KR20100111198A - Cooker - Google Patents

Abstract

The present invention relates to a cooking appliance. In the present invention, the inside of the cooking chamber is circulated by the driving of the cooling fan, and the moisture contained in the air discharged to the outside of the cooking chamber is condensed and discharged to the outside of the cooking apparatus. Therefore, according to the present invention, the phenomenon that the steam supplied to the cooking chamber is discharged together with the air to the outside of the cooking chamber is reduced.

Description

Cooker {Cooker}

The present invention relates to a cooking appliance, and more particularly to a cooking appliance for cooking food using steam.

A cooking appliance is a household electric appliance which heats food by using electricity or gas. Recently, a cooking device has been introduced to add a steam function for supplying steam to the food for replenishing moisture evaporated in the cooking process of the food.

An object of the present invention is to reduce the phenomenon that the steam supplied to the cooking chamber is discharged together with the air for ventilating the cooking chamber flows inside the cooking apparatus.

Cooking apparatus according to an embodiment of the present invention for achieving the above object, a cavity provided with a cooking chamber; At least one electrical component installed in the cavity; A steam generator installed in the cavity and supplying steam to the cooking chamber; A cooling fan for flowing air for cooling the electric component and circulating the cooking chamber; And a duct suctioned into the cooking chamber to circulate the cooking chamber and guide the air discharged to the outside of the cooking chamber, and condense steam contained in the air discharged to the outside of the cooking chamber. It includes.

Cooking device according to another embodiment of the present invention, a cavity provided with a cooking chamber; Electrical components installed in the cavity; A cooling fan installed in the cavity to flow air; And a steam generator supplying steam to the cooking chamber. A cooking apparatus comprising: a first flow passage through which air sucked into the interior by driving of the cooling fan flows; A second flow passage through which a portion of the air flowing through the first flow passage flows; A third flow passage through which the rest of the air flowing through the first flow passage flows; And a fourth flow passage through which the air flowing through the second and third flow passages flows and is discharged to the outside. It includes, flows the first flow path and is sucked into the cooking chamber circulates the cooking chamber and is discharged to the outside of the cooking chamber steam contained in the air flowing in the second flow path is condensed and flows into the fourth flow path .

According to the present invention, the phenomenon that the steam supplied to the cooking chamber is discharged together with the air for ventilation of the cooking chamber is reduced.

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

1 is a perspective view showing an embodiment of a cooking appliance according to the present invention, Figure 2 is a perspective view showing another embodiment of the present invention from another angle, Figure 3 is an exploded perspective view showing an embodiment of the present invention.

1 to 3, the cooking chamber 101 is provided inside the cavity 100 of the cooking appliance. The cooking chamber 101 is a place where food is cooked.

The cavity 100 includes an upper plate 110, a bottom plate 120, a rear plate 130, and two side plates 140. The upper plate 110 and the bottom plate 120 respectively form an upper surface and a lower surface of the cavity 100. In addition, the rear plate 130 forms the rear surface of the cavity 100, and the side plate 140 forms both side surfaces of the cavity 100.

Although not shown, the upper case 110 and the side plate 140 shield the outer case. Thus, the outer case will be formed to have a substantially U-shaped longitudinal section.

Therefore, the cavity 100 is substantially formed in a polyhedral shape in which the front surface is opened. In addition, the upper plate 110 and the bottom plate 120 substantially form the ceiling and the bottom surface of the cooking chamber 101, respectively. The rear plate 130 and the side plate 140 form a rear surface and both side surfaces of the cooking chamber 101.

The upper plate 110 is provided with an irradiation opening (not shown) and a porous portion (not shown). The irradiation opening is an entrance area in which the microwave generated from the magnetron 210 to be described later is irradiated into the cooking chamber 101. In addition, the porous part (not shown) is for transmitting energy, that is, light and heat, of the halogen heater 260 to be described later into the cooking chamber 101.

The rear plate 130 has a plurality of suction holes (not shown) and discharge holes (not shown). The suction hole is a place where air is sucked into the convection chamber to be described later in the cooking chamber 101, and the discharge hole is a place where air is discharged into the cooking chamber 101 from the inside of the convection chamber. In other words, the cooking chamber 101 and the convection chamber communicate with each other by the suction hole and the discharge hole.

In addition, any one of the side plate 140, in the present embodiment, a plurality of cooking chamber exhaust holes (not shown) are formed in the side plate 140 on the right side of the drawing in FIG. The cooking chamber exhaust hole serves as an outlet through which the air supplied into the cooking chamber 101 with the microwaves is discharged to the outside of the cooking chamber 101 through the irradiation opening. And one of the side plate 140, in this embodiment is a steam injection hole (not shown) is formed in the side plate 140 on the left side in the drawing in FIG. The steam spraying hole is for supplying steam generated by the steam generator 300 to be described later into the cooking chamber 101.

The front plate 150 and the back plate 160 are provided at the front and rear surfaces of the cavity 100, respectively. Substantially the front plate 150, the rear surface is fixed to the front end of the upper plate 110, the bottom plate 120 and the side plate 140. The back plate 160 is fixed to a part of the rear surface of the rear plate 130. The front plate 150 and the back plate 160 further extend outwardly of the cavity 100 in the up, down, left and right directions.

A communication opening 161 is formed at an upper end of the back plate 160 extending upward of the upper plate 110. The communication opening 161 communicates an upper portion of the cavity 100 with an electrical equipment chamber to be described later.

On the other hand, the back plate 160 is provided with a convection cover 163 and an insulator 165. The convection cover 163 is fixed to the rear surface of the rear plate 130 to form a convection chamber between the front surface and the rear surface of the rear plate 130. The insulator 165 is fixed to the rear surface of the rear plate 130 to shield the convection cover 163.

