KR100191546B1 - A cooling apparatus of magnetron - Google Patents

Abstract

The present invention is a magnetron cooling device that is forcedly cooled by a blower of a magnetron, and a magnetron used in a microwave heating apparatus such as a microwave oven effectively improves the oscillation efficiency by cooling the heat generated from the anode body during high frequency oscillation. In order to provide a cooling device of a magnetron, a positive electrode body having a plurality of positive electrode vanes having a resonant cavity formed therein, a plurality of cooling pieces formed on an outer circumferential surface of the positive electrode body and forcedly cooled, and a magnet formed on the upper side of the positive electrode body; And an upper bracket formed at an upper end of the magnet and having hook grooves and air guide pieces formed on both sides thereof, and one side of the inner circumferential surface of the locking groove contacts one side of the air guide piece, and the air guide piece is a magnet and an anode body. Inclined to guide the air to the part where it contacts Characterized by name.

Description

Magnetron Chiller

The present invention relates to a cooling device for a magnetron, and more particularly, to a magnetron for a microwave heating device such as a microwave oven, a magnetron cooling device that improves the oscillation efficiency by effectively cooling the heat generated from the anode body during high frequency oscillation. It is about.

Conventional magnetron is generally provided on the anode body (2) having a plurality of anode vanes (1) having a resonant cavity formed therein, as shown in Figure 1, the cathode body (2) is provided on the outer surface of the forced cooling by the blowing means A plurality of cooling pieces 3 are provided, and upper and lower end pole pieces 5a and 5b and magnets 11a and 11b fixed to be covered with upper and lower end metal pipes 4a and 4b respectively on the upper and lower ends of the positive electrode body.

In addition, upper and lower end brackets 10a and 10b are installed at upper and lower ends of the magnets 11a and 11b, and a hook groove 10c is formed at the upper end of the upper bracket 10a to improve the mounting and convenience of the magnetron. And a cathode lead wire having a cathode filament 6 and an upper and lower electron escape preventing plate 7a and 7b which are supported by an insulating support 8a in the lower metal pipe 4b and positioned at the center of the anode vane 1 at the upper end thereof. (8) and an output section 9 formed on the upper side of the upper metal pipe 4a together with the antenna 9a drawn out from the anode vane 1 and the like.

According to this configuration, the magnetron is mounted at a predetermined position such as a microwave oven by using the hook groove 10c of the upper bracket 10a, and then, when power is applied through the power supply unit 12, the negative electrode at the end of the negative lead line 8 The electrons emitted from the filament 6 and its kinetic energy are attracted to the tip end side of the anode vane 1, and the heat electrons generated by the electric power are generated by the magnetic field induced by the upper and lower magnetic pole pieces 5a and 5b. Under the influence, it is transmitted to the electromagnetic field formed between the anode vanes 1 and radiates to the outside from the output unit 9 through the antenna 9a. At this time, the oscillated microwave oscillates 2450MHz as the fundamental wave.

However, the efficiency of the magnetron is about 60-80%, which is very high. However, the power loss of 20-40% generates high heat (about 200 ° C.) by heating the cathode body 2 during high frequency oscillation. Severe high heat is generated in the areas where the magnets 11a and 11b are in contact with the positive electrode body 2, which causes problems such as deterioration of the oscillation efficiency and poor safety.

In order to solve this problem, various methods for cooling the cathode body 2 have been proposed and practically used. However, a method of forcibly cooling a plurality of cooling pieces 3 on the outer surface of the anode body 2 is used. do.

That is, the cooling piece 3 fitted to the positive electrode body 2 receives heat to radiate heat to the outside, and cool air to the cooling piece 3 as a separate blowing means (not shown) in order to increase the cooling efficiency. This is the forced air cooling method to supply.

However, the conventional magnetron cooling device has a problem that the cooling efficiency is lowered because the forced cooling air is not concentrated toward the contact between the magnet and the anode body.

The present invention has been made in view of the above problems, and provides a magnetron cooling device that improves the oscillation efficiency by effectively cooling the heat generated in the anode body during high frequency oscillation of a magnetron used in microwave heating equipment such as a microwave oven. There is a purpose.

1 is a cross-sectional view of main parts of a conventional magnetron.

Figure 2 is a perspective view showing one embodiment of the upper bracket of the present invention.

3 is a cross-sectional view of the present invention magnetron cooling device.

Explanation of symbols for the main parts of the drawings

22a-top bracket, 22c-hanging groove,

22d air guide, 24a magnet,

27-cooling piece, 28-anode body,

29-anode vanes.

