JP2019027771A - Heating cooking machine - Google Patents

Abstract

To provide a heating cooking machine capable of surely removing an RFID tag before starting heating.SOLUTION: A heating cooking machine has an interface and a processor. The interface is connected to an RFID reader for receiving a response from an RFID tag with respect to a radio wave radiated to the inside of a heating chamber via an antenna. In the case where the RFID reader has received a response from the RFID tag after radiating the radio wave from the antenna, the processor prohibits execution of heating processing in the heating chamber.SELECTED DRAWING: Figure 2

Description

  Embodiments described herein relate generally to a cooking device.

  2. Description of the Related Art Conventionally, there is a system that performs accounting processing by reading information indicating a product from an RFID tag attached to the product. As an operation of this system, in recent years, an RFID tag is often attached to a product such as a food that is supposed to be heated by a heating cooker such as a microwave oven. In the microwave oven, when an article with an RFID tag including metal is heated, the RFID tag may be abnormally heated or sparks may be scattered. For this reason, the conventional microwave oven needs to remove the RFID tag attached to the article before heating by the user's own judgment. However, the user may be instructed to heat the article with the RFID tag attached without being aware of it in a microwave oven. Even in such a case, there is a demand for a device that can reliably remove the RFID tag before starting heating.

JP 2005-182482 A

  In order to solve the above-described problems, an object of the present invention is to provide a heating cooker that can reliably remove an RFID tag before starting heating.

  According to the embodiment, the cooking device has an interface and a processor. The interface is connected to an RFID reader that receives a response from the RFID tag with respect to the radio wave irradiated into the heating chamber via the antenna. When the RFID reader receives a response from the RFID tag after radiating radio waves from the antenna, the processor cannot perform the heating process in the heating chamber.

Drawing 1 is an outline view showing an example of composition of a microwave oven as a cooking-by-heating machine concerning an embodiment. FIG. 2 is a block diagram illustrating a configuration example of a control system in the microwave oven as the heating cooker according to the embodiment. Drawing 3 is a flow chart for explaining the 1st example of operation of a microwave oven as a cooking-by-heating machine concerning an embodiment. FIG. 4 is a flowchart for explaining a second operation example of the microwave oven as the heating cooker according to the embodiment. FIG. 5 is a flowchart for explaining a third operation example of the microwave oven as the cooking device according to the embodiment. Drawing 6 is an outline view showing the example of composition of the microwave oven as the cooking-by-heating machine concerning the 1st modification of an embodiment. FIG. 7 is a block diagram illustrating a configuration example of a microwave oven as a cooking device according to a second modification of the embodiment.

Hereinafter, embodiments will be described with reference to the drawings.
Drawing 1 is an outline view showing the example of composition of microwave oven 1 as a cooking-by-heating machine (electric cooking appliance, electromagnetic wave heating device, microwave oven) concerning an embodiment.
In the configuration example shown in FIG. 1, the microwave oven 1 has a heating chamber 2 for heating an article such as food. The heating chamber 2 is configured as a warehouse in which articles to be heated are arranged. For example, the heating chamber 2 is formed of a wide metal plate with a flat wall in the cabinet. The heating chamber 2 is irradiated with microwaves generated by a magnetron (see FIG. 2). The article (food item) accommodated in the heating chamber 2 is heated by being irradiated with microwaves. The inner wall of the heating chamber 2 is formed of a flat and wide metal plate so that it does not generate much heat even when it is irradiated with microwaves.

  The microwave oven 1 is provided with an opening of the heating chamber 2 on the front surface of the main body. In the microwave oven 1, an openable / closable door 3 is provided at the opening of the heating chamber 2. The door 3 is opened and closed by the user. The user opens the door 3 and places an article such as a food item to be heated in the heating chamber 2. After placing the article in the heating chamber 2, the user closes the door 3 and gives an instruction to start heating. Note that the door 3 may be provided with a window (inside view portion) so that the user can visually recognize the inside of the heating chamber 2.

