KR19990010374U - Installation structure of magnetron for microwave oven - Google Patents

Abstract

The present invention relates to an installation structure of a magnetron for a microwave oven. In the related art, in order to install a magnetron in a waveguide, a hook is formed at one side of the waveguide bracket by bending it up and down so that the magnetron is fitted in a hole drilled in the magnetron bracket, and the other side is assembled with a screw. However, if the microwave oven is inadvertently dropped during the transportation or drop test, the hanger formed on the waveguide bracket cannot open the weight of the magnetron, and a gap is generated between the waveguide bracket and the magnetron bracket, causing high frequency leakage. There is a problem.

Therefore, the present invention forms a bent portion 211 at a right angle at one end of the waveguide bracket 110 in fastening the magnetron 100 to the waveguide, but an insertion hole 211b is formed at the corner portion 211a of the bent portion 211. One side end (111a) of the magnetron bracket 110 is to be fitted to the insertion hole (211b) by drilling the magnetron bracket even if the weight of the magnetron 100 is transmitted to the waveguide bracket 210 as it is due to the impact Since one side end 111a of 110 supports the bent portion 211, the bent portion 211 is not deformed, so that a gap does not occur between the waveguide bracket 210 and the magnetron bracket 110, so that high frequency leakage occurs. There is no concern at all.

Description

Installation structure of magnetron for microwave oven

The present invention relates to an installation structure of a magnetron that generates high frequency radiation and irradiates it into a cooking chamber of a microwave oven. More specifically, in installing the magnetron in a waveguide, the shape of the waveguide bracket is changed to inadvertently drop the microwave oven. The present invention relates to a magnetron installation structure for microwave ovens, which can effectively prevent high frequency leakage without causing a gap between the magnetron bracket because the waveguide bracket is not deformed even when the drop test is performed.

In general, a vacuum tube called magnetron is widely used in an oscillation tube of a radar, and is used in daily microwave ovens as a household product. The high frequency oscillated from the magnetron of the microwave oven depends on the type of food and its use in the home. It is used to cook foods to suit the taste by direct heating or reheating after thawing.

That is, the microwave oven is provided with a magnetron in one side of the electric compartment, the high frequency generated by the magnetron is irradiated into the cooking chamber through the waveguide, the bottom of the cooking chamber is provided with a tray on which the cooking vessel is placed, the lower portion of the tray A tray motor capable of rotating the tray is installed so that the cooking vessel placed thereon is rotated along the tray, so that the high frequency radiated to the cooking chamber is evenly transmitted to the food in the container and uniformly heated.

As described above, the magnetron oscillating high frequency, which is a heating source of a microwave oven, is composed of a cathode cylinder, a main component, a plurality of heat sinks, a permanent magnet, and the like, and a heat sink is inserted into the anode cylinder, and a permanent magnet is disposed above and below the anode cylinder. Other components are connected to the components.

The magnetron constructed as described above has a cathode placed on the center axis of the anode cylinder, and a magnetic field is applied in parallel with the biaxial axis. At this time, the magnetic field is ferrite permanent magnet. In other words, the electrons from the cathode of the central axis are projected toward the surrounding anode. At this time, due to the strong magnetic field acting in the up and down direction, the electrons are bent and the vortex turns to the anode. When electrons enter the cavity, the cavity acts like the serial circuit of the coil and the condenser, causing a vibration current, and high frequency oscillates.

When the magnetron oscillates a high frequency as described above, the upper heat is generated, so that a heat sink is installed in the anode tube to disperse the heat, and the dispersed heat is generated by a cooling fan installed at one side of the electric room. It is being cooled by air.

1 is an exploded perspective view showing a conventional magnetron mounting structure, and FIG. 2 is a conventional coupling side view. As shown in the related art, in order to couple the magnetron 10 to a waveguide (not shown), the waveguide bracket 21 ) And install the magnetron bracket 11 on one side of the yoke of the magnetron 10, but on one side of the waveguide bracket 21, a hooking hole 21a is formed on the upper and lower sides, and the other end of the protrusion 21b which is perforated with a screw hole. ) Is formed, the one end portion (11a) of the magnetron bracket 11 has a structure in which the engaging hole (11c) that can be caught by the engaging hole (21a) is perforated but there are many problems as described in detail As follows.

