KR100938381B1 - A microwave oven - Google Patents

Abstract

The present invention relates to a microwave oven. In the present invention, a plurality of components are cooled by an air flow formed by one fan assembly, and a phenomenon in which the air flow formed by the fan assembly is re-introduced into the fan assembly is prevented by the air barrier. Therefore, according to this invention, there exists an advantage which can cool a product with a simpler structure.

Microwave Oven, Fan Assembly, Air Guide

Description

Microwave oven {A microwave oven}

The present invention relates to a microwave oven, and more particularly to a microwave oven capable of cooling the components more smoothly.

In general, a microwave oven is a cooking apparatus for cooking food using microwaves and / or heater heat. Such microwave ovens are equipped with electrical components for generating microwaves and / or heaters for generating heater heat. And a microwave oven is provided with the cooling system for cooling the said electric component or / and a heater.

However, a cooling system provided in a conventional microwave oven does not efficiently cool the electric component and / or the heater. Therefore, a problem arises in that the operation reliability and efficiency of the microwave oven are deteriorated.

The present invention is to solve the conventional problems as described above, the object of the present invention is to provide a microwave oven configured to cool the parts more efficiently.

According to an embodiment of the present invention for achieving the object as described above, the present invention is a cavity provided with a cooking chamber; An electric component installed on an upper surface of the cavity and including at least a magnetron; An upper heater spaced apart from the electric component on an upper surface of the cavity; A convection motor installed at the rear of the cavity; A fan installed at one end of the upper surface of the cavity and forming an air flow flowing toward the other end of the upper surface of the cavity; A barrier member provided on an upper surface of the cavity to prevent the airflow from being re-inhaled into the fan; And a partition member that divides the air flow formed by the fan into an air flow for cooling the electric component and a convection motor and an air flow for cooling the upper heater. It includes.
According to another embodiment of the present invention, there is provided a cooking chamber, a cavity having an electrical equipment chamber on its upper surface; Electric parts and an upper heater installed in the electric room; A fan assembly installed at one end of the electrical equipment room, the fan assembly including first and second vent fans forming airflows which are partitioned from each other and flowing toward the other end of the electrical equipment room; And a barrier member provided in the electric compartment and preventing the airflow from being re-introduced into the first and second vent fans. And an airflow formed by the first vent fan cools the electric component, and the airflow formed by the second vent fan cools the upper heater.

delete

According to the microwave oven according to the present invention as described above, there is an advantage that the components can be cooled more efficiently.

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

1 is an exploded perspective view showing an embodiment of a microwave oven according to the present invention, Figure 2 is a rear view showing a back of an embodiment of the present invention.

Referring to this, the upper plate 110, the bottom plate 120, and the inner plate 130 are respectively formed on the upper and lower surfaces, the bottom surface and both sides of the cavity 100 of the microwave oven. The inner plate 130 is formed in a U-shape that is opened toward the front as a whole and includes a rear portion and a pair of side portions.

The front plate 140 and the back plate 150 are coupled to the front and rear ends of the cavity 100, respectively. The front plate 140 and the back plate 150 substantially form the front and rear appearance of the microwave oven. The front plate 140 and the back plate 150 are formed in a rectangular plate shape extending outward from the upper surface of the upper plate 110, the bottom surface of the bottom plate 120, and the side surface of the inner plate 130, respectively. do.

In addition, the base plate 160 is coupled to the lower portion of the cavity 100. Front and rear ends of the base plate 160 are fixed to the lower end of the front plate 140 and the lower end of the back plate 150. In addition, the base plate 160 is spaced apart from the bottom plate 120 by a predetermined distance in a state coupled to the lower portion of the cavity 100.

The outer case 170 is coupled to the upper and both sides of the cavity 100. The outer case 170 includes an upper surface portion and a pair of side portions, and is formed in a c-shape that is open downward. And while the outer case 170 is coupled to the upper and both sides of the cavity 100, the upper surface portion and the side portion of the outer case 170, respectively, the side portion of the upper plate 110 and the inner plate 130 Spaced apart from the predetermined distance.

