KR101751066B1 - Convection device and cooking appliance comprising the same - Google Patents

Abstract

The present invention relates to a convection apparatus and a cooking apparatus including the same. In the present invention, the bearing housing for supporting the bearing is positioned by the bearing bracket so as to be spaced apart from the convection cover. Therefore, according to the present invention, the effect of preventing the bearing from being deformed or damaged by heat can be expected.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a convection device and a cooking device including the convection device,

The present invention relates to a cooking appliance.

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

SUMMARY OF THE INVENTION It is an object of the present invention to provide a convection device and a cooking device including the convection device, which are configured to enable more efficient cooking.

Another object of the present invention is to provide a convection device and a cooking device including the same, which are configured to further enhance the durability of the product.

According to an aspect of the present invention, there is provided a convection chamber for forming a convection chamber communicating with a cooking chamber. A convection fan installed inside the convection chamber and forming a flow of air circulating between the cooking chamber and the convection chamber; A convection motor for providing a driving force for rotation of the convection fan; A motor shaft coupled to one end of the convection fan to transmit the driving force of the convection motor to the convection fan; A fan shaft having one end coupled to the other end of the convection fan to support the convection fan rotatably and the other end protruding outside the convection cover; A bearing member rotatably supporting the other end of the fan shaft; A bearing bracket fixing the bearing member such that the bearing member is positioned apart from the outer surface of the convection cover; And at least one convection heater installed inside the convection chamber for heating air flowing by the convection fan; .

According to an aspect of an embodiment of the cooking apparatus of the present invention, a cavity provided with a cooking chamber; A door selectively opening and closing the cooking chamber; And a convection device according to any one of claims 1 to 7 provided on one side of the cavity; .

According to the embodiments of the convection apparatus and the cooking apparatus including the same as described above, the bearing housing supporting the bearings is positioned away from the convection cover by the bearing bracket. Therefore, it is possible to expect the effect of preventing the bearing from being deformed or damaged by heat.

1 is a perspective view showing an embodiment of a cooking apparatus according to the present invention.
2 is an exploded perspective view showing a main part of an embodiment of the present invention.
3 is an exploded perspective view showing a convection apparatus constituting an embodiment of the present invention.
4 is an exploded perspective view showing a convection fan constituting an embodiment of the present invention.
5 is an exploded perspective view showing a main part of an embodiment of the present invention.
FIG. 6 to FIG. 9 are working state views showing the installation process of the bearing member and the bearing bracket in the embodiment of the cooking apparatus according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, configurations of embodiments of a cooking apparatus according to the present invention will be described in detail with reference to the accompanying drawings. Hereinafter, a microwave oven for cooking food using a microwave, among the cooking appliances, will be described as an example.

FIG. 1 is a perspective view showing an embodiment of a cooking apparatus according to the present invention, FIG. 2 is an exploded perspective view showing a main part of an embodiment of the present invention, FIG. 3 is an exploded perspective view showing a convection apparatus constituting an embodiment of the present invention FIG. 4 is an exploded perspective view showing a convection fan constituting an embodiment of the present invention, and FIG. 5 is an exploded perspective view showing a main part of an embodiment of the present invention.

Referring to FIG. 1, a front plate 110 is formed on a front surface of a cavity 100 of a microwave oven, and a back plate 120 is formed on a rear surface of the cavity 100. The upper and lower surfaces of the cavity 100 are formed by the upper plate 130 and the bottom plate 140, respectively. Two side plates 150 are formed on opposite sides of the cavity 100. At this time, the upper plate 130, the bottom plate 140, and the side plate 150 may be formed by bending one member or may be formed and fixed to each other.

Meanwhile, a cooking chamber 160 is provided in the cavity 100. The upper surface and the lower surface of the cooking chamber 160 are connected to the back plate 120, the upper plate 130, the bottom plate 140, and the lower plate 140. The cooking chamber 160 is formed in a rectangular parallelepiped shape, And the side plate 150 are formed. The cooking chamber 160 is a place where cooking is performed. The cooking chamber 160 is selectively opened and closed by a door (not shown).

An electric field chamber 170 is provided on one side of the cavity 100. Various electrical components are installed inside the electric field chamber 170. 1, the electric field chamber 170 is shown on the right side of the cooking chamber 160, but the position of the electric field chamber 170 is not limited thereto.

