KR200337675Y1 - A structure of wire for Microwave oven - Google Patents

Abstract

The present invention relates to a wire connection structure of the microwave oven. Wire connection structure according to the present invention, the wire 400 for connecting between a plurality of electrical components installed in the electric room 200; A barrier 300 installed inside the electric compartment 200 to prevent the heated air from flowing back toward the electric compartment 200 in the process of cooling the electric component; It is configured to include a connector 500 for connecting the wire 400 provided before and after the barrier (300). The connector 500 includes a plug 510 and a socket 530. In this way, the wire connection between the components of the electrical equipment room 200 may be facilitated, and the back of the heated air from the rear of the electrical equipment room 200 may be prevented from flowing backward.

Description

Wire structure of microwave oven {A structure of wire for Microwave oven}

The present invention relates to a microwave oven. More particularly, the present invention relates to a structure in which electric wires connecting electrical components installed at the front and rear of the electrical equipment compartment are respectively connected by a connector passing through the barrier.

2. Description of the Related Art In general, a microwave oven is a device for cooking food by generating microwave waves in a magnetron by supplying electric current, and irradiating the microwaves with heated objects such as food.

Such a microwave oven is classified into a household microwave oven having a small magnetron and a commercial microwave oven having a large or a plurality of magnetrons. Commercial microwave ovens are often used in convenience stores, which are frequently used, or in restaurants that require food to be cooked in a short time.

Hereinafter, the configuration of a commercial microwave oven as described above (hereinafter referred to as a microwave oven) will be described in detail with reference to the accompanying drawings. 1 is a perspective view showing the configuration of a microwave oven according to the prior art, Figure 2 is a partial perspective view showing a state in which the wire is connected through the barrier side of the microwave oven according to the prior art.

As shown, the microwave oven includes an outer case (Out case 10) that forms the exterior, a base plate (Base Plate 11), a cavity into which food to be cooked (Cabity 13), a front plate (Front Plate 15), It comprises a back plate (Back Plate 17), and the electrical equipment chamber 20 is installed a plurality of electrical components for operating the cavity (13). In addition, the front of the cavity 13, the door 30 for selectively opening and closing the space of the cavity 13 is provided.

The base plate 11 is located below the cavity 13, and an upper surface right side forms a bottom surface of the electric compartment 20. A portion of the base plate 11 is provided with a plurality of suction ports (not shown) for suctioning outside air into the microwave oven, and below the base plate 11, a microwave oven is provided. Is provided with a support foot (not shown) to be spaced apart from a predetermined height from the bottom surface is installed.

The front plate 15 forms a front surface of the cavity 13, and has a substantially rectangular frame structure so that the space inside the cavity 13 can be opened to the outside.

The back plate 17 is located at the rear of the cavity 13, and one side of the front plate forms a rear surface of the electric compartment 20. In addition, the back plate 17 is provided with an exhaust port (not shown) for discharging the air of the electric compartment 20 to the outside of the microwave oven.

In the electric compartment 20, a plurality of electric components such as a transformer 21, a magnetron 23, a blower fan 25, and a capacitor 27 are installed.

The transformer 21 converts a commercial voltage into a high voltage to supply the magnetron 23, and more specifically, the base plate 11 that forms the bottom surface of the electric chamber 20. It is fixed to the upper surface by fastening members such as screws.

The magnetron 23 is installed on the upper side of the electric chamber 20, and generates a high frequency of about 2000 hertz using the high voltage supplied from the transformer 21. The high frequency wave is irradiated into the cavity 13 through the waveguide 13a mounted along the upper and lower surfaces of the cavity 13.

The blower fan 25 is provided below the electric chamber 20 and near the suction port upper side of the base plate 11. Although not shown, the blower fan 25 is axially coupled with the fan motor.

On the other hand, the air intake side of the blower fan 25 is directed to the intake port of the base plate 11, the outlet side is opened to the interior of the electric chamber 20, more specifically to the transformer 21 side.

The capacitor 27 is installed to compensate for the voltage transferred from the transformer 21 to the magnetron 23.

As described above, the barrier 29 is vertically installed in the electric compartment 20 in which electric components such as the transformer 21, the magnetron 23, the blower fan 25, and the capacitor 27 are installed.

