 311 and 321 are positioned to overlap each other up and down. Substantially, the thermistor mounting holes 311 and 321 cut a portion of the inner cover 310 and the outer cover 320 corresponding to the front and the upper side of the first and second fan mounting holes 341 to be described later. It is formed.

Although not shown, a heat insulating material may be provided between the inner cover 310 and the outer cover 320. The insulation serves to prevent a phenomenon in which heat of the convection heater 710 and 720 is transferred to the outside.

The side covers 330 and 340 are respectively fixed to the side surfaces of the inner cover 310. Hereinafter, for convenience of description, the right side in FIG. 3 is referred to as a first side cover 330 and the left side in FIG. 2 is referred to as a second side cover 340.

A first fan installation hole 331 and two heater installation holes 333 are formed in the first side cover 330. The first fan installation hole 331 is for installation of the convection fan 400. The first heater installation hole 333 is for installation of the convection heater 710, 720. The first heater installation hole 333 has a shape corresponding to the pinch portion of the convection heater 710 and 720 so that the pinch portion of the convection heater 710 and 720 may be inserted, for example, a D shape. It can be formed as. The first fan installation hole 331 and the first heater installation hole 333 are formed by cutting a portion of the first side cover 330, respectively. In this case, the first fan installation hole 331 is positioned relatively to the intake port 121 as compared to the exhaust port 123. The first heater installation hole 333 is positioned to be relatively adjacent to the exhaust port 123 as compared to the intake port 121. Therefore, the first heater installation hole 333 is positioned substantially below the first fan installation hole 331.

A second fan installation hole 341 and a heater installation opening 343 are formed in the second side cover 340. The second fan installation hole 341 is formed at a position facing the first fan installation hole 331. The heater installation opening 343 is for installation of the convection heater 710 and 720. The heater bracket 730 to be described later is fixed to the heater installation opening 343. The heater installation opening 343 is formed by cutting the second side cover 340 to a size larger than a region overlapping with the first heater installation hole 333 from side to side.

The convection fan 400 is installed inside the convection chamber 301 and serves to circulate air between the cooking chamber 160 and the convection chamber 301. In this embodiment, the convection fan 400 is rotated about a horizontal axis of rotation. In more detail, when the convection fan 400 is driven, air in the cooking chamber 160 is sucked into the convection chamber 301 through the inlet 121, and the exhaust port 123 is opened. Through the air inside the convection chamber 301 is discharged into the cooking chamber 160.

In this embodiment, as the convection fan 400, a cross flow fan is formed in which air intake and exhaust in a plane direction perpendicular to the rotation axis thereof is formed. Referring to FIG. 6, the convection fan 400 includes three disks 310, 320, 330 and a plurality of blades 340 positioned between the disks. The disks 310, 320, 330 are formed in a substantially disk shape and are spaced apart from each other by a predetermined interval. The blades 340 are positioned between the discs 310, 320, 330 at predetermined angles, respectively. Hereinafter, for convenience of description, the right side of the drawing in FIG. 6 is positioned between the first disk 310, the left side of the drawing between the second disk 320, and the first and second disks 310 and 320. This is called a third disk 330.

A plurality of blade fixing holes 311 and 321 for fixing the blades 340 are formed in the first and second disks 310 and 320, respectively. The blade fixing holes 311 and 321 are spaced apart at predetermined intervals from the edges of the first and second discs 310 and 320.

First and second coupler fixing holes 313 and 323 are formed in the first and second disks 310 and 320, respectively. The first and second coupler fixing holes 313 and 323 are first and second to be described later in order to fix the convection fan 400 to the first motor shaft 510 and the fan shaft 370 which will be described later. This is where the couplers 351 and 361 are fixed. The first and second coupler fixing holes 313 and 323 are formed by cutting a central portion of the first disk 310.

First and second couplers 351 and 361 are inserted into and fixed to both sides of the convection fan 400, and the first and second coupler fixing holes 313 and 323, respectively. A first motor shaft 510 is coupled to the first coupler 351, and a fan shaft 370 is coupled to the second coupler 361. The first and second couplers 351 and 361 are typically formed of a rubber material having a predetermined elastic force. In addition, the first and second couplers 351 and 361 are formed to have longitudinal cross-sections of the first and second coupler fixing holes 313 and 323 and the first and second coupler fixing holes 313 ( 323) respectively inserted into an interference fit.