Furthermore, the microwave oven 1 has a display 4, a speaker 5, a switch 6 and the like on the front surface. In the configuration example shown in FIG. 1, the microwave oven 1 is provided with an operation panel having a display 4, a speaker 5, and a switch 6 next to the door 3.
The display 4 displays various information. For example, the display 4 displays operation guidance, information indicating the state of the microwave oven, a warning, or the like. The speaker 5 outputs sound that can be recognized by the user. For example, the speaker 5 outputs a sound corresponding to the user's operation or outputs an alarm for the user.

  The switch 6 is a button for the user to input an operation instruction. For example, the switch 6 includes a button (start switch) for instructing the start of heating. The switch 6 may be configured so that the user can input various information (for example, heating start instruction, heating stop instruction, heating power setting, heating time setting, reset, and the like). In addition, you may comprise the indicator 4 with the display apparatus with a touch panel. In this case, the display device with a touch panel may function as an operation device including a start switch.

  Moreover, the heating chamber 2 is provided with an antenna 7 on at least one of the walls in the cabinet. The antenna 7 is a wide metal plate such as a planar antenna, for example, and is configured to reflect microwaves. The antenna 7 is connected to a communication control circuit (see FIG. 2) as an RFID reader. The antenna 7 transmits and receives radio waves that can detect the RFID tag (radio waves that can be communicated with the RFID tag).

  The microwave oven 1 has various sensors. In the example illustrated in FIG. 1, the microwave oven 1 includes an article sensor 8 and an open / close sensor 9. The article sensor 8 is a sensor that detects an article placed in the heating chamber 2. The article sensor 8 is constituted by, for example, a weight sensor that detects the weight of an article placed in the heating chamber 2. The opening / closing sensor 9 is a sensor that detects opening / closing of the door 3.

Next, a control system of the microwave oven 1 according to the embodiment will be described.
FIG. 2 is a block diagram illustrating a configuration example of a control system in the microwave oven 1 according to the embodiment.
2, the microwave oven 1 includes a control unit (processor) 11, a memory 12, a power supply unit 13, a magnetron 14, an interface 15, an RFID reader (communication control circuit) 16, and the like. In addition to the memory 12, the power supply unit 13, the magnetron 14, and the interface 15, the display unit 4, the speaker 5, the switch 6, the article sensor 8, and the open / close sensor 9 are connected to the processor 11.

  The processor 11 implements various processes by executing a program. The memory 12 includes a RAM, a ROM, a rewritable nonvolatile memory, and the like. The memory 12 stores programs executed by the processor 11 and control data. For example, the processor 11 realizes processing to be described later by executing a program stored in the memory 12.

The power supply unit 13 supplies power to each unit. For example, the power supply unit 13 is connected to a commercial power supply and supplies power from the commercial power supply to each unit. The power supply unit 13 may include a battery. For example, the power supply unit 13 is connected to a magnetron 14 and supplies power to the magnetron 14 in accordance with control by the processor 11.
The magnetron 14 receives the power supply from the power supply unit 13 and generates a microwave. The magnetron 14 irradiates the generated microwave into the heating chamber 2. The magnetron 14 has a microwave output controlled by the processor 11.

  The interface 15 is an interface that connects the processor 11 and the RFID reader 16. The RFID reader 16 is connected to the processor 11 via the interface 16 and to the antenna 7. The RFID reader 16 includes a communication control circuit for transmitting and receiving radio waves for communication with the RFID tag via the antenna 7. The RFID reader 16 emits a radio wave requesting a response to the RFID tag. Further, the RFID reader 16 receives radio waves as a response from the RFID tag via the antenna 7. The RFID reader 16 detects the presence of the RFID tag by a response from the RFID tag. That is, the RFID 16 and the antenna 7 function as a tag detector that detects the RFID tag.

  Further, the processor 11 controls the contents displayed on the display device 4. The processor 11 controls the sound output from the speaker 5. The processor 11 processes information input using the switch 6. For example, the processor 11 receives a heating command by an input to the start switch 6 and determines whether or not heating is required. Further, the processor 11 receives information indicating the detection results of the article sensor 8 and the open / close sensor 9 and performs control according to the detection results of each sensor.

