KR200189012Y1 - Thermistor mounting device for ventilation hooded microwave oven - Google Patents

Abstract

The present invention relates to a fastening device for closely contacting a thermistor assembly to a heat sink mounted inside a microwave oven.

A fastening device according to the present invention includes a heat sink 22 installed inside a microwave oven to dissipate heat from a heat generating part; A thermistor assembly 24 having a thermistor for detecting overheating of the heat sink and a fastening hole 26a formed in a bracket 26 at an upper end thereof; The fastening hole 20a is formed at the same position as the fastening hole of the bracket, and includes an elastic creep 20 for elastically pressing the thermistor assembly toward the heat sink. The elastic creep 20 has a shape that is in close contact with the entire surface of the thermistor assembly opposite to the heat sink, so that the whole of the thermistor assembly 24 is pressed against the heat sink. According to the present invention, the thermistor assembly is always in close contact with the heat sink, and accurately detects the overheat.

Description

Thermistor mounting device for ventilation hooded microwave oven}

The present invention relates to a device for fastening a thermistor of a microwave oven to a heat sink, and more particularly, to a thermistor fastening device configured to accurately sense the temperature by fixing the thermistor in close contact with the heater sink. will be.

The microwave boosts a predetermined current supplied to a high pressure, and uses the high pressure to oscillate the microwave in the magnetron. The microwaves thus produced are fed into the cavity and irradiated to the heating object to heat the food.

Previously, the microwave oven is equipped with a printed circuit board (PCB) for processing a user input signal or various control signals therein, and a heat sink for dissipating the printed circuit board and the driving elements around the microwave oven. It is installed. 1 shows the components around such a heatsink.

As shown in FIGS. 1A and 1B, a heat sink 12 that performs a heat dissipation function is installed in an upright state on the printed circuit board 10. The thermistor 16 for detecting whether the heat sink 12 is overheated is installed to be in close contact with the heat sink 12 by the bracket 14. The thermistor 16 is built in the lower part of the bracket 14, and is usually provided integrally. The upper part of the bracket 14 is fixed by using the screw S, so that the lower part of the bracket 14 is fixed. The thermistor 16 embedded therein is fixed to the heat sink 12.

Usually, the thermistor 16 currently supplied is attached to the inside of the bracket 14 as mentioned above, and the whole incorporating the thermistor 16 in this way is called a thermistor assembly below.

However, looking at the conventional fastening structure, the thermistor 16 is fixed to the heat sink 12 by a screw (S) in a state supported by the bracket (14). That is, although the upper end of the bracket 14 supporting the thermistor 16 is fixed to the heat sink 12 by a screw S, the screw S is simply a heat sink only at the upper end of the bracket 14. It only performs the function of fixing to 12).

In addition, in order to transmit a signal detected by the thermistor 16, a lead wire 18 is connected to the thermistor under the lead wire. The lower end of the thermistor 16 is spaced apart from the heat sink 12 by the lead wire 18. There is concern. In FIG. 1, reference numeral C denotes an interval that may occur between the sinking heat sink 12 and the thermistor 16. That is, according to the conventional structure, since the thermistor assembly 17 incorporating the thermistor 16 is fixed to the heat sink 12 by the bracket 14 only at the upper part, the lower part of the lower part of the intermediate part is connected to the lead wire. There is a fear that the heat sink 12 is separated from the main body.

As such, when the thermistor 16 does not come into close contact with the heat sink 12, the heat sink may not be properly sensed, and there are many disadvantages in that it may be a problem whether or not the electrical element is damaged by overheating. .

An object of the present invention is to provide a structure capable of sufficiently bringing the heat sink and thermistor into close contact.

In order to sufficiently close the thermistor to the heat sink as described above, it is preferable to use a kind of elastic member that can press the lower side of the thermistor to the heat sink side, and the present invention focuses on this point.

Figure 1a is a side view showing a fastening device of a conventional thermistor.

Figure 1b is a front view showing a fastening device of a conventional thermistor.

Figure 2a is a side view showing a thermistor fastening device of the present invention.

Figure 2b is a front view showing a fastening device of the thermistor of the present invention.

Explanation of symbols on the main parts of the drawings

20 ..... Elastic creep 20a, 26a ..... Fastener

22 ..... heatsink 24 ..... thermistor assembly

30 ..... Printed circuit board S ..... Fastening screw

The thermistor fastening device according to the present invention for achieving the above object, the heat sink is installed in the microwave oven to dissipate heat in the heat generating component; A thermistor assembly having a thermistor for detecting overheating of the heat sink and a fastening hole formed in a bracket of an upper end portion; And a fastening hole is formed at the same position as that of the fastening hole of the bracket, and includes an elastic crep that elastically presses the thermistor assembly toward the heat sink. Therefore, it is characterized in that the fastening to the heat sink with a screw through the two fastening holes.

