KR100509336B1 - Temperature sensing device for electric jar - Google Patents

Abstract

The present invention relates to a temperature sensing device installed inside the electric pressure cooker for sensing the temperature. According to the invention, it is installed inside the electric pressure cooker, as a temperature sensing device for sensing the temperature during heating; A temperature sensor 20 for sensing a temperature; A mount (30) having a sensor housing (32) in which the temperature sensor can be stored; It is installed on the opened front surface of the mount, and includes a sensor cap 40 made of silicon for supporting the front surface of the sensor. The sensor cap 40 is formed in a hook shape in which the rear end portion 42 is bent inward, and the rear end portion is supported by the mount by being caught by a locking jaw formed on the outer circumferential surface of the mount.

Description

Temperature sensing device for electric pressure cooker {Temperature sensing device for electric jar}

The present invention relates to a temperature sensing device used in an electric pressure cooker, and more particularly, to a temperature sensing device configured to be more convenient and at the same time to increase the reliability of the temperature sensing.

In an electric pressure cooker or an electric rice cooker, a temperature sensor is used to sense the temperature inside the rice cooker when performing cooking using electricity as a power source. The temperature sensor is for detecting a temperature change to be used for determining the number of servings and controlling the heating temperature when cooking by detecting a temperature change when heating the inside of the rice cooker for cooking.

In Figure 1, in the general electric pressure cooker, the configuration of a conventional temperature sensing device for sensing the temperature of the inner pot is shown in cross section. As shown in the drawing, a conventional temperature sensing device includes a temperature sensor 2 for sensing a temperature and a schematic cylindrical mount 4 for storing a temperature sensor 2 therein to maintain a constant position. It is included. That is, the temperature sensor 2 maintains the position defined by the mount 4 in a state accommodated inside the mount 4.

And inside the temperature sensor (for example, the inner pot side of the electric pressure cooker), a cover 6 made of aluminum having high thermal conductivity is mounted. The aluminum cover 6 is mounted to protect the temperature sensor 2 and to transmit the temperature in the inner pot to the temperature sensor 2 accurately. The cover 6 is in a state in which the inner end 8a can be firmly supported by the mount 4 by being caught by one outer peripheral surface of the mount 4. And the process of fastening the cover 6 to the mount is made through a predetermined pressing process.

The sensor 2 is supported in place by the mount 4 inside the cover 6, and a silicon pad 8 is interposed between the cover 6 and the sensor 2 to protect the sensor. It is. In addition, a spring 10 is mounted to the rear of the mount 4 so that the mount 4 having the sensor 2 built therein elastically supports the inside of the electric pressure cooker by the elastic force of the spring 10. do. The outer end (right end in the drawing) of the spring 10 is supported by, for example, an inner portion of the outer casing of the electric pressure cooker, so as to substantially elastically mount the mount 4 into the electric pressure cooker. I can support it.

And the rear (outside) of the temperature sensor 2, the wire 11 for transmitting the detected signal, and the connector 12 is installed at the end of the wire 11 for electrical connection with other parts Is installed.

However, the following disadvantages are pointed out in the conventional temperature sensing device having the above configuration.

The overall structure is complicated, including covers made of aluminum. Such a complicated structure causes disadvantages such as the limitation of productivity due to the increase in manufacturing cost and the complexity of the manufacturing process.

In the process of mounting the aluminum cover 6 to the mount 4 by pressing, a non-uniform spacing occurs between the sensor 2 and the cover 6. That is, due to the assembly tolerance resulting from the process of pressing the cover 6 to the mount 4, the degree of adhesion of the sensor is different, there is a risk of lowering the reliability of temperature sensing. And when the deviation of the temperature detected by the sensor occurs, there is a disadvantage that ultimately the temperature control for cooking or warming of the pressure cooker may be a problem.

The present invention is to solve the above problems, the main object is to provide a temperature sensing device for an electric pressure cooker having a simpler structure.

Another object of the present invention is to provide a temperature sensing device for an electric pressure cooker that can further increase the reliability of the temperature sensing.

According to the present invention for achieving the above object, it is installed inside the electric pressure cooker, as a temperature sensing device for sensing the temperature during heating; A temperature sensor for sensing a temperature; A mount having a sensor housing for accommodating the temperature sensor; The technical gist of the present invention is to include a sensor cap made of silicon which is provided on the opened front surface of the mount and supports the front surface of the sensor.

And according to the Example, the said sensor cap is comprised so that the rear end part may be supported by a mount by fastening to a mount.

According to another embodiment, the sensor cap is formed in a hook shape in which the rear end is bent inward, and the rear end is configured to be supported by the mount by being caught by a locking jaw formed on the outer circumferential surface of the mount.

The mount extends outward from the sensor housing, and the mount further includes a fixing part for fixing the inside of the electric pressure cooker.

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

2 is a cross-sectional view of a temperature sensing device according to the present invention. As shown, the temperature sensing device according to the present invention includes a temperature sensor 20 for sensing a temperature and a mount 30 for storing and supporting the temperature sensor 20.

The mount 30 is injection-molded with a synthetic resin material, for example, a cylindrical sensor housing 32 capable of inserting the temperature sensor 20 therein, and extending outward from the sensor housing. It may be composed of a fixing portion 34 for fixing itself. The sensor housing part 32 is formed in a cylindrical shape, for example, and is formed to hold the temperature sensor 20 therein and maintain it at a constant position. In addition, the fixing part 34 extends outwardly (or radially) from the sensor housing part 32 to substantially maintain the mount 30 at a predetermined position inside the electric pressure cooker.

