KR20020050025A - An air flow system for micro wave oven - Google Patents

Abstract

PURPOSE: An air flow system for a microwave oven is provided to form the air flow in the microwave oven by using only one intake fan assemblage. CONSTITUTION: An intake fan assemblage(70) sucks external air, and flows the air in a microwave oven. The air flow passes through a horizontal partition(60), and is divided into both sides by a vertical partition(65), and cools electric parts in the top of a cavity(50). The air flow passed through an upper heater duct(94) and a lower heater duct(104) is supplied to an upper heater and a lower heater, respectively. The upper heater and lower heater are installed on the upper and lower part of the cavity(50) respectively. The air flow for cooling the upper heater and lower heater is transferred to the lower part of the cavity(50), and a front grille(56) exhausts the air flow into the outside of the microwave oven.

Description

An air flow system for micro wave oven

The present invention relates to a microwave oven, and more particularly to an air flow system of the microwave oven for cooling the heat generated inside the microwave oven.

A microwave oven mainly uses microwaves to heat food and sometimes uses a heater as an auxiliary heat source. There are various types of such microwaves, one of which is a built-in type. Built-in microwave ovens are designed to be installed inside the kitchen furniture.

FIG. 1 shows a main configuration of a built-in microwave oven according to the prior art, and FIG. 2 shows a flow of air for cooling the heater in the configuration of the built-in 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 equipment chamber 2 'is provided with a cooling fan 2 "for dissipating heat generated from the electrical components.

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 16 is a passage through which cooling air flows in order to manage the temperature at the both ends of the lower heater 12 and the temperature of the heater cover 14, and the lower cooling fan 18 is disposed upstream of the air tunnel 16. It is

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

An insulator 26 is installed on the air tunnel 24. The insulator 26 is to insulate between the top and the bottom so that the heat of the upper heater 20 side is not transferred between the insulator 26 and the outer case 28.

On the other hand, a partition wall 26 is provided between one side of the cavity 1 and the outer case 28, the passage for passing 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 air flowing in the upper portion of the microwave oven is formed by driving the exhaust motor assembly 10. 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 part is discharged to the exhaust grill 7 through a lower part of the air tunnel 16 and a base plate (not shown) which is a bottom surface of the microwave oven.

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.

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, when operating the microwave oven, a plurality of fan assemblies are used. (2 ", 10, 18, 25) is driven at the same time there is a problem that a lot of noise occurs.

In addition, there is a problem that the manufacturing cost of the microwave oven is increased by using a plurality of fan assembly (2 ", 10, 18, 25) as described above.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to form air flow in a microwave oven using one fan motor assembly.

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 perspective view showing the configuration of a preferred embodiment of the air flow system of the microwave oven according to the present invention.

Figure 4 is a cross-sectional view showing the configuration and the air flow state of the embodiment of the present invention.

Figure 5 is an operating state showing the air flow in the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

50: cavity 52: cooking chamber

54: door 55: door handle

56: front grille 58: control panel

60: horizontal partition wall 62: first exhaust hole

64: second exhaust hole 65: vertical partition wall

70: intake fan assembly 75: back plate

76,76 ': Intake 80: Magnetron

82: high voltage transformer 84: high voltage capacitor

90: upper heater 91: heater cover

92: upper air tunnel 94: upper heater duct

100: lower heater 101: heater cover

102: lower air tunnel 104: lower heater duct

According to a feature of the present invention for achieving the object as described above, the present invention is the cavity formed by the intake fan assembly and the air delivered from the intake fan assembly to allow the air flow inside the microwave oven by sucking the outside air The electric equipment cooling air flow for cooling the upper electric component, the upper heater cooling air flow for cooling the upper heater is formed by the air delivered from the intake fan assembly and installed in the upper portion of the cavity, and delivered from the intake fan assembly And a lower heater cooling airflow configured to cool the lower heater installed at the lower portion of the cavity, and an exhaust grill configured to exhaust the airflow formed by the intake fan assembly to the outside of the microwave oven.

The electrical equipment cooling air flow is partitioned on both sides by a partition wall installed at an upper end of the cavity, and the first air flow is delivered to the exhaust grill through a passage formed between one side wall of the cavity and the outer case, and the The second air flows to the exhaust grill through a passage formed between the other side wall of the cavity and the outer case.

One of the first and second airflows passes through the magnetron to dissipate heat and is transferred into the cavity.

The upper heater cooling airflow and the lower heater cooling airflow are each formed by separate ducts.

The exhaust grill is provided at the front of the microwave oven corresponding to the lower portion of the cavity.

The intake fan assembly is provided with a plurality of intake holes in the rear plate and the outer case so that the outside air can be sucked through the rear and both sides of the microwave oven.

