KR20180067750A - Apparatus for detecting cooking container and cooling temperature sensor in gas range - Google Patents

Abstract

The present invention relates to a gas range cooking vessel detecting apparatus and a temperature sensor cooling apparatus. The presence or absence of the cooking vessel on the burner head is detected by detecting a change in the driving current of a fan blowing air for detecting the presence or absence of the cooking vessel to the upper side of the burner head through the air supply passage communicating with the internal space of the gas range burner head. As a result, if it is determined that there is a cooking vessel, ignition is permitted, and the temperature sensor is cooled by driving the fan for a predetermined time when overheating is detected during operation of the gas range and the gas range is automatically extinguished based on the temperature sensed by the temperature sensor, which protrudes upward from the internal space of the gas range burner head and is in contact with the cooking container placed on the burner head to detect the temperature of the cooking vessel for overheating detection. According to the present invention, it is possible to easily detect the presence or absence of the cooking vessel by using a fan that blows air to the upper side of the gas range burner head. In particular, when the gas range is overheated, the gas range is automatically extinguished, and then the fan is driven so that the temperature sensor of the gas range can be quickly cooled. Accordingly, the automatic cooking performance can be maximized by solving the problem that the automatic cooking performance which requires precise temperature control is hindered when a user re-ignites the gas range to automatically cook.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cooking apparatus,

The present invention relates to a gas range, and more particularly, to a gas range cooking vessel detection and a temperature sensor cooling apparatus.

In Patent Document 1, when the cooking vessel is placed on a tripod, the amount of movement of the rod when the rod is press-fitted and moved by the bottom of the cooking vessel is converted into a physical quantity that changes with the increase or decrease of the movement amount, A cooking vessel detecting device capable of acquiring not only the presence or absence of the cooking vessel placed on the tripod, but also information about the type of the cooking vessel is posted.

On the other hand, Patent Document 2 discloses a gas burner having a pot bottom temperature sensor including a pot burner having a flame hole formed on the outer periphery thereof and a pot bottom temperature sensor which is raised and protruded upward in a burner inner space surrounded by the burner It is posted.

The rod of Patent Document 1 described above corresponds to the rod of the temperature sensor as shown in Patent Document 2. Since the cooking vessel detecting device of Patent Document 1 is coupled to the lower end of the rod in the form of a case accommodating the coil spring, Is complex.

On the other hand, Patent Document 3 discloses an overheat prevention control method for a gas range that includes a temperature sensor for detecting the temperature of the cooking container and performs an overheat prevention function for controlling the heating based on the detection temperature of the temperature sensor have.

According to Patent Document 3, when overheat is detected by the temperature sensor, it is possible to prevent the overheating of the gas range by automatically extinguishing the gas range during the cooking operation. However, even if the gas range is automatically extinguished, There is a problem that the automatic cooking performance which requires precise temperature control is hindered when the user repeatedly re-ignites the gas range in a state in which the temperature sensor is not completely cooled because the temperature sensor was gradually cooled.

For example, when automatic cooking such as egg boiling, ramen cooking, and fried cooking is performed using a gas range, a normal timer is set and a cooking temperature according to the type of automatic cooking is set. As described above, For example, in a state in which the temperature sensor does not cool down to a low temperature region where the temperature resolution of the temperature sensor is excellent, when the user re-ignites the gas range and automatically cooks the gas range, It is impossible to precisely control the cooking temperature for the automatic cooking sensed by the user. As a result, the automatic cooking performance is deteriorated.

KR 10-1465890 B1 KR 10-2013-0137559 A KR 10-1265549 B1

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and apparatus for blowing air for detecting the presence or absence of a cooking vessel to the upper side of a burner head through a gas supply line communicating with an internal space of a gas- When the presence or absence of the cooking container on the burner head is detected by sensing a change in the driving current of the loading fan, if it is determined that the cooking container is present, the ignition is permitted. When the gas range is automatically extinguished due to the detection of the overheating during the operation of the gas range based on the detection temperature of the temperature sensor sensing the temperature of the corresponding cooking vessel in order to detect the overheat in a state of being in contact with the cooking vessel, To provide a gas range cooking vessel detection and a temperature sensor cooling apparatus for cooling the temperature sensor will be.