That is, the hook 21a formed at one side of the waveguide bracket 21 is fitted into the catching hole 11c of the magnetron bracket 11 and the protrusion 21b formed at the other side of the waveguide bracket 21 is the magnetron bracket 11. The magnetron 10 is fixed to the waveguide by tightening with screws by fastening it to the other end 11b of the cuff). However, if the microwave oven is inadvertently dropped during transportation or an impact is applied during the drop test, the magnetron 10 cannot withstand the weight of the magnetron 10. 2, the magnetron bracket 11 and the waveguide bracket 21 do not come into close contact with each other as the catching hole 21a of the waveguide bracket 21 opens or sags downward as shown in FIG. There is a problem.

Therefore, an object of the present invention is to solve the above problems, and even if the impact is applied during the drop test after installing the magnetron in the waveguide, there is no gap between the waveguide bracket and the magnetron bracket, so there is no risk of high frequency leakage. It is to provide magnetron installation structure for stove.

The object of the present invention is achieved by forming a bent portion at a right angle at one end of the waveguide bracket, but drilling the insertion hole at the corner of the bent portion so that one end of the magnetron bracket is fitted into the insertion hole.

When the magnetron is installed in the waveguide, the one end of the magnetron bracket is inserted into the insertion hole formed in the bent portion of the waveguide bracket so that the bent portion is deformed because one end of the magnetron is tightly inserted into the insertion hole even when an impact is applied. By preventing the above object can be effectively achieved.

1 is an exploded perspective view of a main portion showing a conventional configuration.

2 is a side view of the conventional combination

Figure 3 is an exploded perspective view showing the main portion showing an embodiment according to the present invention

4 is a side view of the combination of the subject innovation

Explanation of symbols for main parts of the drawings

100: magnetron 110: magnetron bracket

111a: One end 210: Waveguide bracket

211: bend portion 211a: corner portion

211b: Inserter

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

That is, Figure 3 is an exploded perspective view showing an embodiment of the present invention and Figure 4 is a combination side view of the present invention as illustrated in the present invention is a magnetron 100 in the installation of a waveguide, waveguide bracket 210 One side of the bent portion 211 is formed at right angles, but the corner portion 211a of the bent portion 211 is drilled through the insertion hole 211b to one end 111a of the magnetron bracket 110 is the insertion hole (211b) In the drawing, reference numeral 111b in the drawing denotes the other end of the magnetron bracket and 212 is a protrusion formed on the other side of the waveguide bracket.

According to the present invention, the magnetron 100 for irradiating high frequency inside the cooking chamber of the microwave oven is installed in the waveguide (not shown), and then the waveguide is damaged by the impact when the microwave is inadvertently dropped during the drop test or during transportation. The bracket 210 is deformed to withstand the load of the magnetron 100 so that a gap is generated between the waveguide bracket 210 and the magnetron bracket 110 to effectively prevent high frequency leakage.

That is, as illustrated in FIG. 3, one side of the waveguide bracket 210 is bent at an angle of 90 degrees to form the bent portion 211, and then an insertion hole 211b is formed at the corner portion 211a of the bent portion 211. First, one end 111a of the magnetron bracket 110 in which the magnetron 100 is installed is inserted into the insertion hole 211b of the bent portion 211, and then the magnetron bracket 110 is brought into close contact with the waveguide bracket 210. The other end 111b of the magnetron bracket 110 is in contact with the protrusion 212 formed on the other side of the waveguide bracket 210, so that the screw may be fastened thereto.

When the magnetron 100 is fastened to the waveguide as described above, the waveguide bracket 210 is not deformed even when the microwave oven is inadvertently dropped during the transportation or the drop test, which is one end 111a of the magnetron bracket 110. Since it is tightly fitted in the insertion hole 211b formed in the bent portion 211 of the waveguide bracket 210, that is, one side end 111a of the magnetron bracket 110 supports the bent portion 211, so Therefore, even when the weight of the magnetron 100 is transmitted as it is, the bent portion 211 is not deformed, so no gap is generated between the magnetron bracket 110 and the waveguide bracket 210, so that the high frequency oscillated from the magnetron 100 leaks. There is no concern at all.

As described above, in the present invention, in installing the magnetron for microwave ovens in the waveguide, bent one side of the waveguide bracket by 90 degrees to form a bent portion and forming an insertion hole in the bent portion so that one end of the magnetron bracket is tight to the insertion hole. Since the bent part is not deformed even by the impact caused by the drop test because it is inserted, the waveguide bracket and the magnetron bracket can be kept in close contact with each other.

Claims (1)

In fastening the magnetron 100 to the waveguide, a bent portion 211 formed at right angles is formed at one end of the waveguide bracket 210, and the insertion hole 211b is drilled at the corner portion 211a of the bent portion 211. Magnetron mounting structure for a microwave oven, characterized in that one side end 111a of the magnetron bracket 110 is fitted into the insertion hole 211b.