A predetermined blower (not shown) is formed at one side of the lower side of the barrier 29, and the blower corresponds to the outlet of the blower fan 25. And the wire insertion groove (29a) to be described later is formed at the approximately right middle end of the barrier (29).

The wire insertion groove 29a is a kind of communication path recessed from the right outer edge of the barrier 29 to the left side, and the wire insertion groove 29a is formed by cutting one side of the barrier 29.

When the barrier 29 is installed, the electric compartment 20 is separated into the front and rear. Therefore, the air blown into the electric compartment 20 by the blower fan 25 is blown to the transformer 21 side, that is, rearward through the air vent of the barrier 29.

On the other hand, a control panel 40 for displaying the state of the cavity is provided in front of the microwave oven, more precisely in front of the front plate (15).

Looking at the air flow of the microwave oven, that is, the suction and discharge of the air is configured as described above are as follows.

First, when the fan motor is started by an electrical signal, a blowing fan (not shown) inside the blower fan axially coupled with the fan motor rotates. Rotation of the blower fan is performed by the suction side of the blower fan 25 being opened toward the suction port of the base plate 11, so that outside air below the microwave oven passes through the suction port of the base plate 11, 20) Let it suck inside. The outside air sucked in this way is blown into the electric compartment 20 through the outlet of the blower fan 25.

At this time, a barrier 29 is installed between the transformer 21 and the blower fan 25, so that the air blown through the outlet of the blower fan 25 is prevented from flowing back to the front side of the electric chamber 20.

As described above, the external air blown into the electric chamber 20 is directly blown toward the transformer 21 in which heat is generated in the process of converting a commercial voltage into a high voltage.

In this process, air is cooled after the transformer 21 is discharged to the outside of the microwave oven through the exhaust port of the back plate (17).

On the other hand, a part of the air passing through the transformer 21 is guided by the inclined surface of the barrier 29, and the cavity 13 through a suction hole (not shown) formed in the perforated wall right side of the cavity 13 Flows inside.

The electric wire chamber 20 is provided with a plurality of wires 50, the electric wire 50 has a function of supplying power to a plurality of electric components installed in the electric chamber 20, and between the electric components It is a function of transmitting a formal signal. When the wire 50 is connected between the front electrical component and the rear electrical component 20 in the electric compartment 20 for the function as described above, the electric wire 50 of several strands across the electric compartment 20 It is provided.

However, the conventional microwave oven as described above has the following problems.

The barrier 29 installed in the electrical equipment compartment 20 is installed at the same time as the electrical component is installed or before the electrical component. Therefore, when the barrier 29 is first installed and the wire 50 is connected between the electric components, the wire 50 is blocked by the barrier 29 and cannot be connected to the front or rear parts.

Therefore, in order to connect between electric component parts in the state in which the barrier 29 is installed, the electric wire 50 of a state longer than the distance between electric component parts is provided. Then, it is inserted into the wire insertion groove 29a formed at the right end of the barrier 29.

However, when the wire 50 is connected as described above, after the wire 50 is connected with the difficulty of connecting one by one, it must be inserted into the wire insertion groove 29a. Therefore, the connection process of the wire 50 becomes complicated, and there is a problem in that assembly productivity of the microwave is lowered.

In addition, the barrier 29 is in a state of being installed to prevent backflow of the air discharged from the blower fan 25 as described above. However, if the barrier 29 is provided with a wire insertion groove 29a, the hot air heated in the process of cooling the air behind the electric chamber 20, that is, the transformer 21 through the wire insertion groove 29a, is applied to the electric field. Backward to the front of the chamber 20.

When the air in the rear flows backward as described above, the heat contained in the air in the rear of the battlefield is transmitted to the control panel 40 side. The control panel 40 is provided with a number of components that are sensitive to heat such as PCBs, there is also a problem that the components malfunction due to the heated air in the rear of the electrical equipment room (20).

Malfunctions of such components interfere with the normal operation of the microwave oven, which in turn leads to a problem that the user's dissatisfaction is heightened.

Therefore, the present invention is to solve the problems in the prior art as described above, and to provide a structure to prevent the heated air from flowing back toward the front of the battle chamber through one side of the barrier in the process of cooling the electrical component.

Another object of the present invention is to facilitate the connection between the front and rear wires.

