KR970011496B1 - Capacitor of magnetron for microwave oven - Google Patents

Abstract

The capacitor is characterized by the features that: an open aperture part(111) is formed on one side of a shield case(100); a projecting part(110) is formed on the edge of the open aperture part; a reinforcement rivet(112) is formed around the projecting part; a bend(32) is formed on bottom of a fixing tap(31) of a penetration conductor(30) which is inserted into a penetration hole(13) of a ceramic dielectric(10); and the top/bottom of the ceramic dielectric(10) and the penetration hole(13) are moulded with an epoxy insulation resin(120).

Description

Capacitor of Magnetron for Microwave Oven

1 is an exploded perspective view illustrating an embodiment of the present invention.

Figure 2 is a (a) is a front cross-sectional view illustrating an embodiment of the present invention.

(B) is a side cross-sectional view illustrating an embodiment of the present invention.

3 is an exploded perspective view illustrating the prior art.

* Explanation of symbols for main parts of the drawings

100: shield case 110: protrusion

111 opening 112

120: insulating resin 10: ceramic dielectric

11 separation electrode 12 common electrode

13 through hole 20 electrode plate

30: through conductor 31: fixed tab

32: bending piece 40: insulating plate

50: insulated box 60: insulated cylinder

80: grounding metal ball 81: top cover

The present invention relates to a capacitor capable of effectively shielding noise generated in a magnetron of a microwave oven. In particular, the present invention provides a simple and good performance of a capacitor to improve productivity and lower the overall manufacturing cost of a capacitor. It is about.

In general, one side of the microwave oven is equipped with a magnetron for generating a high frequency, and the primary and secondary induction coils of the high-voltage transformer attached to the bottom plate of the main body of the magnetron are generated by mutual induction. As the high voltage is stably applied to the magnetron, the magnetron generates high frequency.

The high frequency generated by the magnetron is configured to irradiate the inside of the cooking chamber through the waveguide, and the food placed inside the cooking chamber is heated and cooked by the high frequency wave.

The main power line of the magnetron is mainly composed of filament, cathode (CATHODE), and anode (ANODE). When a high voltage is applied to the magnetron and oscillates a high frequency, high frequency, that is, unwanted radiation is generated through the cathode and the filament, resulting in electromagnetic waves. The choke coil and capacitors are installed at two places of the filament power supply line to absorb the high frequency noise by using the characteristic that the choke coil is inductive resistance, and connected to the choke coil. The capacitor absorbs or cuts off unnecessary high frequencies.

The choke coil and the capacitor are installed inside and outside of the shield case attached to the lower part of the magnetron. Mainly, one end of both coils is connected to the power supply line of the magnetron filament, and the other end is connected to the conductor wire of the capacitor. It serves to absorb unnecessary high frequency waves.

However, magnetron high frequency absorption capacitors occupy about one-fifth of the total material cost of magnetron despite being functional means of magnetron. This is due to the complicated structure of capacitors and TDK, a Japanese manufacturer. As royalties paid for, the structure was relatively simple and required the development of a unique capacitor at the time.

Therefore, the technical structure of the through-type capacitor of Japanese T.D.K., Inc., which is the prior art, will be described in detail as follows.

First of all, Japanese tea. D. Looking at the case of the prior art of the case of the ceramic case 10 as shown in Figure 3 the upper and lower body and the separating electrode 11 and the common electrode 12 is attached to the ceramic dielectric 10 having a through hole 13; An electrode plate 20 interviewed with the separation electrode 11; A through-conductor 30 having an insulating tube 40 externally inserted into the through-hole 13 of the ceramic dielectric 10 and having a fixing tab 31 formed thereon; A ground metal sphere (80) in which the common electrode (12) is interviewed and fixedly installed on the shield case (100), and the upper cover (81) having an opening is integrally formed; An insulating cylinder 60 inserted below the ground metal sphere 80; An insulator box 50 installed to surround the top cover 81 of the ground metal sphere 80; It is mainly composed of an insulating filler filled in the insulator 50.

