KR200151443Y1 - Microwave oven - Google Patents

Abstract

A microwave oven is disclosed, which allows high frequency to be incident evenly inside a cooking chamber, and allows high frequency to be contacted with food in multiple times. The microwave oven includes a cooking chamber and a control chamber, a cabinet including partition walls separating the cooking chamber and the control chamber, a transformer for generating a high voltage, a circular first radio wave absorbing means and a second radio wave absorbing member for absorbing leakage radio waves, A first wave absorbing member includes a circular waveguide extending to the control chamber side, a magnetron for outputting a high frequency, a dispersion member for distributing high frequency, a resistor having a slit, and a delay element for adjusting a delay time of the high frequency. By improving the shape of the waveguide, the high frequency can be uniformly incident inside the cooking chamber, and the high frequency can be touched by the food in multiple to improve the heating effect on the food.

Description

Microwave Oven with Circular Waveguide

The present invention relates to a microwave oven, and more particularly, an electron capable of effectively heating food by injecting a high-frequency microwave energy generated from a magnetron into a cooking chamber while spreading a large area while allowing multiple incidents. A circular waveguide for a stove.

As is known, a microwave oven is a device for dielectric heating of food by applying a high voltage to a high frequency oscillating tube to generate a high frequency.

In general, microwave ovens are equipped with a transformer that generates a high voltage. The transformer generates a high voltage by mutual induction of the primary and secondary induction coils. A magnetron is used as the high frequency oscillation tube, and the magnetron is applied with a high voltage by a transformer. The magnetron is subjected to a high voltage generates a high frequency. The high frequency generated in the above process proceeds into the cooking chamber of the microwave oven through the waveguide and the slit formed in the partition wall between the waveguide and the cooking chamber. When the high frequency passes through the slit, the high frequency is diffracted by the slit to enter the cooking chamber. The diffracted high frequency is reflected on the surfaces of the cooking chamber to reach the food or directly to the food to heat the food.

1 shows such a conventional microwave oven. Referring to FIG. 1, the microwave oven 10 includes a cabinet 20. The cabinet 20 includes a cooking chamber 30 and a control chamber 40. The cooking chamber 30 and the control chamber 40 are separated from each other by the partition wall 50. A transformer 42 is disposed at one lower side of the control chamber 40. The waveguide 48 is attached to a predetermined position of the partition 50 toward the control chamber 40, and the magnetron 44 is coupled to one end of the waveguide 48. The transformer 42 is electrically connected to the magnetron 44. The transformer 42 receives power from the outside to apply a high voltage to the magnetron 46, and the magnetron 44 generates a high frequency. At one end of the magnetron 44, an antenna 46 for transmitting the high frequency is integrally formed. Slits 52 are formed in the partition wall 50 so that the high frequency generated by the magnetron 44 can be incident into the cooking chamber 30.

The operation of the microwave oven 10 having such a configuration is as follows.

In general, an operating switch (not shown) of a microwave oven is attached to the front part of the cabinet 20. First, the user presses the operation switch to operate the microwave oven. A microcomputer (not shown) embedded in the microwave oven 10 transmits an operation signal to the transformer 42 to cause the transformer 42 to generate a high voltage. The high voltage generated from the transformer 42 is transmitted to the magnetron 44 so that the magnetron 44 generates a high frequency. The high frequency generated by the magnetron 44 is incident to the cooking chamber 30 through the slits 52 formed in the antenna 46, the waveguide 48, and the partition wall 50. The high frequency wave is diffracted while passing through the slit 52. The diffracted high frequency spreads widely and proceeds into the cooking chamber 30. The high frequency propagated into the cooking chamber 30 directly reaches the food or is reflected by the surfaces of the cooking chamber 30 to reach the food, thereby heating the food according to the above process.

However, the microwave oven 10 having the above-described configuration has a high frequency reflected in the waveguide 48, loss occurs, and the diffraction range is also limited. Therefore, since the high frequency incident to the cooking chamber 30 only penetrates the food by a limited depth, when a large amount of food is placed in the cooking chamber 30, there is a problem that the food is unevenly heated.

In order to solve the above problem, a microwave oven having a slit having various shapes has been developed so that a large amount of high frequency can be irradiated to food. These slits are designed to heat food by non-uniformly diffracting high frequency incident into the cooking chamber or by reducing loss of high frequency incident. However, the effect of evenly heating the food was not obtained.

The present invention is devised to solve the problems of the prior art as mentioned above, the object of the present invention is to allow high frequency evenly incident inside the cooking chamber, heating the food to the food by multiple high frequency It is to provide a circular waveguide for a microwave oven that can improve the effect.

