KR102165573B1 - Cooking Device Comprising Fire Detecting Sensor - Google Patents

Abstract

In a cooking appliance system including a plurality of cooking appliances connected through a flow path according to the technical idea of the present disclosure, an air circulation device for generating an air flow in the flow path, a first cooking appliance connected to the flow path, and It may include a first opening and closing device and a control unit for controlling the opening and closing operation of the first opening and closing device.

Description

Cooking Device Comprising Fire Detecting Sensor {Cooking Device Comprising Fire Detecting Sensor}

The technical idea of the present disclosure relates to a cooking appliance, and more particularly, to a cooking appliance that cuts off power based on a fire detection sensor.

Recently, in homes and businesses, cooking appliances using electricity have been widely used. Examples of such cooking devices include an electric rice cooker, a highlight and/or induction heating type electric range, a microwave oven, a light wave cooker, and an electric oven. Such a cooking appliance includes a heating means (hereinafter, collectively referred to as a heater) including a resistive heater, a magnetron, a light wave generator, an induction heating high frequency generator, etc. operated by electricity. These cooking devices include a temperature sensor for sensing the temperature of food or a cooking container containing food, and can automatically cook food by controlling the operation of the heater based on the temperature detected by the temperature sensor.

Conventionally, when the heater itself, components around the heater, and electronic components for operating the heater are overheated, a fire may occur in the cooking device, and the fire is detected by the microcomputer through a temperature sensor, thereby shutting off the power of the cooking device. This prevented the spread of fire. However, when the micom breaks down, the fire of the cooking appliance cannot be properly recognized, and the spread of the fire cannot be prevented.

A problem to be solved by the technical idea of the present disclosure is to provide a cooking appliance including a power control unit capable of detecting a fire independently from a microcomputer.

In order to achieve the above object, a cooking appliance for cooking food through heating according to an aspect of the technical idea of the present disclosure includes a microcomputer for controlling the cooking appliance, a first sensor and a second sensor for detecting a fire, A power control unit that independently outputs a power cutoff signal from the microcomputer according to a fire detection result of at least one of the first sensor and the second sensor, and a power cutoff that cuts off power supply from an external power source based on the power cutoff signal May contain wealth.

According to an embodiment, the first sensor and the second sensor may be characterized in that they detect fire in different ways.

According to an embodiment, a gate connected to the first sensor and the second sensor is further included, wherein the gate is sent to the power control unit when a fire detection signal is received from the first sensor and the second sensor. It may be characterized by outputting a power control signal.

According to an embodiment, the first sensor may be a temperature sensor that detects the temperature of the cooking appliance, and the second sensor may be a smoke sensor that detects smoke generated from the cooking appliance.

According to an embodiment, the first sensor outputs the fire detection signal when the temperature of the cooking appliance exceeds a predetermined reference temperature, and the second sensor outputs a predetermined reference concentration of smoke generated from the cooking appliance. When the concentration is exceeded, the fire detection signal may be output.

According to an embodiment, the micom outputs a power control signal to the power control unit when the cooking appliance does not operate, and the power control unit outputs the power cutoff signal to the power cut-off unit in response to the power control signal. It can be characterized by that.

According to an embodiment, further comprising: an alarm unit for outputting a fire detection alarm to a user according to the control of the micom and a power module for supplying power to the cooking appliance, wherein the first sensor is connected to the micom to prevent fire. When detected, outputs a fire detection signal to the micom, and the micom outputs an alarm signal for outputting the fire detection alarm to the alarm unit in response to the fire detection signal, and cuts off power to cut off power to the power module It may be characterized by outputting a signal.

According to an embodiment, when detecting a fire, the second sensor does not output a fire detection signal to the microcomputer, but outputs a fire detection signal to the power control unit.

The cooking appliance according to the technical idea of the present disclosure includes a power control unit that receives a fire detection signal from the fire detection sensor and shuts off the power of the cooking appliance independently from the micom based on this, thereby preventing the spread of fire despite the malfunction of the micom. Can be effectively prevented.

1 is a block diagram showing a cooking appliance according to an exemplary embodiment of the present disclosure.
2 is a diagram illustrating a cooking appliance according to an exemplary embodiment of the present disclosure.
3 is a diagram illustrating a cooking appliance according to an exemplary embodiment of the present disclosure.
4 is a flow chart showing a method of operating a cooking appliance according to an exemplary embodiment of the present disclosure.
5 is a flow chart showing a method of operating a cooking appliance according to an exemplary embodiment of the present disclosure.
6 is a flow chart showing a method of operating a cooking appliance according to an exemplary embodiment of the present disclosure.