In addition, the back cover 170 is provided on the back of the back plate 160. The back cover 170 is fixed to the rear surface of the back plate 160 to shield a part of the back plate 160 including at least the communication opening 161. A plurality of inlets 171 are formed at lower ends of both sides of the back plate 160, respectively. The inlet 171 is an entrance area through which air is sucked into the cooking apparatus by driving the cooling fan 230 to be described later.

In addition, a base plate 180 is provided below the cavity 100. An upper surface of the base plate 180 is fixed to the lower ends of the front plate 150, the back plate 160, and the back cover 170. An exhaust port 181 is formed in the base plate 180 spaced apart from the lower end of the back plate 160 by a predetermined distance from the front side. The exhaust port 181 serves as an outlet through which the air flowing in the cooking apparatus is discharged to the outside by the driving of the cooling fan 230. The exhaust port 181 may be, for example, formed in a rectangular shape that is long left and right as a whole. In addition, condensed water formed by condensation of steam contained in the air discharged through the cooking chamber exhaust hole through the exhaust port 181 may be discharged to the outside. Although not shown, a leg (not shown) is provided at the bottom edge of the base plate 180.

In addition, a housing mounting portion 183 is formed on the base plate 180. The housing mounting portion 183 is formed by recessing a portion of the base plate 180 corresponding to the front of the exhaust port 181 upward. The housing mounting portion 183 is provided with a tank housing 400 to be described later. And a through hole (not shown) is formed at the rear end of the housing mounting portion 183.

An electrical equipment chamber is formed between the rear surface of the back plate 160, the front surface of the back cover 170, and the upper surface of the base plate 180. In the electric compartment, a plurality of electric parts 210 and 220 and a cooling fan 230 for cooling the electric component are installed.

More specifically, the magnetron 210 is installed in the electric room. The magnetron 210 oscillates the microwave irradiated into the cooking chamber 101. In addition, the high-voltage transformer 220 is installed in the electrical equipment room. The high voltage transformer 220 serves to apply a high voltage current to the magnetron 210. In addition, the upper surface of the cavity 100, that is, the upper plate 110 is provided with a wave guide 211 for guiding the microwaves generated from the magnetron 210 into the cooking chamber 101.

In addition, a cooling fan 230 is installed inside the electric compartment corresponding to the magnetron 210 and the high voltage transformer 220. The cooling fan 230 forms a flow of air circulating in the cooking chamber. The cooling fan 230 includes two fans and one fan motor for driving the fans. As the fan, a sirocco fan which sucks air in the axial direction and discharges it in the circumferential direction may be used. The fan is provided such that an intake portion formed at one end thereof in the axial direction is located adjacent to the intake port 171, and an exhaust portion formed at a portion of the circumference thereof faces upward. Accordingly, the cooling fan 230 sucks air through the inlet 171 and discharges the air upwards, that is, toward the electric chamber.

In addition, an air barrier 231 is installed in the electric compartment to prevent the air discharged from the cooling fan 230 from being resorbed into the cooling fan 230. The air barrier 231 may be substantially divided into an area in which the electric component including the magnetron 210 and the high voltage transformer 220 is installed and an area in which the cooling fan 230 is installed. have. In addition, an exhaust opening 233 corresponding to the exhaust portion of the cooling fan 230 is formed in the air barrier 231.

On the other hand, the upper heater 240 is installed above the cooking chamber 101. The upper heater 240 provides heat for radiant heating of the food in the cooking chamber 101. A siege heater may be used as the upper heater 240.

In addition, a convection heater 251 and a convection fan 253 are installed in the convection chamber. The convection heater 251 provides heat for convection heating of the food in the cooking chamber 101. The convection pan 253 forms a flow of air circulating through the cooking chamber 101 and the convection chamber. In more detail, when the convection fan is driven, air is circulated through the cooking chamber 101 and the convection chamber through the suction and discharge holes. Therefore, the heat of the convection heater 251 is convexed to the cooking chamber 101 by the convection fan 253. The convection fan 253 may operate according to whether the steam generator 300 is operated separately from the operation of the convection heater 251. This will be described later.

In addition, a convection motor 255 is installed in the electric room. The convection motor 255 provides a driving force for the operation of the convection fan 253. The convection motor 255 is also cooled by the cooling fan 230.

Meanwhile, a halogen heater 260 is installed on the upper plate 110. The halogen heater 260 provides light and heat to the inside of the cooking chamber 101 through the porous part. The halogen heater 260 is shielded by a reflector and a heater cover. In addition, the upper plate 110 is provided with a lamp 290 for illuminating the interior of the cooking chamber 101.

In FIG. 1, in which the cooking chamber exhaust hole is formed, an exhaust duct 270 is provided in the side plate 140 on the right side of the drawing. The exhaust duct 270 circulates the air discharged through the cooking chamber exhaust hole, that is, the cooking chamber 101 and guides the air to the exhaust port 181 to the outside of the cooking chamber 101. To this end, the exhaust duct 270 is formed in a polyhedral shape in which one surface is opened, and is installed in the side plate 140 to shield the cooking chamber exhaust hole. A discharge port 271 is formed at the bottom of the exhaust duct 270.

Meanwhile, the exhaust duct 270 condenses the steam contained in the air discharged to the outside of the cooking chamber 101 to form condensed water. To this end, the exhaust duct 270 is formed such that a flow cross section through which air discharged to the outside of the cooking chamber 101 flows is reduced. For example, since a part of the outlet 271 is shielded, the same effect as that of the reduction of the flow cross-sectional area can be expected. In this embodiment, the exhaust duct 270 is provided with a shielding rib 273 for shielding a part of the discharge port 271. The shielding rib 273 extends inclined downward toward the exhaust port 181 at one side of the exhaust duct 270 corresponding to the discharge port 271.

