KR100402587B1 - Air flow system for microwave oven - Google Patents

Abstract

The present invention relates to a microwave oven, and more particularly to an air flow system of the microwave oven.

The present invention, through the front grill 100 having a suction unit 101, the outside air is sucked into the interior and the discharge portion 102 is discharged to the outside the air circulated inside, and through the suction unit 101 Air flow forming means 50 is installed at one end of the cavity to form an air flow circulating inside by sucking outside air, and formed by the air flow forming means 50 to oppose along the cavity 41. While cooling in a direction, the parts installed on the outer surface of the cavity 41 are cooled, and a part cooling air flow discharged through the discharge part 102 and a part of the part cooling air flow are delivered to the cavity 41 and circulated. After that, it is composed of the air flow discharged through the discharge portion (102).

According to the configuration as described above, due to the reduction in the fan assembly is reduced the assembly process and manufacturing cost, there is an effect of achieving a low noise structure.

Description

Air flow system for microwave oven {Air flow system for microwave oven}

The present invention relates to a microwave oven, and more particularly to a low noise structure, a relatively simple internal structure is the microwave flow system of the microwave material material is reduced by the simple structure.

A microwave oven is a device that generates a microwave by supplying a current, and heats the heating object by irradiating the microwave to the heating object.

In general, the microwave is the most basic heating method by supplying microwaves into the cavity to irradiate the heating object. In addition, since the microwave heating method has only a single heating characteristic by microwaves, recent microwave ovens include a heater as another heating source therein.

The installation of the additional heating source can obtain a high temperature heat in a relatively fast time to obtain the effect of improving the cooking speed, but an additional cooling device was installed to prevent damage to the components due to heat.

Such a microwave oven can be roughly divided into a general microwave oven, which is usually placed on a table, and a hood-use microwave oven provided on the upper wall of the gas oven range and having an exhaust function.

However, many kitchen products such as gas oven range or kimchi refrigerator have recently been designed as built-in type. By being designed as such a built-in type, kitchen appliances and kitchen furniture are harmonized, and there is an advantage in that they can provide a sense of unity.

A conventional built-in microwave oven (hereinafter, simply referred to as a microwave oven) will be described with reference to the drawings.

1 shows a main configuration of a microwave oven according to the prior art, and FIG. 2 shows a flow of air for cooling the heater in the configuration of the microwave oven according to the prior art.

As shown in these figures, the cooking chamber 2 is formed inside the cavity 1 constituting the frame of the microwave oven, and the cooking chamber 2 is a portion where cooking of the food is made. One side of the cavity 1 corresponding to the cooking chamber 2 is provided with an electrical equipment chamber 2 ′ in which electrical equipment constituting a microwave oven is installed. Such an electrical component chamber 2 'is provided with a cooling fan assembly 2 "for dissipating heat generated from the electrical component.

The front surface of the cooking chamber 2 is selectively opened and closed by the door 3 and selectively communicates with the outside. The door 3 selectively opens and closes the inside of the cooking chamber 2 to partition the inside of the cooking chamber 2 from the outside during cooking.

A suction grill 5 is installed at the front of the microwave oven corresponding to the upper part of the door 3 to suck outside air into the microwave oven, and the air flowing inside the microwave oven is located at the lower part of the door 3. Exhaust grill 7 discharged to the outside is installed.

In addition, the front of the microwave oven corresponding to the upper end of the suction grill (5) is provided with a control panel unit 8 for the operation for driving the microwave oven. On the other hand, the exhaust motor assembly 10 for air flow in the inside of the microwave oven is installed on the left side of the upper surface of the cavity 1 to provide a driving force for air suction through the suction grill 5 and the upper portion of the microwave oven. The flowed air is delivered to the lower part through one side of the cavity 1 to be discharged to the exhaust grill 7.

The lower heater 12 is provided on the lower surface of the cavity 1 to provide heat to the food inside the cooking chamber 2. The lower heater 12 is shielded by the heater cover 14. The heater cover 14 is shielded by the air tunnel 16. The air tunnel

Reference numeral 16 denotes a passage through which cooling air flows to manage the temperature at the both ends of the lower heater 12 and the temperature of the heater cover 14, and the lower fan assembly 18 is provided at an upstream portion thereof. .

Next, the upper heater 20 is installed on the upper surface of the cavity 1. The upper heater 20 is covered by the heater cover 22 to provide heat to the cooking chamber 2 from the upper surface of the cavity 1. An air tunnel 24 is installed on the upper surface of the cavity 1 to shield the heater cover 22. The air tunnel 24 guides the airflow for cooling the upper heater 20 and the heater cover 22, and the air tunnel

An upper fan assembly 25 is provided upstream of the 24. The upper fan assembly 25 provides air for cooling the upper heater 20 into the air tunnel 24.