Meanwhile, the cooking chamber 101 is provided inside the cavity 100. Substantially, the upper plate 110, the bottom plate 120, and the inner plate 130 and the rear and side portions of the ceiling surface, the bottom surface, the rear surface, and both sides of the cooking chamber 101 are formed. The cooking chamber 101 is a place where food is cooked by microwaves and / or heater heat.

An electrical equipment chamber 103 is provided in the space between the upper plate 110 and the upper surface portion of the outer case 170. The electric component chamber 103 is provided with an electric heater component 200 for generating microwaves and an upper heater assembly 200 for generating heater heat, and a fan assembly 300 for cooling the electric components and the upper heater assembly 200. do. The electric component includes a magnetron 104 and a high voltage transformer 105.

The upper heater assembly 200 is a portion for generating a heater heat for radiant heating food in the cooking chamber 101. The upper heater assembly 200 includes at least one heater (not shown), a heater cover 210 for shielding the heater, and a connection duct 220 connecting the heater cover 210 and the fan assembly 300. Include. One end of the heater cover 210 is in communication with the suction opening 151 to be described below. The connection duct 220 connects the other end of the heater cover 210 to the fan assembly 300.

The fan assembly 300 is installed long in the front and rear at the left end of the electric chamber 103 corresponding to the left side of the drawing of the upper heater assembly 200. The fan assembly 300 includes a fan motor 310 and a pair of vent fans 320 and 330 respectively provided at both sides of the fan motor 310. Hereinafter, the one of the vent pans 320 and 330, which is relatively rearward in the drawing, is referred to as the first fan 320 and the one that is relatively forward is referred to as the second fan 330. The first fan 320 sucks indoor air to cool the electric component including the magnetron 104, the high-pressure transformer 105, the lower heater 780 and the turntable motor 790 to be described, and the cooking chamber 101. It forms an air flow to discharge oil or water vapor in the inside. The second fan 330 forms an airflow for cooling the upper heater assembly 200, and an airflow for cooling the lower heater 780 and the turntable motor 790.

In addition, the electric chamber 103 is provided with a first air barrier 410. The first air barrier 410 serves to prevent the air discharged from the fan assembly 300 from being sucked back into the fan assembly 300, more specifically, the second fan 330. . To this end, the first air barrier 410 is provided between the front end of the electric chamber 103, that is, between the front plate 140 and the second fan 330. Accordingly, in the drawing of the electrical component chamber 103 in which the fan assembly 300 is installed by the first air barrier 410, the left end portion and the electrical component and the upper heater assembly 200 are installed. The remaining part of 103 is partitioned.

Upper and lower ends of the front plate 140 are provided with a plurality of inlets 141 and outlets 143, respectively. The inlet 141 and the outlet 143 of the front plate 140 are formed by cutting the upper end or the lower end of the front plate 140 into a predetermined shape. The inlet 141 and the outlet 143 of the front plate 140 serve as an inlet or outlet through which the air is intaken and exhausted by the fan assembly 300, respectively.

Meanwhile, a suction grill 600 is provided at a front end of the upper plate 110 corresponding to the rear of the suction port 141 of the front plate 140. The suction grill 600 is formed in the shape of a flat hexahedron having an approximately front surface opening. The suction grill 600 guides the indoor air sucked through the suction port 141 of the front plate 140 to the fan assembly 300. In addition, the suction grill 600 prevents a phenomenon in which foreign matter is inserted into the outside and prevents a phenomenon in which the heater heat of the upper heater assembly 200 is transferred to the room. To this end, a plurality of suction holes 610 are formed on the front and upper surfaces of the suction grill 600.

The control bracket 180 is provided at the top of the front plate 140. The control bracket 180 is formed in a plate shape having a width corresponding to the left and right widths of the front plate 140. At this time, the front surface of the control bracket 180 is located on the same plane as the front surface of the front plate 140.

