KR0120627Y1 - Magnetron temperature detector - Google Patents

Abstract

The present invention relates to a temperature detection device of a magnetron that detects the heat generation temperature of the magnetron and stops the supply of the magnetron when a certain temperature is exceeded, thereby preventing the damage of the magnetron. A temperature detecting means is arranged between a power input terminal attached to an outer surface of one side of a case and a choke coil connected to a first terminal piece for supplying a voltage to a cathode of a magnetron.

Description

Magnetron temperature detector

1 is a schematic cross-sectional view of a conventional temperature detection device of a magnetron.

Figure 2 is a detailed cross-sectional view of the magnetron temperature detection device according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: positive electrode 2: power input terminal

3: vane 5: filament

7: Top end hat 8: Bottom end hat

15, 16: Metal pipe 21: Ceramin pipe

25: antenna 27: antenna cap

39: first cathode 40: second cathode

45: first terminal piece 46: second terminal piece

47: choke coil 50: temperature detection means

51,52: Bracket

The present invention relates to a magnetron temperature detection device capable of detecting the heat generation temperature of the magnetron to prevent the breakage of the magnetron by cutting off the power supply of the magnetron when the temperature exceeds a predetermined temperature.

In general, the temperature detection device of a conventional magnetron is a magnetron, as shown in FIG. 1, in which the operating voltage (about 4000 V) of the magnetron is supplied through the choke coil 47 through the power input terminal 2 of the magnetron. When applied to the cathode terminal, the magnetron is operated to output a high frequency to the cavity of the microwave oven through the antenna and the antenna cap 27 not shown in the ceramic tube 21.

In the drawing, reference numeral 20 denotes a one-dimensional terminal connected to an input power supply voltage terminal of a microwave oven.

In the magnetron configured as described above, heat is generated when the magnetron operates, and when the exothermic temperature is about 280 ° C. or more, the magnetron breaks.

In order to prevent this, in the related art, a thermostat 4 having a switch function to turn on / off a power supply voltage is attached to the yoke 10 so that heat generated from the anode cylinder, which is the maximum heat generating portion of the magnetron, is transferred through the heat sink. When delivered to (10) it was configured to detect the primary power supply voltage supplied to the microwave oven.

Since the thermostat 4 of the conventional magnetron configured as described above is attached to the surface of the magnetron, the heat generation temperature of the magnetron could not be immediately detected, and thus, the magnetron may be damaged by overheating.

Therefore, the temperature detection device of the magnetron according to the present invention detects the heat generation temperature of the magnetron directly inside the magnetron, and when the temperature exceeds the predetermined temperature, the magnetron temperature detection can be prevented by immediately blocking the voltage applied to the magnetron. To provide a device.

In order to achieve the above object, the apparatus for detecting a temperature of a magnetron according to the present invention includes a power input terminal attached to one outer surface of a filter case to supply operating power to the magnetron, and a voltage supplying voltage to a cathode of the magnetron. A temperature detecting means is arranged between choke coils connected to one terminal piece.

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

Figure 2 is a detailed cross-sectional view of the temperature detection device of the magnetron according to an embodiment of the present invention.

In Fig. 2, reference numeral 1 denotes an anode cylinder formed in a cylindrical shape by, for example, a copper plate, and is disposed on a plurality of vanes 3 forming a plurality of resonant cavities on the inner surface of the anode cylinder 1. In the vicinity of the central axis of these anode cylinders 1, an action space is formed by the tip portions of the plurality of vanes 3, and in this action space, for example, thorium-tungsten or the like is spirally wound so as to radiate hot electrons. The once filament 5 is arrange | positioned. At both ends of the filament 5, upper and lower end hedges 7 and 8 are fixed so as to prevent radiation of hot electrons in the direction of the central axis, which is a trimming current that does not contribute to oscillation. The first lead wire 9 is welded to the bottom surface of the upper end of the upper end hat 7 through a through hole (not shown) formed near the center of the lower end hat 8. Weld is fixed. Here, the second lead wire 11 penetrates non-contact with the lower end head 8 and the filament 5, and all of the lead wires 9 and 11 are made of molybdenum, and thus the filament 5 To supply the operating current.