2) and an exhaust port 123 (see FIG. 2) are formed on the back surface of the cooking chamber 160, that is, on the back plate 120. The intake port 121 serves as an inlet through which the air inside the cooking chamber 160 is sucked into the convection chamber 301 to be described later. The air outlet 123 serves as an outlet through which the air inside the convection chamber 301 is discharged to the inside of the cooking chamber 160. In the present embodiment, the exhaust port 123 is positioned below the intake port 121. [ In addition, the air inlet 121 and the air outlet 123 may be formed substantially in the form of pores. This prevents leakage of the microwave supplied to the inside of the cooking chamber 160 and prevents the foreign substances generated in the cooking process of the inside of the cooking chamber 160 from flowing into the inside of the convection chamber 160 .

A back cover 180 is provided on the back surface of the back plate 120. The back cover 180 shields the convection cover 300, which will be described later. In the present embodiment, the back cover 180 is formed in a polyhedral shape having a substantially open front face. A cooling air inlet 181 is formed on the right side of the back cover 180 in the drawing. A cooling exhaust port 183 is formed on the left side of the back cover 180 in the drawing. The cooling air inlet port 181 and the cooling air outlet port 183 are places where air for cooling the convection motor 500 to be described later is sucked and discharged. 1 of the back cover 180 which is relatively adjacent to the convection motor 500 and the cooling exhaust port 183 is located at the upper right side in the drawing in the present embodiment, 1 of the back cover 180 that is relatively spaced apart from the motor 500 is located at the lower left side of the drawing.

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 a microwave into the cooking chamber 160 may be installed in the electric field chamber 170. An upper heater 200 for supplying a heater heat to the inside of the cooking chamber 160 may be installed on the upper plate 130.

In this embodiment, a convection device is installed behind the cooking chamber 160, that is, on the rear surface of the back plate 120. The convection device serves to supply high-temperature air to the inside of the cooking chamber 160. 3, the convection device includes a convection cover 300, a convection fan 400, a convection motor 500, a cooling fan 600, a convection heater 710, and an air guide 800 .

More specifically, the convection cover 300 is fixed to the back surface of the back plate 120 to form a convection chamber 301. At this time, the convection cover 300 may be substantially located 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 heaters 710 and 720 and the air guide 800 are installed, And communicates with the cooking chamber 160. 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 vertical section. The inner cover 310 and the outer cover 320 are fixed to the back surface of the back plate 120 in order. Accordingly, the outer cover 320 substantially blocks the inner cover 310 from the rear. Thermistor mounting holes 311 and 321 are formed in the inner cover 310 and the outer cover 320, respectively. The thermistor mounting holes 311 and 321 are vertically overlapped with each other. The thermistor mounting holes 311 and 321 substantially correspond to the inner cover 310 and the outer cover 320 corresponding to the front and the upper sides of the first and second shaft mounting holes 331 and 341, As shown in FIG.

Although not shown, a heat insulating material may be provided between the inner cover 310 and the outer cover 320. The heat insulating material prevents the heat of the convection heaters 710 and 720 from being transmitted to the outside.

The side covers 330 and 340 are fixed to the side surfaces of the inner cover 310, respectively. For convenience of explanation, the first side cover 330 and the second side cover 340 are referred to as the first side cover 330 and the second side cover 340, respectively.

A first shaft installation hole 331 is formed in the first side cover 330. The first shaft installation hole 331 is for installing the convection fan 400. The first heater mounting hole 335 is for installing the convection heaters 710 and 720. The first shaft mounting hole 331 is formed by cutting a part of the first side cover 330.

The first side cover 330 is provided with a first heater mounting portion 333. The first heater mounting portion 333 is formed such that a part of the first side cover 330 protrudes to the right in the drawing. In other words, the first heater mounting portion 333 is formed by protruding a part of the first side cover 330 to the outside of the convection chamber 301.

In addition, two first heater mounting holes 335 are formed in the first heater mounting portion 333. The first heater mounting hole 335 may have a shape corresponding to the end portion of the convection heaters 710 and 720 so that one end of the convection heaters 710 and 720 may be inserted at one end, D shape. The first heater mounting hole 335 is formed by cutting a part of the first side cover 330 and a part of the first heater mounting part 333 substantially.

