JPH08167382A - Magnetron for microwave oven - Google Patents

Abstract

PURPOSE: To provide a magnetron for a microwave oven where a thermal demagnetization quantity of a permanent magnet is reduced without dropping the magnetomotive force. CONSTITUTION: A permanent magnet 18 is positioned between a ferromagnetic yoke 20 and a flange 15b of a metallic sealing body 15. Tapered parts T1, T2 are formed at least on one of the inner circumferential part or the outer circumferential part of the permanent magnet 18 so that at least either the diameter of the outer circumferential part of the permanent magnet 18 or the diameter of the inner circumferential part of the permanent magnet may be larger on the ferromagnetic yoke 20 side than on the flange 15b side.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetron for a microwave oven in which the magnetic efficiency of a permanent magnet is improved and the amount of thermal demagnetization is reduced.

[0002]

2. Description of the Related Art A conventional magnetron for a microwave oven will be described with reference to FIG. Reference numeral 31 is a cylindrical copper anode, and the cathode 32 is located in the center thereof. Anode 3
A plurality of vanes 33 are radially formed between the cathode 1 and the cathode 32. A pole piece 34 is provided so as to cover the end opening of the anode 31, and a metal sealing body 35 is provided above the pole piece 34. Metal seal 3
5 is composed of a tubular portion 35a and a flange portion 35b,
The flange portion 35b is bonded to the pole piece 34. An output unit 36 that outputs a high frequency signal is formed above the metal sealing body 35. An antenna 37 that transmits the high frequency signal to the output unit 36 is provided.

Further, an annular permanent magnet 38 is arranged so that the tubular portion 35a of the metal sealing body 35 is fitted into the central opening portion. The flange portion 3 of the metal sealing body 35
A small protrusion 35c is formed on 5b. Protrusion 35
c reduces the contact area between the flange 35a portion of the metal sealing body 35 and the permanent magnet 38 so that the heat of the anode 31 is not transmitted to the permanent magnet 38 through the flange portion 35b as much as possible.

A plurality of aluminum heat dissipation plates 39 are joined to the outer peripheral portion of the anode 31. Heat sink 3
9 is thermally coupled to the anode 31 and radiates the heat generated by the anode 31. Further, a ferromagnetic yoke 40 is provided so as to surround the anode 31, the cathode 32, the metal sealing body 35, the permanent magnet 38, the heat dissipation plate 39, and the like. York 40
Are magnetically connected to the permanent magnet 38 to form a magnetic circuit.

FIG. 3 shows the output side of the upper half of the magnetron for a microwave oven, and the input side of the lower half is not shown. However, the structure on the input side is almost the same as that on the output side, and a pole piece is provided so as to cover the lower end opening of the anode, and a metal sealing body is provided below the pole piece. Then, the flange portion of the metal sealing body is adhered to the pole piece. On the input side, an input terminal for supplying a power supply voltage to the cathode is connected to the cathode through the opening of the pole piece.

[0006]

The conventional magnetron for a microwave oven as described above has the anode 3 when the operating state is entered.
Heat is generated in 1. These heats are radiated through the heat dissipation plate 39. However, a part of the heat is transmitted to the metal sealing body 35 located on the output side and the input side, and further to the permanent magnet 38. In the recent magnetron for microwave oven, the metal sealing body 35 is made of pure iron having good heat conductivity. For this reason,
The heat of the anode 31 is transmitted to the metal sealing body 35 in the portion in contact with the anode 31 and is transmitted to the entire metal sealing body 35.
It is transmitted to 8. By the way, the permanent magnet 38 is usually a ferrite magnet. For ferrite magnets,
When the temperature rises, thermal demagnetization occurs and the magnetic force rapidly decreases.
As a method of preventing such thermal demagnetization, for example, as described above, a small protrusion 35c is formed on the flange portion of the metal sealing body 35.
Is provided to reduce the contact area between the flange portion 35b of the metal sealing body 35 and the permanent magnet 38. Further, there is a method in which the wall surface of the inner peripheral portion of the annular permanent magnet 35 is tapered so that the flange side 35b of the metal sealing body 35 spreads to reduce the heat transferred from the metal sealing body 35 to the permanent magnet 38. .

By the way, in the former method, that is, in the case where the projection 35c is provided on the flange portion 35b of the metal sealing body 35, if the height of the projection 35c is increased, the permanent magnet 3 is increased.
The heat transferred to 8 can be reduced. However, since the protrusion 35c is raised, the permanent magnet 38 is moved farther from the oscillating portion, and the magnetic efficiency is deteriorated. Further, in recent magnetrons for microwave ovens, in order to collect magnetic flux in the action space of the oscillating portion, the magnetic domains of the ferrite magnet are oriented so as to be directed toward the center of the oscillating portion. For this reason, a part of the magnet does not contribute to oscillation. Therefore, when the wall surface of the inner peripheral portion of the permanent magnet 38 is tapered so that the flange side 35b of the metal sealing body 35 spreads like the latter method, the portion contributing to oscillation is further reduced and the magnetomotive force is increased. descend.