According to an aspect of the present invention, there is provided a cooking apparatus for detecting a cooking zone of a gas range and a temperature sensor for cooling the cooking zone, A fan for blowing in air for detecting the presence or absence of air; A temperature sensor protruding upward from an inner space of the gas range burner head and sensing a temperature of the cooking container in a state of being in contact with the cooking container placed on the burner head for detecting overheating; A fan driving signal for driving the fan at a predetermined number of revolutions (RPM) for a predetermined period of time before ignition of the gas range is output, and a change in the driving current of the fan is detected after the fan driving signal is output, If it is determined that the cooking container is present as a result of detection, if the ignition is permitted and the ignition switch is operated to the ignition position, the gas range is ignited and if the overheating of the gas range is detected based on the temperature sensed by the temperature sensor during operation of the gas range A micro control unit (MCU) for cooling the temperature sensor by automatically extinguishing the gas range and then outputting the fan driving signal to drive the fan at a predetermined number of revolutions (RPM) for a predetermined time; A fan driving unit for supplying a driving current for driving the fan by the fan driving signal; And a fan drive current sensing unit for sensing a drive current of the fan and transmitting the sensed current to the micro control unit (MCU).

In the gas range cooking vessel detection and temperature sensor cooling apparatus according to the present invention, when the driving current of the fan increases to a predetermined value or more after the fan driving signal is output, the micro control unit (MCU) .

In the gas range cooking vessel detection and temperature sensor cooling apparatus according to the present invention, the air supply passage communicating with the internal space of the gas range burner head blows air through the lower end opening of the burner head, And air is blown through the hole.

According to the present invention, it is possible to easily detect the presence or absence of the cooking container by using a fan that blows air to the upper side of the gas range burner head. Especially, when the gas range is overheated, the gas range is automatically extinguished, The temperature sensor of the present invention can be quickly cooled. Therefore, when the temperature sensor that has been already heated during the overheating operation of the gas range has been completely cooled and the user has re-ignited the gas range to automatically cook, It is possible to maximize the automatic cooking performance by solving the problem that the automatic cooking performance which requires the control is hindered.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a configuration diagram showing a gas range cooking vessel detection and temperature sensor cooling apparatus according to the present invention. Fig.
2 is a cross-sectional view showing the structure of a gas range equipped with a fan and a temperature sensor included in the gas-range cooking vessel detection and temperature sensor cooling apparatus according to the present invention.
3 is a cross-sectional view showing another structure of a gas range equipped with a fan and a temperature sensor included in the gas-range cooking vessel detection and temperature sensor cooling apparatus according to the present invention.

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

Referring to FIG. 1, the apparatus 100 for detecting and calibrating a gas range cooking vessel according to the present invention includes a fan 110, a temperature sensor 120, a micro control unit (MCU) 130, (140), and a fan drive current sensing unit (150).

2 to 3, a gas range 200 equipped with the fan 110 and the temperature sensor 120 of the gas range cooking vessel detection and temperature sensor cooling apparatus 100 according to the present invention includes a main body (not shown) A burner 230 installed in the burner opening 210 and heating the cooking container by burning the fuel gas, and a cooking container 210 such as a pot, And a pedestal 240 for lifting up the pedestal.

The gas range 200 includes a burner body 250 formed in a circular ring shape, a mixing tube 260 extending from the burner body 250, a circular ring burner head 270 installed on the upper surface of the burner body 250, .

A burner cap 280 is provided at an upper portion of the burner body 250.

When the fuel gas is injected toward the inside of the mixing pipe 260 at the opening end 261 of the mixing pipe 260 extending from the burner body 250, a mixed gas of fuel gas and air And is supplied to the burner body 250, and the mixed gas is blown out from the sputum 271. Combustion of the gas range 200 is initiated by igniting the mixture gas thus spouted with the spark plug 290.

Secondary air is required for combustion of the mixed gas during the operation of the gas range 200. About half of the secondary air flows through the opening 272 formed in the lower end of the burner head 270 disposed at the center of the gas range 200, To the gap between the burner head 270 and the burner cap 280, as shown in Fig. Therefore, during the combustion of the gas range 200, an upward flow is formed by the secondary air supplied into the opening portion 272.

A support pipe 121 of the temperature sensor 120 is installed inside the opening 272 and a substantially cylindrical thermal head 122 is provided at the upper end of the support pipe 121 with respect to the support pipe 121 And is slidably mounted in the elevating direction. A temperature sensor 120 is formed by the support pipe 121 and the thermal head 122.

The temperature sensing sensor element and the coil spring are built in the thermal head 122. When the coil spring elastically lifts the thermal head 122 upwardly and there is no cooking vessel on the base 240, The upper end of the cooking chamber 122 rises to be in a state of protruding beyond the upper surface of the pedestal 240 (the surface on which the cooking vessel is lifted).