For example, the mount 30 incorporating the sensor 20 as described above may be configured to be elastically supported inward by a spring as in the prior art. Alternatively, when the sensor 20 is used as a top sensor installed inside the cover of the electric pressure cooker, it is also configured to fix the mount 30 to the inside of the electric pressure cooker by bolting using the fixing part 34. It is possible.

A sensor cap 40 made of silicon is provided on the opened front surface (left side in the drawing) of the sensor housing portion 32. The sensor cap 40 is mounted on the front opening of the mount 30 to perform a function of protecting the sensor 20. Since the sensor cap 40 is made of silicon, it has a substantially constant elasticity and flexibility. Therefore, the sensor 20 supported in close contact with the inner side of the sensor cap 40 (the right side in the drawing) may substantially maintain an accurate close contact with the sensor cap 40.

The sensor cap 40 is coupled to the mount 30 to maintain a state that does not break, it is possible to maintain the sensor 20 in the correct position. For example, the sensor cap 40, as shown, the rear end 42 is formed in a hook shape bent inward, it is formed on the engaging jaw 36 formed on the outer peripheral surface of the mount 30 By configuring the hook, the sensor cap 40 can be accurately coupled to the mount 30 to maintain its position. However, in the embodiment for coupling the sensor cap 40 to the mount 30, of course, many other variations are possible.

For example, the rear end 42 of the sensor cap 40 may be fitted to any part of the mount 32 to be fixed. The rear end 42 of the sensor cap 40 may be fixed to one side of the fixing part 34 of the mount 30 (by pressing or by forming a separate fastening structure and fastening to each other). In addition, the sensor cap 40 may be configured to press-fit the outer circumferential surface of the sensor housing 32 of the mount 32 to maintain the fastening state. Alternatively, the sensor cap 40 may also be configured to be fixed to the mount 30 by using a separate fastening element.

Thus, by combining the sensor cap 40 to the mount 30 to configure the overall temperature sensor, the following advantages are expected. That is, conventionally, a pressing process using a predetermined mold was essential to attach a separate cover made of aluminum to a mount. However, according to the present invention, by forming the sensor cap 40 by using a silicon having a certain flexibility and elasticity, it becomes possible to substantially couple the sensor cap 40 to the mount 30 more easily, For example, simple handwork allows for efficient assembly.

And by using the sensor cap 40 made of silicon, it is possible to omit the configuration of the conventional aluminum cover, it is possible to sufficiently solve various disadvantages that may occur when the aluminum cover is mounted. That is, it is possible to solve the disadvantages caused by the assembly tolerance that may occur during the conventional aluminum cover press process (such as the occurrence of non-uniform gap in the sensor part) and the complicated problem of the presser process. Of course it is done.

As described above, according to the present invention, by using the mount 30 and the sensor cap 40, to simplify the sensor assembly used in the electric pressure cooker, and to configure the configuration to enable more accurate temperature sensing It can be seen that the technical idea.

The above-described temperature sensing device according to the present invention has a structure that can be used as a top sensor installed inside the cover of the electric pressure cooker, and can also be used as a sensor mounted outside the inner pot of the electric pressure cooker.

Within the scope of the basic technical spirit of the present invention, it will be apparent to those skilled in the art that many other modifications are possible and that the present invention should be interpreted based on the appended claims.

According to the present invention as described above it can be expected the following effects.

First, it can be seen that the structure of the present invention is greatly simplified compared with the conventional structure including the aluminum cover. As described above, the simplification of the structure according to the present invention can substantially reduce the number of components and at the same time improve productivity in the assembly process.

And according to the present invention, by using the sensor cap 40 made of silicon, it is expected that the separate device is unnecessary in the assembly process and can be assembled more simply. This point can be said to substantially reduce the manufacturing cost of the product and to improve the productivity.

In addition, according to the present invention, by maintaining a constant contact between the sensor 20 and the sensor cap 40 at all times, the deviation of the cap can be eliminated, it is possible to substantially improve the temperature sensing performance. According to this point, more accurate temperature control is possible in an electric pressure cooker, and it can be said that the effect which can further raise the reliability of a product can be expected.

1 is a schematic cross-sectional view showing a conventional sensing device.

Figure 2 is a schematic cross-sectional view showing a sensing device of the present invention.

Explanation of symbols on the main parts of the drawings

20 .... Temperature Sensor 30 ..... Mount

32 ..... Sensor housing 34 ..... Fixed part

40 ..... Sensor Cap

Claims (4)

A temperature sensing device installed inside the electric pressure cooker for sensing a temperature during heating; A temperature sensor 20 for sensing a temperature; A mount (30) having a sensor housing (32) in which the temperature sensor can be stored; The temperature sensing device of the electric pressure cooker is installed on the opened front of the mount, comprising a sensor cap made of silicon for supporting the front of the sensor. The temperature sensing device of the electric pressure cooker according to claim 1, wherein the sensor cap is supported by the mount by its rear end portion (42) being fastened to the mount (30). The electric pressure cooker of claim 1, wherein the sensor cap is formed in a hook shape in which the rear end is bent inward, and the rear end is supported by the mount by being caught by a locking jaw formed on the outer circumferential surface of the mount. Temperature sensor. The mount of any one of claims 1 to 3, wherein the mount extends outward from the sensor housing portion 32, and the mount further includes a fixing portion 34 for fixing the inside of the electric pressure cooker. Temperature sensing device of the electric pressure cooker configured by.