1 is a cross-sectional view schematically showing a conventional microwave oven.

2 is a cross-sectional view schematically showing a microwave oven according to an embodiment of the present invention.

3 is a perspective view of the microwave waveguide according to FIG. 2.

* Description of the symbols for the main parts of the drawings *

10, 100: microwave 20, 120: cabinet

30, 130: cooking chamber 40, 140: control room

42, 142: transformer 44, 144: magnetron

46, 146: antenna 48, 148: waveguide

50, 150: bulkhead 52, 152: slit

160: wave dispersion film 162: first choke ring

164: second choke ring 170: resistor

174: resistive film

In order to achieve the above object, the microwave oven according to the present invention is provided with a cabinet. The cabinet includes a cooking chamber and a control chamber. The cooking chamber and the control chamber are separated from each other by a partition wall. A transformer is installed at one lower side of the control room. At a predetermined position of the partition wall, a circular first choke ring serving as a first radio wave absorbing means for absorbing leakage radio waves is provided. The first choke ring is provided with a circular waveguide having a second choke ring, which is a second wave absorbing means, at an opposite end of the first choke ring to absorb leakage radio waves. The second choke ring of the waveguide is fixedly provided with a magnetron for generating a high frequency by receiving a high voltage from the transformer. A wave dispersion film is formed in the waveguide to disperse high frequency concentration, and the first choke ring has a resistor having a slit having a shape that gradually widens outward from the inside of the waveguide so as to delay and release the high frequency wave. It is fixedly installed. In the middle of the resistor is provided with a resistance film for adjusting the delay time of the high frequency incident into the cooking chamber.

The user presses the operation switch of the microwave oven on the front of the cabinet to operate the microwave oven. The microcomputer embedded in the microwave oven transmits an operation signal to the transformer. The transformer receiving the operation signal generates a high voltage. Since the transformer and the magnetron are electrically connected to each other, the high voltage generated from the transformer is transmitted to the magnetron, and thus high frequency is generated in the magnetron. The high frequency generated by the magnetron is radiated through the antenna and reaches the wave dispersion film. The wave dispersion film is dispersed so that the high frequency incoming in the form of a spherical wave can be spread sufficiently inside the waveguide. At this time, the radio wave which adversely affects the radio wave incident to the cooking chamber while being reflected in the lost radio wave or the waveguide is absorbed by the first choke ring and the second choke ring having the choke structure. The high frequency passing through the wave dispersion film passes through the slit formed in the resistor. Since the slit is formed in a gradually widening shape, the slit serves as a condenser for radio waves, and serves to store radio waves for a while. In this case, the resistance film adjusts the time that the high frequency is delayed in the slit. Since the propagation is delayed due to the shape of the slit, the phase of the high frequency is changed, and since the high frequencies having the changed phase are incident to the cooking chamber continuously, multiple high frequencies can obtain the effect of heating food.

According to the present invention, the high frequency can be irradiated uniformly inside the cooking chamber, and the high frequency can be irradiated to the inside of the cooking chamber multiplely, thereby improving the heating effect on the food.

2 is a cross-sectional view showing a microwave oven according to an embodiment of the present invention. Referring to FIG. 2, the microwave oven 100 includes a cabinet 120. The cabinet 120 includes a cooking chamber 130 and a control chamber 140. The cooking chamber 130 and the control chamber 140 are separated from each other by the partition wall 150.

The lower side of the control room is provided with a transformer 142 for generating a high voltage by receiving power. The first choke ring 162, which is the first radio wave absorption member, is fixedly attached to a predetermined position of the partition wall 150 toward the control room 140 side. The thickness of the first choke ring is preferably about 2 mm. A circular waveguide 148 is fixed to the first choke ring. A second choke ring 164 is provided at the opposite end of the first choke ring 162 of the waveguide 148. One end of the second choke ring is provided with a magnetron 144. The first and second choke rings 162 and 164 have a choke structure in which the structure is rolled inside. Therefore, the electromagnetic wave incident into the choke is not reflected again but is absorbed in the choke structure.

3 is a perspective view illustrating the shape of the waveguide according to FIG. 2. Referring to FIG. 3, the magnetron 144 is electrically connected to the transformer 142. When the user applies power, the transformer 142 applies a high voltage to the magnetron 144. The magnetron 144 applied with the high voltage radiates high frequency through the antenna 146 extending toward the waveguide 148. The wavefront of the high frequency radiated through the antenna 146 is a spherical wave, and the high frequency encounters the wave dispersion film 160 installed inside the waveguide 148 while traveling inside the waveguide 148.