The present invention solves the above-mentioned drawbacks, and an object of the present invention is to provide a magnetron for a microwave oven in which the amount of thermal demagnetization of the permanent magnet is reduced without lowering the magnetomotive force.

[0009]

According to the present invention, a cylindrical anode, a cathode located at the center of the anode, a pole piece located at an end opening of the anode, and a flange portion on the pole piece are provided. A metal sealing body which is joined and has a tubular portion extending from the flange portion, a ferromagnetic yoke arranged so as to surround the tubular portion of the metal sealing body, the ferromagnetic yoke and the metal seal. In a magnetron for a microwave oven, which comprises an annular permanent magnet located between flanges of a body, at least one of a diameter of an outer peripheral portion of the permanent magnet and an inner peripheral portion of the permanent magnet is the yoke from the flange side. A tapered portion is formed on at least one of the inner peripheral portion and the outer peripheral portion of the permanent magnet so that the side becomes larger.

Further, the tapered slope formed on the inner peripheral portion of the permanent magnet is inclined so as to substantially follow the orientation of the magnetic domains of the permanent magnet.

[0011]

According to the above construction, the permanent magnet is located between the ferromagnetic yoke and the flange of the metal sealing body. And
A tapered portion on at least one of the inner peripheral portion and the outer peripheral portion of the permanent magnet so that at least one of the outer peripheral portion of the permanent magnet and the inner peripheral portion of the permanent magnet is larger on the yoke side than on the flange side. Are formed. Thus, when the taper is formed on the outer peripheral portion of the permanent magnet, a passage is formed toward the contact portion between the flange portion of the metal sealing body and the permanent magnet. In this case, the cooling air can be sent through the passage, and the temperature rise of the permanent magnet can be reduced. Further, when the inner peripheral portion of the permanent magnet is tapered, the contact area between the metal sealing body and the permanent magnet is small, and the heat transferred from the metal sealing body to the permanent magnet is small.

As a result, the temperature rise of the permanent magnet is reduced, and a magnetron for a microwave oven with a small amount of thermal demagnetization of the permanent magnet can be realized without lowering the magnetomotive force.

Further, when the taper is inclined so as to substantially follow the orientation of the magnetic domains of the permanent magnet, the reduction of the effective magnetic flux is reduced, and the material efficiency of the ferrite forming the permanent magnet is improved.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to FIG.

Reference numeral 11 denotes a cylindrical copper anode. The cathode 12 is located at the center of the anode 11. In addition, a plurality of vanes 13 are radially arranged in the space between the anode 11 and the cathode 12.
Is provided. Further, the pole piece 14 is provided so as to cover the end opening of the anode 11. A metal sealing body 15 is arranged above the pole piece 14. The metal sealing body 15 includes a tubular portion 15a and a flange portion 1
5b, the flange portion 15b is the pole piece 14
Adhered to. An output unit 16 that outputs a high frequency signal is provided above the pole piece 14. An antenna 17 that transmits a high frequency signal is connected to the output unit 16.

Further, an annular permanent magnet 18 is arranged so that the tubular portion 15a of the metal sealing body 15 is fitted into the central opening portion. The flange portion 1 of the metal sealing body 15
A small protrusion 15c is formed on 5b. Protrusion 15
With c, the contact surface between the flange 15a portion of the metal sealing body 15 and the permanent magnet 18 is reduced so that the heat of the anode 11 is less likely to be transmitted to the permanent magnet 18 through the flange portion 15b.

Further, tapers T1 and T2 are provided on the outer peripheral portion and the inner peripheral portion of the annular permanent magnet 18, respectively. in this case,
At the outer peripheral portion of the permanent magnet 18, the taper T is set so that the outer diameter D2 on the yoke side is larger than the outer diameter D1 on the flange side.
1 is formed. Also, in the inner peripheral portion of the permanent magnet 18, a taper T2 is formed so that the inner diameter d2 on the yoke side is larger than the inner diameter d1 on the flange side. A plurality of heat sinks 19 made of aluminum are joined to the outer peripheral portion of the anode 11. The heat dissipation plate 19 is thermally coupled to the anode 11 and radiates the heat of the anode 11. In addition, a ferromagnetic yoke 20 is provided so as to surround the oscillation unit including the anode 11 and the cathode 12, the permanent magnet 18, the heat dissipation plate 19, and the like. At this time, the yoke 20 is magnetically connected to the permanent magnet 18 to form a magnetic circuit.

