KR0152847B1 - Microwave leakage prevention device of microwave oven - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high frequency leakage preventing device of a microwave oven, and conventionally, when manufacturing a door of a microwave oven, two pieces of inner surface and an outer surface are welded to form a choke channel to form one piece. There is a problem in that the door cannot be manufactured, and in the case of a low-cost model, if the panel is manufactured by replacing the heat-resistant film without the front panel or the internal viewing glass, the structure of the door seal cannot be used. There was a hard problem. Therefore, the present invention can be manufactured so that the one-piece inner plate and the outer plate can form the choke seal, and can be used in models without a door panel or inexpensive models using heat-resistant film instead of see-through glass. In addition to savings, it also contributes to increased productivity.

Description

Microwave Leakage Prevention Device

1 is a perspective view of a general microwave oven to which a conventional high frequency leakage preventing device is applied.

2 is a partial cross-sectional view showing a conventional high frequency leakage preventing choke seal structure.

Figure 3 is a partially cutaway perspective view showing in detail the structure of a conventional high frequency leakage preventing choke seal.

4 is an explanatory diagram showing fringing capacitance formed by a slot provided in the choke seal.

5 is an explanatory diagram showing a high frequency energy flow leaking from the heating chamber to the outside.

6 is a partial cross-sectional view showing the structure of the choke seal for preventing high frequency leakage of the present invention.

Figure 7 is a partially cutaway perspective view showing in detail the structure of the choke seal for preventing high frequency leakage of the present invention.

8 is a cross-sectional view of a microwave oven having a door having a structure of a choke seal for preventing high frequency leakage of the present invention.

FIG. 9 is an explanatory diagram showing the impedance of λ / 4 choke seal in FIGS. 6 and 7. FIG.

FIG. 10 is a transmission characteristic diagram according to the angle of incidence of incident waves in the choke in FIG.

* Explanation of symbols for main parts of the drawings

1: microwave oven body 2: door

3: Perspective glass 4: Outer plate body

5: inner plate 5'a: upper horizontal portion

5'b: Lower horizontal part 5'c: Vertical part

6: chalk seal 7: chalk cover

9,10: Contact seal

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a door choke seal structure for preventing high frequency leakage in a microwave oven, and in particular, to effectively prevent high frequency leakage to the outside through a gap between the front panel and the door when the microwave oven is heated. It relates to a high frequency leakage preventing device of a microwave oven.

As is well known, microwave ovens are convenient kitchen containers for cooking food by heating the food by heating the food inside the heating chamber by heating the food inside the heating chamber. If it is irradiated over a certain amount, it will cause fatal harm to the human body. Therefore, high frequency should be prevented from leaking from the heating chamber to the outside.

Microwave ovens that are commonly used are configured such that a predetermined gap is formed between the front panel of the heating chamber and the door.

Therefore, the high-frequency leakage preventing device of the microwave oven for preventing the high-frequency leakage through the gap is the inner side to form a primary capacitive seal between the door to open and close the heating chamber, and the front panel and the door of the heating chamber. An outer plate body having an upper end attached to and fixed to the inner plate and the inner plate to form a choke channel at a predetermined interval between the inner plate and the lower plate of the inner plate is bent in two stages to the choke seal side. Second step between the step portion having a horizontal portion and the vertical portion, a slot formed at regular intervals in the vertical portion and the lower horizontal portion of the step portion, the c-shaped bent portion of the lower end of the outer plate body and the front panel of the heating chamber With a choke cover to close the opening of the choke channel formed between the bent portion forming the capacitive seal and the lower horizontal portion of the stepped portion and the bent portion of the outer plate. It is composed.

The prior art thus constructed will be described in detail with reference to FIGS. 1 and 2 as follows.

First, as shown in FIG. 3, when the flow of the high frequency energy formed from the heating chamber 8 is displayed as a vector, it can be displayed as X component, Y component, and Z component, respectively.

At this time, the cause of high frequency leakage is a high frequency leakage to the X component and the Z component.