In the present embodiment, the first shaft installation hole 331 is positioned relatively adjacent to the intake port 121 as compared with the exhaust port 123. The first heater mounting portion 333 is positioned adjacent to the exhaust port 123 relative to the intake port 121. Therefore, the first heater mounting portion 333, that is, the first heater mounting portion 333, is positioned substantially below the first shaft mounting hole 331. [

The second side cover 340 is provided with a second shaft mounting hole 341 and two heater through holes 343. The second shaft mounting hole 341 is formed at a position facing the first shaft mounting hole 331. The heater through holes 343 are for installing the convection heaters 710 and 720. The convection heaters 710 and 720 are positioned inside the convection chamber 301 substantially through the heater through holes 343. [ The heater through hole 343 is formed by cutting a part of the second side cover 340 in a circular shape having a diameter equal to or larger than the diameter of the convection heaters 710 and 720. The heater through hole 343 is overlapped with the first heater mounting hole 335 so that the first heater mounting hole 335 is located inside the heater through hole 343.

5). The bracket mounting portion 345 is for fixing a bearing bracket 570 to be described later (refer to FIG. 5). The bracket mounting portion 345 is formed in the second side cover 340 . The bracket mounting part 345 is formed by protruding a part of the second side cover 340 outward of the convection chamber 301. This is for separating the bearing housing 560, which will be described later, from the second side cover 340. A detailed description thereof will be given later. In the present embodiment, the bracket mounting portion 345 is formed in a ring shape centering on the second shaft mounting hole 341.

A plurality of fastening holes 347 are formed on the bracket mounting portion 345. The fastening hole 347 is a place where a fastener S for fastening the bearing bracket 570 is fastened. It is preferable that the fastening holes 347 are formed of at least two or more.

A heater bracket 350 is fixed to the second side cover 340. The heater bracket 350 is substantially fixed to the second side cover 340 to shield the heater through-hole 343. Accordingly, the heater bracket 350 is formed in a shape and size that can shield at least the heater through-hole 343. At this time, the heater bracket 350 is detachably fixed to the second side cover 340. For example, the heater bracket 350 may be fixed to the second side cover 340 by means of fasteners such as bolts (not shown).

On the other hand, the heater bracket 350 is provided with a second heater mounting portion 351. The second heater mounting portion 351 may be formed on the heater bracket 350 corresponding to the first heater mounting portion 333 while the heater bracket 350 is fixed to the second side cover 340. [ Is formed on the left side of the drawing, that is, protruding out of the convection chamber 301. As shown in Fig. Therefore, it can be said that the distance between the first and second heater mounting portions 333 and 351 is substantially increased relative to the distance between the inner surfaces of the first and second side covers 330 and 340 .

In addition, two second heater mounting holes 353 are formed in the second heater mounting portion 351. The other one of both ends of the convection heaters 710 and 720 is inserted into the second heater mounting hole 353. Like the first heater installation hole 335, the second heater installation hole 353 may be formed in a D shape corresponding to the shape of the end portion of the convection heaters 710 and 720. The second heater mounting holes 353 are formed at positions corresponding to the first heater mounting holes 335, respectively. The second heater mounting hole 353 is overlapped with the heater through hole 343 so as to be located inside the heater through hole 343 like the first heater mounting hole 335 .

The convection fan 400 is installed inside the convection chamber 301 and circulates air between the cooking chamber 160 and the convection chamber 301. In the present embodiment, the convection fan 400 rotates about the rotational axis in the horizontal direction. More specifically, when the convection fan 400 is driven, the air inside the cooking chamber 160 is sucked into the convection chamber 301 through the inlet 121, The air inside the convection chamber 301 is discharged into the inside of the cooking chamber 160. In the present embodiment, a transverse fan is used as the convection fan 400, in which an air intake / exhaust device in a plane direction orthogonal to the rotation axis thereof is formed.

Referring to FIG. 4, the convection fan 400 includes three disks 410, 420, and 430 and a plurality of blades 440 positioned between the disks. The disks 410, 420, and 430 are formed in a substantially disc shape, and are spaced apart from each other by a predetermined distance. The blades 440 are positioned between the disks 410, 420, and 430 at predetermined angles, respectively. In FIG. 4, the first disk 410, the second disk 420, and the first and second disks 410 and 420 are disposed on the right side of FIG. And is referred to as a third disk 330.