And the control panel 190 is provided on the front of the control bracket 180. The control panel 190 receives various operation signals for the operation of the microwave oven and displays various information regarding the operation of the microwave oven. The control panel 190 shields the upper portion of the suction port 141 of the front plate 140 and the suction hole 610 of the suction grill 600 in a state in which the control bracket 180 is installed.

In addition, the control panel 190 is cooled by the indoor air sucked through the suction hole 610 and the suction opening 620 of the suction port 141 and the suction grill 600 of the front plate 140. The control panel In order to further increase the cooling efficiency of the 190, a heat sink (not shown) may be provided on the rear surface of the control panel 190 adjacent to the suction hole 610 and the suction opening 620 of the suction grill 600. Can be.

Meanwhile, referring to FIGS. 1 and 2, suction openings 151 and discharge openings 157 are provided at upper and lower ends of the back plate 150. The suction opening 151 and the discharge opening 157 of the back plate 150 are partially cut off of the back plate 150 corresponding to an upper portion of the upper plate 110 or a lower portion of the bottom plate 120. Is formed. The suction opening 151 of the back plate 150 serves as an entrance area through which the air cooled by the upper heater assembly 200 and the air cooled by the high pressure transformer 105 are sucked. Hereinafter, a part of the suction opening 151 of the back plate 150 which communicates with the electric chamber 103 corresponding to immediately after the high voltage transformer 105 is referred to as the electric chamber suction opening 153, and the upper portion A part of the suction opening 151 of the back plate 150 that communicates with the heater assembly 200 is called a heater suction opening 155. The outlet opening 157 of the back plate 150 communicates with the space between the bottom plate 120 and the base plate 160 and is sucked through the inlet opening 151 of the back plate 150. Acts as an exit through which

Also, referring to FIG. 2, a convection chamber 710 is provided at the rear of the back plate 150 corresponding to the rear surface of the cooking chamber 101. The convection chamber 710 is in communication with the cooking chamber 101. The convection chamber 710 is formed by the back plate 150 and a convection cover 720 provided on the back surface of the back plate 150. The convection cover 720 is formed in the shape of a flat hexahedron having an approximately front surface opening.

In addition, a convection heater 730 and a convection fan 740 are installed in the convection chamber 710. As the convection heater 730, a sheath heater that is bent in a ring shape as a whole may be used. The convection fan 740 is located inside the convection heater 730 and rotates about a horizontal axis horizontally in front and rear of the convection heater 730. The convection fan 740 sucks air into its central portion and discharges it in the radial direction.

The convection heater 730 and the convection fan 740 are for convection heating of food in the cooking chamber 101. That is, when the convection fan 740 is driven, the food in the cooking chamber 101 is convection by air circulating in the cooking chamber 101 and the convection chamber 710 in a state that includes the heater heat of the convection heater 730. Heated.

A convection motor 760 is installed on the rear surface of the convection cover 720 corresponding to the outside of the convection chamber 710. The convection motor 760 drives the convection fan 740. The convection motor 760 cools the electric component and is cooled by the air sucked through the suction opening 151 of the back plate 150.

The back plate 150 is provided with a back cover 770. The back cover 770 is formed to have a size capable of shielding the suction opening 151 and the discharge opening 157 of the convection cover 720 and the back plate 150. Accordingly, the air sucked through the suction opening 151 of the back plate 150 is discharged through the discharge opening 157 of the back plate 150 between the back plate 150 and the back cover 770. The flow path of is formed.

A second air barrier 420 is provided between the back plate 150 and the back cover 770. The second air barrier 420 cools a flow path through which air cooling the upper heater assembly 200 flows in the space between the back plate 150 and the back cover 770 and the high pressure transformer 105. It serves to partition the flow path through which air flows. At this time, the convection motor 760 is located on a flow path through which air cooled the high-pressure transformer 105 flows.