In addition, a guide duct 280 is provided on the bottom of the base plate 180. The guide duct 280 guides the air discharged to the outside of the cooking appliance through the exhaust port 181 in a predetermined direction. In the present embodiment, the guide duct 280 is formed in a polyhedral shape having approximately an upper surface and both side surfaces thereof to guide air discharged through the exhaust port 181 to both sides of the cooking appliance.

In addition, the guide duct 280 may collect condensed water that is condensed while the air discharged to the outside of the cooking chamber 101 flows through the exhaust duct 270. In this way, the condensed water collected in the guide duct 280 may be evaporated by the air discharged through the exhaust port 181, or may flow down through both end portions of the guide duct 280.

Meanwhile, a steam generator 300 is installed at the side plate 140 on the left side of the drawing, which corresponds to the opposite side of the exhaust duct 270. The steam generator 300 generates steam supplied to the cooking chamber 101.

The tank housing 400 is installed below the base plate 180, more specifically, in the housing mounting unit 183. The tank housing 400 may be formed in a polyhedral shape at least the front of the tank housing. In this embodiment, the tank housing 400 is formed in a polyhedral shape in which the front and top surfaces are opened.

In addition, a water supply tank 500 is installed to be withdrawn in and out of the tank housing 400. The steam water supplied to the steam generator 300 is stored in the water supply tank 500.

A water feed pump 600 is positioned between the bottom plate 120 and the base plate 180. The water supply pump 600 serves to pump the steam water stored in the water supply tank 500 to the steam generator 300.

The condensate tray 700 is installed at the front end of the base plate 180. The condensate tray 700 is for collecting the condensate discharged into the space between the front surface of the cavity 100, that is, the front surface of the front plate 150 and the rear surface of the door 800 to be described later. The front surface of the condensate tray 700 is preferably located on the same plane as the front surface of the door 800 in a state in which the door 800 shields the cooking chamber 101. On the front surface of the condensate tray 700, a through opening 701 through which the water supply tank 500 passing in and out of the tank housing 400 passes is formed.

The cooking chamber 101 is selectively opened and closed by the door 800. For example, the door 800 may be opened and closed in a pull-down manner in which an upper end rotates around a lower end thereof, thereby opening and closing the cooking chamber 101.

Hereinafter, with reference to the accompanying drawings, a steam generating device constituting a cooking apparatus according to the present invention will be described in more detail.

4 is a perspective view showing a steam generator constituting an embodiment of the present invention, Figure 5 is an exploded perspective view showing a steam generator constituting an embodiment of the present invention, Figure 6 constitutes an embodiment of the present invention 7 is an exploded perspective view showing a steam generator from another angle, FIG. 7 is a cross sectional view showing a steam generator constituting an embodiment of the present invention, and FIG. 8 is a longitudinal sectional view showing a steam generator constituting an embodiment of the present invention. .

First, referring to FIGS. 4 to 6, as described above, the steam generator 300 generates steam supplied into the cooking chamber 101. The steam generator 300 includes a heating chamber 310, a steam heater 360, a temperature sensor 370 and an overheat prevention unit 380.

More specifically, the heating chamber 310 is provided with a heating space 301 for storing steam water. The heating chamber 310 is fixed to one side of the cavity 100, that is, the side plate 140 on the left side of the drawing in FIG. 1. The heating chamber 310 includes a chamber body 320 and a chamber cover 330, and the heating space 301 is formed by the chamber body 320 and the chamber cover 330. The shape and size of the heating space 301 is not limited, but the heating space 301 is preferably formed in a relatively wide cross-sectional area in the vertical direction as compared with the cross-sectional area in the horizontal direction. This is to enhance the reheating efficiency of the steam generated by being heated by the steam heater 360. Detailed description thereof will be made later in the description of the steam heater 360.

The chamber body 320 may be, for example, formed in a polyhedral shape in which a portion of one surface thereof is opened. Of course, the shape of the chamber body 320 is not limited thereto. That is, the chamber body 320 may be formed in a different shape as long as it can form the heating space 301 together with the chamber cover 330.

A plurality of steam outlets 321 are formed in the chamber body 320. The steam outlet 321 is where steam is supplied to the cooking chamber 101. In this embodiment, the steam is discharged in the horizontal direction through the steam outlet 321 is supplied to the cooking chamber 101. The steam outlet 321 is formed at the upper end of the other surface of the chamber body 320 corresponding to the opposite side of the opening of the chamber body 320 and communicates with the heating space 301. The steam outlet 321 does not necessarily need to be located at the upper end of the other surface of the chamber body 320, but at least above the water supply port 331 to be described later. The steam outlet 321 is in communication with the steam injection hole formed in the cooking chamber 101 in a state where the heating chamber 310 is fixed to the side plate 140.

In addition, a second packing seating rib 322 and a steam guide rib 323 are provided on the other surface of the chamber body 320 in which the steam outlet 321 is formed. The second packing seating rib 322 is formed by protruding a part of the other surface of the chamber main body 320 into a closed curve in which at least the steam outlet 321 is located therein. The steam guide rib 323 protrudes from the inner surface of the second packing seating groove 324 corresponding to the outer circumference of the steam outlet 321.

Substantially, a second packing seating groove 324 is formed between the second packing seating rib 322 and the steam guide rib 323. The second packing member 350 to be described later is seated in the second packing seating groove 324.