Alternatively, when the cooking vessel is placed on the pedestal 240, the thermal head 122 is pressed downward by the bottom surface of the cooking vessel and the lower end of the thermal head 122 is pressed against the force of the coil spring To the bottom surface of the cooking vessel. Therefore, the temperature of the bottom surface of the cooking container can be detected by the temperature sensing sensor element built in the thermal head 122.

The fan 110 is connected to the upper portion of the burner head 270 through a gas supply pipe 111 communicating with the lower end opening 272 of the burner head 270, Air is blown to detect the presence of the cooking vessel.

As shown in FIG. 2, the air supply tube 111 communicating with the internal space of the gas range burner head blows air through the lower end opening portion 272 of the burner head 270, (Not shown) formed in the side wall of the main body 270 to blow air.

The temperature sensor 120 protrudes upward from the inner space of the burner head 270 and contacts the cooking container placed on the burner head 270 to detect the temperature of the cooking container Detection.

The micro control unit (MCU) 130 outputs a fan driving signal for driving the fan 110 at a predetermined rotation speed (RPM) for a predetermined time before ignition of the gas range 200, When the presence of the cooking container on the burner head 270 is detected by detecting a change in the driving current of the fan 110 and it is determined that the cooking container exists, if the ignition is permitted and the ignition switch 131 is operated to the ignition position, When the overheating of the gas range 200 is sensed based on the temperature sensed by the temperature sensor 120 during operation of the gas range 200, the gas range 200 is automatically extinguished, And outputs a driving signal to cool the temperature sensor 120.

When the driving current of the fan (110) increases to a predetermined reference value or more after the fan driving signal is output, the micro control unit (MCU) 130 determines that the cooking container exists.

The fan driving unit 140 supplies a driving current for driving the fan 110 by the fan driving signal.

The fan driving current sensing unit 150 senses the driving current of the fan 110 and transmits the sensing current to the micro control unit (MCU) 130.

The gas-range cooking vessel detection and temperature sensor cooling apparatus 100 according to the present invention configured as above operates as follows.

When the user places the cooking container (for example, a pot) on the burner head 270 before the ignition operation of the gas range 200, that is, before the burning, the temperature sensor 120 is lowered by the cooking container.

Before the user fully operates the ignition switch 131 to the ignition position to ignite the gas range 200 in a state where the cooking vessel is mounted on the burner head 270 as described above, The micro control unit (MCU) 130 outputs a fan driving signal for driving the fan 110 at a predetermined rotation speed (RPM) for a predetermined period of time, 140).

Accordingly, when the fan 110 supplies the driving current for driving the fan 110 to the fan 110, the fan 110 rotates at a predetermined RPM for a predetermined period of time, Air for detecting the presence or absence of the cooking container is blown into the upper side of the burner head 270 through the air supply opening 111 communicating with the lower opening portion 272 of the cooking chamber 270.

At this time, the air blown to the upper side of the burner head 270 strikes the bottom surface of the cooking container and receives resistance.

That is, when there is no cooking vessel on the burner head 270, the air blown to the upper side of the burner head 270 escapes to the upper side of the burner head 270 without any resistance. When the container is lifted up, the air blown to the upper side of the burner head 270 strikes the bottom surface of the cooking container and receives resistance, and the resistance thus generated acts as a load corresponding to the fan 110.

As a result, more driving current is required for the fan 110 to rotate at a predetermined revolution (RPM) for a predetermined time.

As the fan 110 rotates at a predetermined RPM for a predetermined time after the fan driving signal is output, more driving current flows as compared to when the fan 110 starts to rotate. At some point, The microcontroller unit (MCU) 130 easily recognizes that the cooking container is present on the burner head 270 of the current gas range 200 and allows the ignition if the driving current of the burner head 270 is higher than a predetermined reference value.

When the ignition switch 131 is operated by the user to the ignition position by the user, the micro control unit (MCU) The range 200 is ignited and operated.

Actually, when the ignition switch 131 is operated to the ignition position, the micro control unit (MCU) 130 activates the ignition device (IG; ignition) 132 when the power is supplied and outputs an ignition signal to the gas range The gas supply amount control valve 133 (for example, a proportional control valve) for controlling the flow rate of the gas supplied to the burner 230 of the combustion chamber 200 is opened to burn the gas, and as the thermal power adjustment switch 134 is operated, The opening degree of the valve 133 is adjusted to adjust the thermal power.