In addition, a partition wall 26 is provided between one side surface of the cavity 1 and the outer case 28 to pass the air passing through the air tunnel 24 to the lower portion of the cavity 1. To form.

In the conventional microwave oven having the above configuration, the exhaust motor assembly

By the driving of 10, a flow of air flowing in the upper portion of the microwave oven is formed. That is, the outside air is sucked into the inner upper portion of the microwave oven through the suction grill 5, and the air flowing in the inner upper portion is transferred to the exhaust motor assembly 10, as shown by an arrow in FIG. 1. It is transmitted downward through one side of the cavity (1). The air delivered to the lower portion is a base plate which is a lower surface of the air tunnel 16 and the bottom of the microwave oven.

It discharges to the said exhaust grill 7 through between (not shown).

In addition, the upper fan assembly 25 is driven to cool the upper heater 20. The air flow formed by the upper fan assembly 25 is guided into the air tunnel 24 to manage temperature while passing through the upper heater 20 which is shielded by the heater cover 22. Air passing through the air tunnel 24 as described above is moved to the lower portion of the cavity 1 through the flow path between the partition wall 26 and the side wall of the cavity 1 through the exhaust grill (7) It is discharged to the outside.

In addition, the air that enters the upper part of the electric compartment 2 'for cooling the electric compartment 2' cools the electric parts of the electric compartment 2 'by the cooling fan assembly 2' 'to the cooking chamber 2; It enters and exits the cooking chamber 2 together with the air containing the moisture and is moved to the lower part of the cavity 1 along the space formed between the cavity 1 and the partition wall 26 and discharged to the exhaust grill 7.

In addition, a part of the air that enters the electric compartment 2 'dissipates the lower heater 12 mounted on the lower part of the cavity 1 by the lower fan assembly 18 formed on the bottom of the electric compartment 2' and the air tunnel ( It flows along the 16 and is discharged to the exhaust grill (7).

The air flow by the exhaust motor assembly 10 is for dissipating the heater and lowering the temperature of the air exiting the exhaust grill 7.

However, the microwave oven according to the prior art as described above has the following problems.

In a conventional microwave oven having such a configuration, a plurality of fan assemblies 2 ", 10, 18, and 25 should be used to form air flow in the microwave oven. Therefore, a plurality of fan assemblies ( 2 ", 10, 18, 25 are driven at the same time there is a problem that a lot of noise occurs.

In addition, the use of a plurality of fan assemblies 2 ", 10, 18, 25 as described above, there is also a problem that the manufacturing cost of the microwave oven increases.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to provide an air flow system of a microwave oven in which noise is reduced by a microwave oven in which the number of fan assemblies is reduced.

Another object of the present invention is to provide an air flow system of a microwave oven in which cost is reduced by reducing the number of fan assemblies and air tunnels.

1 is a bottom perspective view showing the main structure of a built-in type microwave oven according to the prior art;

Figure 2 is a cross-sectional view showing that the air flows inside the built-in microwave oven according to the prior art.

Figure 3 is a front view showing the main configuration and air flow of the microwave oven according to an embodiment of the present invention.

Figure 4 is a top view showing the air flow and parts mounted on the upper cavity according to an embodiment of the present invention.

Figure 5 is a side view showing the air flow of the cavity side according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1. Cavity 2. Cooking Room

5. Suction grill 7. Exhaust grill

10. Exhaust Motor Assembly 12. Lower Heater

16. Air Tunnel 18. Lower Fan Assembly

20. Upper heater 22. Heater cover

24. Air Tunnel 25. Upper Fan Assembly

26. Partition Wall 40. Cavity

41. Cooking chamber 42. Cavity top

50. Intake fan assembly 51. Outlet

60. Partition wall 61. First through hole

62. Second through hole 70. Back plate

71. Rear intake 80. Upper heater

85. High voltage transformer 86. High voltage capacitor

87. Magnetron 88. Wave Guide

90.Air duct 100.Front grill

101.Suction part 102.Exhaust part

110. Separator 120. Air tunnel

130. Lower heater 132. Turntable motor

In the microwave flow system of the present invention for achieving the object as described above, the front grill is separated by the inlet portion in which the outside air is sucked into the inside by the separator plate and the discharge portion in which the air circulated inside is discharged to the outside And an airflow forming means installed at one end of the cavity to form an airflow circulating inside by sucking the outside air through the suction unit, and formed by the airflow forming means to flow in opposite directions along the cavity. While cooling the components installed on the outer surface of the cavity and discharged through the discharge portion, and part of the cooling air flow is delivered to the inside of the cavity and circulated after the internal air flow discharged through the discharge portion do.