Referring to FIG. 1, a wave guide 430 is provided at a side portion on the right side of the inner plate 130. The wave guide 430 serves to guide the air cooled by the magnetron 104 and the microwaves generated by the magnetron 104 to the inside of the cooking chamber 101.

In addition, a discharge duct 440 is provided at a side of the left side of the inner plate 130 corresponding to the opposite side of the wave guide 430. The discharge duct 440 is guided into the cooking chamber 101 by the wave guide 430 to guide the air passing through the cooking chamber 101 downward. To this end, the discharge duct 440 may be formed in a hexahedral shape whose bottom surface is opened.

Meanwhile, a lower heater 780 (see FIG. 4) is provided in the space between the bottom plate 120 and the base plate 160. The lower heater 780 generates a heater heat for radiant heating of food in the cooking chamber 101. As the lower heater 780, a ceramic heater may be used. The lower heater 780 is cooled by air flowing downward by the first and fan assemblies 300 and 300.

In addition, a turntable motor 790 (see FIG. 4) is provided in a space between the bottom plate 120 and the base plate 160 corresponding to the front of the lower heater 780. The turntable motor 790 serves to provide a driving force for rotation of a turntable (not shown) rotatably installed on the bottom surface of the cooking chamber 101. In addition, the turntable motor 790 is also cooled by air flowing downward by the fan assembly 300, similarly to the lower heater 780.

Referring back to FIG. 1, a door 820 is provided to selectively open and close the cooking chamber 101. The door 820 opens and closes the cooking chamber 101 in a pull-down manner in which an upper end rotates up and down about a hinge 821 provided at a lower end of the rear surface of the door 820. The upper end of the door 820 is spaced apart from the lower end of the control panel 190 by a predetermined distance. The front surface of the door 820 is located on the same plane as the front surface of the control panel 190.

Hereinafter, the flow of air in an embodiment of the microwave oven according to the present invention will be described in more detail with reference to the accompanying drawings.

Figure 3 is a plan view showing the flow of air in the embodiment of the microwave oven according to the present invention, Figure 4 is a side view showing the flow of air in an embodiment of the present invention.

First, referring to FIG. 3, when the first fan 320 of the first fan assembly 300 is driven, the inlet 141 of the front plate 140 and the intake hole 610 of the suction grill 600 are driven. Indoor air is sucked into the intake portion of the first fan 320. As such, the indoor air sucked into the first fan 320 is discharged through the exhaust part of the first fan 320 to cool the magnetron 104 and the high pressure transformer 105. A portion of the air cooled by the magnetron 104 and the high-pressure transformer 105 flows through the waveguide 430 in a state including the microwave generated from the magnetron 104 and is delivered to the inside of the cooking chamber 101. The air delivered to the inside of the cooking chamber 101 is guided by the discharge duct 440 in the state of containing oil and water vapor generated in the process of cooking food and is guided to the outside of the cooking chamber 101. And the remaining part of the air cooling the magnetron 104 and the high-pressure transformer 105 is reflected in the process of cooling the magnetron 104 and the high-voltage transformer 105, the electric field suction opening of the back plate 150 ( 153 flows into the space between the backplate 150 and the backcover 770.

Meanwhile, the second fan 330 of the first fan assembly 300 is driven simultaneously with the first fan 320. When the second fan 330 is driven, indoor air flows to the intake portion of the second fan 330 through the suction port 141 of the front plate 140 and the suction hole 610 of the suction grill 600. Is inhaled. The indoor air sucked into the intake portion of the second fan 330 is discharged through the exhaust portion of the second fan 330 to cool the upper heater assembly 200. The air cooled by the upper heater assembly 200 flows into the space between the back plate 150 and the back cover 770 through the heater suction opening 155 of the back plate 150.