A plurality of blade fixing holes 411 and 421 for fixing the blade 440 are formed on the first and second disks 410 and 420, respectively. The blade fixing holes 411 and 421 are spaced apart from each other by a predetermined distance on the rim of the first and second disks 410 and 420.

First and second coupler fixing holes 413 and 423 are formed in the first and second disks 410 and 420, respectively. The first and second coupler fixing holes 413 and 423 are formed by cutting a central portion of the first disk 410. The first and second coupler fixing holes 413 and 423 are formed in the first and second couplers 421 and 422 to couple the convection fan 400 to the first motor shaft 510 and the fan shaft 540, 451) 461 are fixed.

A first motor shaft 510 is coupled to the first coupler 451 and a fan shaft 540 is coupled to the second coupler 461. The first and second couplers 451 and 461 are formed to have a longitudinal profile of more than the first and second coupler fixing holes 413 and 423 and the first and second coupler fixing holes 413 and 413 423, respectively.

Referring again to FIG. 3, the convection motor 500 provides a driving force for 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, the first motor shaft 510 extending to the left in the drawing in FIG. 3 of the motor shafts 510 and 520 and the second motor shaft 520 extending to the right in FIG. 3 are referred to as the second motor shaft 520 . Substantially the first and second motor shafts 510 and 520 can be understood as one axis. The first motor shaft 510 extends through the first shaft mounting hole 331 and into the convection chamber 301. The first motor shaft 510 is coupled to one end of the convection fan 400, that is, to the right end of the convection fan 400 in the drawing. The second motor shaft 520 extends in a direction away from the convection chamber 301.

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

The motor bracket 530 is provided with a guide portion 533. The guide portion 533 serves to guide the air for cooling the convection motor 500 by the rotation of the cooling fan 600, which will be described later. That is, the guide portion 533 serves to guide the air sucked through the cooling air inlet port 181 to cool the convection motor 500 and to discharge the air through the cooling air outlet port 183. In this embodiment, the guide portion 533 is formed in a substantially L-shape so as to surround substantially the upper side and the rear side of the cooling fan 600.

3 to 5, in order to rotatably support the other end of the convection fan 400, that is, the left end of the convection fan 400 on the second side cover 340, (540). The fan shaft 540 has a predetermined length and is installed through the second shaft mounting hole 341. A part of the fan shaft 540 is positioned inside the convection chamber 301 and the rest of the fan shaft 540 is positioned outside the convection chamber 301. A portion of the fan shaft 540 located inside the convection chamber 301 is coupled to the other end of the convection fan 400, that is, to the left end of the drawing of the convection fan 400.

A bearing member is installed at the other end of the fan shaft 540 protruding outside the convection chamber 301 through the second shaft installation hole 341. The bearing member serves to rotatably support the fan shaft 540. The bearing member includes a bearing 550 and a bearing housing 560.

The bearing housing 560 supports the bearing 550 and absorbs vibration generated during the rotation of the convection fan 400. [ For this purpose, the bearing housing 560 may be formed of a flexible material having a predetermined elasticity, for example, a rubber material. Of course, the material of the bearing housing 560 is not necessarily limited to a rubber material, and any materials can be used as long as the material can absorb vibrations.

Referring to FIG. 5, the bearing housing 560 includes a bearing fixing portion 561 and a bracket fixing portion 565. The bearing fixing portion 561 is for fixing the bearing 550 to the bearing housing 560. The bracket fixing portion 565 is for fixing the bearing housing 560 to the bearing bracket 570.

More specifically, the bearing fixing portion 561 is formed into a flat cylindrical shape having a substantially open side. A bearing insertion groove 562 (see FIG. 9) is formed in the bearing fixing portion 561. The bearing insertion groove 562 is substantially where the bearing 550 is inserted. At this time, the bearing insertion groove 562 may be formed in a shape and size that the bearing 550 can be inserted.