Next, operation | movement of the microwave oven 1 as a heating chamber which concerns on embodiment is demonstrated.
The microwave oven 1 according to the embodiment performs an operation of detecting that an RFID tag is included in an article placed in the heating chamber 2 or an article to be placed in the heating chamber 2. For example, when the microwave oven 1 detects an RFID tag, the microwave oven 1 disables (prohibits) the heat treatment and outputs an alert. Thereby, the microwave oven 1 prevents the article | item with which the RFID tag was attached from being heated in the heating chamber 2. FIG.

First, a first operation example of the microwave oven 1 according to the embodiment will be described.
FIG. 3 is a flowchart for explaining a first operation example in the microwave oven 1 according to the embodiment.
In the first operation example, the processor 11 determines whether or not the door 3 is opened based on the detection result of the open / close sensor 9 (ACT 11). If it is determined that the door 3 has been opened (ACT 11, YES), the processor 11 instructs the RFID reader 16 to radiate radio waves via the interface 15 to radiate radio waves from the antenna 7 (ACT 12). Here, the RFID reader 16 radiates radio waves from the antenna 7 and makes radio waves as a response from the RFID tag receivable.

  The antenna 7 is installed in the heating chamber 2 or in the vicinity of the heating chamber 2. The antenna 7 is configured to radiate radio waves to the communication range including the inside of the heating chamber 2. The RFID tag existing in the communication range is activated by a radio wave from the antenna 7 and transmits a radio wave as a response. That is, the RFID reader 16 irradiates the communication range with a radio wave for communication via the antenna 7 and receives a response from the RFID tag in the communication range.

  The processor 11 determines the presence / absence of an RFID tag in the heating chamber 2 or in the vicinity of the heating chamber 2 based on whether or not the RFID reader 16 receives a response from the RFID tag (ACT 13). That is, when the RFID reader 16 receives a response from the RFID tag, the processor 11 determines that there is an RFID tag in the heating chamber 2 or in the vicinity of the heating chamber 2.

  When it is determined that there is an RFID tag (ACT 13, YES), the processor 11 prohibits the heating process in the heating chamber 2 (ACT 14). For example, the processor 11 sets the setting so that the heating process cannot be performed even when a heating start instruction (heating instruction) is input by a start button or the like (heating disabled setting). If it is determined that there is an RFID tag (ACT13, YES), the processor 11 outputs an alert notifying that there is an RFID tag (ACT15). For example, the processor 11 displays on the display 4 that there is an RFID tag in the heating chamber 2 or in the vicinity of the heating chamber 2 or that heat treatment is not possible. Further, the processor 11 may output an alarm from the speaker 5 as an alert.

On the other hand, if it is determined that there is no RFID tag (ACT 13, NO), the processor 11 cancels the non-heating setting (ACT 16). Here, it is assumed that the processor 11 cancels the non-heating setting when the RFID reader 16 detects that there is no RFID tag in the communication range.
The processor 11 continues the processing of ACT13-16 until the opening / closing sensor 9 detects that the door 3 is closed after the door 3 is opened (ACT17, NO).

  When it is detected that the door 3 is closed (ACT 17, YES), the processor 11 stops the irradiation of radio waves from the antenna 7 by the RFID reader 16 (ACT 18). After stopping the irradiation of radio waves from the antenna 7 as the door 3 is closed, the processor 11 can accept a heating command. For example, when the user closes the door 3 and presses the start button of the switch 6, the processor 11 receives a heating command.

  When the heating command is received (ACT 19, YES), the processor 11 determines whether or not the heating process can be executed (ACT 20). Here, it is assumed that the processor 11 determines whether or not the heat treatment can be performed based on the presence or absence of the heat disabling setting. That is, when the heating impossibility is not set (ACT20, YES), the processor 11 performs a heating process (ACT21). For example, the processor 11 starts the microwave irradiation by the magnetron 14 and executes the heating process in the heating chamber 2.

  Further, when the heating disabled is set (ACT20, NO), the processor 11 disables the heating process. In this case, the processor 11 outputs an alert for warning that the heating process according to the heating command cannot be executed (ACT 22). For example, the processor 11 displays a guide indicating that the heating process cannot be performed because an RFID tag is detected on the display 4. Further, the processor 11 may output an alarm through the speaker 5.