During the operation of the gas range 200, the temperature sensor 120 is lowered by the cooking container placed on the burner head 270 and is in contact with the cooking container. In this state, the temperature of the corresponding cooking container is sensed To the micro control unit (MCU) 130.

If the micro-control unit (MCU) 130 detects overheating of the gas range 200 based on the temperature sensed by the temperature sensor 120 during operation of the gas range 200, the micro- And outputs the fan driving signal to cool the temperature sensor 120 by driving the fan 110 at a predetermined rotation speed (RPM) for a predetermined period of time.

If overheat is detected by the temperature sensor 120, it is possible to prevent overheating of the gas range 200 by automatically extinguishing the gas range 200 during the cooking operation.

Particularly, the micro control unit (MCU) 130 automatically extinguishes the gas range 200 and outputs a fan driving signal to drive the fan 110 at a predetermined rotation speed (RPM) for a predetermined period of time, The temperature sensor 120 which has been already heated during the overheating operation of the gas range conventionally can be cooled down to a low temperature region where the temperature resolution of the temperature sensor 120 is excellent, It is possible to solve the problem that the automatic cooking performance which requires precise temperature control is hindered when the user re-ignites the gas range to perform automatic cooking.

Further, the problem of heat resistance durability caused by the temperature sensor 120 being exposed to high temperature for a long time is solved, and accurate temperature detection can be performed due to improvement in durability and durability.

For example, when automatic cooking such as egg boiling, ramen cooking, and fried cooking is performed using a gas range, a normal timer is set and a cooking temperature according to the type of automatic cooking is set. As described above, If the temperature of the temperature sensor 120 is quickly cooled down to a low temperature region with excellent temperature resolution after the gas range 200 is automatically extinguished, the user re-ignites the gas range 200 to perform automatic cooking The cooking temperature for automatic cooking sensed by the temperature sensor 120 can be precisely controlled, and as a result, the automatic cooking performance can be maximized without being hindered.

The present invention is not limited to the above-described embodiments, and various modifications and changes may be made without departing from the scope of the present invention as defined in the following claims. For example, There is a technical spirit to the extent that anyone can change and implement it.

100: Gas range cooker detection and temperature sensor cooling system
110: Fan 111:
120: Temperature sensor 121: Support pipe
122: Thermal head 130: Micro control unit (MCU)
140: fan driving unit 150: fan driving current sensing unit
131: ignition switch 132: ignition device (IG; ignition)
133: Gas supply amount control valve 134: Thermal power adjustment switch
200: gas range 210: opening
220: top plate 230: burner
240: pedestal 250: burner body
260: mixing pipe 261:
270: burner head 271:
272: opening 280: burner cap
290: Spark plug

Claims (3)

A fan for blowing air to the upper side of the burner head through a gas supply line communicating with the internal space of the gas range burner head to detect the presence or absence of the cooking chamber;
A temperature sensor protruding upward from an inner space of the gas range burner head and sensing a temperature of the cooking container in a state of being in contact with the cooking container placed on the burner head for detecting overheating;
A fan driving signal for driving the fan at a predetermined number of revolutions (RPM) for a predetermined period of time before ignition of the gas range is output, and a change in the driving current of the fan is detected after the fan driving signal is output, If it is determined that the cooking container is present as a result of detection, if the ignition is permitted and the ignition switch is operated to the ignition position, the gas range is ignited and if the overheating of the gas range is detected based on the temperature sensed by the temperature sensor during operation of the gas range A micro control unit (MCU) for cooling the temperature sensor by automatically extinguishing the gas range and then outputting the fan driving signal to drive the fan at a predetermined number of revolutions (RPM) for a predetermined time;
A fan driving unit for supplying a driving current for driving the fan by the fan driving signal; And
A fan driving current sensing unit sensing a driving current of the fan and transmitting the sensed current to a microcontroller (MCU);
And a temperature sensor for detecting the temperature of the cooking cavity. The micro-control unit (MCU) according to claim 1, wherein the micro-control unit (MCU) determines that the cooking chamber is present when the driving current of the fan increases to a predetermined reference value or more after the fan driving signal is output Temperature sensor cooling device. The air conditioner according to claim 1, characterized in that the air supply passage communicating with the internal space of the gas range burner head blows air through a lower end opening of the burner head or blows air through a vent hole formed in a side wall of the burner head Gas Range Cooking vessel detection and temperature sensor cooling system.

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