1 is a perspective view showing the configuration of a microwave oven according to the prior art.

Figure 2 is a partial perspective view showing a state in which the wire is connected through the barrier one side of the microwave oven according to the prior art.

Figure 3 is an exploded perspective view showing the configuration of a microwave oven to which a preferred embodiment of the wire connection structure of the microwave oven according to the present invention is applied.

Figure 4 is a partial perspective view showing a wire connection structure of the microwave oven according to the preferred embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

200: battle room 210: transformer

230: magnetron 250: blower fan

251: fan housing 270: capacitor

300: barrier 310: connector insertion opening

400: wire 500: connector

510: plug 530: socket

The electric wire connection structure of the microwave oven of the present invention for achieving the above object, and a wire for connecting between a plurality of electric components installed in the electric room; A barrier installed inside the electrical equipment room to prevent the heated air from flowing back to the front of the electrical equipment room during the cooling of the electrical equipment; It is configured to include a connector for connecting the wires provided before and after the barrier.

The connector may include a plug provided at one end of the wire; It is preferably configured to include a socket to which the plug is fitted.

In addition, it is preferable that a connector inserting hole into which at least one side of the plug or socket is inserted is formed in the barrier, and the connector inserting opening has a shape corresponding to the outer edge of the plug or socket.

Hereinafter, with reference to the accompanying drawings the wire connection structure of the microwave oven of the present invention as described above.

3 is an exploded perspective view showing the configuration of the microwave oven in a state where the wire connection structure according to the present invention is applied, Figure 4 is a partial perspective view showing the wire connection structure of the present invention microwave oven.

As shown, the microwave oven is composed of the out cover, the cavity 150, and the electrical equipment room (200).

The out cover is to form the appearance of a microwave oven, and is generally made by punching an iron plate into a predetermined shape. Looking at the out cover in more detail, it is composed of an upper cover (Upper Cover 101), a base cover (Base Cover 103), a front cover (Front Cover 105), a back cover (Back Cover 107).

The upper cover 101 is formed in a substantially 'c' shape, and is assembled from above the cavity 150 from below. Thereafter, the upper cover 101 protects the cavity 150 by simultaneously covering the upper and left and right surfaces of the cavity 150.

The base cover 103 is installed below the cavity 150 to protect the bottom surface of the cavity 150.

The front cover 105 forms a front surface of the cavity 150 and functions to protect the front surface of the cavity 150.

The back cover 107 is installed on the rear surface of the cavity 150.

The upper cover 101, the base cover 103, the front cover 105, the back cover 107 as described above to form a slope appearance of the microwave oven by being coupled to each other and at the same time the cavity 150 therein To protect.

The cavity 150 is a configuration in which the food is substantially cooked, and forms a predetermined space therein to feed the food. That is, when the high frequency is irradiated while food is put into the space, the food is cooked after the set time. The electric field chamber 200 is formed in the right side of the cavity 150.

The electrical equipment chamber 200 is formed by the wall surface of the cavity 150 and the out cover 100 surrounding the cavity 150. That is, the upper surface and the right surface of the battlefield chamber 200 are the inner wall surface of the upper cover 101, the left surface is formed by the right outer wall surface of the cavity 150. And the bottom is the upper surface of the base cover 103, the front is the back of the front cover 105, the rear is made of the front of the back cover 107.

In the electric compartment 200, a transformer 210, a magnetron 230, a blower fan 250, a capacitor 270, and a barrier 300 are installed.

The transformer 210 is a type of transformer for converting a voltage applied to a microwave oven, for example, a commercial voltage of 110 volts or 220 volts into a high voltage of at least 2000 volts. The high voltage is generated by the transformer 210 to supply the magnetron to be described below.

The magnetron 230 generates a high frequency of 2000 hertz using the high voltage supplied from the transformer 210 described above. The high frequency generated by the magnetron 230 is scanned into the cavity 150 through waveguides 150a respectively installed above and below the cavity 150. In particular, the waveguide 150a is provided above and below the cavity 150 to scan a larger amount of high frequency waves into the cavity 150. When the high frequency is scanned from above and below the cavity 150, the food put into the cavity 150 can be cooked at a faster time by a large amount of high frequency.