On the other hand, the bracket fixing portion 565 extends radially from one side of the outer peripheral surface of the bearing fixing portion 561. The bracket fixing portion 565 may be positioned at the front end of the outer peripheral surface of the bearing fixing portion 561 corresponding to the entrance side of the bearing insertion groove 562. [ A bracket fixing slot 566 is formed in the bracket fixing portion 565. The bracket fixing slot 566 is formed by recessing a part of the outer peripheral surface of the bracket fixing portion 565 in the center direction thereof. An inclined guide surface 567 (see FIG. 9) is provided at the distal end of the bracket fixing portion 565. The inclined guide surface 567 is formed by inclining the distal end of the bracket fixing portion 565 in such a manner that the diameter gradually decreases toward the center of the bracket fixing portion 565. The inclined guide surface 567 serves to guide the bearing housing 560, which is fixed to the bearing bracket 570, substantially to the bracket fixing portion 565.

A bearing bracket 570 is fixed to the outer side surface of the second side cover 340. The bearing bracket 570 is for supporting the bearing housing 560 as described above. In this embodiment, the bearing bracket 570 includes a bracket body 571 and a cover fixing portion 577. [

More specifically, the bracket body 571 includes a front portion 572 and a rim portion 575. [ At this time, the bracket body 571 including the front portion 572 and the rim portion 575 may be formed into a cup shape as a whole.

The front portion 572 is formed in a circular plate shape having a predetermined diameter. A housing fixing hole 573 is formed in the front portion 572. The housing fixing hole 573 is where the bearing housing 560 is inserted. It is preferable that the housing fixing hole 573 is smaller than the diameter of the bracket fixing portion 565 and has a diameter equal to or larger than the diameter of the bracket fixing slot 566. A portion of the front surface portion 572 adjacent to the outer circumference of the housing fixing hole 573 is formed in the housing fixing hole 573 when the bearing housing 560 or the bearing fixing portion 561 is inserted into the housing fixing hole 573 , And is inserted into the bracket fixing slot 566. A plurality of first cooling holes 574 are formed in the front portion 572. The first cooling hole 574 is formed by cutting a part of the front portion 572 except for the housing fixing hole 573. The first cooling hole 574 is a place where air for cooling the bearing housing 560 flows.

The rim portion 575 extends obliquely at a predetermined angle from the rim of the front portion 572. A plurality of second cooling holes 576 are formed in the rim portion 575. The second cooling holes 576 are for cooling the bearing housings 560 in the same manner as the first cooling holes 574. The front portion 572 and the cover fixing portion 577 are positioned apart from each other substantially by the rim portion 575.

The cover fixing portion 577 extends radially at the tip of the bracket body 571, substantially at the tip of the rim 575. At this time, the cover fixing portion 577 is formed in a shape and size corresponding to the bracket mounting portion 345. The cover fixing part 577 is fixed to the second side cover 340 by the fastening part S in a state where one side of the cover fixing part 577 is in contact with the bracket mounting part 345. For this, a plurality of through holes 578 are formed in the cover fixing portion 577. The through hole 578 penetrates through the fastener S for fixing the bearing bracket 570 to the second side cover 340 and substantially the bracket mounting portion 345.

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

The convection heaters 710 and 720 serve to heat air discharged from the inside of the convection chamber 301 into the cooking chamber 160 by the rotation of the convection fan 400. The convection heaters 710 and 720 are positioned relatively downstream of the convection fan 400 on the airflow flowing by the convection fan 400. [ This is to prevent the convection fan 400 from being damaged by the air heated by the convection heaters 710 and 720.

Meanwhile, the air guide 800 substantially surrounds the inner space of the convection chamber 301 in a region 303 in which air sucked into the convection chamber 301 from the inside of the cooking chamber 160 flows And a region 305 (hereinafter referred to as a "discharge region") through which the air discharged into the cooking chamber 160 flows in the convection chamber 301. The air guide 800 circulates the inside of the cooking chamber 160 and the inside of the convection chamber 301 by circulating the convection fan 400 evenly through the inside of the cooking chamber 160 It also serves as a guide.