In addition, the chamber body 320 is provided with a plurality of flow interference unit 325. The flow interference part 325 serves to interfere with the discharge of steam through the steam outlet 321. More specifically, the steam whose interference to the steam outlet 321 is interfered by the flow interference unit 325 can be reheated by the steam heater 360.

The flow interference part 325 protrudes from the inner surface of the chamber body 320 and substantially partitions a portion of the heating space 301 in a horizontal direction and partitions in a vertical direction. The flow interference part 325 includes a guide part 325A formed in a vertical direction and an interference part 325B extending in a horizontal direction from an upper end of the guide part 325A, respectively. Therefore, the flow interference portion 325 will be formed on the inner surface of the chamber body 320 to have a T-shaped or ┌ or 종단 longitudinal section as a whole. And the flow interference portion 325 is located on the inner surface of the chamber body 320 corresponding to the lower side of the steam outlet 321. In the present embodiment, the flow interference portion 325 is disposed in two rows up and down below the steam outlet 321. At this time, the guide portion 325A of the flow interference portion 325 constituting the upper and lower rows are positioned in regions not overlapping each other in the vertical direction, and the interference portion 325B of the flow interference portion 325 constituting the same row. Are spaced apart from each other in the horizontal direction.

7, the close contact rib 326 is provided on one surface of the chamber body 320 adjacent to the edge of the heating space 301. The close contact rib 326 is formed by protruding a part of one surface of the chamber body 320 to form a closed curve as a whole.

In addition, a first packing seating groove 327 is formed on one surface of the chamber body 320 corresponding to the outer side of the contact rib 326. The first packing seating groove 327 is where the first packing member 340 to be described later is seated. The first packing seating groove 327 is formed by recessing a portion of one surface of the chamber body 320 to form a closed curve as a whole so as to surround the close contact rib 326.

A mounting flange 328 is provided at one side of the rim surface of the chamber body 320. The mounting flange 328 extends to the outside of the chamber body 320 at one side of the rim surface of the chamber body 320. The mounting flange 328 is for installation of the overheat protection unit 380.

In addition, a contact portion 326 is formed on an inner surface of the chamber body 320. The contact part 326 increases the contact area between the steam water stored in the heating space 301 and the chamber main body 320 so that the heat of the steam heater 360 is stored in the heating space 301. It is intended to be more efficiently delivered to the water. In this embodiment, the contact portion 326 is formed by recessing a portion of the inner surface of the chamber body 320. However, the contact portion 326 may be formed by recessing a portion of the rear surface of the chamber cover 330.

The chamber cover 330 is fastened to the chamber body 320. At this time, the rear surface of the chamber cover 330 is in close contact with one surface of the opening of the chamber body 320, thereby substantially forming the heating space 301.

The chamber cover 330 is provided with a water supply port 331. In this embodiment, the water inlet 331 is located at the center of the chamber cover 330. However, the water inlet 331 may be located anywhere in the chamber cover 330 corresponding to an upper side and a lower side of the steam outlet 321 from the bottom surface of the heating space 301. However, the water inlet 331 supplies steam water to the inside of the heating space 301 in a direction that does not intersect at least with a direction in which steam is discharged through the steam outlet 321, preferably in a parallel direction. do.

The chamber cover 330 is provided with a water supply pipe 332. The water supply pipe 332 is for supplying steam water to the heating space 301. In this embodiment, the water supply pipe 332 is formed in a substantially L-shape. In addition, the water supply pipe 332 passes through one side of the chamber cover 330 corresponding to the steam outlet 321, for example, a central portion of the chamber cover 330. In this case, one end of the water supply pipe 332 is exposed to the inside of the heating space 301 through the water supply port 331 while the chamber cover 330 is fastened to the chamber body 320. (In fact, one end of the water supply pipe 332 may also be said to form the water supply port 331.) The other end of the water supply pipe 332 extends outside the heating space 301. The second water supply tube 603 to be described later is connected. In the present embodiment, the water supply pipe 332 is used to supply steam water into the heating space 301, but is not necessarily limited thereto. For example, only the water inlet 331 may be formed in the chamber cover 330, and a water supply tube for water supply may be connected to the water inlet.

The barrier unit 333 is provided on the rear surface of the chamber cover 330. The barrier unit 333 is supplied to the inside of the heating space 301 through the water supply pipe 332, the steam water falling by gravity, one side of the heating space 301, that is, the chamber body 320 or / And serves to prevent the phenomenon of jumping by hitting one side of the chamber cover 330. To this end, the barrier unit 333 is an inner surface of the chamber body 320 on the rear surface of the chamber cover 330 corresponding to the one end of the water supply pipe 332 exposed to the inside of the heating space 301. It extends toward the shielding part of the heating space 301 in the horizontal direction. Therefore, the falling distance of the steam water supplied to the inside of the heating space 301 through the water supply pipe 332 is substantially reduced by the barrier part 333, so that the phenomenon of falling steam water may be reduced. have.

In addition, an overflow prevention part 334 is provided on the rear surface of the chamber cover 330. The overflow preventing unit 334 serves to prevent the steam water stored in the heating space 301 from boiling over through the steam outlet 321. To this end, the overflow prevention part 334 is an interior of the heating space 301 corresponding to one end of the water supply pipe 332 and the flow interference portion 325 exposed to the interior of the heating space 301. To shield some.

The overflow preventing unit 334 substantially divides the heating space 301 into two regions. Hereinafter, a part of the heating space 301 corresponding to the lower portion of the overflow preventing part 334 is a saturation region 301A and a part of the heating space 301 corresponding to the upper part of the overflow preventing part 334. Is referred to as an overheating region 301B. The saturation region 301A and the superheating region 301B will be described like the steam heater 360.