The intake fan assembly is partitioned by a space in which the electric component is installed and a partition wall to discharge air through an exhaust hole to form an air flow.

According to the air flow system of the microwave oven according to the present invention having such a configuration, it is possible to dissipate heat generated by sucking outside air using one intake fan assembly and transferring the sucked air to each part of the microwave oven. Will be.

Hereinafter, a preferred embodiment of the air flow system of the microwave oven according to the present invention as described above will be described in detail with reference to the accompanying drawings.

3 is a perspective view showing the main structure of the embodiment of the present invention, and FIG. 4 is a cross-sectional view of the main structure of the embodiment of the present invention. As shown in the drawing, the cooking chamber 52 is formed inside the cavity 50 forming the frame of the microwave oven. In the cooking chamber 52, the food is heated by microwaves or heaters.

The front of the microwave oven is provided with a door 54 for selectively opening and closing the cooking chamber 52. The door 54 is provided with a door handle 55 for opening and closing the door 54. The front grill 56 is installed at the lower front side of the microwave oven corresponding to the lower part of the door 55. The air circulated in the microwave oven is discharged to the outside through the front grill 56. In addition, a control panel 58 indicating an operation and a driving state for driving the microwave oven is installed at the upper end of the front surface of the microwave oven corresponding to the upper part of the door 55.

On the other hand, the inside of the microwave oven is partitioned back and forth in the horizontal partition wall 60, the front and rear partitioned front and rear is partitioned left and right again by the vertical partition wall (65). The horizontal partition wall 60 is to allow the intake fan assembly 70 to be described below to be located in a separate compartment, and the first and second exhaust holes for blowing air to the upper surface of the cavity 50 on one side thereof. (62, 64) are formed. The vertical partition wall 65 partitions the upper portion of the cavity 50 from side to side to allow air blown from the first and second exhaust holes 62 and 64 to flow through separate paths.

An intake fan assembly 70 is installed at the rear of the microwave oven partitioned by the horizontal partition wall 60 to suck external air therein. The configuration of the intake fan assembly 70 is known and consists of a motor and a sirocco fan on both sides. The intake fan assembly 70 sucks air at both ends to discharge air in the circumferential direction of the rotating fan, and discharge ports of the housing communicate with the first and second exhaust holes 62 and 64, respectively. .

The back plate 75 forms a rear surface of the microwave oven while partitioning a space in which the intake fan assembly 70 is placed together with the horizontal partition wall 60. The back plate 75 is perforated with a plurality of intake holes 76, 76 'through which the outside air is introduced by the suction force of the intake fan assembly 70. Of course, intake holes (not shown) for sucking outside air may be formed in the outer case 112 and the base plate 110 forming the appearance of the microwave oven.

Next, various electric parts installed in the upper portion of the cavity 50 will be described. First, the magnetron 80 is installed on the right side (based on the drawing) partitioned by the vertical partition wall 65. On the left side, a high voltage transformer 82 and a high voltage capacitor 84 are provided. Meanwhile, a main board (not shown) connected to the control panel 58 may be mounted in the space where the high voltage transformer 82 and the high voltage capacitor 84 are installed.

And the structure for providing heater heat to the inside of the cooking chamber 52 is demonstrated. The upper heater 90 is installed on the upper surface of the cavity 50. The upper heater 90 is shielded by the heater cover 91 and is located in the air tunnel 92. The air tunnel 92 serves to dissipate the upper heater 90 to guide the upper heater cooling airflow. The air tunnel 92 extends along the side wall of the cavity 50, as shown in FIG. 4.

The air blown through the first exhaust hole 62 is transferred to the air tunnel 92 through the upper heater duct 94. The upper heater duct 94 serves to communicate the first exhaust hole 62 and the air tunnel 92. The upper heater duct 94 is installed at one side of the upper surface of the cavity 50 together with the lower heater duct 104 to be described below.

A lower heater 100 for supplying heater heat to the inside of the cooking chamber 52 is also installed in the lower portion of the cavity 50. The lower heater 100 is shielded by the heater cover 101 and is installed in the lower air tunnel 102. The lower air tunnel 102 serves to guide the lower heater cooling air flow for heat dissipation of the lower heater 100. The downstream portion of the lower air tunnel 102 is formed to be extended toward the front grill 56 to guide the airflow passing through the lower heater 100 to the outside of the microwave oven.

A lower heater duct 104 is used to guide the air delivered from the intake fan assembly 70 to the lower air tunnel 102. The lower heater duct 104 communicates the first exhaust hole 62 and the lower air tunnel 102. The lower heater duct 104 extends to the lower air tunnel 102 along one side wall of the cavity 50. The upper heater duct 94 and the lower heater duct 104 may be in communication with the first exhaust hole 62 or may be joined together to communicate with each other.