In this embodiment, one end of the air guide 800 is in contact with the rear surface of the back plate 120 between the inlet 121 and the outlet 123. In this embodiment, the tip of the air guide 800 is in contact with the back surface of the back plate 120 corresponding to the upper chamber of the air outlet 123. The other end of the air guide 800 is positioned adjacent to the convection fan 400. The air guide 800 is bent at a predetermined curvature to divide the suction area 303 and the discharge area 305 such that the flow cross sectional area of the discharge area 305 is increased in a direction in which air flows. That is, the air guide 800 divides the inside of the convection chamber 301 such that the flow cross-sectional area of the discharge area 305 increases from the convection fan 400 toward the air outlet 123.

On the other hand, the thermistor mounting holes 311 and 321 are provided with a thermistor 900 for sensing the temperature. Substantially the thermistor 900 is positioned between the intake port 121 and the convection fan 400. That is, the thermistor 900 is relatively moved in the flow direction of the air sucked into the convection chamber 301 from inside the cooking chamber 160 through the inlet 121, relative to the convection fan 400 Is located on the upstream side. Therefore, the thermistor 900 senses the temperature of the air sucked into the convection chamber 301 from inside the cooking chamber 160 through the inlet 121.

Hereinafter, the cooking process of the embodiment of the cooking apparatus according to the present invention will be described in more detail.

First, various heating sources are operated to cook the food inside the cooking chamber 160. For example, microwaves oscillated from the magnetron and / or heater heat of the upper heater 200 are supplied to the interior of the cooking chamber 160 and used for cooking food.

Meanwhile, when the convection device is operated in the cooking process of the cooking chamber 160, the air inside the cooking chamber 160 is supplied to the convection chamber 301 through the inlet 121 by rotation of the convection fan 400 As shown in FIG. The air sucked into the inside of the convection chamber 301 is discharged to the inside of the cooking chamber 160 through the air outlet 123 by the continuous rotation of the convection fan 400.

At this time, the air sucked into the convection chamber 301 from the inside of the cooking chamber 160 through the inlet 121 and the air sucked from the inside of the convection chamber 301 through the exhaust port 123, Air is exhausted to the inside of the air guide 800 by the air guide 800. The air discharged from the convection chamber 301 to the inside of the cooking chamber 160 through the air outlet 123 is guided substantially by the air guide 800 so that the inside of the cooking chamber 160 And circulates evenly. The air discharged to the inside of the cooking chamber 160 is heated by the convection heaters 710 and 720 so that hot air is substantially supplied into the cooking chamber 160 to heat the food.

Hereinafter, a process of installing the bearing member and the bearing bracket in the embodiment of the cooking apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

6 to 9 are operation state diagrams showing the installation process of the bearing member and the bearing bracket in the embodiment of the cooking apparatus according to the present invention.

6, when the inner cover 310 and the first side cover 330 are fixed, a space between the inner cover 310 and the first side cover 330, that is, a space between the inner cover 310 and the first side cover 330, The convection fan 400 is installed in the inside of the casing 301. One end of the convection fan 400 is coupled to one end of the first motor shaft 510 protruding into the space between the inner cover 310 and the first side cover 330. One end of the fan shaft 540 is coupled to the other end of the convection fan 400. The convection fan 400 and the fan shaft 540 may be engaged before or after the first motor shaft 510 is coupled to one end of the convection fan 400.

Next, referring to FIG. 7, the second side cover 340 is fixed to the inner cover 310. When the second side cover 340 is fixed to the inner cover 310, the other end of the fan shaft 540 passes through the second shaft installation hole 341 to the outside of the convection chamber 301 Respectively.

Referring to FIG. 8, when the convection cover 300 is assembled, the bearing bracket 570 is fixed to the outer surface of the second side cover 340. More specifically, in the state where the cover fixing portion 577 is in contact with the bracket mounting portion 345, by means of the fastening tool S which is inserted into the fastening hole 347 through the through hole 578, (570) is fixed to the outer side surface of the second side cover (340). At this time, substantially the housing fixing hole 573 is spaced from the outer side surface of the second side cover 340.