Meanwhile, a close groove 335 is formed on the rear surface of the chamber cover 330. The close contact groove 335 is formed by recessing a portion of the rear surface of the chamber cover 330 to be joined to the close contact rib 326. Therefore, in the state in which the chamber cover 330 is fastened to the chamber body 320, the close contact rib 326 is inserted into the close contact groove 335.

Meanwhile, a sensor mounting part 336 is provided on the front surface of the chamber cover 330. In this embodiment, the sensor mounting portion 336 is formed in a substantially hexahedral shape protruding from the front surface of the chamber body 320, the water supply pipe 332 passes through the sensor mounting portion 336, but the sensor mounting portion ( The shape of 336 is not limited thereto. The sensor mounting part 336 has a sensor insertion hole 337 into which the temperature sensor 370 is inserted.

The first packing member 340 is provided between the chamber body 320 and the chamber cover 330. The first packing member 340 is for preventing leakage of steam water stored in the heating space 301. When the first packing member 340 is substantially seated in the first packing seating groove 327, when the rear surface of the chamber cover 330 is in close contact with one surface of the chamber body 320, the chamber It is in contact with the rear surface of the main body 320.

Meanwhile, the second packing member 350 is seated in the second packing seating groove 324. The second packing member 350 is a saturated steam or superheated steam supplied to the cooking chamber 101 through the steam outlet 321 and the steam injection hole between the side plate 140 and the chamber body 320. It prevents water leakage through gaps. The second packing member 350 is formed in a shape corresponding to the second packing seating groove 324. In addition, a communication hole 351 corresponding to the steam guide rib 323 is formed in the second packing member 350. Therefore, in a state in which the second packing member 350 is seated in the second packing seating groove 324, the edge of the second packing member 350 is in close contact with the second packing seating rib 322. The steam guide rib 323 is inserted into the communication hole 351.

The steam heater 360 generates steam supplied to the cooking chamber 101 by heating steam water stored in the heating space 301. Referring to FIG. 8, for this purpose, the steam heater 360 is inserted into the chamber body 320 so as to be positioned adjacent to both side ends and the bottom of the heating space 301, and is formed in a U shape. The heat of the steam heater 360 is transferred to the steam water stored in the heating space 301 through the heating chamber 310, that is, the chamber body 320 and the chamber cover 330.

In addition, the steam heater 360 may form a saturated steam by heating the steam water stored in the heating space 301, and may form an overheated steam by heating the saturated steam. More specifically, a part of the steam heater 360 adjacent to the saturation region 301A generates saturation steam by heating steam water. A portion of the steam heater 360 adjacent to the superheated region 301B reheats the generated saturated steam to generate an overheated steam. Of course, the saturation steam generated by the steam heater 360 is supplied to the cooking chamber 101 according to the amount of steam water stored in the heating space 301, the output of the steam heater 360, or the like. The overheated steam generated by the reheating may be supplied to the cooking chamber 101.

The temperature sensor 370 is inserted into the sensor mounting portion 336, more specifically, the sensor insertion hole 337. The temperature sensor 370 detects the temperature of the steam water stored in the heating space 301, substantially, the temperature of the heating chamber 310. As the temperature sensor 370, for example, a thermistor may be used.

The overheat prevention unit 380 is mounted to the mounting flange 328. The overheat prevention unit 380 serves to prevent overheating of the steam heater 360. For example, the overheat prevention unit 380 supplies the steam heater 360 when the temperature of the steam water stored in the heating space 301 detected by the temperature sensor 370 is greater than or equal to a preset safety temperature. By cutting off the power, the overheating of the steam heater 360 is prevented. As the overheat protection unit 380, for example, a thermostat may be used.

Hereinafter, a tank housing, a water supply tank, and a water supply pump constituting an embodiment of a cooking appliance according to the present invention will be described in detail with reference to the accompanying drawings.

9 is an exploded perspective view showing a tank housing, a water supply tank and a water supply pump constituting an embodiment of the present invention.

9, the tank housing 400, the water supply tank 500, and the water supply pump 600 serve to supply steam water to the heating chamber 310. In other words, when the water supply tank 500 is inserted into the tank housing 400 while the steam water is stored, the steam water stored in the water supply tank 500 by the water supply pump 600 is heated in the heating chamber. It is supplied to the heating space 301 of (310).

More specifically, the through hole 401 is formed on the rear surface of the tank housing 400. The through hole 401 is where the tank pipe 423 to be described later penetrates. In addition, a rear side of the tank housing 400 corresponding to the rear of the through hole 401 is provided with a connecting tube 403 and a third packing member 405. The connecting pipe 403 serves to connect the tank pipe 423 and the first water supply tube 601. The connection pipe 403 extends into the space between the bottom plate 120 and the base plate 180 through the through hole of the housing mounting portion 183 in a state fixed to the rear surface of the tank housing 400. do. The third packing member 405 serves to prevent leakage of steam water through a gap between the tank pipe 423 and the connecting pipe 403.

The water supply tank 500 includes a tank body 410, a tank cap 420, and a tank handle 430. The tank body 410 and the tank cap 420 is formed with a storage space 401 in which steam water supplied to the heating chamber 310 is stored.

The tank body 410 is formed in the shape of a polyhedron having an approximately upper surface opened. In the present embodiment, the tank body 410 is formed in a flat hexahedral shape in which the upper surface is opened, but the shape of the tank body 410 is not limited thereto. However, the tank body 410 should be formed in a shape and size that can be withdrawn into and out of the tank housing 400.