  In the microwave oven of the first operation example, the RFID reader emits radio waves triggered by the opening of the door, and detects the presence or absence of the RFID tag in or near the heating chamber. When the RFID tag is detected, the processor of the microwave oven disables the execution of the heating process and outputs an alert. Thereby, according to the first operation example, when the user opens the door and puts the article to be heated into the heating chamber, the RFID tag attached to the article is detected and the heating process is disabled. be able to. Further, according to the first operation example, when the heat treatment is disabled in response to detection of the RFID tag, an alert is output to alert the user.

Next, a second operation example of the microwave oven 1 according to the embodiment will be described.
FIG. 4 is a flowchart for explaining a second operation example in the microwave oven 1 according to the embodiment.
In the second operation example, the processor 11 determines whether or not an article has been placed in the heating chamber 2 based on the detection result of the article sensor 8 (ACT 31). When the article is detected by the article sensor 8 (ACT31, YES), the processor 11 instructs the RFID reader 16 to radiate radio waves via the interface 15 to radiate radio waves from the antenna 7 (ACT32). Here, the RFID reader 16 irradiates a communication radio wave to the communication range via the antenna 7 so that a response from the RFID tag in the communication range can be received.

  While radiating radio waves from the antenna 7, the processor 11 determines the presence or absence of the RFID tag depending on whether or not the RFID reader 16 has received a response from the RFID tag (ACT 33). When the RFID reader 16 receives a response from the RFID tag, the processor 11 determines that there is an RFID tag in the heating chamber 2.

  When it is determined that there is an RFID tag (ACT 33, YES), the processor 11 prohibits the heating process in the heating chamber 2 (ACT 34). For example, the processor 11 sets the setting so that the heating process cannot be executed even when a heating command is input by a start button or the like (heating disabled setting). If it is determined that there is an RFID tag (ACT 33, YES), the processor 11 outputs an alert notifying that there is an RFID tag (ACT 35). For example, the processor 11 displays on the display 4 that there is an RFID tag in the heating chamber 2 or that heat treatment is not possible. Further, the processor 11 may output an alarm from the speaker 5 as an alert.

On the other hand, if it is determined that there is no RFID tag (ACT 33, NO), the processor 11 cancels the setting that disables heating (ACT 36). Here, it is assumed that the processor 11 cancels the non-heating setting when the RFID reader 16 detects that there is no RFID tag in the communication range.
The processor 11 continues to perform the processing of ACT33-36 until the heating command is received after the article is detected by the article sensor 8 (ACT37, NO).

  When receiving the heating command (ACT 37, YES), the processor 11 stops the irradiation of the radio wave from the antenna 7 by the RFID reader 16 (ACT 38). Further, the processor 11 determines whether or not the heat treatment can be performed (ACT 39). Here, it is assumed that the processor 11 determines whether or not the heat treatment can be performed based on the presence or absence of the heat disabling setting. That is, when the heating impossibility is not set (ACT39, YES), the processor 11 executes the heating process (ACT40). For example, the processor 11 starts the microwave irradiation by the magnetron 14 and executes the heating process in the heating chamber 2.

  Further, when the heating disabled is set (ACT39, NO), the processor 11 disables the heating process. In this case, the processor 11 outputs an alert for warning that the heating process according to the heating command cannot be performed (ACT 41). For example, the processor 11 displays a guide indicating that the heating process cannot be performed because an RFID tag is detected on the display 4. Further, the processor 11 may output an alarm through the speaker 5.

  In the microwave oven of the second operation example, the RFID reader emits radio waves triggered by the detection of the article in the heating chamber, and detects the presence or absence of the RFID tag in the heating chamber. When the RFID tag is detected, the processor of the microwave oven disables the execution of the heating process and outputs an alert. Thus, according to the second operation example, when the user puts the article to be heat-treated into the heating chamber, the RFID tag attached to the article can be detected to disable the heat treatment. Further, according to the second operation example, when the heat treatment is disabled in response to detection of the RFID tag, an alert is output to alert the user.