Since the conventional prior art is formed of a considerable number of parts, there is a closed end in which the productivity is reduced since the time required for the assembly process is increased as well as the material cost is increased, and the capacitor is separated from the shield case 100 separately. In the process of assembling the deterioration of the ground force is deteriorated bar high-frequency noise could not be effectively shielded.

In addition, in the fixed installation of the ground metal sphere 80 to the shield case 100, four holes in the shield case 100 and then press-molded the ground metal sphere 80 to the bar, as described above High frequency noise is leaked out, and noise shielding cannot be maximized.

The through-type capacitor connecting the choke coil and the external terminal inside the shield case is designed to suppress conduction noise through the lead as well as to block radiation noise, and thus the structure thereof is complicated and very expensive. Therefore, the magnetron maker (Maker) is putting a lot of effort to design a structure that can simplify or replace the structure of the capacitor.

Accordingly, an object of the present invention is to provide a noise shielding device of a magnetron for a microwave oven, which is relatively simple in structure, which can reduce material cost and improve productivity.

Hereinafter, described in detail by the accompanying drawings a preferred embodiment that can achieve the above object is as follows.

That is, the present invention and the shield case 100 is provided on one side of the magnetron; A protrusion 110 having one side surface of the shield case 10 provided with an opening 111; A ceramic dielectric 10 fixed to an upper surface of the protruding portion 110 and having a through hole 13 and a separation electrode 11 and a common electrode 12 attached to upper and lower surfaces of the body; A through tab 30 inserted into the through hole 13 and having a fixing tab 31 formed at an upper portion thereof, and a bending piece 32 disposed below the fixing tab 31; The ceramic dielectric 10 is formed by an insulating resin 120 molded between the lower portion and the through hole 13.

According to the present invention, when the high frequency noise generated in the magnetron is reversed, the choke coil connected to the filament of the magnetron is partially canceled by the coil's inductive resistance, and the remaining high frequency noise is connected to the choke coil. It continues to be extinguished by the ceramic dielectric 10 configured to insert the through-conductor 30 while passing through, and is grounded completely to the common electrode 12 and the shield case 100 which is large.

The above-described action effect is a general configuration and effect of the shielding device of the high frequency noise made of the through-type capacitor, the most important feature of the configuration of the present invention by bending the shield case 100 integrally punching the opening 111 By forming the provided protrusions 110, the ground metal sphere 80 is fixed to the shield case 100 in the prior art to the role that the protrusions 110 to perform instead. Therefore, there is a significant material savings effect, and in particular, since a separate work process due to attaching the ground metal sphere 80 is eliminated, productivity can be improved.

In addition, the related art includes a ceramic dielectric body 10 and an electrode plate 20 which are installed in contact with an upper portion of the ground metal sphere 80 attached to the shield case 100; An insulating box 50 which is covered on the outside of the ceramic dielectric material 10 and an insulating cylinder 60 which is installed below the protrusion 110 of the shield case 100; A ceramic dielectric 10 provided in contact with an upper portion of the protrusion 110 formed integrally with the shield case 100 in a manner of injecting an insulating filler into the insulator 50 and the insulating cylinder 60; The ceramic dielectric 10 and the ceramic dielectric 10 attached to the shield case 100 by molding the insulating resin 120 outside the ceramic dielectric 10 and the lower portion of the protrusion 110 of the shield case 100. The through-conductor 30 fitted in the through-hole 13 of the is to be firmly fixed, it is not necessary to install a separate insulator box 50 and the insulating cylinder 60, assembly with a significant component saving effect The effect is to simplify the process.

In particular, the present invention of molding the insulating resin 120 on the outside of the ceramic dielectric 10 and the lower portion of the protrusion 110 as described above is a reinforcement time of the insulating filler filled in the insulator 50 in the prior art. The longer the longer the time it takes for the overall production is prevented.