The tank cap 420 is detachably coupled to the tank body 410 to shield the opened upper surface of the tank body 410. The tank cap 420 is provided with a water supply hole 421 for supplying steam water to the water storage space 401. The water supply hole 421 is selectively opened and closed by a water supply cap 423.

In addition, the tank cap 420 is provided with a tank pipe 423. One end of the tank pipe 423 is located in the storage space 401 to be spaced apart from the bottom surface of the tank body 410 by a predetermined distance. The other end of the tank pipe 423 extends to the rear of the tank cap 420. The tank pipe 423 is inserted into the connection pipe 403 through the through hole 401 in a state where the water supply tank 500 is mounted inside the tank housing 400.

The tank handle 430 is fixed to the front of the tank body 410. The tank handle 430 is a part that the user grips by hand to withdraw the water supply tank 500 into and out of the tank housing 400. In a state in which the water supply tank 500 is mounted inside the tank housing 400, the front surface of the tank handle 430 is on the same plane as the front surface of the condensate tray 700 and the door 800. Can be located.

The water feed pump 600 is connected by the connecting pipe 403 and the first water supply tube 601, and is connected by the water supply pipe 332 and the second water supply tube 603. Therefore, when the feed water pump 600 is operated, the steam water stored in the feed water tank 500 is pumped and supplied to the heating chamber 310.

Hereinafter, a configuration of an embodiment of a cooking appliance according to the present invention will be described in detail with reference to the accompanying drawings.

10 is a schematic view showing the configuration of an embodiment of the present invention.

Referring to FIG. 10, the controllable components for cooking of the food in the cooking chamber 101 may include an upper heater 240, a halogen heater 260, a convection heater 251, a convection fan 253, and a magnetron ( 210, the steam heater 360 and the feed water pump 600 may be mentioned. In addition, the temperature sensor 370 and the overheat prevention unit 380 are used to prevent overheating of the steam heater 360. Such various components are controlled by the control unit (C). When the upper heater 240, the halogen heater 260, the convection heater 251 and the magnetron 210 is used alone to cook food in the cooking chamber 101, that is, steam into the cooking chamber 101 If this is not supplied, it is not the object of interest of the present invention. Hereinafter, a description will be given focusing on the function of the controller C when steam is supplied to the cooking chamber 101.

First, when the steam heater 360 operates to supply steam to the cooking chamber 101, the controller C operates at least one of the upper heater 240 and the halogen heater 260. That is, the halogen heater 260, in particular the halogen heater 260 through the porous portion for the steam supplied to the cooking chamber 101 to transfer the light and heat of the halogen heater 260 to the cooking chamber 101. This is to prevent the phenomenon of being delivered to the encapsulation portion. In this case, at least one operation time of the upper heater 240 and the halogen heater 260 overlaps at least part of the operation time of the steam heater 360. In addition, at least one of the upper heater 240 and the halogen heater 260 is terminated at least simultaneously with or after the operation of the steam heater 360. Therefore, steam is evaporated by the operation of at least one of the upper heater 240 and the halogen heater 260, thereby preventing the steam from being transferred to the halogen heater 260 through the porous part.

Meanwhile, when the steam heater 360 is operated to supply steam to the cooking chamber 101, the controller C operates the convection motor 255 irrespective of the operation of the convection heater 251. . This is to allow the steam supplied to the cooking chamber 101 to circulate the cooking chamber 101 evenly. That is, the convection fan 253 is operated by the convection motor 255 to circulate air in the cooking chamber 101 to substantially circulate steam. In this case, an operation time of the convection motor 255 overlaps at least a part of the operation time of the steam heater 360. In addition, the convection motor 255 ends at least simultaneously with or after the end of the operation of the steam heater 360. Of course, when the convection heater 251 is used to cook the food in the cooking chamber 101, the convection heater 251 will also operate.

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

First, the cooking of a food using steam in an embodiment of the cooking appliance according to the present invention will be described.

In the case of cooking using steam, at least one of various heating sources is operated to heat the food in the cooking chamber 101 to supply energy into the cooking chamber 101. The steam generator 300 is operated to supply steam to the cooking chamber 101.

In addition, when the steam generator 300 is operated, at least one of the upper heater 240 and the halogen heater 260 of the heating source is operated. This is to prevent a phenomenon in which steam leaking through the porous part is transferred to the encapsulation part of the halogen heater 260. In addition, regardless of the operation of the convection heater 251, the convection motor 255 for driving the convection fan 253 operates to circulate air in the cooking chamber 101. This is to allow the steam supplied to the cooking chamber 101 to be evenly spread in the cooking chamber 101.

On the other hand, in order to supply steam to the cooking chamber 101, first the water supply pump 600 is operated to supply the steam water stored in the water supply tank 500 to the inside of the heating chamber 310, that is, the heating space 301. At this time, the steam water stored in the water supply tank 500 is supplied to the heating space 301 through the water supply port 331 by the operation of the water supply pump 600. By the way, the steam water supplied to the heating space 301 through the water supply port 331, the barrier portion 333 is located below the water supply port 331 before hitting the bottom surface of the heating space 301. Bumped into Therefore, a phenomenon in which the spring water supplied to the heating space 301 through the water inlet 331 is excessively splashed by hitting the bottom surface of the heating space 301 may be prevented.