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

1 is a block diagram showing a cooking appliance according to an exemplary embodiment of the present disclosure.

Referring to FIG. 1, the cooking appliance 1 may include a component arrangement space 10 and a cooking space 20. The component arrangement space 10 refers to a space in which all or most of various electronic/electric components constituting the cooking apparatus 1 are accommodated and arranged, and may be a space mainly surrounded by a case of the cooking apparatus 1. The cooking space 20 may represent a space capable of receiving or seating food or a space capable of receiving or seating the cooking container 210 containing food.

In the component placement space 10, a power cut-off unit 110, a power control unit 120, a microcomputer 130, a first sensor 151, a second sensor 152, an alarm unit 160, a power module 170, A heater driver 180 and a heater 190 may be included.

A power cut-off unit 110 may be disposed on a line connecting the power module 170 and external power. The power cut-off unit 110 may be controlled by the power control unit 120, and the operation may be switched to an on state or an off state. Since the line may be turned on or off by the operation of the power cut-off unit 120, the first power P1 from an external power source may be applied to or cut off the power module 170. In an embodiment, the power cut-off unit 110 may be implemented as a switching element such as a relay.

In response to the first power control signal PC1 of the microcomputer 130 or the second power control signal PC2 from the gate 140, the power control unit 120 transmits a first power cutoff signal to the power cutoff unit 110. PB1) can be printed. The power cut-off unit 110 may cut off power received from an external power source in response to the first power cut-off signal PB1.

According to an embodiment of the present disclosure, since the power control unit 120 controls the power cut-off unit 110 in response to the second power control signal PC2 received from the gate 140 independently from the micom 130 Even when the microcomputer 130 malfunctions, it is possible to effectively cut off power in response to a fire. In addition, according to an embodiment of the present disclosure, the power control unit 120 outputs the first power cut-off signal PB1 to the power cut-off unit 110 in response to the first power control signal PC1 of the microcomputer 130. In addition, the power cut-off unit 110 can minimize the power consumption of the cooking appliance 1 by cutting off external power.

The micom 130 may control the heating operation of the heater 190 by controlling power applied to the heater 190. In addition, in an embodiment in which the first sensor 151 is a temperature sensor, the micom 130 determines the temperature of the food or cooking container 210 to be heated based on the measured value of the first sensor 151, Feedback control for adjusting the heating operation of the heater 190 may be performed by outputting the heating control signal HC to the heater driver 180 based on the temperature. The micom 130 receives the first fire detection signal FD1 from the first sensor 151 and outputs a second power cutoff signal PB2 to the power module 170 based on the first sensor 151 to apply it to the heater 190 Power can be cut off.

The gate 140 may receive a first fire detection signal FD1 from the first sensor 151 and a second fire detection signal FD2 from the second sensor 152. The gate 140 may output a second power cut-off signal PC2 to the power control unit 120 based on at least one of the first fire detection signal FD1 and the second fire detection signal FD2. In one embodiment, the gate 140 may be an AND gate, and in another embodiment, the gate 140 may be an OR gate.

The first sensor 151 and the second sensor 152 may detect fire in different ways and may output a fire detection signal to the microcomputer 130 or the gate 140. In one embodiment, the first sensor 151 may be a temperature sensor, and the second sensor 152 may be a gas sensor. In an embodiment in which the first sensor 151 is a temperature sensor, the first fire detection signal FD1 may mean the temperature of the cooking appliance 1 or the cooking area 20, or the first fire detection signal FD1 ) May mean that the temperature of the cooking appliance 1 or the cooking region 20 is equal to or higher than a predetermined threshold temperature. The first sensor 151 may be disposed in the component placement space 10 to sense the temperature of the food or cooking container 210 accommodated in the cooking space 20. Alternatively, the first sensor 151 may be disposed in the cooking space 20 and configured to directly sense the temperature of the food or cooking container 210.