And according to one embodiment of the present invention, the elastic creep has a shape that is in close contact with the entire surface of the thermistor assembly opposite the heat sink.

According to the present invention, since the thermistor assembly is supported by the elastic creep to be in close contact with the heat sink side, it is always possible to detect whether the heat sink is overheated, and the effect of enabling accurate operation is expected. It becomes possible.

Next, the present invention will be described in more detail with reference to the embodiments of the present invention shown in the drawings.

As shown in the drawing, a heat sink 22 is provided on an upper portion of the printed circuit board 30 provided in the electronic cabinet of the microwave oven. On one side of the heat sink 22, the thermistor assembly 24 is fixed to the heat sink 22 by an elastic creep 20 having a fixed elasticity by the fastening screw S.

The thermistor assembly 24 means that the thermistor is built in or the thermistor is fixed to one side. A fastening hole 26a for fastening with a screw is formed in the bracket 26 extending upward from the thermistor assembly 24.

According to the present invention, an elastic creep is added to the outside of the thermistor assembly 24 to fix the thermistor assembly 24 to the heat sink 22. That is, according to the present invention, by installing an elastic creep that elastically presses the thermistor assembly 24 from the right side to the left side, the thermistor assembly 24 is fixed to be in close contact with the heat sink.

The elastic creep 20 according to the present invention has a shape that can be in close contact with the upper end bracket 26 of the thermistor assembly 24 and the main body of the lower thermistor assembly 24, and has a predetermined elasticity. For example, it may be made of a thin metal material. In addition, the lower portion of the elastic creep 20 is to be in close contact with the body portion and the lower end of the thermistor assembly 24, and furthermore, to be elastically pushed to the body portion and the lower end of the thermistor assembly 24 to the heat sink side. do.

That is, in the illustrated embodiment, the elastic creep 20 is molded in a shape in which its lower portion is bent stepwise outward, and this shape has substantially the same shape as that of the thermistor assembly.

And the upper part of the elastic creep 20 is formed with a screw fastening hole (20a) that can be screwed. The screw fastening hole 20a is molded at a position coinciding with the fastening hole 26a of the bracket 26 on the upper portion of the thermistor assembly 24.

In order to fix the thermistor assembly 24 to the heat sink 22 by using the elastic creep 20 of the present invention configured as described above, one fastening screw S is used. That is, in a state in which the fastening hole 20a of the elastic creep 20 and the fastening hole 26a of the upper bracket 26 of the thermistor assembly 24 are positioned so as to be integral with each other, one screw S is used. The elastic creep 20 and thermistor assembly 24 are fixed to the heat sink together.

When the thermistor assembly 24 is fixed using the screw S in this way, the outside (right side in the drawing) of the creep 20 is in a state of being completely in contact with the thermistor assembly 24. Accordingly, the lower end portion of the elastic creep 20 having elasticity elastically presses the thermistor assembly 24 with the heat sink 22 on the left side.

Accordingly, when the thermistor assembly 24 is fixed to the heat sink 22 by the fastening structure of the present invention, the elastic creep 20 is in close contact with the body of the thermistor assembly 24 as well as the lower end thereof. It is pressed toward the heat sink 22. Thus, the thermistor assembly 24 can be installed in a completely close state to the heat sink 24.

According to the present invention as described above, the basic technical idea is to fasten the thermistor assembly 24 to elastically support the heat sink 22 by using the elastic creep 20. Within the technical scope of the present invention, of course, many other modifications are possible to those skilled in the art. For example, the elastic creep 20 may be modified in a variety of shapes within the range in which the thermistor assembly 24 can be elastically pressed to the heat sink 22 side. In addition, in the illustrated embodiment, the heat sink is illustrated as being installed on the upper portion of the printed circuit board, but the structure according to the present invention, in order to heat the heat of the heat generating parts in the inside of the microwave oven, heat is installed in any part Of course, it can also be applied to the sink.

According to the present invention configured as described above, the thermistor assembly is completely in contact with the heat sink side, it is possible to always accurately detect whether the heat sink is overheated. Therefore, by applying the structure according to the present invention, it is possible to always accurately detect whether the microwave oven is overheated, and thus it will be possible to provide a reliable microwave oven.

Claims (2)

A heat sink installed inside the microwave oven to dissipate heat from the heat generating parts; A thermistor assembly having a thermistor for detecting overheating of the heat sink and a fastening hole formed in a bracket of an upper end portion; And a fastening hole is formed at the same position as the fastening hole of the bracket, and includes an elastic creep that elastically presses the thermistor assembly toward the heat sink, and fastens the heat sink with a screw through the two fastening holes. Thermistor fastening device for a microwave oven. The thermistor fastening device according to claim 1, wherein the elastic creep has a shape in close contact with the entire surface of the thermistor assembly opposite to the heat sink.