9, when the bearing bracket 570 is fixed to the outer surface of the second side cover 340, the bearing 550 is coupled to the other end of the fan shaft 540. When the bearing 550 is coupled to the fan shaft 540, the bearing 550 is inserted into the bearing housing 560 and the bearing housing 560 is fixed to the bearing bracket 570. At this time, the process of inserting the bearing 550 into the bearing housing 560 and the process of fixing the bearing housing 560 to the bearing bracket 570 may be performed together. That is, when the bearing housing 560 is moved to the right in the figure with the bearing 550 coupled to the fan shaft 540, the bearing housing 560 is fixed to the bearing bracket 570 And the process of inserting the bearing 550 into the bearing housing 560 may be performed together. The bearing housing 560 may be moved to fix the bearing housing 560 to the bearing bracket 570 in a state where the bearing 550 is inserted into the bearing housing 560, The process of fixing the bearing 550 to the fan shaft 540 and the process of coupling the bearing 550 to the fan shaft 540 may be performed together. The bearing housing 560 is moved to fix the bearing housing 560 to the bearing bracket 570 in a state where the bearing 550 is inserted into the bearing housing 560, 570 and a process of coupling the bearing 550 to the fan shaft 540.

Since the bearing housing 560 is formed of a material having a predetermined elasticity, the bearing housing 560 is elastically deformed in the process of being inserted through the housing fixing hole 573, A part of the bearing bracket 570 is inserted into the bracket fixing slot 566. [ Interference between the bearing housing 560 and the bearing bracket 570 can be prevented by the inclined guide surface 567 in the process of inserting the bearing housing 560 into the housing fixing hole 573. [

In this embodiment, the bearing housing 560 is spaced from the outer surface of the second side cover 340 in a state where the bearing housing 560 is fixed to the bearing bracket 570. Therefore, the phenomenon that light and / or heat of the convection heaters 710 and 720 are substantially transferred to the bearing housing 560 through the second side cover 340 can be minimized.

Cooling of the bearing housing 560 located inside the bearing housing 560, particularly substantially within the bearing bracket 570, by air flowing through the first and second cooling holes 574, . Therefore, it is possible to prevent deformation and damage of the bearing housing 560 due to heat.

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.

In the above-described embodiment, the microwave oven is described as an example, but it is needless to say that the present invention can also be applied to other cooking utensils in which a convection device can be used, for example, an electric oven or an electric oven range.

Claims (9)

A convection cover forming a convection chamber communicating with the cooking cavity;
A convection fan installed inside the convection chamber and forming a flow of air circulating between the cooking chamber and the convection chamber;
A convection motor for providing a driving force for rotation of the convection fan;
A motor shaft coupled to one end of the convection fan to transmit the driving force of the convection motor to the convection fan;
A fan shaft having one end coupled to the other end of the convection fan to support the convection fan rotatably and the other end protruding outside the convection cover;
A bearing inserted into the other end of the fan shaft to allow the fan shaft to rotate;
A bearing housing in which the bearing is inserted, and the fan shaft absorbs vibrations generated during the rotation process;
A bearing bracket positioned between the bearing housing and the convection cover for fixing the bearing housing such that the bearing housing is spaced apart from the outer surface of the convection cover; And
At least one convection heater installed inside the convection chamber and heating the air flowing by the convection fan; Lt; / RTI >
Wherein at least one cooling hole through which air for cooling the bearing housing flows is formed in the bearing bracket. The method according to claim 1,
The bearing housing includes:
A bearing fixing portion having a bearing insertion groove into which the bearing is inserted; And
And a bracket fixing part extending radially from one side of the outer circumferential surface of the bearing fixing part and having a bracket fixing slot in which a part of an outer circumferential surface is recessed in a center direction thereof. 3. The method of claim 2,
Wherein the inclined guide surface whose diameter is gradually decreased toward the center of the bracket fixing portion is provided at the tip of the bracket fixing portion. The method according to claim 1,
Wherein the bearing housing is elastically deformed in a process of being fixed to the bearing bracket. 3. The method of claim 2,
The bearing bracket
A bracket body formed with a housing fixing hole to be inserted into a bracket fixing slot of the bearing housing; And
A cover fixing portion which is located apart from the housing fixing hole and is fixed to an outer surface of the convection cover; . delete The method according to claim 1,
And a bracket mounting part protruding outside the convection chamber at one side of the convection cover and fixing the bearing bracket. A cavity provided with a cooking chamber;
A door selectively opening and closing the cooking chamber; And
A convection device according to any one of claims 1 to 5 and 7, provided on one surface of the cavity; . 9. The method of claim 8,
Further comprising a back cover surrounding the convection device including the bearing, the bearing housing, and the bearing bracket.

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