In the figure, reference numerals 13 and 14 are funnel-shaped pole pieces which are fixed to both openings of the anode cylinder 1 to form a magnetic path for uniformly converging the magnetic flux in the working space, and both ends of the anode cylinder 1 The outer edges of both ends remaining after being seated at the inner cutout are bent and fixed, and are hermetically welded and fixed, and the upper and lower portions of the funnel-shaped magnetic pole pieces 13 and 14 are vacuumed inside the anode cylinder 1. Metal tubes 15 and 16 for sealing are respectively fixed to the middle of the pole pieces 13 and 14 or the ends of the anode cylinder 1 by welding, respectively, and are fixed to the outer surfaces of the metal tubes 15 and 16. Ring-shaped permanent magnets 18 and 19 are arranged at a distance of. An output side ceramic tube 21 formed in a ceramic cylindrical shape is fixedly connected to the upper opening end of the metal tube 15 by welding or the like, and the output side ceramic tube 21 is formed at the upper end of the copper tube. The exhaust pipe 23 is fixed to the antenna 25, the one side is coupled to the vane 3 is welded fixed near the inner central portion of the exhaust pipe 23 to output the high frequency oscillated in the resonant cavity, The outer surface of the exhaust pipe 23 is covered with an antenna cap 27 that protects the welded and fixed portion of the exhaust pipe 23, prevents sparking due to electric field concentration, acts as a high frequency antenna, and draws high frequency output to the outside.

In addition, on the outer circumferential surface of the anode cylinder 1, a plurality of aluminum heat sinks 29 extending in the radial direction of the tube are fitted by a clamp member 31 fixed to the yoke 10 described later, and the heat sinks 29 ) Is covered by the yoke 10 for forming a porcelain together with the permanent magnets 18 and 19. In addition, a first gasket 33 formed of a metal mesh or the like between the upper side of the permanent magnet 18 on the output side and the opening of the yoke 10 to prevent radio leakage of high frequency waves is provided in the second gasket 35. It is arrange | positioned through the.

The ceramic cap-shaped stem insulator 41 for hermetically penetrating the pair of first and second cathode leads 39 and 40 in the filter case 37 has another round shape at the opening end thereof. The metal tube 16 is sealed, and the flange 17 of the metal tube 16 is sealed at the input side opening end of the anode cylinder 1 so as to cover the second pole piece 14. In addition, the stem insulator 43 and a pair of first and second cathode leads 39 and 40 are provided in a pair of first and second terminal pieces 45 disposed outside the bottom of the stem insulator 43. 46 is hermetically sealed and electrically connected to the pair of first and second terminal pieces 45 and 46 disposed on the stem insulator 43.

As shown in FIG. 2, in the magnetron temperature detecting device according to the present invention, the power input terminal 2 is configured to apply an operating power (about 4000V) to the magnetron on one outer surface of the filter case 37. Insulated from (37) and coupled to each other, the choke coil 47 is electrically connected to the power input terminal 2 and the first terminal piece 45, and the choke coil 47 and the power input terminal (2). In the case where the temperature in the filter case 37 of the magnetron becomes higher than a predetermined temperature (for example, about 280 ° C), the temperature detecting means 50 is connected so that the power applied to the magnetron can be cut off immediately.

In addition, the filter case 37 has a bracket of insulating material at a predetermined distance from both ends of the temperature detecting means 50 connected to the choke coil 49 so that the temperature detecting means 50 can be stably operated. 52 is provided.

The temperature detecting means 50 is composed of a bimetal in which two metals having different thermal expansion rates are electrically coupled.

Hereinafter, the effect of the magnetron temperature detection device configured as described above will be described.

First, when the operating voltage of the magnetron is applied from the power input terminal 2 attached to one outer surface of the filter case 37 of the magnetron, the operating voltage output from the power input terminal 2 is the filter case 37. It is applied to the first cathode 39 of the magnetron through a choke coil 47 electrically connected to the first terminal piece 45 in the magnetron, and the magnetron oscillates the ultra-high frequency to start operation.

At this time, the temperature detecting means 50 electrically connected between the choke coil 47 and the power input terminal 2 detects the temperature in the filter case 37 of the magnetron.

If the temperature detected by the temperature detecting means 50 is equal to or higher than a predetermined temperature (for example, about 280 ° C. or more), the power supply terminal 2 immediately cuts off the power applied to the magnetron. Breakage can be prevented.

According to the magnetron temperature detection device according to the present invention as described above, if the heat generating temperature of the magnetron is directly detected inside the magnetron to be above a predetermined temperature, the voltage applied to the magnetron is immediately cut off to prevent damage to the magnetron. It has a great effect.

Claims (3)

In the magnetron, a second connected to a power input terminal 2 attached to one outer surface of the filter case 37 to apply an operating power to the magnetron, and a first terminal piece 45 for supplying a voltage to the cathode of the magnetron. The temperature detection device of the magnetron, characterized in that the temperature detecting means 50 is disposed between the oak coils (47). The temperature detection device of the magnetron according to claim 1, wherein the temperature detection means (50) is a bimetal in which two metals having different thermal expansion coefficients are electrically coupled. 2. The magnetron temperature detecting device according to claim 1, wherein at both ends of the temperature detecting means (50), a bracket of an insulating material is fixed at a predetermined distance so that the temperature detecting means (50) can be stably operated. .