In addition, as illustrated in FIGS. 1 and 2, the through conductor 30 is inserted into the through hole 13 of the ceramic dielectric 10 to serve as a conductor through which high frequency noise passes. In particular, through By forming the bent piece 32 integrally under the fixed tab 31 provided on the upper portion of the conductor 30, the bent piece 32 is folded and fixed to the separation electrode 11. In the description of the bar to serve as the electrode plate 20 is inserted into the through-conductor 30, which is placed on the upper surface of the separation electrode 11, there is a reduction effect of the part.

The through conductor 30 is a body of the through conductor 30 in a state in which the bending piece 32 of the through conductor 30 is fixed to the circumference of the through hole 13 of the separation electrode 11 and fixed. After the insulating resin 120 is molded, the insulating resin 120 is filled between the through hole 13 and the through conductor 30 to insulate the through conductor 30. It is configured to the bar, in the prior art, it is possible to reduce the components because there is no need to use a separate insulated tube (40) fitted to the through-conductor 30, in this case the important thing is to be drilled in the ceramic dielectric (10) The size of the through hole 13 is larger than that of the body of the through conductor 30 so as to secure sufficient space for the insulating resin 120 to be filled, and a bending piece provided on the top of the through conductor 30. It is formed smaller than the width of 32 so that the bent piece 32 is caught on the periphery of the through hole 13 of the separation electrode It is preferred.

In the present invention, the high frequency noise generated in the magnetron is continuously extinguished by the ceramic dielectric material 10 configured to insert the through conductor 30 while passing through the through conductor 30, and then the common electrode 12 and the common electrode 12. Compared to the conventional technique in which the ground metal sphere 80 is fixed to the shield case 100 in the process of being grounded to the shielded case 100 and completely extinguished, the protrusion that replaces the role of the ground metal sphere 80 ( Since the 110 is integrally formed in the shield case 100, the ground resistance is considerably reduced since the common electrode 12 of the ceramic dielectric 10 directly contacts the protrusion, so that the high frequency noise is shielded in the shield case 100. It is effectively grounded to) and completely destroyed.

In addition, by forming the reinforcing ribs 112 around the protrusion 110, the strength of the shield case 100 may be increased, and the molding is formed on the exterior of the ceramic dielectric 10 and the lower part of the protrusion 110. The insulating resin 120 can firmly bind components of the capacitor installed in the shield case 100 by using an epoxy-based insulating material having a low permeability and adhesion.

As described above, according to the present invention, the component constituting the capacitor is inserted into the ceramic dielectric body 10 which is in contact with the protrusion 110 of the shield case 100 and the through hole 13 of the ceramic dielectric body 10. It is configured by the through-conductor 30, because the number of parts is reduced by half compared to the prior art it is possible to simplify the assembly process with the reduction and effect of the overall manufacturing cost.

Claims (2)

In the capacitor case of the microwave magnetron including the ceramic dielectric 10 having the separating electrode 11 and the common electrode 12 attached to the upper and lower surfaces of the body and having the through hole 13 formed thereon, one of the shield cases 100 is used. An opening 111 is formed at a side surface, a protrusion 110 is formed at an edge of the opening, and a reinforcing rib 112 is formed at the periphery of the protrusion, and a through hole of the ceramic dielectric 10 is provided to be in contact with the protrusion. A bent piece 32 is formed under the fixed tab 31 of the through-conductor 30 to be inserted into the upper portion 13 of the ceramic dielectric material 10. The ceramic dielectric material 10 is formed in contact with the upper separation electrode 11 of the ceramic dielectric material 10. A magnetron capacitor for a microwave oven, characterized in that the molding is formed by covering the epoxy resin insulating resin 120 having high permeability and adhesion to the upper and lower portions and the through hole (13). The method of claim 1, wherein the size of the through-hole 13 drilled in the ceramic dielectric material 10 is larger than the size of the body of the through-conductor 30 to provide sufficient space for filling the insulating resin 120. It is secured and formed smaller than the width of the bent piece 32 provided on the upper portion of the through conductor 30 so that the bent piece 32 is caught on the periphery of the through hole 13 of the separation electrode 11 Capacitor of magnetron for microwave oven.