In FIG. 1, the upper half of the output side is shown and the lower half of the input side is not shown. However, the input side has almost the same structure as the upper half. For example, anode 1
A pole piece is provided so as to cover the opening at the lower end of the pole piece 1, and a metal sealing body is provided below the pole piece. Then, the flange portion of the metal sealing body is adhered to the pole piece. Further, the structure in which the annular permanent magnet is arranged so as to fit the tubular portion of the metal sealing body is similar to that on the output side. On the input side, an input terminal for supplying a power supply voltage to the cathode is connected to the cathode through the opening of the pole piece.

According to the above construction, the metal seal 15 is formed by the taper T1 formed on the outer peripheral portion of the permanent magnet 18.
A passage is formed toward the contact portion between the flange portion 15b and the permanent magnet 18. Cooling air can be sent through this passage, and the temperature rise of the permanent magnet 18 can be reduced.

Further, due to the taper T2 formed on the inner peripheral portion of the permanent magnet 18, the contact area between the metal sealing body 15 and the permanent magnet 18 is reduced, and the metal sealing body 15 is removed from the permanent magnet 1.
The heat transferred to 8 can be reduced. In this case, by decreasing the effective magnetic flux by inclining the taper so as to substantially follow the orientation of the magnetic domains indicated by the arrow. Further, as a result of the decrease in the effective magnetic flux being reduced, the material efficiency of ferrite is improved.

Next, another embodiment of the present invention will be described with reference to FIG. In FIG. 2, the same parts as those in FIG. 1 are designated by the same reference numerals, and overlapping description will be omitted. In the case of this embodiment, the taper T2 is formed on the entire inner peripheral portion of the permanent magnet 18 from the magnetic pole surface on the yoke side to the magnetic pole surface on the flange portion side. In this case, although the magnetic loss is increased as compared with the embodiment of FIG.
The contact area between the tubular portion 15a of No. 5 and the permanent magnet 18 becomes smaller, and accordingly, the heat transfer from the metal sealing body 15 to the permanent magnet 18 becomes smaller.

In each of the above embodiments, the taper is formed on the outer peripheral portion or the inner peripheral portion of the output side permanent magnet. However, a taper similar to that on the output side can be provided on the outer peripheral portion and the inner peripheral portion of the permanent magnet provided on the input side (not shown). Also in this case, the diameter of the outer peripheral portion and the diameter of the inner peripheral portion of the permanent magnet are formed to be larger on the yoke side than on the flange side. Also,
If the permanent magnets on both the output side and the input side are provided with tapers, respectively, the effect becomes larger.

According to the above construction, the cooling air can be efficiently sent to the contact portion between the flange portion of the metal sealing body and the permanent magnet. Further, the heat transferred from the tubular portion of the metal sealing body to the permanent magnet is reduced. Further, if the taper is inclined so as to substantially follow the orientation of the magnetic domains of the permanent magnet, the reduction of the effective magnetic flux can be reduced. Therefore, the temperature rise of the permanent magnet can be reduced, and the thermal demagnetization amount can be reduced. In addition, the amount of decrease in the effective magnetic flux that contributes to oscillation is small, and the material efficiency of the permanent magnet is improved.

[0024]

According to the present invention, it is possible to realize a magnetron for a microwave oven in which the thermal demagnetization amount of the permanent magnet is reduced without lowering the magnetomotive force.

[Brief description of drawings]

FIG. 1 is a sectional view showing an embodiment of the present invention.

FIG. 2 is a sectional view showing another embodiment of the present invention.

FIG. 3 is a cross-sectional view showing a conventional example.

[Explanation of symbols]

 11 ... Anode 12 ... Cathode 13 ... Vane 14 ... Pole piece 15 ... Metal sealing body 15a ... Cylindrical part 15b ... Flange part 15c ... Protrusion 16 ... Output part 17 ... Antenna 18 ... Permanent magnet 19 ... Heat sink 20 ... Yoke T1 , T2 ... taper

Claims (2)

[Claims] 1. A cylindrical anode, a cathode located at the center of the anode, a pole piece located at an end opening of the anode, and a flange portion joined to the pole piece,
A metal sealing body having a tubular portion extending from the flange portion, a ferromagnetic yoke arranged so as to surround the tubular portion of the metal sealing body, and the ferromagnetic yoke and the metal sealing body. In a magnetron for a microwave oven, which comprises an annular permanent magnet located between flanges, at least one of a diameter of an outer peripheral portion of the permanent magnet and an inner peripheral portion of the permanent magnet is closer to the yoke than the flange. A magnetron for a microwave oven, characterized in that a tapered portion is formed on at least one of an inner peripheral portion and an outer peripheral portion of the permanent magnet so as to be large. 2. The magnetron for a microwave oven according to claim 1, wherein the tapered slope formed on the inner peripheral portion of the permanent magnet is inclined so as to substantially follow the orientation of the magnetic domains of the permanent magnet.