The wave dispersion layer 160 has a rectangular mesh shape and is composed of Teflon. The wave dispersion film 160 disperses a high frequency wave toward the cooking chamber 130 between the rectangular meshes and passes through the wave dispersion film 160. The high frequency wave injected by the wave dispersion layer 160 meets the resistor 170.

The resistor 170 is made of a conductive metal, and a slit 152 narrowing from the cooking chamber 130 toward the magnetron 144 is formed in the middle. The resistor has a shape in which the semicircle pillars are cut out in a semicircle form to face each other, and a resistance film 174 that is a delay element is formed across the slit 152 in the middle of the two semicircle pillars. The resistive film 174 is formed by printing carbon on a thin film-epoxy substrate. The resistive film 174 is formed in succession to concave and convex. In this way, concave and convex portions are formed continuously, and the resistance value of the resistive film 174 is optimized by adjusting the period and length of the concave and convex portions.

The high frequency passing through the wave dispersion layer 160 is incident to the slit 152 of the resistor 170. Since the slit 152 has a shape of being widened to the cooking chamber 130, the slit 152 functions as a condenser to store the high frequency when the high frequency passes the slit 152. Thus, the high frequency causes a delay in passing the slit 152. At this time, the resistance film 174 adjusts the delay time. As the time incident to the cooking chamber 130 is delayed in the process, a change in phase of the high frequency occurs every time. The high frequency, which has changed over time, continues to leave the slit 152 completely.

The high frequency wave is first dispersed by the wave dispersion layer 160 and second wave is diffracted by the slit 152 to diffuse into a wider area than the effect of a general slit. During the process, high frequency or lost radio waves that do not pass through the slit 152 of the resistor 170 prevent the high frequency continuously output from the antenna 146 from entering the cooking chamber 130. The radio waves that interfere with the high frequency incident to the cooking chamber 130 are absorbed by the first choke ring and the second choke ring. The high frequency incident into the cooking chamber 130 reaches the food directly or by reflecting the surfaces in the cooking chamber 130, whereby the food is heated.

The microwave oven according to the present invention described above can improve the shape of the waveguide so that the high frequency can be uniformly incident inside the cooking chamber, and the high frequency can be touched to the food in multiple to improve the heating effect on the food.

Although the preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, the present invention is not limited thereto and may be improved or modified by those skilled in the art within the scope of the technical idea of the present invention.

Claims (11)

A cabinet including a cooking chamber and a control chamber and including a partition wall separating the cooking chamber and the control chamber; A transformer installed at one side of the lower side of the control room to generate a high voltage by receiving power; A circular waveguide fixedly connected to the partition wall and extending toward the control room; A magnetron fixedly connected to an opposite side of the partition wall of the waveguide, the magnetron having an antenna and receiving a high voltage from the transformer to output a high frequency through the antenna; Dispersion means installed in the waveguide and dispersing high frequency output from an antenna; A resistor in which a slit is formed for injecting the high frequency dispersed in the dispersing means into the control room; And And a delay element installed in the resistor to adjust the delay time of the high frequency wave. 2. The apparatus of claim 1, further comprising: circular first radio wave absorbing means installed on the partition wall to absorb leakage radio waves; And A second wave absorbing means installed on an opposite side of the first wave absorbing means of the waveguide and for absorbing leakage radio waves together with the first wave absorbing means, wherein the waveguide is fixedly connected to the first wave absorbing means. And the magnetron is fixedly connected to the second electromagnetic wave absorbing means. 3. The microwave oven according to claim 2, wherein said first radio wave absorbing means has a choke structure. The microwave oven according to claim 2, wherein the second radio wave absorption means has a choke structure. The microwave oven according to claim 1, wherein the dispersing means has a mesh shape and is made of Teflon. The microwave oven of claim 1, wherein the resistor is made of a conductive metal. The microwave oven according to claim 1, wherein the resistor is formed by cutting a semi-circular column in a semicircle form to face each other. 8. The microwave waveguide of claim 7, wherein the resistor includes a slit that widens in the direction of the cooking chamber from the waveguide. The microwave oven of claim 1, wherein the delay element is installed while crossing a slit formed in the resistor. The microwave oven according to claim 1, wherein the delay element is formed by printing carbon on a thin film glass-epoxy substrate. The microwave oven according to claim 1, wherein the delay element has a shape in which concave and convex are continuously formed.