In order to achieve the above object, the present invention provides a magnetron cooling apparatus forcibly cooled by a blowing means, comprising: a positive electrode body having a plurality of positive electrode vanes formed therein with resonant cavities; A plurality of cooling pieces to be cooled, the magnet formed on the upper end of the positive electrode body, and the upper bracket formed on the upper end of the magnet and formed on both sides of the hook groove and the air guide piece is characterized in that it is provided.

In addition, one side of the inner circumferential surface of the engaging groove is in contact with the one side of the air guide piece, the air guide piece is characterized in that it is formed to be inclined to guide the air to the portion where the magnet body and the positive electrode contact.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing an embodiment of the upper bracket of the present invention, the engaging groove (22c) and the air guide piece (22d) is formed on both sides of the upper bracket (22a), the output portion (not shown) is inserted in the center The insertion groove 22e is formed, and the engaging groove 22c has one side of the inner circumferential surface thereof in contact with one side of the air guide piece 22d, and the air guide piece 22d has a magnet (not shown) and a positive electrode body ( Not shown) is formed to be inclined to guide the air to the contact portion.

Insert the insertion groove formed in the center of the upper bracket (22a) to the magnetron by inserting it into the output unit (not shown), wherein the air guide piece (22d) is cut on the three sides of the locking groove (22c) on the basis of the remaining one side Fold in the lower direction to form an inclination angle.

3 is a cross-sectional view of the magnetron cooling apparatus of the present invention, and includes a cathode body 28 having a plurality of anode vanes 29 having a resonance cavity formed therein, and an air blowing means (not shown) provided on an outer surface of the anode body 28. There are provided a plurality of cooling pieces 27 forcibly cooled by.

Hook grooves 22c and air guide pieces 22d for guiding cooling air are formed on both sides of the upper bracket 22a to improve the mounting and convenience of the magnetron, and one side of the inner circumferential surface of the hook grooves 22c. It is configured to be in contact with one side of the air guide piece (22d).

In addition, the cathode filament 25 for emitting electrons is formed in the center of the anode vane 29, and an output unit configured with an antenna (not shown) drawn from the anode vane 29 on the upper side of the upper bracket 22a ( 20).

Referring to the operation of the present invention configured as described above in detail.

The magnetron is mounted at a predetermined position such as a microwave oven using the hook groove 22c formed in the upper bracket 22a. Then, when the power is applied, the electrons emitted from the cathode filament 25 and the kinetic energy thereof are the anode vanes ( 29) is attracted to the distal end side, wherein the heat electrons generated by the electric power are transmitted to an electromagnetic field formed between the anode vanes 29 under the influence of the magnetic field, and output through the antenna (not shown). In the radiated to the outside, the oscillating microwave will oscillate 2450MHz as a fundamental wave.

At this time, the cathode body 28 is heated during the high frequency oscillation to generate high heat (about 200 ° C.), and particularly high heat is generated at the portion where the magnet 24a and the cathode body 28 come into contact with each other.

Therefore, the cold air is supplied to the cooling piece 27 by a separate blowing means (not shown) as a forced air cooling method, wherein the cold air is provided by the air guide piece 22d installed on the upper bracket 22a of the present invention. The magnet 24a and the positive electrode body 25 is to be supplied intensively to the site.

Therefore, the magnetron is forcedly cooled by the plurality of cooling pieces 27 formed on the outer surface of the anode body 28 and at the same time, the high heat generating portion is intensively cooled to prevent power loss and stability failure.

The above description is only one embodiment of the present invention, and any change may be made within the scope of the present invention.

As described above, the present invention effectively cools heat generated by power loss in the anode body, thereby obtaining safe operation and high oscillation efficiency, and preventing overheating and combustion of peripheral devices.

Claims (2)

In the cooling device of the magnetron forcibly cooled by the blowing means, the cathode body (28) having a plurality of anode vanes (29) having a resonant cavity formed therein, A plurality of cooling pieces 27 formed on the outer circumferential surface of the positive electrode body 28 and forcedly cooled; A magnet 24a formed on the anode body 28, and Cooling apparatus of the magnetron, characterized in that the upper bracket (22a) is formed on the top of the magnet (24a) and the hook groove (22c) and the air guide piece (22d) is formed on both sides thereof. According to claim 1, One side of the inner peripheral surface of the engaging groove 22c is in contact with one side of the air guide piece (22d), The air guide piece (22d) is a magnetron cooling device, characterized in that formed to be inclined to guide the air to the portion in contact with the magnet (24a) and the positive electrode body (28).