The air flow forming means is installed at one end of the upper surface of the cavity to suck air from the lower side of the cavity to form a part cooling air flow along the upper surface of the cavity toward the other end.

The component cooling air flow is divided into a heater cooling air flow for cooling the upper heater, and an electrical component cooling air flow for cooling the electrical components.

The air flow is guided to the discharge part through a separate air tunnel.

A partition wall having a through-hole formed on one side of the airflow forming means is installed so that air sent by the airflow forming means does not flow back to the airflow forming means.

An air inlet is further provided on a rear surface of the outer case adjacent to the airflow forming means.

According to the present invention having such a configuration, the conventional multiple fan assembly is composed of a single intake fan assembly, noise is reduced to form an airflow flowing through the microwave oven, the manufacturing cost is reduced by reducing the number of parts.

Hereinafter, with reference to Figures 3, 4, 5 attached to a preferred embodiment of the present invention as described above in detail.

In the microwave oven, a cooking chamber 41 in which food is cooked is formed in the cavity 40. An intake fan assembly 50 is installed on the left side of the cavity upper surface 42 (see FIG. 4) to inhale outside air to form an airflow flowing through the inside of the microwave oven.

The configuration of the intake fan assembly 50 is known and consists of a motor and a sirocco fan on both sides. The intake fan assembly 50 discharges air to the intake fan assembly discharge port 51 in the circumferential direction of the fan which sucks air at both ends thereof.

A plate-shaped partition wall 60 having a first through hole 61 and a second through hole 62 respectively formed at a position corresponding to the intake fan assembly discharge port 51 is provided in series with the intake fan assembly discharge port 51. . The partition wall 60 is installed in the cavity upper surface 42 from the rear plate 70 to the front plate to prevent the air discharged from the intake fan assembly 50 back to the intake fan assembly 50.

A rear suction port 71 is formed in the rear plate 70 corresponding to the intake fan assembly 50, and serves as a passage through which external air flows into the intake fan assembly 50. Such an inlet may be further formed at one side of the outside of the microwave to expand the air inflow into the intake fan assembly 50.

The upper heater 80 is mounted on the right side of the first through-hole 61 of the partition wall 60 (see FIG. 4) to transmit radiant heat into the cavity 40, and the main substrate (above) on the upper heater 80. Not shown) is installed spaced apart. The upper heater 80 is made of a combination of a halogen heater and a ceramic heater with a relatively low amount of heat generation, which is of course possible to use other heaters as a configuration according to an embodiment of the present invention.

On the right side of the second through hole 62, a high voltage transformer 85, a high voltage capacitor 86, and a magnetron 87, which are magnetron generating means, are installed as shown. The wave guide 88 for guiding the microwaves generated from the magnetron 87 into the cavity 40 is connected to one side of the magnetron 87 and the cavity 40.

The air duct 90, one side of which is connected to the magnetron 87, is connected to the side of the cavity 40, and the other side of the air duct 90 radiates the magnetron 87 to guide the hot air formed into the cavity 40.

The position of the electric component and the upper heater 80 located in the cavity upper surface 42 is a configuration according to the embodiment of the present invention to the last, and of course, the position of the electric component can be changed in the basic airflow of the present invention.

On the other hand, the front grill 100 is formed on the front lower end of the microwave oven, the separating plate 110 is installed from the rear plate 70 to the front grill 100 on the rear surface of the front grill 100. The separating plate 110 is a rectangular plate shape to prevent mixing of the air flow sucked through the front grill 100 and exhausted.

The front grill 100 has a suction part on the left side (based on FIG. 3) based on the separator 110.

The right side is divided into the exhaust unit 102 by 101. One side of the air exhaust unit 102 is connected, and the air tunnel 120 connected to the side of the cavity 40 and the other side is a passage through which air in the cavity 40 exits.

Finally, the lower heater 130 is mounted on the lower surface of the cavity 40 to transfer heat to the cooking chamber 41, and the turntable motor 132 is mounted adjacent to the lower heater 130 to lower the cooking chamber 41. It is installed in the turntable to rotate the food is placed.

The lower heater 130 is a ceramic heater series that is not overheated by a certain temperature by its own characteristics is used according to an embodiment of the present invention, which is also the same as the upper heater 80 using a different heater Of course it is also possible.

According to the embodiment of the present invention, the microwave oven having the above configuration has the following airflow.