Meanwhile, the fan shaft 370 extends outside of the convection chamber 301, that is, outside of the second side cover 340, while being coupled to the second coupler 361. The fan shaft 370 extending to the outside of the second side cover 340 is fixed to the bearing 381. The bearing 381 is rotatably supported by a bearing housing 383 fixed to an outer surface of the second side cover 340.

3 and 4, the convection motor 500 provides a driving force for the rotation of the convection fan 400 and the cooling fan 600. To this end, the convection motor 500 is provided with motor shafts 510 and 520. The motor shafts 510 and 520 extend in both directions from the convection motor 500. Hereinafter, one of the motor shafts 510 and 520 extending to the left in the drawing in FIG. 3 is referred to as the first motor shaft 510 and the one extending to the right in the drawing in FIG. 3 is called the second motor shaft 520. . Substantially, the first and second motor shafts 510 and 520 may be understood as one axis. The first motor shaft 510 extends into the convection chamber 301 through the first fan installation hole 331. The first motor shaft 510 is coupled to the first coupler 351. The second motor shaft 520 extends away from the convection chamber 301.

The convection motor 500 is fixed to the outside of the convection chamber 301 and substantially to the outer side of the first side cover 330. At this time, the convection motor 500 is fixed to the outer surface of the first side cover 330 by a motor bracket 530. Substantially, a shaft through hole 531 through which the first motor shaft 510 passes may be formed in the motor bracket 530.

The cooling fan 600 serves to flow air for cooling the convection motor 500. In this embodiment, an axial fan is used as the cooling fan 600. The cooling fan 600 is coupled to the second motor shaft 520. Therefore, the cooling fan 600 is located in the upstream side relative to the convection motor 500 in the direction in which the air sucked through the cooling inlet 181 flows.

The convection heater 710 and 720 serves to heat the air discharged from the interior of the convection chamber 301 to the interior of the cooking chamber 160 by the rotation of the convection fan 400. Substantially the convection heaters 710 and 720 are positioned relatively downstream of the convection fan 400 on the flow of air flowing by the convection fan 400. This is to prevent damage of the convection fan 400 by the air heated by the convection heater (710) (720).

In the present embodiment, the two convection heaters 710 and 720 are installed inside the convection chamber 301. In addition, as the convection heater 710 and 720, for example, a bar type carbon heater, a ceramic heater, a halogen heater, or the like may be used. One end of the convection heater 710 and 720, substantially one of the pinch portions of the convection heater 710 and 720 is inserted into the first heater installation hole 333. The other end of the convection heater 710 and 720, that is, the other of the pinch portions of the convection heater 710 and 720 is supported by the heater bracket 730.

The heater bracket 730 supports the other one of the pinch parts of the convection heater 710 and 720. To this end, two heater heater holes 731 are formed in the heater bracket 730. The heater bracket 730 is fixed to the second side cover 340 in a state of shielding the heater installation opening 343.

The first air guide 810 is a region 303 in which air suctioned into the convection chamber 301 from the inside of the cooking chamber 160 flows substantially inside the convection chamber 301. Hereinafter referred to as a 'suction area' and an area 305 (hereinafter referred to as an 'emission area') through which air discharged into the cooking chamber 160 flows inside the convection chamber 301. . In addition, the first air guide 810, the air circulating the interior of the cooking chamber 160 and the interior of the convection chamber 301 by the rotation of the convection pan 400, the interior of the cooking chamber 160 It also guides you through the cycle.

Referring to FIG. 5, in this embodiment, one end of the first air guide 810 is in contact with a rear surface of the back plate 120 corresponding to the inlet 121 and the exhaust port 123. In this embodiment, the front end of the first air guide 810 is in contact with the rear surface of the back plate 120 that is directly above the exhaust port 123. The other end of the first air guide 810 is positioned adjacent to the convection fan 400. In addition, the first air guide 810 divides the suction area 303 and the discharge area 305 so as to be bent at a predetermined curvature so that the flow cross-sectional area of the discharge area 305 increases in a direction in which air flows. . That is, the first air guide 810 partitions the inside of the convection chamber 301 so that the flow cross section of the discharge region 305 increases from the convection fan 400 toward the exhaust port 123. .