In order to prevent such a high frequency energy component, the choke which prevents the progress of the high frequency energy to X component, and the choke which prevents the progress to Z direction are needed, respectively.

Here, the slot 5'd periodically formed in the stepped portion 5 'acts as a bandstop filter to the high frequency energy traveling in the X direction, thereby preventing high frequency leakage in the X axis direction.

The fringing capacitance formed by this periodic slot structure is as shown in FIG.

That is, fringing of C ₁ and C ₂ occurs between the front panel 1 'and the slot 5'd, and the slot 5'c and the outer plate 4 of the choke channel 6 are perpendicular to each other. Between the portions 4d there is a fringe of C ₃ and C ₄ .

It is also shown in Floguet's Theorem that this periodic slot structure can act as a filter.

In other words, when a ω-β relationship is derived from such a structure, β becomes an imaginary in a band. In this case, the ω-β relationship is a region where high-frequency energy is attenuated. 3, the width (D ₁₎ and is a function of the width (D ₂₎ of the slot bit (5'd), the front panel (1 a vertical section (5'c) a) ") and the vertical part (5'c) It is a function of the interval between.

Therefore, when the high frequency energy is attenuated in the vicinity of 2450 MHz of the high frequency used in the microwave, such a periodic structure acts as a bandstop filter, thereby preventing leakage of structural wave energy traveling in the X direction.

In addition, the choke in the Z direction has a λ _g / 4 choke seal as the main role, and the flow of high frequency energy from the heating chamber 8 can be expressed as in FIG.

That is, when high frequency energy flows from point A on the side of the heating chamber 8 to point C outside, the impedance relationship on the heating chamber 8 side can be represented by jx, and the point where jx becomes infinite is on the AC path. If it is located in the AC transmission path is to be able to block the leakage of high-frequency energy.

Here, the lambda _g / 4 choke seal comprises two capacitive seals 9 and 10, as mentioned above, and a stepped portion 5 'in which a slot 5'd having a certain period is formed. ).

In the case of forming a choke seal having such a structure, the choke channel 60 has a length L, a width W, and a lower horizontal portion 5'd of the stepped portion 5 'and a lower horizontal surface of the outer plate 4. The height H between (4c) and the like are major factors, and the important factors in forming the periodic slots 5'd and the first and second capacitive seals 9 and 10 are the third factor. As shown in the figure, D ₁ , D ₂ , E, and the upper vertical portion 5'a of the inner plate body 5 and the like.

As described above, a slotted structure having a certain period and an auxiliary capacitive seal are formed to simultaneously prevent leakage of high-frequency energy in the X-axis direction and the Z-axis direction, and are provided in two stages on the inner plate of the choke channel. By forming a bent step, it is possible to reduce the width of the choke channel to make the door thin.

However, in the prior art as described above, the door can be manufactured from one piece by forming a choke channel by welding two pieces of the inner face and the outer face when manufacturing the door of the microwave oven. There is no problem, and in the case of a low-cost model, when the panel is manufactured by replacing the heat-resistant film without the front panel or the internal viewing glass, the structure of the door seal cannot be used, and thus it is difficult to delete the front panel or the viewing glass. .

Accordingly, an object of the present invention is to provide a microwave high frequency leakage preventing device for manufacturing a door of a microwave oven with a single panel (fragment) and to increase flexibility in door manufacturing while using the front panel and the sight glass as it is. have.

The present invention for achieving the above object is connected to the inner plate body 4 and the inner plate body (4) which is in contact with the front panel (1 ') of the heating chamber, the front panel of the heating chamber and the second bend is Separated by the choke seal between the outer plate body 5 and the outer plate body 4 and the outer plate body 5 to shield the high-frequency energy leaked to the outside from the heating chamber, leakage from the heating chamber to the outside Shielding means for shielding the high frequency energy of the Z component to be formed, and the choke cover is mounted in a straight line between the upper horizontal portion of the outer plate 5 and the lower horizontal portion of the inner plate body.