First, the air sucked through the suction part 101 partitioned by the separator plate 110 and the rear suction port 71 formed on the rear plate 70 in the front grill 100 formed in the front of the microwave is the intake fan assembly 50. ) Is discharged to the intake fan assembly discharge port 51 by the centrifugal force of the fan which is sucked at both ends and rotates.

The air flow formed at the intake fan assembly discharge port 51 flows through the cavity upper surface 42 through the first and second through holes 61 and 62 formed in the partition wall 60.

The airflow passing through the partition wall first through hole 61 mainly cools the main board (not shown) installed and spaced apart from the upper heater 80 and the upper heater 80 mounted on the upper surface of the cavity and the cavity 40. It flows down along the outside side.

In addition, the airflow passing through the second through hole 62 mainly cools the high pressure transformer 85, the high pressure capacitor 86, the magnetron 87, and the like installed on the cavity upper surface 42, and the magnetron 87. Some airflow having a relatively high temperature is cooled into the cavity 40 through the air duct 90 and the rest flows down along the side of the cavity 40.

As such, the airflow directed toward the lower part of the cavity 40 is exhausted from the front grill 100 to the exhaust part 102 partitioned by the separating plate 110, and some airflows are mounted on the lower part of the cavity 40. The lower heater 130, which is a heating means, is cooled and exhausted to the exhaust unit 102.

On the other hand, the hot air flow introduced into the cooking chamber 41 to the exhaust unit 102 through the air tunnel 120 formed on one side of the cavity 40 together with the moisture generated in the cooking chamber 41 during the microwave operation. Exhausted.

The microwave oven according to the embodiment of the present invention having the airflow as described above forms an airflow by one intake fan assembly 50 to remove heat and remove moisture in the cavity 40. This is a structure in which the cooling fan assembly that is conventionally mounted to each heating means is eliminated, and noise generated by rotation of the plurality of cooling fan assemblies is reduced.

In addition, the assembly time is shortened and the manufacturing cost is reduced by the structure in which the cooling fan assembly and the fastening means including the air tunnel and the bolt, which are conventionally installed in each heating means, are removed.

In addition, by forming the rear suction port 71 in the rear plate 70 corresponding to the intake fan assembly 50, more sufficient cooling air may be introduced. Therefore, it is possible to reliably cool the heat-generating components by introducing sufficient outside air, so that an effect of increasing the reliability of driving the microwave will be expected.

Lastly, in the inlet grill and exhaust grill are formed in the prior art, the intake and exhaust passages in the microwave oven according to the embodiment of the present invention, the suction part 101 and the exhaust part 102 in the front grill 100, the separating plate. By being partitioned and installed by 110, the grill part is reduced by one compared with the prior art, and manufacturing cost is reduced.

According to the present invention as described above, there is an effect that the noise is reduced due to the use of one intake fan assembly.

In addition, the structure of the cooling fan assembly, the air tunnel, and the fastening means related to the cooling action of each heating means is eliminated, thereby reducing manufacturing costs and improving productivity.

In addition, the air intake passage is enlarged through the rear suction port formed in the rear plate, so that the heat-generating parts are smoothly cooled, thereby ensuring the reliability of driving the microwave.

Finally, by forming the inlet port and the exhaust part in the front grill, the grill part is reduced from two places to one place than in the prior art, thereby reducing the manufacturing cost.

Claims (7)

A front grill which separates an intake part through which the outside air is sucked into the inside by a separator plate and a discharge part through which the air circulated inside is discharged to the outside; An airflow forming means installed at one end of the cavity to form an airflow circulating inside by sucking external air through the suction unit; A component cooling air flow formed by the air flow forming means and flowing in an opposite direction along the cavity to cool down a component installed on the outer surface of the cavity and discharged through the discharge portion; The air flow system of the microwave oven, characterized in that a part of the cooling air flow is delivered to the inside of the cavity, including the internal air flow discharged through the discharge portion after circulating. delete The electron flow forming apparatus of claim 1, wherein the airflow forming unit is installed at one end of the upper surface of the cavity to suck air from the lower side of the cavity to form a part cooling airflow along the upper surface of the cavity toward the other end. Range air flow system. The air flow system according to claim 1, wherein the component cooling air flow is divided into a heater cooling air flow for cooling the upper heater and an electrical component cooling air flow for cooling the electrical components. 4. The air flow system according to claim 3, wherein the air flow is guided to the discharge part through a separate air tunnel. [5] The electronic device as claimed in claim 1 or 4, wherein a partition wall having a through-hole is provided at one side of the airflow forming means to prevent the air sent by the airflow forming means from flowing back to the airflow forming means. Range air flow system. 7. The air flow system according to claim 6, wherein an air inlet is further provided on a rear surface of the outer case adjacent to the air flow forming means.