In an embodiment in which the second sensor 152 is a gas sensor, the second sensor 152 may detect gas around the cooking apparatus 1. The gas sensor is for detecting that a fire has occurred in various electronic components of the cooking appliance 1, and has electrical characteristics in response to at least one of carbon monoxide, carbon dioxide, water vapor, sulfurous acid gas, nitrogen, hydrogen, sulfur, smoke, or soot particles. It can be configured to change. When the second sensor 152 detects gas and its electrical characteristics change, the power control unit 120 detects a change in operating voltage due to the change, and controls the power cut-off unit 110 to control the heater 190 and the By disconnecting from the external power source, the cause of the fire can be eliminated.

In an exemplary embodiment, the second sensor 152 may measure the gas concentration around the cooking appliance 1 and output the second fire occurrence signal FD2 by comparing the gas concentration with the threshold concentration. For example, when gas particles are attached to the semiconductor surface of the second sensor 152, electrical characteristics at both ends of the semiconductor may change, so that a change in voltage across the second sensor 152 may be detected. Alternatively, when gas particles enter the inner space of the second sensor 152, light passing through the space may be scattered, and electrical characteristics of the semiconductor surface receiving the light may be changed. In addition, the second sensor 152 may be configured to have a driving circuit by itself and output an analog/digital signal of a specific waveform when gas is detected. The power control unit 120 may determine whether a fire has occurred based on the signal of this specific waveform.

When a fire occurs, the micom 130 may output an alarm signal AS to the alarm unit 160, and the alarm unit 160 may output a predetermined warning message to the user in response thereto. The warning message may be output through sound or light, and for this, the alarm unit 160 may include at least one speaker or a light emitting device.

The power module 170 receives the first power P1 from an external power source, transforms and/or modulates the input AC power to provide power requested by each part of the cooking appliance 1 (for example, the heater 190 The second power (P2)) required by) can be supplied. The power supply module 170 includes a filtering circuit for removing high-frequency noise included in the AC voltage, a rectifier circuit for converting the AC voltage to a DC voltage, a smoothing circuit for smoothing the rectified DC voltage, and a heater and/or the smoothed DC voltage. Alternatively, it may include a transformer circuit for boosting or stepping down to a voltage required by the controller. The power module 170 may include a diode bridge circuit and a switching mode power supply (SMPS).

The heater driver 180 may drive the heater 190 by outputting a driving signal DS to the heater 190 in response to the heating control signal HC of the microcomputer 130. The heater 190 collectively refers to all means for heating the food or cooking container 210 accommodated in the cooking space 20 by outputting thermal energy or electromagnetic energy by power applied from the power module 170. The heater 190 includes an induction heating coil, an electric resistive heating element, an electromagnetic wave generator, a light wave generator, and the like.

2 is a diagram illustrating a cooking appliance according to an exemplary embodiment of the present disclosure. In detail, FIG. 2 shows an electric rice cooker including a power control unit. Contents overlapping with FIG. 1 are omitted.

Referring to FIG. 2, the cooking appliance 1a may include a component placement space 10 and a cooking space 20, and the component placement space 10 includes a power cut-off unit 110, a power control unit 120, and The microcomputer 130, the sensor unit 150, and the heater 190 may be included. Although not shown, the cooking appliance 1a may further include a gate, an alarm unit, a power module, and a heater driver.

The cooking vessel 210 may be accommodated in the main body of the cooking appliance 1a. The space in which the cooking vessel 210 is accommodated constitutes the cooking space 20, and the inner space of the main body of the cooking apparatus 1a constitutes a component arrangement space 10. The component arrangement space 10 includes various electric/ Electronic components may be disposed A sensor unit 150 for detecting a fire may be disposed at the bottom of the cooking space 20. The sensor unit 150 may be a first sensor for detecting the temperature of the cooking container. 1 and 151. An induction heating coil may be disposed as a heater 190 for heating the cooking container 210 on a part of the bottom or side of the cooking space 20. In addition, the sensor unit A second sensor (FIGS. 1, 152) may be positioned independently of the first sensor (FIGS. 1 and 151) to detect a fire in the component placement space 10. In one embodiment, the component 150 may be located. A plurality of second sensors (FIGS. 1 and 152) may be disposed in the placement space 10.

As shown, the power control unit 120 may be configured and disposed in a module form independent from the microcomputer 130. The power control unit 120 may receive a fire detection signal from the sensor unit 150 and control the power cut-off unit 110 based on this.

According to the technical idea of the present disclosure, the power control unit 120 can immediately detect a fire that may occur in the component arrangement space 10 or the cooking space 20, and when a fire is detected, the power supply without control of the microcomputer 130 Since the connection to is turned off, it is possible to prevent the fire from spreading by continuing to supply external power even when a fire occurs.