At this time, the air discharged to the exhaust parts of the first fan 320 and the second fan 330 is prevented from being re-sucked into the intake portion of the second fan 330 by the first air barrier 410. In addition, the air discharged to the exhaust portion of the first fan 320 and the second fan 330 and flows into the space between the back plate 150 and the back cover 770 is mutually by the second air barrier 420 Compartment. Therefore, the convection motor 760 is cooled only by the air discharged to the exhaust of the second fan 330 to cool the magnetron 104 and the high pressure transformer 105.

Air flowing into the space between the back plate 150 and the back cover 770 flows through the space between the bottom plate 120 and the base plate 160 through the outlet 143 of the front plate 140. It is discharged indoors. At this time, the lower heater 780 and the turntable motor 790 are cooled by the air flowing through the space between the bottom plate 140 and the base plate 160.

Within the scope of the basic technical idea of the present invention, many modifications are possible to those skilled in the art, and the scope of the present invention should be interpreted based on the appended claims. will be.

According to the microwave oven according to the present invention as described above, the following effects can be expected.

First, in the present invention, the components constituting the microwave oven by the fan assembly, in particular, the electric component for generating microwaves and the heater for generating heater heat are more efficiently cooled. Therefore, overheating of the parts can be prevented, thereby improving the operation reliability of the microwave oven.

In the present invention, the airflow formed by the fan assembly by the air guide is prevented from flowing into the fan assembly. Therefore, the cooling efficiency of the component by the fan assembly is improved.

1 is an exploded perspective view showing an embodiment of a microwave oven according to the present invention.

Figure 2 is a rear view showing the back of the embodiment of the present invention.

Figure 3 is a plan view showing the flow of air in the embodiment of the microwave oven according to the present invention.

Figure 4 is a side view showing the flow of air in an embodiment of the present invention.

Claims (13)

Cavity is provided with a cooking chamber; An electric component installed on an upper surface of the cavity and including at least a magnetron; An upper heater spaced apart from the electric component on an upper surface of the cavity; A convection motor installed at the rear of the cavity; A fan installed at one end of the upper surface of the cavity and forming an air flow flowing toward the other end of the upper surface of the cavity; A barrier member provided on an upper surface of the cavity to prevent the airflow from being re-inhaled into the fan; And A partition member for partitioning the air flow formed by the fan into an air flow for cooling the electric component and a convection motor and an air flow for cooling the upper heater; Microwave including a. The method of claim 1, The barrier member is provided between the upper end of the cavity and the fan. delete delete delete The method of claim 1, The partition member is a microwave oven for shielding the upper heater. The method of claim 1, And at least one of a lower heater and a turntable motor installed on a bottom surface of the cavity and cooled by an airflow cooling the electric component and the convection motor. A cavity provided with a cooking chamber, and an electrical equipment chamber provided on an upper surface thereof; Electric parts and an upper heater installed in the electric room; A fan assembly installed at one end of the electrical equipment room, the fan assembly including first and second vent fans forming airflows which are partitioned from each other and flowing toward the other end of the electrical equipment room; And A barrier member provided in the electric compartment and preventing the airflow from being re-introduced into the first and second vent fans; Including, The airflow formed by the first vent fan cools the electric component, and the airflow formed by the second vent fan cools the upper heater. The method of claim 8, A part of the airflow formed by the first vent pan is introduced into the cooking chamber while the electric component is cooled, and the remaining part of the airflow formed by the first vent pan cools the electric component. Microwave oven flowing in the rear of the cavity in the state. The method of claim 9, And an airflow formed by the first vent fan and flowing to the rear of the cavity in a state in which the electric component is cooled, cooling the convection motor installed at the rear of the cavity. The method of claim 9, And an airflow formed by the first vent fan and flowing to the rear of the cavity in a state in which the electric component is cooled, cools at least one of a lower heater and a turntable motor installed at a bottom of the cavity. The method of claim 8, The air flow formed by the second vent fan is flown to the rear of the cavity in the state that the upper heater is cooled. delete

Images