Next, a third operation example of the microwave oven 1 according to the embodiment will be described.
FIG. 5 is a flowchart for explaining a third operation example in the microwave oven 1 according to the embodiment.
In the third operation example, the processor 11 detects the presence or absence of an RFID tag when receiving a heating command. That is, the processor 11 determines whether or not there is a heating command in a state where the heating command can be received (ACT 51).

  When a heating command is received (ACT 51, YES), the processor 11 instructs the RFID reader 16 to radiate radio waves via the interface 15 to radiate radio waves from the antenna 7 (ACT 52). Here, the RFID reader 16 irradiates a communication radio wave to the communication range via the antenna 7 so that a response from the RFID tag in the communication range can be received.

  While radiating radio waves from the antenna 7, the processor 11 determines the presence or absence of the RFID tag depending on whether or not the RFID reader 16 has received a response from the RFID tag (ACT 53). When the RFID reader 16 receives a response from the RFID tag, the processor 11 determines that there is an RFID tag in the heating chamber 2.

  If it is determined that there is an RFID tag (ACT 53, YES), the processor 11 cancels the received heating command (ACT 54), and outputs an alert notifying that there is an RFID tag (ACT 55). For example, the processor 11 displays on the display 4 that there is an RFID tag in the heating chamber 2 or that heat treatment is not possible. Further, the processor 11 may output an alarm from the speaker 5 as an alert.

  If it is determined that there is no RFID tag (ACT 53, NO), the processor 11 stops the irradiation of radio waves from the antenna 7 by the RFID reader 16 (ACT 56), and executes the heating process (ACT 57). In this case, the processor 11 irradiates the heating chamber 2 with microwaves by the magnetron 14 and executes a heating process on the article in the heating chamber 2.

  In the microwave oven of the third operation example, when a heating command is received, the RFID reader emits radio waves and detects the presence or absence of the RFID tag in the heating chamber. If the RFID tag is detected, the processor of the microwave oven cancels the heating command (makes the heating process impossible) and outputs an alert. Thus, according to the third operation example, when the user inputs a heating command, the RFID tag in the heating chamber can be detected and the heating process can be disabled. Further, according to the third operation example, when an RFID tag is detected, an alert is output to alert the user.

(First modification)
Next, the structural example of the microwave oven which concerns on the 1st modification of embodiment is demonstrated.
FIG. 6 is an external view illustrating a configuration example of the microwave oven 101 according to the first modification.
Similar to the microwave oven 1 shown in FIG. 1, the microwave oven 101 shown in FIG. 6 includes a heating chamber 2, a door 3, a display 4, a speaker 5, a switch 6, an article sensor 8 and an open / close sensor 9. A microwave oven 101 shown in FIG. 6 is provided with a planar antenna 110 in the vicinity of the opening of the heating chamber 2 instead of the antenna 7 installed in the heating chamber 2 of the microwave oven 1 shown in FIG.

  The planar antenna 110 is installed in the heating chamber 2 or in the vicinity of the opening of the heating chamber 2 so as to radiate radio waves to the RFID tag. In the example shown in FIG. 6, the planar antenna 110 is installed above the opening of the heating chamber 2. The planar antenna 110 reads (detects) an RFID tag attached to an article when the user places the article (food) in the heating chamber 2 with the door 3 opened.

  The planar antenna 110 may be installed at a position where the RFID tag attached to the article placed in the heating chamber 2 can be read (communicable), and is limited to the one installed above the opening of the heating chamber 2. It is not a thing. For example, the planar antenna 110 may be installed on the side or in the vicinity of the opening of the heating chamber 2 or may be installed on the door 3 or the like.

  Further, the planar antenna 110 may be configured to be integrated with the housing of the microwave oven 101 when the door 3 is closed, and to protrude above the opening when the door 3 is opened. However, the planar antenna 110 may not be configured to be housed with the door 3 closed, and may be installed on the top surface, bottom surface, or side surface of the main body of the microwave oven 101.

  Note that the microwave oven 101 according to the modification shown in FIG. 6 may have a configuration in which the antenna 7 in the microwave oven 1 shown in FIG. 1 and FIG. For this reason, the microwave oven 101 according to the first modification can realize the same operation as that of the microwave oven 1 described above, and thus a detailed description of the operation example and the like will be omitted.