3 is a diagram illustrating a cooking appliance according to an exemplary embodiment of the present disclosure. In detail, FIG. 3 shows an electric range including a power control unit. Contents overlapping with FIG. 1 are omitted.

Referring to FIG. 3, the cooking appliance 1b may include a component placement space 10 and a cooking space 20, and the component placement space 10 includes a power cut-off unit 110, a power control unit 120, and The microcomputer 130, the sensor unit 150, and the heater 190 may be included. Although not shown, the cooking appliance 1b may further include a gate, an alarm unit, a power module, and a heater driver.

The cooking appliance 1b may have a cooking container disposed thereon. Accordingly, the space in which the cooking container is placed may constitute the cooking space 20, and the internal space of the cooking appliance 1b may constitute the component arrangement space 10. Various electric/electronic components may be arranged in the component arrangement space 10. A sensor unit 150 for detecting a fire may be disposed at the bottom of the cooking space 20. The sensor unit 150 is disposed independently from the first sensor (FIGS. 1 and 151) for sensing the temperature of the cooking container and the second sensor (FIGS. 1 and 152) for detecting a fire. ) Can be located.

At least one induction heating coil or highlight may be disposed on a part of the bottom or side of the cooking space 20 as a heater 190 for heating the cooking container 210.

As shown, the power control unit 120 may be configured and disposed in a module form independent from the microcomputer 130. The power control unit 120 may receive a fire detection signal from the sensor unit 150 and control the power cut-off unit 110 based on this.

According to the technical idea of the present disclosure, the power control unit 120 can immediately detect a fire that may occur in the component arrangement space 10 or the cooking space 20, and when a fire is detected, the power supply without control of the microcomputer 130 Since the connection to is turned off, it is possible to prevent the fire from spreading by continuing to supply external power even when a fire occurs.

4 is a flow chart showing a method of operating a cooking appliance according to an exemplary embodiment of the present disclosure.

Referring to FIGS. 1 and 4, when there is a user's heating operation (S120), the micom 130 may supply power to the heater 190 by outputting a heating control signal HS to the heater driving unit 180. The first sensor 151 may detect a fire by measuring the temperature of the cooking appliance 1 and the second sensor 152 measuring a gas concentration (S130). When a fire is detected, the power control unit 120 may cut off power by controlling the power cut-off unit 110 (S180). When a fire is not detected, the micom 130 may determine whether the temperature of the cooking region 20 has reached the target temperature based on the temperature measurement result of the first sensor 151 (S140). When the target temperature is not reached, the micom 130 may increase the temperature of the cooking region 20 by continuously supplying power to the heater 190 by repeating steps S120 to S140. When the target temperature is reached, the micom 130 may control the heater driver 180 to maintain the target temperature (S150).

While maintaining the target temperature, the first sensor 151 may detect the fire by measuring the temperature of the cooking appliance 1 and the second sensor 152 measuring the gas concentration (S160). When a fire is detected, the power control unit 120 may cut off power by controlling the power cut-off unit 110 (S180). When a fire is not detected, the micom 130 may determine whether there is a user's power operation (S170). If there is no power operation by the user, the temperature of the cooking area 20 can be controlled to the target temperature by repeating steps S150 to S170. If there is power operation by the user, the micom 130 uses the power control unit 120 Can output power control signal to. The power control unit 120 may cut off power by controlling the power cut-off unit 110 in response thereto (S180), and accordingly, standby power consumption may be minimized.

5 is a flow chart showing a method of operating a cooking appliance according to an exemplary embodiment of the present disclosure. In detail, FIG. 5 shows an operation in which the cooking appliance detects a fire (S130 or S160 in FIG. 4). 5 illustrates step S130 of FIG. 4, it is natural that it can also be applied to step S160 of FIG. 4.

1 and 5, the first sensor 151 may sense the temperature of the cooking appliance (S131). The first sensor 151 or the power control unit 120 may determine whether the temperature of the cooking appliance 1 sensed by the first sensor 151 is equal to or higher than a first predetermined temperature (S132). When the temperature of the cooking appliance 1 is not higher than the first temperature, it is determined that no fire has occurred, and the next step (S140) may be performed.