Again, the second air guide 820 guides the air cooling the convection motor 500 by the rotation of the cooling fan 600. That is, the second air guide 820 serves to guide the air sucked through the cooling inlet 181 to cool the convection motor 500 and to be discharged through the cooling exhaust port 183. The air sucked into the space between the back cover 180 and the convection cover 300 through the cooling inlet 181 by the rotation of the cooling fan 600 is substantially the convection motor 500. This is to prevent a phenomenon in which the cooling of the convection motor 500 is inefficiently flowed into the space between the upper portion of the back cover 180 and the upper portion of the convection cover 300 corresponding to the upper portion of the upper portion of the back cover 180.

In the present exemplary embodiment, the second air guide 820 is formed to have a substantially 'L' shape and is positioned to substantially surround the upper and rear sides of the cooling fan 600. Hereinafter, for convenience of description, a portion of the second air guide 820 positioned horizontally is referred to as a horizontal portion 821, and a portion of the second air guide 820 positioned vertically is referred to as a vertical portion 823. One end of the second air guide 820, that is, one side end of the horizontal portion 821 and one side end of the vertical portion 823 is fixed to the motor bracket 530. Of course, the second air guide 820 may be fixed to an outer surface of the first side cover 330 according to the shape and size of the motor bracket 530. The front end of the horizontal portion 821 is in contact with the rear surface of the back plate 120. Therefore, substantially, air flows into the space between the rear surface of the back plate 120 and the inner surface of the second air guide 820 (substantially the bottom surface of the horizontal portion 821 and the front surface of the vertical portion 823). Will be guided.

The second air guide 820 extends inclined upwardly and rearwardly from the motor bracket 530 toward the cooling inlet 181. That is, the horizontal portion 821 extends inclined upward from the motor bracket 530 toward the cooling intake port 181, and the vertical portion 823 extends from the motor bracket 530 to the cooling intake port 181. Extends obliquely backward towards That is, the flow cross-sectional area of the space through which the air sucked through the cooling intake port 181 flows is substantially reduced, and thus, between the back cover 180 and the convection cover 300 through the cooling intake port 181. The air sucked into the space may be guided toward the convection motor 500 by the second air guide 820.

In addition, the air cooled by the convection motor 500 flows downward along the first side cover 330 and is discharged through the cooling exhaust port 183. A space flows between the lower portion of the back cover 180 and the convection cover 300 adjacent to 720. Accordingly, the convection heater 710 and 720 are indirectly cooled by the air cooling the convection motor 500, or the air that cools the convection motor 500 is heated by the convection heater 710 and 720. It serves as a kind of air curtain to prevent the phenomenon that is transmitted to the outside.

The thermistor mounting holes 311 and 321 are installed with a thermistor 900 for sensing a temperature. Substantially the thermistor 900 is located between the inlet 121 and the convection fan 400. That is, the thermistor 900 is relatively in comparison with the convection fan 400 in the flow direction of air sucked into the convection chamber 301 from the inside of the cooking chamber 160 through the inlet 121. Located upstream. Therefore, the thermistor 900 detects the temperature of the air sucked into the convection chamber 301 from the inside of the cooking chamber 160 through the inlet 121.

And the tip of the thermistor 900 is located between the axis of rotation of the convection fan 400 and the upper end of the inner surface of the inner cover (310). This is considered by the rotation of the convection fan 400 in consideration of the flow amount of air sucked into the interior of the convection chamber 301 from the inside of the cooking chamber 160, the thermistor ( To position 900). In more detail, since the inlet port 121 and the exhaust port 123 are spaced up and down, the air discharged from the inside of the convection chamber 301 to the inside of the cooking chamber 160 through the exhaust port 123 is In general, it will flow along the bottom surface, the front surface (substantially the back surface of the door) and the ceiling surface of the cooking chamber 160. Therefore, substantially the amount of air flowing in a portion corresponding to the upper portion of the rotation axis of the convection fan 400 relatively to the rotation axis of the convection fan 400 corresponds to the lower side of the rotation axis of the convection fan 400. It will be more than the amount of air flowing through the part. In this embodiment, the tip of the thermistor 900 is located above the rotation axis of the convection fan 400 with respect to the rotation axis of the convection fan 400, thereby enabling a more accurate sensing of the temperature. .