The blower fan 250 includes a fan housing 251 and a blowing fan (not shown) that rotates inside the fan housing 251. The blowing fan is configured in a substantially turbine shape provided with a plurality of blades in a radial shape.

On the other hand, in the airflow generated by the blowing fan, the air below is introduced into the fan housing 251 by the rotation of the blowing fan. Then, the inside of the fan housing 251 is rotated and discharged. As described above, the lower side of the fan housing 251 is opened downward so that the air below is introduced into the fan housing 251. As described above, the blowing fan rotates by being axially coupled to a fan motor (not shown).

The air sucked by the blower fan 250 is blown directly toward the transformer 210. This is to cool the heat generated during the transformer 210 converts the commercial voltage into a high voltage.

The capacitor 270 is a kind of capacitor that is passed in the process of transmitting the high voltage generated by the transformer 210 to the magnetron 230. Therefore, when the voltage generated by the transformer 210 does not become a high voltage above a certain level, it is compensated by the voltage stored in the capacitor 270. In this case, even if a deviation occurs in the voltage from the transformer 210, the voltage supplied to the magnetron 230 is kept constant.

On the other hand, the barrier 300 is installed in the electric chamber 200 in the vertical direction. The barrier 300 is formed by bending a predetermined iron plate, and the left side is fixed to the right wall surface of the cavity 150. And the lower end is fixed in close contact with the upper surface of the base cover 103.

It is preferable that the barrier 300 is fixed by joining fastening members such as screws or welding.

Meanwhile, an air outlet (not shown) is formed at the lower side of the barrier 300, and a connector insertion hole 310 is formed at an approximately middle portion.

The blower is perforated so that the air sucked by the blower fan 250 is blown to the rear of the electric chamber 200, that is, the transformer 210. Therefore, the air vent is preferably formed at a position corresponding to the outlet side of the fan housing 251 of the blower fan 250.

The connector insertion hole 310 is formed so as to communicate a predetermined size between the front and rear of the electric compartment partitioned by the barrier 290. In addition, a connector to be described below is inserted into the connector insertion hole 310.

The barrier 300 configured as described above corresponds to the width of the electric compartment 200, more specifically, the distance from the right side wall of the cavity 150 to the right end of the base cover 103. And it corresponds to the height of the electric chamber 200, that is, the distance from the upper surface of the base cover 103 to the lower surface of the upper cover 101. Therefore, when the barrier 300 is installed in the battlefield chamber 200, the space of the battlefield chamber 200 is partitioned back and forth.

The barrier 300 is installed between the transformer 210 and the blower fan 250 that are installed in the electrical equipment room 200. Therefore, the air blown by the blower fan 250 is prevented from flowing backward by the barrier 300.

On the other hand, the electric wire 400 is provided between a plurality of electric components provided in the electric compartment 200, that is, the transformer 210, the magnetron 230, the blower fan 250, and the capacitor 270. The wire 400 is provided to supply power to the electrical components as described above, and to transmit and receive electrical signals. Accordingly, the wire 400 traverses the space of the electrical equipment room 200 back and forth to connect the electrical equipments installed in the electrical equipment room 200.

In particular, connecting the electric wire 400 between the electric component installed on the front side of the electric compartment 200 and the electric component installed on the rear side is inserted into the connector insertion hole 310 of the barrier 300 installed therebetween. This is made possible by the connector 500.

As shown in FIG. 4, the connector 500 includes a plug 510 and a socket 530 that is mated with the plug 510.

The plug 510 is provided at an end portion of the electric wire facing backward from the front electric component of the electric equipment compartment, and the socket 530 is provided at the end of the electric wire facing forward from the rear electric component. However, the position of the plug 510 and the socket 530 may be changed according to a user's selection.

Hereinafter, looking at the wire 400 is connected through the barrier 300 by the connector 500 as follows.

Once the blower fan 250 is installed on the front side of the electric compartment 200. Then, the wires connected to the blower fan 250 and the wires connected to the control panel C are collected to form a plug 510 at an end thereof. On the other hand, the transformer 210, the magnetron 230, and the capacitor 270 are installed on the rear side of the electric compartment 200. A socket 530 is formed at an end of the wire connected to the component.

In the state where a plurality of electrical components are installed in the electrical equipment room 200 as described above, the barrier 300 having the connector insertion hole 310 is formed in the electrical equipment room 200.