(Second modification)
Next, a configuration example of a microwave oven according to a second modification of the embodiment will be described.
FIG. 7 is a block diagram illustrating a configuration example of the microwave oven 201 according to the second modification.
A microwave oven 201 according to the second modification shown in FIG. 7 has an interface 215 to which an RFID reader (tag detector) 210 as an external device can be connected. That is, the microwave oven 201 includes an interface 215 that can connect an RFID reader 210 as an external device, instead of omitting the antenna 7 and the RFID reader 16 in the microwave oven 1 shown in FIGS. 1 and 2. The interface 215 includes an external connector provided on the casing of the microwave oven 201 in order to connect to the RFID reader 210 as an external device. The interface 215 may be connected to the RFID reader 210 by wireless communication.

  The RFID reader 210 includes an antenna 211 and a communication control circuit 212. The RFID reader 210 transmits and receives radio waves according to control from the processor 11 of the microwave oven 201 connected via the interface 215. For example, the RFID reader 210 emits radio waves in accordance with an instruction from the processor 11 and supplies information read from the RFID tag to the processor 11. With this configuration, the RFID reader 210 functions as a tag detector that can be controlled by the processor 11.

  The RFID reader 210 as an external device connected to the microwave oven 201 may be installed at a position where an RFID tag attached to an article placed in the heating chamber 2 can be read (communicable). For example, the RFID reader 210 may be installed on the upper part, the lower part, or the side part of the main body of the microwave oven 201, or may be installed so as to be attached to the door 3. Further, the RFID reader 210 may be disposed at a position away from the microwave oven 201 as long as it can irradiate the heating chamber 2 with radio waves.

  7 is the same as the microwave oven 1 shown in FIGS. 1 and 2 except for the antenna 7, the RFID reader 16, and the interface 15. Is omitted. The microwave oven 201 is the same as the microwave oven 1 shown in FIGS. 1 and 2 except that the antenna 7 and the RFID reader 16 can be connected as external devices. That is, the microwave oven 201 according to the second modified example can realize the same operation as that of the microwave oven 1 described above, and thus a detailed description of the operation example is omitted.

  According to the embodiment as described above, the microwave oven as the cooking device can be prevented from performing the heat treatment with the RFID tag placed in the heating chamber. Furthermore, according to the embodiment, the microwave oven as the heating cooker can output an alert when the RFID tag is detected, and can prompt the user to remove the RFID tag from the heating chamber. .

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1, 101, 201 ... Microwave oven (heating cooking machine), 2 ... Heating chamber, 3 ... Door, 4 ... Display device (notifier), 5 ... Speaker (notifier), 6 ... Switch, 7, 110, 211 ... Antenna, 8 ... Article sensor, 9 ... Open / close sensor, 11 ... Processor, 12 ... Memory, 15, 215 ... Interface, 16, 212 ... Communication control circuit.

Claims (5)

An interface connected to an RFID reader that receives a response from the RFID tag to radio waves irradiated into the heating chamber via the antenna;
When the RFID reader receives a response from the RFID tag after radiating radio waves from the antenna, a processor that disables the heating process in the heating chamber;
Having a heating cooker. An alarm that outputs an alert,
The processor outputs an alert by the alarm when the RFID reader receives a response signal from the RFID tag.
The cooking device according to claim 1. An openable / closable door provided in the heating chamber;
An opening / closing sensor for detecting opening / closing of the door,
The processor emits radio waves from the antenna when the open / close sensor detects the opening of the door;
The heating cooking machine of any one of Claim 1 or 2. An article sensor that detects that an article is installed on the installation table in the heating chamber; and the processor detects the antenna when the article sensor detects that an article is installed on the installation table in the heating chamber. Irradiate radio waves from
The heating cooking machine of any one of Claim 1 or 2. Has a switch to instruct the heat treatment,
The processor emits radio waves from the antenna after the switch is instructed to start heat treatment,
The heating cooking machine of any one of Claim 1 or 2.