When described in detail with respect to the operation and effect of the present invention configured as described above.

The distribution of the electromagnetic field inside the heating chamber 8 can be expressed in a complex and sum of many modes, and the direction and polarization of the electromagnetic waves incident on the choke seal 6 of the door in this heating chamber are freely divided. In general, the polarization of electromagnetic waves that contribute to leakage into the gap of the door is TE ^x mode.

In order for the electromagnetic wave of such polarization to leak to the outside of the door, the resonance characteristic of the choke is greatly affected by the incident angle of incidence, and thus, a countermeasure for this polarization is required.

8 shows the resonance characteristics of the choke coil according to the incident angle of the electromagnetic wave, and a choke design insensitive to the change of the angle of the incident wave is required.

As described above, the high-frequency leakage prevention can be shown as X component, Y component, and Z component, respectively, as shown in FIG. 8 when the flow of the high frequency energy formed from the heating chamber 8 is displayed as a vector.

At this time, the high frequency leakage substantially causes high frequency leakage to the X component and the Y component.

In order to shield such high-frequency energy components, the outer plate 5 shielding the leakage of high-frequency energy in the X direction, the choke seal and the front panel of the microwave oven door preventing the leakage of high-frequency energy in the Z-direction (1). A structure of the inner plate body 4 that contacts the ') to form the primary contact seal 9 and the secondary contact seal 10 is required.

The process of shielding the high frequency energy of the X- and Y-direction components is as follows.

As shown in FIGS. 6 and 7, the upper right vertical portion is integrally formed with the inner plate body 4 which contacts the front panel 1 'to form the primary contact seal 9 and the secondary contact seal 10. As shown in FIG. An upper horizontal portion 5'a which is first bent at the end of 4b and has a predetermined length in the horizontal direction, and a vertical portion having a predetermined length in the vertical direction with the end of the upper horizontal portion 5'a; (5'c) and the outer plate body (5) consisting of the lower horizontal portion (5'b) having a predetermined length in the horizontal direction bends at the end of the vertical portion (5'c) in the X direction It cuts off the leakage of ongoing high frequency energy.

The inner plate 4 integrally connected to the outer plate 5 has a structure similar to the S-shape, and contacts the front panel 1 ′ of the inner plate 4 having the structure to make a primary contact. The upper and lower vertical portions 4b and 4e of the inner plate body 4 forming the seal 9 and the secondary contact seal 10 and the front panel 1 'form a parallel plate line, and the characteristic impedance at this time Becomes Zo α (1 / gap), so that the smaller the gap, the more advantageously it works.

In addition, the two contact seals 9 and 10 and 4a, 4d, 4c, and 4b forming the inner plate 4 and the outer plate 5 are connected to each other to form a lambda / 4 choke seal. When forming the λ / 4 choke seal, the length L and width W of the choke seal 6 and the lower horizontal portion 5'b of the outer plate 5 and the lower side of the inner plate 4 are formed. The height H between the horizontal portions 4a is an important factor, and the geometric size formed by the length L and the width W is the upper and lower horizontal portions 5'a of the outer plate 5. (5'b) and the vertical portion (5'c) is controlled to allow resonance to occur at the operating frequency of 2,450MHz.

At this time, the upper horizontal portion (5 'a) of the outer plate (5) is designed to be the thickness of the choke cover (7), the choke cover (7) to prevent the debris, such as food into the choke seal (6) Give it.

Then, the choke cover 7 is inserted into the size of the upper horizontal portion 5'a to increase the thickness of the microwave oven door by inserting the choke cover, i.e., to increase the door thickness by adding the width of the choke cover. You can stop it.

The difference in the characteristic impedance of the transmission line between 4d-4b and 4d-5'c of the inner plate 4 is caused by the step of the upper horizontal portion 5'a of the outer plate 5, which is together Since Z _{O1 and} Z _O2 are determined by the ratio of L and C in the choke region, the resonance point of the transmission line may occur even below λ / 4.