When the temperature of the cooking appliance 1 is equal to or higher than the first temperature, the second sensor 152 may sense the concentration of gas surrounding the cooking appliance (S133). The second sensor 152 or the power control unit 120 may determine whether the gas concentration around the cooking appliance 1 sensed by the second sensor 152 is equal to or greater than a predetermined first concentration (S134). If the gas concentration around the cooking appliance 1 is not more than the first concentration, it is determined that no fire has occurred, and the next step S140 may be performed. When the gas concentration around the cooking appliance 1 is greater than or equal to the first concentration, it is determined that a fire has occurred, and the power control unit 120 controls the power cut-off unit 110 to cut off the power supplied to the cooking appliance (S180). .

6 is a flow chart showing a method of operating a cooking appliance according to an exemplary embodiment of the present disclosure. In detail, FIG. 6 is a flow chart illustrating an embodiment in which the cooking appliance additionally checks whether the micom operates normally. 6 shows only the case of step S130 of FIG. 4, it is natural that it can also be applied to step S160 of FIG. 4.

Referring to FIGS. 1 and 6, when a fire is detected by the sensor units 151 and 152 (S130), the power control unit 120 may output a normal operation confirmation signal to the microcomputer 130 (S136). . In one embodiment, the micom 130 may output a predetermined response signal to the power control unit 120 in case of normal operation, and the power control unit 120 determines whether the micom 130 is operating normally can do. The power control unit 120 determines whether the microcomputer 130 operates normally (S137), and if the microcomputer 130 is operating normally, the power control unit 120 may not perform a power cut (S138). In this case, if an actual fire occurs, power may be cut off by the microcomputer 130. When the microcomputer 130 is not operating normally, the power control unit 120 may cut off the power by controlling the power cutoff unit 110.

As described above, exemplary embodiments have been disclosed in the drawings and specifications. In the present specification, embodiments have been described using specific terms, but these are only used for the purpose of describing the technical idea of the present disclosure, and are not used to limit the meaning or the scope of the present disclosure described in the claims. . Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of the present disclosure should be determined by the technical spirit of the appended claims.

Claims (8)

In a cooking appliance that cooks food through heating,
A power module for rectifying power input from an external power source and outputting the rectified power;
A power cut-off unit configured to apply or cut off the power input from the external power supply to the power module through a switching operation according to a first power cut-off signal;
A first sensor for detecting a fire;
During normal operation, based on the fire detection result of the first sensor, a second power cutoff signal is provided to the power module so that the output of the rectified power is cut off, or the input of the power to the power module is cut off. A microcomputer that outputs a first power control signal; And
During normal operation of the micom, the first power cut-off signal is provided to the power cut-off unit according to the first power control signal, and when the micom is abnormally operated, the fire detection result of the first sensor Cooking apparatus comprising a power control unit for providing the first power cut off signal to the power cut off independently of the microcomputer. The method of claim 1,
A second sensor for detecting a fire; further includes,
The power control unit outputs the first power cutoff signal according to the fire detection result of the first sensor and the second sensor,
The first sensor and the second sensor, characterized in that for detecting a fire in different ways. The method of claim 2,
Further comprising; a gate connected to the first sensor and the second sensor,
The gate, when receiving a fire detection signal from the first sensor and the second sensor, transmits a power second control signal to the power control unit so that the power control unit outputs the first power cutoff signal. Cooking equipment. The method of claim 3,
The first sensor is a temperature sensor that detects the temperature of the cooking appliance, and the second sensor is a smoke sensor that detects smoke generated from the cooking appliance. The method of claim 4,
The first sensor outputs the fire detection signal when the temperature of the cooking appliance exceeds a predetermined reference temperature,
And the second sensor outputs the fire detection signal when the concentration of smoke generated from the cooking appliance exceeds a predetermined reference concentration. The method of claim 2,
The micom outputs the first power control signal to the power control unit when the cooking appliance does not operate,
Wherein the power control unit outputs the first power cutoff signal to the power cutoff unit in response to the first power control signal. The method of claim 6,
Further comprising an alarm for outputting a fire detection alarm to the user under the control of the microcomputer,
When the first sensor is connected to the micom to detect a fire, the first sensor outputs a fire detection signal to the micom,
Wherein the micom outputs an alarm signal for outputting the fire detection alarm to the alarm unit in response to the fire detection signal, and outputs a power cutoff signal for power off to the power module. The method of claim 7,
When detecting a fire, the second sensor does not output a fire detection signal to the microcomputer, but outputs a fire detection signal to the power control unit.

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