Hereinafter, the operation of the first embodiment of the cooking appliance according to the present invention will be described in more detail with reference to the accompanying drawings.

7 is a side view showing the flow of air between the cooking chamber and the convection chamber in the first embodiment of the cooking appliance according to the present invention, Figure 8 is for cooling the convection motor in the first embodiment of the cooking appliance according to the invention 9 is a rear view showing the flow of air, Figure 9 is a graph showing the temperature difference of the convection motor according to the presence or absence of the second air guide in the first embodiment of the cooking appliance according to the present invention, Figure 10 is a cooking according to the present invention In the first embodiment of the device is a graph showing the difference in the temperature sensed by the thermistor according to the position of the thermistor.

First, referring to FIG. 7, various heating sources are operated to cook food in the cooking chamber 160. That is, the microwaves and / or the heater heat of the upper heater 200, etc., generated from the magnetron are supplied into the cooking chamber 160 to be used for cooking food.

On the other hand, when the convection device is operated in the cooking process of the inside of the cooking chamber 160, the air inside the cooking chamber 160 is rotated through the inlet port 121 by the rotation of the convection fan 400. ) Is sucked into the interior. The air sucked into the convection chamber 301 is discharged into the cooking chamber 160 through the exhaust port 123 by the continuous rotation of the convection fan 400.

At this time, the air suctioned into the convection chamber 301 from the inside of the cooking chamber 160 through the inlet 121 and the cooking chamber 160 through the exhaust port 123 inside the convection chamber 301. Air discharged into the inside of the air is partitioned by the first air guide 810. In addition, the air discharged from the inside of the convection chamber 301 to the inside of the cooking chamber 160 through the exhaust port 123 is substantially guided by the first air guide 810, It will cycle through the inside evenly. In addition, the air discharged into the cooking chamber 160 is heated by the convection heater 710 and 720, so that hot air is substantially supplied into the cooking chamber 160 to heat the food.

Next, referring to FIG. 8, when the convection motor 500 is driven to rotate the convection fan 400, the cooling fan 600 coupled to the second motor shaft 520 also rotates to form the convection motor 500. ) Is cooled. More specifically, when the cooling fan 600 is rotated, the outside air is spaced between the back cover 180 and the convection cover 300 where the convection motor 500 is located through the cooling inlet 181. Is inhaled. The air sucked into the space between the back cover 180 and the convection cover 300 is guided by the second air guide 820 to cool the convection motor 500. The air cooling the convection motor 500 flows downwardly along the first side cover 330 by the continuous rotation of the cooling fan 600, and again the back cover 180 and the convection cover. Flow in the horizontal direction along the space between the 300 is discharged from the inside of the back cover 180 and the convection cover 300 through the cooling exhaust port 183 to the outside. At this time, the air discharged through the exhaust port 123 substantially flows through the lower portion of the space between the back cover 180 and the convection cover 300 adjacent to the convection heater 710 and 720, and the convection heater. It also serves as an air curtain to indirectly cool the 710 and 720 or prevent a phenomenon in which the heater heat of the convection heater 710 and 720 is transmitted to the outside. Therefore, the phenomenon in which the heat of the convection heater 710 and 720 is transferred to the outside is minimized, so that the product can be used more safely.

Referring to FIG. 9, in the conventional case in which the second air guide 820 is not installed, the temperature of the convection motor 500 is increased to 134.7 ° F. However, when the second air guide 820 is installed. It can be seen that the temperature of the convection motor 500 is measured at 127.3 ° F. That is, when the air for cooling the convection motor 500 is guided by the second air guide 820, it can be seen that the convection motor 500 is more efficiently cooled. Therefore, the operation reliability of the convection motor 500 can be improved, and further, the reliability and durability of the product can be improved.

Meanwhile, the control of the operation of the heating source including the convection device is performed according to the temperature sensed by the thermistor 900. That is, the temperature detected by the thermistor 900 is determined as the temperature of the cooking chamber 160 to control the operation of the heating source. Therefore, as the temperature substantially detected by the thermistor 900 approaches the temperature of the cooking chamber 160 which is actually set, more precise control of cooking is possible.