In other words, by placing discontinuous points on the characteristic impedance of the transmission line, the resonance can occur even if L is less than λ / 4. If the lower horizontal part 5'b is adjusted to match the resonance point, an accurate resonance point can be set. You can do that.

The incident wave number of the incident wave incident on the door side in the heating chamber of the microwave oven is Can be displayed as The incident wave in the direction of can be blocked by the mentioned primary contact seal 9, secondary contact seal 10 and λ / 4 choke seal, The incident wave in the direction can be effectively prevented through the secondary bent structure.

The secondary bent structure is formed by the vertical portion 5'c and the lower horizontal portion 5'b of the outer plate body 5, and the period T is formed by the slits D ₁ and D ₂ . Summation, and this structure adjusts the ratio of slit (D ₁ ) and (D ₂ ) to implement a bandstop filter for incident waves in the χ direction, and through the bandstop filter implemented It is possible to block the traveling component wave in the direction.

In this way, the choke resonance which is insensitive to the change in the incident angle of the incident wave can be designed by attenuating the components of the choke with the resonance characteristic of the choke according to the change of the incident angle of the incident wave.

Referring again to the prevention of high-frequency leakage of the microwave oven, when the high-frequency energy formed in the heating chamber 8 leaks in the A direction to the C direction as shown in FIG. The choke seal 6 having a predetermined width W and a length L is primarily shielded from the high frequency in the X-direction by the outer plate 5, which is provided. ) To shield the high frequency in the Z direction.

The choke cover 7 is positioned in a straight line between the upper horizontal portion 5'a of the outer plate 5 and the lower horizontal portion 4a of the inner plate 4, wherein the thickness of the choke cover 7 The choke cover 7 can be fitted to the bottom of the upper horizontal portion 5'a as shown in FIGS. 6 and 7 so that the thickness of the upper horizontal portion 5'a of the outer plate body 5 is the same. To prevent the door from getting thicker.

In addition, a change in characteristic impedance due to the steps W ₁ and W ₂ allows resonance to occur below L / 4, and an accurate resonance point through the lower horizontal portion 5'b of the outer plate 5. This allows the design to be easy or easy to tune by reducing the size of the choke seal by allowing tuning to

In this way, the inner plate and outer plate in one piece can be manufactured to form choke seals, and can be used for models without door panels or low-cost models that use heat-resistant film instead of see-through glass. It also helps to improve productivity.

Claims (5)

A door for opening and closing a heating chamber, an inner plate body 4 in contact with the front panel 1 'of the heating chamber, and an X direction connected to the inner plate body 4 to be bent secondarily to leak out of the heating chamber to the outside. Shielding the high frequency energy of the Z component which is formed by the outer plate body 5 and the choke seal between the inner plate body 4 and the outer plate body 5 to shield the high frequency energy of the outside and leaks to the outside in the heating chamber. A shielding means, and a choke cover mounted in a straight line between the upper horizontal portion of the outer plate 5 and the lower horizontal portion of the inner plate 5, high frequency leakage preventing apparatus of the microwave oven. According to claim 1, wherein the outer plate body is an upper horizontal portion which is in contact with the upper left vertical portion of the inner plate body with a predetermined length in the horizontal direction, and a vertical portion bent vertically downward to the end of the upper horizontal portion having a predetermined period And a lower horizontal portion bent horizontally with a predetermined period at the end of the vertical portion. 3. The high frequency leakage preventing apparatus of the microwave oven according to claim 2, wherein the upper horizontal portion of the outer plate is designed to have the same thickness as the choke cover. 3. The high frequency leakage preventing device of the microwave oven according to claim 2, wherein the upper and lower horizontal parts and the vertical parts adjust the geometric size of the choke seal and control the resonance to occur at a frequency of 2,450 MHz. According to claim 2, The outer plate is a high frequency leakage preventing device of the microwave oven to achieve the same effect of shielding the high-frequency energy of the X direction leaked to the outside from the heating chamber by using the upper horizontal portion and the vertical portion except the lower horizontal portion. .