Meanwhile, the steam heater 360 operates simultaneously with the supply of the steam water to the heating space 301 by the feed water pump 600 to heat the steam water stored in the heating space 301. At this time, the heat of the steam heater 360 is transmitted to the steam water stored in the heating space 301 through the heating chamber 310. In the present embodiment, the contact area of the heating chamber 310 and the steam water is increased by the contact portion 326 formed on the inner surface of the heating chamber 310 corresponding to the heating space 301, so that the steam heater Heat of 360 is more efficiently transferred to the steam water stored in the heating space 301. In addition, the phenomenon in which the steam water stored in the heating space 301 heated by the steam heater 360 boils over and discharged through the steam outlet 321 is prevented by the overflow preventing unit 334.

The steam heater 360 operates to heat the steam water stored in the heating space 301 to generate a saturated steam and an overheated steam. In more detail, in the lower portion of the heating space 301 partitioned by the overflow preventing part 334, that is, in the saturation region 301A, saturation steam is generated by heating steam water, and the heating space 301 is provided. In the upper portion of the overheating region 301B, overheating steam is generated by heating of the saturation steam transmitted from the saturation region 301A. At this time, the saturated steam or the superheated steam in the superheated region 301B is more efficiently heated by the steam heater 360 because the flow is interrupted by the flow interference unit 325.

The steam generated (saturation and overheating) is supplied to the cooking chamber 101 through the steam outlet 321 and the steam injection hole. In this case, the steam discharged through the steam outlet 321 is prevented from leaking through the gap between the side surface of the cavity 100 and one surface of the heating chamber 310 by the second packing member 350.

Therefore, efficient cooking of the food using steam in the cooking chamber 101 can be achieved. For example, in the process of cooking food in the cooking chamber 101 by the heating source, the phenomenon that the food is dried by evaporation of moisture may be prevented.

Next, the flow of air in the embodiment of the cooking appliance according to the present invention will be described in more detail with reference to the accompanying drawings.

11 is a rear view showing the flow of air according to an embodiment of the cooking appliance according to the present invention, Figure 12 is a plan view showing the flow of air according to an embodiment of the present invention, Figure 13 is an embodiment of the present invention FIG. 14 is a left side view showing the flow of air in the embodiment of the present invention, and FIG. 15 is a plan view showing the flow of air according to the embodiment of the present invention.

First, referring to FIG. 11, when the cooling fan 230 is driven, a space between the back plate 160 and the back cover 170 inside the cooking appliance, more specifically, through the inlet 171 (described below). Is called 'first euro' for convenience. The air sucked into the cooking appliance is discharged from the cooling fan 230 and moves upward. At this time, the phenomenon that the air discharged from the cooling fan 230 is resorbed to the cooling fan 230 is prevented by the air barrier 231.

The air discharged from the cooling fan 230 cools various electric parts, that is, the magnetron 210 and the high pressure transformer 220 while flowing in the first flow path. A portion of the air cooled by the magnetron 210 and the high-pressure transformer 220 is guided by the waveguide 211 which transmits the microwaves generated by the magnetron 210 to the inside of the cooking chamber 101. It is transmitted to the inside of the cooking chamber 101 through the cooking chamber suction port.

Referring to FIG. 12, the air delivered to the inside of the cooking chamber 101 is circulated inside the cooking chamber 101 and discharged to the outside of the cooking chamber 101 through the cooking chamber exhaust. The air discharged to the outside of the cooking chamber 101 flows through the space between the side plate 140 and the exhaust duct 270 (hereinafter referred to as “second channel” for convenience of description). The air flowing through the second flow passage is substantially guided downward by the exhaust duct 270 and is discharged through the outlet 271. At this time, by the shielding rib 273 provided on the discharge port 271, the flow cross-sectional area of the second channel is substantially reduced, so that steam contained in the air flowing through the second channel is condensed to generate condensed water. . Air and condensed water discharged through the discharge port 271 flows into a fourth flow path to be described later.

Meanwhile, referring to FIGS. 13 and 14, a portion of the air cooled by the magnetron 210 and the high-pressure transformer 220 is spaced between the upper surface of the upper plate 110 and the bottom of the outer case through the communication opening 161. You are guided to. And the air guided to the space between the upper surface of the upper plate 110 and the bottom surface of the outer case, hit the rear surface of the front plate 150 between the outer surface of the side plate 140 of both sides and the side of the outer case You are guided to space. Hereinafter, the space between the upper surface of the upper plate 110 and the bottom surface of the outer case, and the outer surface of the side plate 140 and the side surface of the outer case is referred to as a third euro. The air flowing through the third flow passage cools the encapsulation portion of the halogen heater 260, particularly the halogen heater 260, installed in the upper plate 110, and the steam generator installed in the side plate 140. Cool 300).

Meanwhile, referring to FIG. 15, air and condensed water flowing through the second and third flow paths are spaces between the bottom plate 120 and the base plate 180 (hereinafter referred to as 'fourth flow path' for convenience of description). Is passed. In addition, the air and the condensed water delivered to the fourth channel are discharged to the outside of the cooking appliance through the exhaust port 181. The air discharged through the exhaust port 181 is guided to flow toward both sides of the cooking appliance by the guide duct 280. In addition, the condensed water discharged through the exhaust port 181 may be collected in the guide duct 280 and evaporated by the air discharged through the exhaust port 181.

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.

According to the steam generator and the cooking apparatus including the same according to the present invention configured as described above it can be expected the following effects.

First, in the present invention, the cooking of the food is made in the cooking chamber using steam generated by the steam generator. Therefore, by supplying the cooking steam in the cooking process, the food can be cooked more efficiently.

In addition, in the present invention, the steam supplied to the cooking chamber is discharged together with the air for ventilating the cooking chamber is condensed while flowing the exhaust duct is discharged in the form of condensate. Therefore, the phenomenon in which the steam supplied to the cooking chamber is discharged to the outside of the cooking chamber and the various electrical components are damaged may be minimized.