Meanwhile, referring to FIG. 10, in the case of the present embodiment, that is, the thermistor 900 is inside the convection chamber 301 and substantially inside the cooking chamber 160 through the inlet 121. When sensing the temperature of the air sucked into the inside of the 301, it can be seen that the temperature closer to the temperature of the cooking chamber 160 is set. More specifically, in the prior art 1 to 5 in FIG. 10, the thermistor 900 is installed inside the cooking chamber 160. That is, the prior art 1 is the case where the thermistor 900 is installed in the center of the upper rear end of the cooking chamber 160, the prior art 2 to 5 is the thermistor 900 is the rear end or the rear end of the side of the cooking chamber 160 In this case, the installation is spaced apart from the front. And (B1) to (B4) shows the sensing temperature of the thermistor 900 in the present embodiment and the prior art according to the set temperature of the cooking chamber 160. That is, (B1) to (B4) is the detection temperature of the thermistor 900 in the present embodiment and the prior art, when the set temperature of the cooking chamber 160 is 230 ℃, 200 ℃, 150 ℃ and 100 ℃, respectively Indicates. Referring to (B1) to (B4), it can be seen that in the case of the present embodiment, the thermistor 900 detects the temperature closest to the set temperature of the cooking chamber 160 as compared with the related art. Furthermore, according to the present embodiment, the heating source can be more precisely controlled based on the temperature sensed by the thermistor 900.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art in light of the above teachings. will be.

Claims (5)

A cooking chamber in which food is cooked;
A chamber in communication with the cooking chamber;
An intake port through which air is sucked into the chamber from the inside of the cooking chamber;
An exhaust port through which air is discharged from the inside of the chamber to the inside of the cooking chamber;
A cross flow fan installed inside the chamber and configured to generate a flow of air between the cooking chamber and the chamber through the intake port and the exhaust port;
A heating source installed inside the chamber and heating air discharged from the inside of the chamber to the inside of the cooking chamber through the exhaust port by rotation of the cross flow fan; And
A temperature sensor positioned inside the chamber corresponding to the intake port and the cross flow fan to sense a temperature of air sucked into the chamber from the inside of the cooking chamber; Cooking apparatus comprising a. The method of claim 1,
The cross flow fan rotates about a horizontal axis of rotation,
And the temperature sensing unit is inserted downward from the upper side of the chamber such that its tip is positioned above the rotation axis of the cross flow fan. A cavity having a cooking chamber in which food is cooked and formed with an inlet and an exhaust port spaced apart from each other on a back plate forming a rear surface of the cooking chamber;
A heating source for providing energy for cooking food in the cooking chamber;
A convection cover fixed to a rear surface of the back plate and forming a convection chamber between an inner surface of the back plate and a rear surface of the back plate;
Installed in the convection chamber, and is sucked into the convection chamber from the inside of the cooking chamber through the inlet port and discharged from the interior of the convection chamber to the interior of the cooking chamber through the exhaust port in a direction orthogonal to the rotation axis thereof; A convection fan for flowing air;
A convection heater installed in the convection chamber and heating the air flowing by the convection fan; And
A thermistor configured to sense a temperature of air sucked into the convection chamber from the inside of the cooking chamber through the inlet; Including,
And the heating source, the convection fan, and the convection heater are controlled according to the temperature sensed by the thermistor. The method of claim 3, wherein
Fan mounting holes for installation of the convection fan, and thermistor mounting holes for installation of the thermistor are formed on both side surfaces and the upper surface of the convection cover, respectively.
The thermistor penetrates through the thermistor installation hole, and a tip thereof is positioned above the fan installation hole. The method of claim 3, wherein
The convection cover,
An inner cover fixed to the rear of the back plate;
An outer cover fixed to a rear surface of the back plate to shield the inner cover; And
At least two side covers fixed to a rear surface of the back plate and both sides of the inner cover; Including,
The convection chamber is formed between the back plate, the inner cover and the side cover,
The thermistor is located inside the convection chamber through the inner cover and the outer cover.

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