Hereinafter, the operation of the air flow system of the microwave oven according to the present invention having the configuration as described above will be described with reference to FIGS. 4 and 5.

First, air is sucked from the outside of the microwave oven to the inside by the intake fan assembly 70. That is, when the intake fan assembly 70 is operated, external air is sucked into the space formed by the horizontal partition wall 60 and the back plate 75 through the intake holes 76 and 76 '. The sucked air is sucked through both ends of the intake fan assembly 70 to the space partitioned by the horizontal partition wall 60 through the first exhaust hole 62 and the second exhaust hole 64, respectively. Delivered.

First, the air discharged through the first exhaust hole 62 is transferred to the right space partitioned by the vertical partition wall 65 and the upper heater duct 94 and the lower heater duct 95. The first airflow, which is air delivered to the right space, cools the magnetron 80 and transmits the air to the bottom of the cavity 50 through the space between the right side of the cavity 50 and the outer case 112 as indicated by arrow a. do.

And it is transmitted to the outside of the microwave oven through the front grill 56 in the lower cavity 50. At this time, some of the air passing through the magnetron 80 is delivered to the inside of the cooking chamber 52 serves to remove water vapor in the cooking chamber 52 during cooking.

Next, some of the air discharged through the first exhaust hole 62 is transferred to the upper heater duct 94. The air delivered to the upper heater duct 94 is transferred to the upper air tunnel 92 as indicated by arrow b to cool the upper heater 90. And it is guided by the upper air tunnel 92 is transferred to the lower portion of the cavity 50 as indicated by the arrow b 'in Figure 4 is discharged to the outside through the front grill (56).

In addition, the rest of the air discharged through the first exhaust hole 62 is delivered to the lower heater duct 104. The air delivered to the lower heater duct 104 is delivered to the lower portion of the cavity 50 as shown in FIG. 4 by the arrow c, and is then delivered to the lower air tunnel 102. The air guided by the lower air tunnel 102 cools the lower heater 100 and is discharged to the outside through the front grill 56 at a downstream portion of the lower air tunnel 102.

Finally, the air which is the second air flow delivered to the upper space of the cavity 50 partitioned by the horizontal partition wall 60 and the vertical partition wall 65 through the second exhaust hole 64 is indicated by arrow d. As shown in the figure, the high pressure transformer 82 and the high pressure capacitor 84 are cooled while flowing along the upper space of the cavity 50 and the arrow is formed through the space formed between the outer case 112 and the side wall of the cavity 50. Flowed as shown by d 'and delivered to the bottom of the cavity 50. And it is discharged to the outside through the front grill 56 from the lower portion of the cavity 50.

The air flow system of the microwave oven according to the present invention as described in detail above was configured to form various air flows inside the microwave oven using one intake fan assembly.

Therefore, since only one motor is rotated during operation of the microwave oven, noise can be relatively reduced, so that low noise can be realized. Therefore, only one expensive motor can be used to reduce the manufacturing cost of the microwave oven.

Claims (7)

An intake fan assembly for sucking air from outside to allow air to flow inside the microwave oven, An electric flow for cooling the electronic parts formed by the air delivered from the intake fan assembly to cool the electric parts above the cavity; Upper heater cooling air flow formed by the air delivered from the intake fan assembly to cool the upper heater is installed on the upper portion of the cavity, A lower heater cooling air flow formed by air delivered from the intake fan assembly and cooling the lower heater installed at the lower portion of the cavity; And an exhaust grill for exhausting the air flow formed by the intake fan assembly to the outside of the microwave oven. According to claim 1, The electrical equipment cooling air flow is partitioned on both sides by a partition wall provided on the upper end of the cavity, A first air flow delivered to the exhaust grill through a passage formed between one side wall of the cavity and the outer case; The air flow system of the microwave oven, characterized in that separated by the second air flow to the exhaust grill through a passage formed between the other side wall of the cavity and the outer case. 3. The airflow system of claim 2, wherein any one of the first and second airflows passes through the magnetron, radiates heat, and is transferred into the cavity. [4] The air flow system of claim 1 or 3, wherein the upper heater cooling airflow and the lower heater cooling airflow are each formed by separate ducts. The air flow system according to claim 4, wherein the exhaust grill is provided at the front of the microwave oven corresponding to the lower portion of the cavity. According to claim 1 or 5, The intake fan assembly of the microwave oven, characterized in that a plurality of intake holes are provided in the back plate and the outer case so that the outside air is sucked through the back and both sides of the microwave oven. Air flow system. The air flow system according to claim 6, wherein the intake fan assembly is partitioned by a space in which the electric component is installed and a partition wall to discharge air through exhaust holes to form an air flow.