1 is a perspective view showing an embodiment of a cooking appliance according to the present invention.

Figure 2 is a perspective view of an embodiment of the present invention from another angle.

Figure 3 is an exploded perspective view showing an embodiment of the present invention.

Figure 4 is a perspective view showing a steam generating device constituting an embodiment of the present invention.

5 is an exploded perspective view showing a steam generator constituting an embodiment of the present invention.

Figure 6 is an exploded perspective view showing a steam generator constituting an embodiment of the present invention from another angle.

Figure 7 is a cross-sectional view showing a steam generator constituting an embodiment of the present invention.

Figure 8 is a longitudinal sectional view showing a steam generating device constituting an embodiment of the present invention.

Figure 9 is an exploded perspective view showing a tank housing, a water supply tank and a water supply pump constituting an embodiment of the present invention.

10 is a schematic view showing a configuration of an embodiment of the present invention.

11 is a rear view showing the flow of air according to an embodiment of the cooking appliance according to the present invention.

12 is a plan view showing the flow of air according to an embodiment of the present invention.

13 is a right side view showing the flow of air according to an embodiment of the present invention.

Figure 14 is a left side view showing the flow of air in an embodiment of the present invention.

15 is a plan view showing the flow of air according to an embodiment of the present invention.

Claims (26)

Cavity is provided with a cooking chamber; At least one electrical component installed in the cavity; A steam generator installed in the cavity and supplying steam to the cooking chamber; A cooling fan for flowing air for cooling the electric component and circulating the cooking chamber; And A duct suctioned into the cooking chamber to circulate the cooking chamber, guide air discharged to the outside of the cooking chamber, and condense steam contained in the air discharged to the outside of the cooking chamber; Cooking appliance comprising a. The method of claim 1, The air flowing by the cooling fan is sucked into the interior of the cooking chamber with the microwave. The method of claim 1, The cooling fan is installed in the lower rear portion of the cavity. The method of claim 1, The electronic component includes a magnetron and a high voltage transformer installed at least on the rear surface of the cavity. The method of claim 1, The electronic component includes a fan motor that provides a driving force for circulating air in the cooking chamber. The method of claim 1, The steam generator is installed on one side of the cavity is cooled by the air flowing by the cooling fan. The method of claim 1, The duct is a cooking device for guiding the air discharged to the outside of the cooking chamber downward. The method of claim 1, The duct is a cooking appliance installed on one side of the cavity corresponding to the opposite side of the steam generator. The method of claim 1, The duct is a cooking appliance that the flow cross-sectional area is reduced. The method of claim 9, Reduction of the flow cross-sectional area of the duct, the cooking appliance is a portion of the air outlet of the duct is discharged to the outside of the cooking chamber guided to the outside of the duct is shielded. The method of claim 1, In the duct, An air outlet through which the air discharged to the outside of the cooking chamber and guided by the duct is discharged to the outside of the duct; And A shielding rib shielding a part of the air discharge port; Cooking apparatus is provided. The method of claim 11, The shielding rib is formed on a base plate provided below the cavity, and is inclined downward toward an exhaust port through which air is discharged to the outside. The method of claim 1, The cooking appliance discharged to the outside of the cooking chamber and the condensed water formed by condensation of steam by the duct is discharged to the outside through the exhaust port formed in the base plate provided in the lower portion of the cavity. The method of claim 13, And a guide duct provided below the exhaust port, to guide air discharged through the exhaust port, and to collect condensed water discharged through the exhaust port. The method of claim 14, The guide duct guides the air discharged through the exhaust port to both sides of the cavity. Cavity is provided with a cooking chamber; Electrical components installed in the cavity; A cooling fan installed in the cavity to flow air; And a steam generator supplying steam to the cooking chamber. In the cooking appliance comprising: A first flow path through which the air sucked into the inside by the driving of the cooling fan flows; A second flow passage through which a portion of the air flowing through the first flow passage flows; A third flow passage through which the rest of the air flowing through the first flow passage flows; And A fourth flow passage through which the air flowing through the second and third flow passages flows and is discharged to the outside; Including, And a steam contained in the air flowing through the first flow path, sucked into the cooking chamber, circulated through the cooking chamber, and discharged to the outside of the cooking chamber to flow the second flow path to condense and flow into the fourth flow path. The method of claim 16, The first flow path is formed in the rear end of the cavity, the cooking appliance is in communication with the intake port through which the air is sucked by the cooling fan. The method of claim 16, At least a portion of the electrical component is located on the first flow path cooking apparatus. The method of claim 16, Steam contained in the air discharged to the outside of the cooking chamber is condensed while flowing in the second flow path by reducing the flow cross-sectional area of the second flow path. The method of claim 16, The second flow path, the cooking appliance is formed in the interior of the duct installed on one side of the cavity. The method of claim 20, The duct is cooker is formed so that the flow cross-sectional area of the second flow path is reduced. The method of claim 21, The decrease in the flow cross-sectional area of the second flow path, the cooking apparatus is a portion of the exhaust port of the duct is shielded. The method of claim 16, The third flow path, the cooking appliance is formed on the upper surface and one side of the cavity. The method of claim 16, The cooking appliance in which a part of the electric component is located on the third passage. The method of claim 16, The fourth flow passage is formed in the lower portion of the cavity, the cooking appliance in communication with the exhaust port formed in the base plate provided in the lower portion of the cavity. The method of claim 25, And a guide duct through which the air discharged through the exhaust port flows through the fourth flow passage, and the condensate discharged through the exhaust port is collected.

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