Thereafter, when the socket 530 is inserted into the connector insertion hole 310 of the barrier 300, an end portion of the socket 530 protrudes toward the front side of the electric chamber 200. Then, the plug 510 is fastened to the end of the protruding socket 530. In this case, the wire 400 penetrates through the barrier 300 partitioning the electric compartment 200, thereby connecting the electric components.

Meanwhile, the size and shape of the connector insertion hole 310 may correspond to the outer shape of the plug 510 or the socket 530 inserted therein. That is, when the socket 530 is inserted into the connector insertion hole 310, a gap is not generated between the socket 530 and the connector insertion hole 310. This is to prevent backflow of air between the outer edge of the socket 530 and the connector insertion hole 310 in a state where the plug 510 and the socket 530 are fastened around the connector insertion hole 310. Of course, when the plug 510 is inserted into the connector insertion hole 310, it is obvious that a gap does not occur between the plug 510 and the connector insertion hole 310.

Looking at the air flow in the configuration as described above are as follows.

When the fan motor is started by the electrical signal, the axially coupled blower fan rotates to suck in the air below. The sucked air is guided by the fan housing 251 and blown to the transformer 210 side of the electric compartment 200. At this time, the air blown from the fan housing 251 is blown directly to the transformer 210 by the air vent of the barrier 300.

The blown air cools the transformer 210 in a heated state and then is discharged to the outside of the microwave oven through an exhaust port of the back cover 107. On the other hand, a part of the air passing through the transformer 210 is guided by the barrier 300 and is introduced into the cavity 150 through an inlet formed in a perforation formed on the right wall surface of the cavity 150.

In this process, the wire 400 penetrates the barrier 300 by the connector 500 composed of the plug 510 and the socket 530. The plug 510 or the socket 530 is tightly fixed to the connector insertion hole 310, so that a passage for communicating the front side and the rear side of the electric chamber 200 is not formed on the barrier 300. Therefore, the air blown to the rear of the battlefield chamber 200 by the blower fan 250 is prevented from flowing back toward the battlefield chamber 200.

In addition, since the connection of the wire 400 is made by the connector 500, the connection between the electrical components is facilitated.

As described above, the present invention is to prevent the air heated by the transformer from flowing into the front of the battlefield. In addition, the present invention is to connect the wires between the connectors. Within the scope of the basic idea of the present invention, more modifications are possible to those skilled in the art.

As described above, in the microwave oven of the present invention, an electric wire connecting between electric components, that is, an electric wire connecting between a front electric component and a rear electric component is connected through a barrier by a connector. This prevents backflow of hot air in the process of cooling the electrical components, ie, the electrical components, between the electric wire and the barrier.

When the reverse flow of the heated air as described above is prevented, the component vulnerable to heat is prevented from malfunctioning by heat, which leads to the advantage that the stable operation of the microwave oven is enabled.

Then, the electric wires are connected by forming a plug at the front electric wire end with respect to the barrier and engaging with each other in the state where the socket is formed at the electric end of the rear electric wire. In this way, it becomes possible to connect more easily between a front electric component and a rear electric component. Therefore, the process of installing a plurality of electrical components inside the electrical chamber is simplified, and the time to manufacture the microwave is shortened.

When the production time is shortened as described above, productivity is improved by increasing the number of microwave ovens produced per hour, and it is possible to manufacture the microwave oven at a lower cost.

Claims (4)

An electric wire connecting between a plurality of electric parts installed inside the electric room; A barrier installed inside the electrical equipment room to prevent the heated air from flowing back to the front of the electrical equipment room during the cooling of the electrical equipment; The wire connection structure of the microwave oven, characterized in that it comprises a connector for connecting the wires provided before and after the barrier. The method of claim 1, wherein the connector, A plug provided at one end of the electric wire; The wire connection structure of the microwave oven, characterized in that comprising a socket to which the plug is fitted. The wire connection structure of the microwave oven according to claim 1 or 2, wherein the barrier is provided with a connector insertion hole into which at least one side of the plug or socket is inserted. The wire connecting structure of the microwave oven according to claim 3, wherein the connector inserting hole has a shape corresponding to an outer edge of the plug or socket.